update serTcpOpen declaration to fix compile errors (#14113)
[betaflight.git] / lib / main / BoschSensortec / BMI270-Sensor-API / bmi2.c
blob556039a1a4050387865ce10b83471a414cb96f1d
1 /**
2 * Copyright (c) 2020 Bosch Sensortec GmbH. All rights reserved.
4 * BSD-3-Clause
6 * Redistribution and use in source and binary forms, with or without
7 * modification, are permitted provided that the following conditions are met:
9 * 1. Redistributions of source code must retain the above copyright
10 * notice, this list of conditions and the following disclaimer.
12 * 2. Redistributions in binary form must reproduce the above copyright
13 * notice, this list of conditions and the following disclaimer in the
14 * documentation and/or other materials provided with the distribution.
16 * 3. Neither the name of the copyright holder nor the names of its
17 * contributors may be used to endorse or promote products derived from
18 * this software without specific prior written permission.
20 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
21 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
22 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
23 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
24 * COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
25 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
26 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
27 * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
28 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
29 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
30 * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
31 * POSSIBILITY OF SUCH DAMAGE.
33 * @file bmi2.c
34 * @date 2020-11-04
35 * @version v2.63.1
39 /******************************************************************************/
41 /*! @name Header Files */
42 /******************************************************************************/
43 #include "bmi2.h"
45 /***************************************************************************/
47 /*! Local structures
48 ****************************************************************************/
50 /*! @name Structure to define the difference in accelerometer values */
51 struct bmi2_selftest_delta_limit
53 /*! X data */
54 int32_t x;
56 /*! Y data */
57 int32_t y;
59 /*! Z data */
60 int32_t z;
63 /*! @name Structure to store temporary accelerometer/gyroscope values */
64 struct bmi2_foc_temp_value
66 /*! X data */
67 int32_t x;
69 /*! Y data */
70 int32_t y;
72 /*! Z data */
73 int32_t z;
76 /*! @name Structure to store accelerometer data deviation from ideal value */
77 struct bmi2_offset_delta
79 /*! X axis */
80 int16_t x;
82 /*! Y axis */
83 int16_t y;
85 /*! Z axis */
86 int16_t z;
89 /*! @name Structure to store accelerometer offset values */
90 struct bmi2_accel_offset
92 /*! offset X data */
93 uint8_t x;
95 /*! offset Y data */
96 uint8_t y;
98 /*! offset Z data */
99 uint8_t z;
102 /******************************************************************************/
104 /*! Local Function Prototypes
105 ******************************************************************************/
108 * @brief This internal API writes the configuration file.
110 * @param[in] dev : Structure instance of bmi2_dev.
112 * @return Result of API execution status
113 * @retval 0 -> Success
114 * @retval < 0 -> Fail
116 static int8_t write_config_file(struct bmi2_dev *dev);
119 * @brief This internal API enables/disables the loading of the configuration
120 * file.
122 * @param[in] enable : To enable/disable configuration load.
123 * @param[in] dev : Structure instance of bmi2_dev.
125 * @return Result of API execution status
126 * @retval 0 -> Success
127 * @retval < 0 -> Fail
129 static int8_t set_config_load(uint8_t enable, struct bmi2_dev *dev);
132 * @brief This internal API loads the configuration file.
134 * @param[in] config_data : Pointer to the configuration file.
135 * @param[in] index : Variable to define array index.
136 * @param[in] dev : Structure instance of bmi2_dev.
138 * @return Result of API execution status
139 * @retval 0 -> Success
140 * @retval < 0 -> Fail
142 static int8_t upload_file(const uint8_t *config_data, uint16_t index, uint16_t write_len, struct bmi2_dev *dev);
145 * @brief This internal API sets accelerometer configurations like ODR,
146 * bandwidth, performance mode and g-range.
148 * @param[in,out] config : Structure instance of bmi2_accel_config.
149 * @param[in,out] dev : Structure instance of bmi2_dev.
151 * @return Result of API execution status
152 * @retval 0 -> Success
153 * @retval < 0 -> Fail
155 static int8_t set_accel_config(struct bmi2_accel_config *config, struct bmi2_dev *dev);
158 * @brief This internal API validates bandwidth and performance mode of the
159 * accelerometer set by the user.
161 * @param[in, out] bandwidth : Pointer to bandwidth value set by the user.
162 * @param[in, out] perf_mode : Pointer to performance mode set by the user.
163 * @param[in, out] dev : Structure instance of bmi2_dev.
165 * @note dev->info contains two warnings: BMI2_I_MIN_VALUE and BMI2_I_MAX_VALUE
167 * @return Result of API execution status
168 * @retval 0 -> Success
169 * @retval < 0 -> Fail
171 static int8_t validate_bw_perf_mode(uint8_t *bandwidth, uint8_t *perf_mode, struct bmi2_dev *dev);
174 * @brief This internal API validates ODR and range of the accelerometer set by
175 * the user.
177 * @param[in, out] odr : Pointer to ODR value set by the user.
178 * @param[in, out] range : Pointer to range value set by the user.
179 * @param[in, out] dev : Structure instance of bmi2_dev.
181 * @note dev->info contains two warnings: BMI2_I_MIN_VALUE and BMI2_I_MAX_VALUE
183 * @return Result of API execution status
184 * @retval 0 -> Success
185 * @retval < 0 -> Fail
187 static int8_t validate_odr_range(uint8_t *odr, uint8_t *range, struct bmi2_dev *dev);
190 * @brief This internal API sets gyroscope configurations like ODR, bandwidth,
191 * low power/high performance mode, performance mode and range.
193 * @param[in,out] config : Structure instance of bmi2_gyro_config.
194 * @param[in,out] dev : Structure instance of bmi2_dev.
196 * @return Result of API execution status
197 * @retval 0 -> Success
198 * @retval < 0 -> Fail
200 static int8_t set_gyro_config(struct bmi2_gyro_config *config, struct bmi2_dev *dev);
203 * @brief This internal API validates bandwidth, performance mode, low power/
204 * high performance mode, ODR, and range set by the user.
206 * @param[in] config : Structure instance of bmi2_gyro_config.
207 * @param[in] dev : Structure instance of bmi2_dev.
209 * @note dev->info contains two warnings: BMI2_I_MIN_VALUE and BMI2_I_MAX_VALUE
211 * @return Result of API execution status
212 * @retval 0 -> Success
213 * @retval < 0 -> Fail
215 static int8_t validate_gyro_config(struct bmi2_gyro_config *config, struct bmi2_dev *dev);
218 * @brief This internal API shows the error status when illegal sensor
219 * configuration is set.
221 * @param[in] dev : Structure instance of bmi2_dev.
223 * @return Result of API execution status
224 * @retval 0 -> Success
225 * @retval < 0 -> Fail
227 static int8_t cfg_error_status(struct bmi2_dev *dev);
230 * @brief This internal API:
231 * 1) Enables/Disables auxiliary interface.
232 * 2) Sets auxiliary interface configurations like I2C address, manual/auto
233 * mode enable, manual burst read length, AUX burst read length and AUX read
234 * address.
235 * 3)It maps/un-maps data interrupts to that of hardware interrupt line.
237 * @param[in] config : Structure instance of bmi2_aux_config.
238 * @param[in, out] dev : Structure instance of bmi2_dev.
240 * @return Result of API execution status
241 * @retval 0 -> Success
242 * @retval < 0 -> Fail
244 static int8_t set_aux_config(struct bmi2_aux_config *config, struct bmi2_dev *dev);
247 * @brief This internal API sets gyroscope user-gain configurations like gain
248 * update value for x, y and z-axis.
250 * @param[in] config : Structure instance of bmi2_gyro_user_gain_config.
251 * @param[in] dev : Structure instance of bmi2_dev.
253 * @verbatim
254 *----------------------------------------------------------------------------
255 * bmi2_gyro_user_gain_config|
256 * Structure parameters | Description
257 *--------------------------|--------------------------------------------------
258 * ratio_x | Gain update value for x-axis
259 * -------------------------|---------------------------------------------------
260 * ratio_y | Gain update value for y-axis
261 * -------------------------|---------------------------------------------------
262 * ratio_z | Gain update value for z-axis
263 * @endverbatim
265 * @return Result of API execution status
266 * @retval 0 -> Success
267 * @retval < 0 -> Fail
269 static int8_t set_gyro_user_gain_config(const struct bmi2_gyro_user_gain_config *config, struct bmi2_dev *dev);
272 * @brief This internal API enables/disables auxiliary interface.
274 * @param[in] config : Structure instance of bmi2_aux_config.
275 * @param[in] dev : Structure instance of bmi2_dev.
277 * @return Result of API execution status
278 * @retval 0 -> Success
279 * @retval < 0 -> Fail
281 static int8_t set_aux_interface(const struct bmi2_aux_config *config, struct bmi2_dev *dev);
284 * @brief This internal API sets auxiliary configurations like manual/auto mode
285 * FCU write command enable and read burst length for both data and manual mode.
287 * @param[in] config : Structure instance of bmi2_aux_config.
288 * @param[in] dev : Structure instance of bmi2_dev.
290 * @note Auxiliary sensor should not be busy when configuring aux_i2c_addr,
291 * man_rd_burst_len, aux_rd_burst_len and aux_rd_addr.
293 * @return Result of API execution status
294 * @retval 0 -> Success
295 * @retval < 0 -> Fail
297 static int8_t config_aux_interface(const struct bmi2_aux_config *config, struct bmi2_dev *dev);
300 * @brief This internal API triggers read out offset and sets ODR of the
301 * auxiliary sensor.
303 * @param[in] config : Structure instance of bmi2_aux_config.
304 * @param[in] dev : Structure instance of bmi2_dev.
306 * @return Result of API execution status
307 * @retval 0 -> Success
308 * @retval < 0 -> Fail
310 static int8_t config_aux(const struct bmi2_aux_config *config, struct bmi2_dev *dev);
313 * @brief This internal API validates auxiliary configuration set by the user.
315 * @param[in, out] config : Structure instance of bmi2_aux_config.
316 * @param[in, out] dev : Structure instance of bmi2_dev.
318 * @note dev->info contains two warnings: BMI2_I_MIN_VALUE and BMI2_I_MAX_VALUE
320 * @return Result of API execution status
321 * @retval 0 -> Success
322 * @retval < 0 -> Fail
324 static int8_t validate_aux_config(struct bmi2_aux_config *config, struct bmi2_dev *dev);
327 * @brief This internal API gets accelerometer configurations like ODR,
328 * bandwidth, performance mode and g-range.
330 * @param[out] config : Structure instance of bmi2_accel_config.
331 * @param[in] dev : Structure instance of bmi2_dev.
333 * @return Result of API execution status
334 * @retval 0 -> Success
335 * @retval < 0 -> Fail
337 static int8_t get_accel_config(struct bmi2_accel_config *config, struct bmi2_dev *dev);
340 * @brief This internal API gets gyroscope configurations like ODR, bandwidth,
341 * low power/ high performance mode, performance mode and range.
343 * @param[out] config : Structure instance of bmi2_gyro_config.
344 * @param[in] dev : Structure instance of bmi2_dev.
346 * @return Result of API execution status
347 * @retval 0 -> Success
348 * @retval < 0 -> Fail
350 static int8_t get_gyro_config(struct bmi2_gyro_config *config, struct bmi2_dev *dev);
353 * @brief This internal API:
354 * 1) Gets the status of auxiliary interface enable.
355 * 2) Gets auxiliary interface configurations like I2C address, manual/auto
356 * mode enable, manual burst read length, AUX burst read length and AUX read
357 * address.
358 * 3) Gets ODR and offset.
360 * @param[out] config : Structure instance of bmi2_aux_config.
361 * @param[in] dev : Structure instance of bmi2_dev.
363 * @return Result of API execution status
364 * @retval 0 -> Success
365 * @retval < 0 -> Fail
367 static int8_t get_aux_config(struct bmi2_aux_config *config, struct bmi2_dev *dev);
370 * @brief This internal API gets gyroscope user-gain configurations like gain
371 * update value for x, y and z-axis.
373 * @param[out] config : Structure instance of bmi2_gyro_user_gain_config.
374 * @param[in] dev : Structure instance of bmi2_dev.
376 * @verbatim
377 *----------------------------------------------------------------------------
378 * bmi2_gyro_user_gain_config|
379 * Structure parameters | Description
380 *-------------------------|--------------------------------------------------
381 * ratio_x | Gain update value for x-axis
382 * ------------------------|---------------------------------------------------
383 * ratio_y | Gain update value for y-axis
384 * ------------------------|---------------------------------------------------
385 * ratio_z | Gain update value for z-axis
387 * @endverbatim
389 * @return Result of API execution status
390 * @retval 0 -> Success
391 * @retval < 0 -> Fail
393 static int8_t get_gyro_gain_update_config(struct bmi2_gyro_user_gain_config *config, struct bmi2_dev *dev);
396 * @brief This internal API gets the enable status of auxiliary interface.
398 * @param[out] config : Structure instance of bmi2_aux_config.
399 * @param[in] dev : Structure instance of bmi2_dev.
401 * @return Result of API execution status
402 * @retval 0 -> Success
403 * @retval < 0 -> Fail
405 static int8_t get_aux_interface(struct bmi2_aux_config *config, struct bmi2_dev *dev);
408 * @brief This internal API gets auxiliary configurations like manual/auto mode
409 * FCU write command enable and read burst length for both data and manual mode.
411 * @param[out] config : Structure instance of bmi2_aux_config.
412 * @param[in] dev : Structure instance of bmi2_dev.
414 * @return Result of API execution status
415 * @retval 0 -> Success
416 * @retval < 0 -> Fail
418 static int8_t get_aux_interface_config(struct bmi2_aux_config *config, struct bmi2_dev *dev);
421 * @brief This internal API gets read out offset and ODR of the auxiliary
422 * sensor.
424 * @param[out] config : Structure instance of bmi2_aux_config.
425 * @param[in] dev : Structure instance of bmi2_dev.
427 * @return Result of API execution status
428 * @retval 0 -> Success
429 * @retval < 0 -> Fail
431 static int8_t get_aux_cfg(struct bmi2_aux_config *config, struct bmi2_dev *dev);
434 * @brief This internal API gets the saturation status for the gyroscope user
435 * gain update.
437 * @param[out] user_gain_stat : Stores the saturation status of the axes.
438 * @param[in] dev : Structure instance of bmi2_dev.
440 * @return Result of API execution status
441 * @retval 0 -> Success
442 * @retval < 0 -> Fail
444 static int8_t get_gyro_gain_update_status(struct bmi2_gyr_user_gain_status *user_gain, struct bmi2_dev *dev);
447 * @brief This internal API is used to extract the output feature configuration
448 * details like page and start address from the look-up table.
450 * @param[out] feat_output : Structure that stores output feature
451 * configurations.
452 * @param[in] type : Type of feature or sensor.
453 * @param[in] dev : Structure instance of bmi2_dev.
455 * @return Returns the feature found flag.
457 * @retval BMI2_FALSE : Feature not found
458 * BMI2_TRUE : Feature found
460 static uint8_t extract_output_feat_config(struct bmi2_feature_config *feat_output,
461 uint8_t type,
462 const struct bmi2_dev *dev);
465 * @brief This internal API gets the cross sensitivity coefficient between
466 * gyroscope's X and Z axes.
468 * @param[out] cross_sense : Pointer to the stored cross sensitivity
469 * coefficient.
470 * @param[in] dev : Structure instance of bmi2_dev.
472 * @return Result of API execution status
473 * @retval 0 -> Success
474 * @retval < 0 -> Fail
476 static int8_t get_gyro_cross_sense(int16_t *cross_sense, struct bmi2_dev *dev);
479 * @brief This internal API gets the accelerometer data from the register.
481 * @param[out] data : Structure instance of sensor_data.
482 * @param[in] reg_addr : Register address where data is stored.
483 * @param[in] dev : Structure instance of bmi2_dev.
485 * @return Result of API execution status
486 * @retval 0 -> Success
487 * @retval < 0 -> Fail
489 static int8_t get_accel_sensor_data(struct bmi2_sens_axes_data *data, uint8_t reg_addr, struct bmi2_dev *dev);
492 * @brief This internal API gets the gyroscope data from the register.
494 * @param[out] data : Structure instance of sensor_data.
495 * @param[in] reg_addr : Register address where data is stored.
496 * @param[in] dev : Structure instance of bmi2_dev.
498 * @return Result of API execution status
499 * @retval 0 -> Success
500 * @retval < 0 -> Fail
502 static int8_t get_gyro_sensor_data(struct bmi2_sens_axes_data *data, uint8_t reg_addr, struct bmi2_dev *dev);
505 * @brief This internal API gets the accelerometer/gyroscope data.
507 * @param[out] data : Structure instance of sensor_data.
508 * @param[in] reg_data : Data stored in the register.
510 * @return None
512 * @retval None
514 static void get_acc_gyr_data(struct bmi2_sens_axes_data *data, const uint8_t *reg_data);
517 * @brief This internal API gets the re-mapped accelerometer/gyroscope data.
519 * @param[out] data : Structure instance of sensor_data.
520 * @param[in] dev : Structure instance of bmi2_dev.
522 * @return None
524 * @retval None
526 static void get_remapped_data(struct bmi2_sens_axes_data *data, const struct bmi2_dev *dev);
529 * @brief This internal API reads the user-defined bytes of data from the given
530 * register address of auxiliary sensor in data mode.
532 * @param[out] aux_data : Pointer to the stored auxiliary data.
533 * @param[in] dev : Structure instance of bmi2_dev.
535 * @return Result of API execution status
536 * @retval 0 -> Success
537 * @retval < 0 -> Fail
539 static int8_t read_aux_data_mode(uint8_t *aux_data, struct bmi2_dev *dev);
542 * @brief This internal API reads the user-defined bytes of data from the given
543 * register address of auxiliary sensor in manual mode.
545 * @param[in] reg_addr : AUX address from where data is read.
546 * @param[out] aux_data : Pointer to the stored auxiliary data.
547 * @param[in] len : Total bytes to be read.
548 * @param[in] burst_len : Bytes of data to be read in bursts.
549 * @param[in] dev : Structure instance of bmi2_dev.
551 * @return Result of API execution status
552 * @retval 0 -> Success
553 * @retval < 0 -> Fail
555 static int8_t read_aux_data(uint8_t reg_addr, uint8_t *aux_data, uint16_t len, uint8_t burst_len, struct bmi2_dev *dev);
558 * @brief This internal API checks the busy status of auxiliary sensor and sets
559 * the auxiliary register addresses when not busy.
561 * @param[in] reg_addr : Address in which AUX register address is
562 * set.
563 * @param[in] reg_data : Auxiliary register address to be set when AUX is
564 * not busy.
565 * @param[in] dev : Structure instance of bmi2_dev.
567 * @return Result of API execution status
568 * @retval 0 -> Success
569 * @retval < 0 -> Fail
571 static int8_t set_if_aux_not_busy(uint8_t reg_addr, uint8_t reg_data, struct bmi2_dev *dev);
574 * @brief his internal API maps the actual burst read length with that of the
575 * register value set by user.
577 * @param[out] len : Actual burst length.
578 * @param[in] dev : Structure instance of bmi2_dev.
580 * @return Result of API execution status
581 * @retval 0 -> Success
582 * @retval < 0 -> Fail
584 static int8_t map_read_len(uint8_t *len, const struct bmi2_dev *dev);
587 * @brief This internal API writes AUX write address and the user-defined bytes
588 * of data to the AUX sensor in manual mode.
590 * @note Change of BMI2_AUX_WR_ADDR is only allowed if AUX is not busy.
592 * @param[in] reg_addr : AUX address in which data is to be written.
593 * @param[in] reg_data : Data to be written
594 * @param[in] dev : Structure instance of bmi2_dev.
596 * @note Change of BMI2_AUX_WR_ADDR is only allowed if AUX is not busy.
598 * @return Result of API execution status
599 * @retval 0 -> Success
600 * @retval < 0 -> Fail
602 static int8_t write_aux_data(uint8_t reg_addr, uint8_t reg_data, struct bmi2_dev *dev);
605 * @brief This internal API maps/unmaps feature interrupts to that of interrupt
606 * pins.
608 * @param[in] int_pin : Interrupt pin selected.
609 * @param[in] feat_int : Type of feature interrupt to be mapped.
610 * @param[in] dev : Structure instance of bmi2_dev.
612 * @return Result of API execution status
613 * @retval 0 -> Success
614 * @retval < 0 -> Fail
616 static int8_t map_feat_int(uint8_t *reg_data_array, enum bmi2_hw_int_pin int_pin, uint8_t int_mask);
619 * @brief This internal API computes the number of bytes of accelerometer FIFO
620 * data which is to be parsed in header-less mode.
622 * @param[out] start_idx : The start index for parsing data.
623 * @param[out] len : Number of bytes to be parsed.
624 * @param[in] acc_count : Number of accelerometer frames to be read.
625 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
627 * @return Result of API execution status
628 * @retval 0 -> Success
629 * @retval < 0 -> Fail
631 static int8_t parse_fifo_accel_len(uint16_t *start_idx,
632 uint16_t *len,
633 const uint16_t *acc_count,
634 const struct bmi2_fifo_frame *fifo);
637 * @brief This internal API is used to parse accelerometer data from the FIFO
638 * data in header mode.
640 * @param[out] acc : Structure instance of bmi2_sens_axes_data where
641 * the parsed accelerometer data bytes are stored.
642 * @param[in] accel_length : Number of accelerometer frames (x,y,z data).
643 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
644 * @param[in] dev : Structure instance of bmi2_dev.
646 * @return Result of API execution status
647 * @retval 0 -> Success
648 * @retval < 0 -> Fail
650 static int8_t extract_accel_header_mode(struct bmi2_sens_axes_data *acc,
651 uint16_t *accel_length,
652 struct bmi2_fifo_frame *fifo,
653 const struct bmi2_dev *dev);
656 * @brief This internal API is used to parse the accelerometer data from the
657 * FIFO data in both header and header-less mode. It updates the current data
658 * byte to be parsed.
660 * @param[in,out] acc : Structure instance of bmi2_sens_axes_data where
661 * where the parsed data bytes are stored.
662 * @param[in,out] idx : Index value of number of bytes parsed.
663 * @param[in,out] acc_idx : Index value of accelerometer data (x,y,z axes)
664 * frame to be parsed.
665 * @param[in] frame : Either data is enabled by user in header-less
666 * mode or header frame value in header mode.
667 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
668 * @param[in] dev : Structure instance of bmi2_dev.
670 * @return Result of API execution status
671 * @retval 0 -> Success
672 * @retval < 0 -> Fail
674 static int8_t unpack_accel_frame(struct bmi2_sens_axes_data *acc,
675 uint16_t *idx,
676 uint16_t *acc_idx,
677 uint8_t frame,
678 const struct bmi2_fifo_frame *fifo,
679 const struct bmi2_dev *dev);
682 * @brief This internal API is used to parse accelerometer data from the FIFO
683 * data.
685 * @param[out] acc : Structure instance of bmi2_sens_axes_data
686 * where the parsed data bytes are stored.
687 * @param[in] data_start_index : Index value of the accelerometer data bytes
688 * which is to be parsed from the FIFO data.
689 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
690 * @param[in] dev : Structure instance of bmi2_dev.
692 * @return None
693 * @retval None
695 static void unpack_accel_data(struct bmi2_sens_axes_data *acc,
696 uint16_t data_start_index,
697 const struct bmi2_fifo_frame *fifo,
698 const struct bmi2_dev *dev);
701 * @brief This internal API computes the number of bytes of gyroscope FIFO data
702 * which is to be parsed in header-less mode.
704 * @param[out] start_idx : The start index for parsing data.
705 * @param[out] len : Number of bytes to be parsed.
706 * @param[in] gyr_count : Number of gyroscope frames to be read.
707 * @param[in] frame : Either data enabled by user in header-less
708 * mode or header frame value in header mode.
709 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
711 * @return Result of API execution status
712 * @retval 0 -> Success
713 * @retval < 0 -> Fail
715 static int8_t parse_fifo_gyro_len(uint16_t *start_idx,
716 uint16_t(*len),
717 const uint16_t *gyr_count,
718 const struct bmi2_fifo_frame *fifo);
721 * @brief This internal API is used to parse the gyroscope data from the FIFO
722 * data in both header and header-less mode It updates the current data byte to
723 * be parsed.
725 * @param[in,out] gyr : Structure instance of bmi2_sens_axes_data.
726 * @param[in,out] idx : Index value of number of bytes parsed
727 * @param[in,out] gyr_idx : Index value of gyroscope data (x,y,z axes)
728 * frame to be parsed.
729 * @param[in] frame : Either data is enabled by user in header-less
730 * mode or header frame value in header mode.
731 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
732 * @param[in] dev : Structure instance of bmi2_dev.
734 * @return Result of API execution status
735 * @retval 0 -> Success
736 * @retval < 0 -> Fail
738 static int8_t unpack_gyro_frame(struct bmi2_sens_axes_data *gyr,
739 uint16_t *idx,
740 uint16_t *gyr_idx,
741 uint8_t frame,
742 const struct bmi2_fifo_frame *fifo,
743 const struct bmi2_dev *dev);
746 * @brief This internal API is used to parse gyroscope data from the FIFO data.
748 * @param[out] gyr : Structure instance of bmi2_sens_axes_data where
749 * the parsed gyroscope data bytes are stored.
750 * @param[in] data_start_index : Index value of the gyroscope data bytes
751 * which is to be parsed from the FIFO data.
752 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
753 * @param[in] dev : Structure instance of bmi2_dev.
755 * @return None
756 * @retval None
758 static void unpack_gyro_data(struct bmi2_sens_axes_data *gyr,
759 uint16_t data_start_index,
760 const struct bmi2_fifo_frame *fifo,
761 const struct bmi2_dev *dev);
764 * @brief This internal API is used to parse the gyroscope data from the
765 * FIFO data in header mode.
767 * @param[out] gyr : Structure instance of bmi2_sens_axes_data where
768 * the parsed gyroscope data bytes are stored.
769 * @param[in] gyro_length : Number of gyroscope frames (x,y,z data).
770 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
771 * @param[in] dev : Structure instance of bmi2_dev.
773 * @return Result of API execution status
774 * @retval 0 -> Success
775 * @retval < 0 -> Fail
777 static int8_t extract_gyro_header_mode(struct bmi2_sens_axes_data *gyr,
778 uint16_t *gyro_length,
779 struct bmi2_fifo_frame *fifo,
780 const struct bmi2_dev *dev);
783 * @brief This API computes the number of bytes of auxiliary FIFO data
784 * which is to be parsed in header-less mode.
786 * @param[out] start_idx : The start index for parsing data.
787 * @param[out] len : Number of bytes to be parsed.
788 * @param[in] aux_count : Number of accelerometer frames to be read.
789 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
791 * @return Result of API execution status
792 * @retval 0 -> Success
793 * @retval < 0 -> Fail
795 static int8_t parse_fifo_aux_len(uint16_t *start_idx,
796 uint16_t(*len),
797 const uint16_t *aux_count,
798 const struct bmi2_fifo_frame *fifo);
801 * @brief This API is used to parse auxiliary data from the FIFO data.
803 * @param[out] aux : Pointer to buffer where the parsed auxiliary data
804 * bytes are stored.
805 * @param[in] aux_length : Number of auxiliary frames (x,y,z data).
806 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
807 * @param[in] dev : Structure instance of bmi2_dev.
809 * @return Result of API execution status
810 * @retval 0 -> Success
811 * @retval < 0 -> Fail
813 static int8_t extract_aux_header_mode(struct bmi2_aux_fifo_data *aux,
814 uint16_t *aux_length,
815 struct bmi2_fifo_frame *fifo,
816 const struct bmi2_dev *dev);
819 * @brief This API is used to parse the auxiliary data from the FIFO data in
820 * both header and header-less mode. It updates the current data byte to be
821 * parsed.
823 * @param[out] aux : Pointer to structure where the parsed auxiliary data
824 * bytes are stored.
825 * @param[in,out] idx : Index value of number of bytes parsed
826 * @param[in,out] aux_idx : Index value of auxiliary data (x,y,z axes)
827 * frame to be parsed
828 * @param[in] frame : Either data is enabled by user in header-less
829 * mode or header frame value in header mode.
830 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
831 * @param[in] dev : Structure instance of bmi2_dev.
833 * @return Result of API execution status
834 * @retval 0 -> Success
835 * @retval < 0 -> Fail
837 static int8_t unpack_aux_frame(struct bmi2_aux_fifo_data *aux,
838 uint16_t *idx,
839 uint16_t *aux_idx,
840 uint8_t frame,
841 const struct bmi2_fifo_frame *fifo,
842 const struct bmi2_dev *dev);
845 * @brief This API is used to parse auxiliary data from the FIFO data.
847 * @param[out] aux : Pointer to structure where the parsed
848 * auxiliary data bytes are stored.
849 * @param[in] data_start_index : Index value of the auxiliary data bytes which
850 * is to be parsed from the FIFO data.
851 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
853 * @return None
854 * @retval None
856 static void unpack_aux_data(struct bmi2_aux_fifo_data *aux,
857 uint16_t data_start_index,
858 const struct bmi2_fifo_frame *fifo);
861 * @brief This internal API is used to reset the FIFO related configurations
862 * in the FIFO frame structure for the next FIFO read.
864 * @param[in, out] fifo : Structure instance of bmi2_fifo_frame.
865 * @param[in] dev : Structure instance of bmi2_dev.
867 * @return None
868 * @retval None
870 static void reset_fifo_frame_structure(struct bmi2_fifo_frame *fifo, const struct bmi2_dev *dev);
873 * @brief This internal API checks whether the FIFO data read is an empty frame.
874 * If empty frame, index is moved to the last byte.
876 * @param[in,out] data_index : The index of the current data to be parsed from
877 * FIFO data.
878 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
880 * @return Result of API execution status
882 * @retval BMI2_OK - Success.
883 * @retval BMI2_W_FIFO_EMPTY - Warning : FIFO is empty
884 * @retval BMI2_W_PARTIAL_READ - Warning : There are more frames to be read
886 static int8_t check_empty_fifo(uint16_t *data_index, const struct bmi2_fifo_frame *fifo);
889 * @brief This internal API is used to move the data index ahead of the
890 * current frame length parameter when unnecessary FIFO data appears while
891 * extracting the user specified data.
893 * @param[in,out] data_index : Index of the FIFO data which is to be
894 * moved ahead of the current frame length
895 * @param[in] current_frame_length : Number of bytes in the current frame.
896 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
898 * @return Result of API execution status
899 * @retval 0 -> Success
900 * @retval < 0 -> Fail
902 static int8_t move_next_frame(uint16_t *data_index, uint8_t current_frame_length, const struct bmi2_fifo_frame *fifo);
905 * @brief This internal API is used to parse and store the sensor time from the
906 * FIFO data.
908 * @param[in,out] data_index : Index of the FIFO data which has the sensor time.
909 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
911 * @return Result of API execution status
912 * @retval 0 -> Success
913 * @retval < 0 -> Fail
915 static int8_t unpack_sensortime_frame(uint16_t *data_index, struct bmi2_fifo_frame *fifo);
918 * @brief This internal API is used to parse and store the skipped frame count
919 * from the FIFO data.
921 * @param[in,out] data_index : Index of the FIFO data which contains skipped
922 * frame count.
923 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
925 * @return Result of API execution status
926 * @retval 0 -> Success
927 * @retval < 0 -> Fail
929 static int8_t unpack_skipped_frame(uint16_t *data_index, struct bmi2_fifo_frame *fifo);
932 * @brief This internal API enables and configures the accelerometer which is
933 * needed for self-test operation. It also sets the amplitude for the self-test.
935 * @param[in] dev : Structure instance of bmi2_dev.
937 * @return Result of API execution status
938 * @retval 0 -> Success
939 * @retval < 0 -> Fail
941 static int8_t pre_self_test_config(struct bmi2_dev *dev);
944 * @brief This internal API performs the steps needed for self-test operation
945 * before reading the accelerometer self-test data.
947 * @param[in] sign : Selects sign of self-test excitation
948 * @param[in] dev : Structure instance of bmi2_dev.
950 * sign | Description
951 * -------------|---------------
952 * BMI2_ENABLE | positive excitation
953 * BMI2_DISABLE | negative excitation
955 * @return Result of API execution status
956 * @retval 0 -> Success
957 * @retval < 0 -> Fail
959 static int8_t self_test_config(uint8_t sign, struct bmi2_dev *dev);
962 * @brief This internal API enables or disables the accelerometer self-test
963 * feature in the sensor.
965 * @param[in] enable : Enables/ Disables self-test.
966 * @param[in] dev : Structure instance of bmi2_dev.
968 * sign | Description
969 * -------------|---------------
970 * BMI2_ENABLE | Enables self-test
971 * BMI2_DISABLE | Disables self-test
973 * @return Result of API execution status
974 * @retval 0 -> Success
975 * @retval < 0 -> Fail
977 static int8_t set_accel_self_test_enable(uint8_t enable, struct bmi2_dev *dev);
980 * @brief This internal API selects the sign for accelerometer self-test
981 * excitation.
983 * @param[in] sign : Selects sign of self-test excitation
984 * @param[in] dev : Structure instance of bmi2_dev.
986 * sign | Description
987 * -------------|---------------
988 * BMI2_ENABLE | positive excitation
989 * BMI2_DISABLE | negative excitation
991 * @return Result of API execution status
992 * @retval 0 -> Success
993 * @retval < 0 -> Fail
995 static int8_t set_acc_self_test_sign(uint8_t sign, struct bmi2_dev *dev);
998 * @brief This internal API sets the amplitude of the accelerometer self-test
999 * deflection in the sensor.
1001 * @param[in] amp : Select amplitude of the self-test deflection.
1002 * @param[in] dev : Structure instance of bmi2_dev.
1004 * amp | Description
1005 * -------------|---------------
1006 * BMI2_ENABLE | self-test amplitude is high
1007 * BMI2_DISABLE | self-test amplitude is low
1009 * @return Result of API execution status
1010 * @retval 0 -> Success
1011 * @retval < 0 -> Fail
1013 static int8_t set_accel_self_test_amp(uint8_t amp, struct bmi2_dev *dev);
1016 * @brief This internal API reads the accelerometer data for x,y and z axis from
1017 * the sensor. The data units is in LSB format.
1019 * @param[out] accel : Buffer to store the acceleration value.
1020 * @param[in] dev : Structure instance of bmi2_dev.
1022 * @return Result of API execution status
1023 * @retval 0 -> Success
1024 * @retval < 0 -> Fail
1026 static int8_t read_accel_xyz(struct bmi2_sens_axes_data *accel, struct bmi2_dev *dev);
1029 * @brief This internal API converts LSB value of accelerometer axes to form
1030 * 'g' to 'mg' for self-test.
1032 * @param[in] acc_data_diff : Stores the acceleration value difference in g.
1033 * @param[out]acc_data_diff_mg : Stores the acceleration value difference in mg.
1034 * @param[in] dev : Structure instance of bmi2_dev.
1036 * @return None
1037 * @retval None
1039 static void convert_lsb_g(const struct bmi2_selftest_delta_limit *acc_data_diff,
1040 struct bmi2_selftest_delta_limit *acc_data_diff_mg,
1041 const struct bmi2_dev *dev);
1044 * @brief This internal API is used to calculate the power of a value.
1046 * @param[in] base : base for power calculation.
1047 * @param[in] resolution : exponent for power calculation.
1049 * @return the calculated power
1050 * @retval the power value
1052 static int32_t power(int16_t base, uint8_t resolution);
1055 * @brief This internal API validates the accelerometer self-test data and
1056 * decides the result of self-test operation.
1058 * @param[in] accel_data_diff : Stores the acceleration value difference.
1060 * @return Result of API execution status
1061 * @retval 0 -> Success
1062 * @retval < 0 -> Fail
1064 static int8_t validate_self_test(const struct bmi2_selftest_delta_limit *accel_data_diff);
1067 * @brief This internal API gets the re-mapped x, y and z axes from the sensor.
1069 * @param[out] remap : Structure that stores local copy of re-mapped axes.
1070 * @param[in] dev : Structure instance of bmi2_dev.
1072 * @return Result of API execution status
1073 * @retval 0 -> Success
1074 * @retval < 0 -> Fail
1076 static int8_t get_remap_axes(struct bmi2_axes_remap *remap, struct bmi2_dev *dev);
1079 * @brief This internal API sets the re-mapped x, y and z axes in the sensor.
1081 * @param[in] remap : Structure that stores local copy of re-mapped axes.
1082 * @param[in] dev : Structure instance of bmi2_dev.
1084 * @return Result of API execution status
1085 * @retval 0 -> Success
1086 * @retval < 0 -> Fail
1088 static int8_t set_remap_axes(const struct bmi2_axes_remap *remap, struct bmi2_dev *dev);
1091 * @brief Interface to get max burst length
1093 * @param[in] max_burst_len : Pointer to store max burst length
1094 * @param[in] dev : Structure instance of bmi2_dev.
1096 * @return Result of API execution status
1097 * @retval 0 -> Success
1098 * @retval < 0 -> Fail
1100 static int8_t get_maxburst_len(uint8_t *max_burst_len, struct bmi2_dev *dev);
1103 * @brief This internal API sets the max burst length.
1105 * @param[in] write_len_byte : read & write length
1106 * @param[in] dev : Structure instance of bmi2_dev.
1108 * @return Result of API execution status
1109 * @retval 0 -> Success
1110 * @retval < 0 -> Fail
1112 static int8_t set_maxburst_len(const uint16_t write_len_byte, struct bmi2_dev *dev);
1115 * @brief This internal API parses virtual frame header from the FIFO data.
1117 * @param[in, out] frame_header : FIFO frame header.
1118 * @param[in, out] data_index : Index value of the FIFO data bytes
1119 * from which sensor frame header is to be parsed
1120 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
1122 * @return None
1123 * @retval None
1125 static void parse_if_virtual_header(uint8_t *frame_header, uint16_t *data_index, const struct bmi2_fifo_frame *fifo);
1128 * @brief This internal API gets sensor time from the accelerometer and
1129 * gyroscope virtual frames and updates in the data structure.
1131 * @param[out] sens : Sensor data structure
1132 * @param[in, out] idx : Index of FIFO from where the data is to retrieved.
1133 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
1135 * @return None
1136 * @retval None
1138 static void unpack_virt_sensor_time(struct bmi2_sens_axes_data *sens, uint16_t *idx,
1139 const struct bmi2_fifo_frame *fifo);
1142 * @brief This internal API gets sensor time from the auxiliary virtual
1143 * frames and updates in the data structure.
1145 * @param[out] aux : Auxiliary sensor data structure
1146 * @param[in, out] idx : Index of FIFO from where the data is to retrieved.
1147 * @param[in] fifo : Structure instance of bmi2_fifo_frame.
1149 * @return None
1150 * @retval None
1152 static void unpack_virt_aux_sensor_time(struct bmi2_aux_fifo_data *aux,
1153 uint16_t *idx,
1154 const struct bmi2_fifo_frame *fifo);
1157 * @brief This internal API corrects the gyroscope cross-axis sensitivity
1158 * between the z and the x axis.
1160 * @param[in] dev : Structure instance of bmi2_dev.
1161 * @param[out] gyr_data : Structure instance of gyroscope data
1163 * @return Result of API execution status
1165 * @return None
1166 * @retval None
1168 static void comp_gyro_cross_axis_sensitivity(struct bmi2_sens_axes_data *gyr_data, const struct bmi2_dev *dev);
1171 * @brief This internal API saves the configurations before performing FOC.
1173 * @param[out] acc_cfg : Accelerometer configuration value
1174 * @param[out] aps : Advance power mode value
1175 * @param[out] acc_en : Accelerometer enable value
1176 * @param[in] dev : Structure instance of bmi2_dev
1178 * @return Result of API execution status
1179 * @retval 0 -> Success
1180 * @retval < 0 -> Fail
1182 static int8_t save_accel_foc_config(struct bmi2_accel_config *acc_cfg,
1183 uint8_t *aps,
1184 uint8_t *acc_en,
1185 struct bmi2_dev *dev);
1188 * @brief This internal API performs Fast Offset Compensation for accelerometer.
1190 * @param[in] accel_g_value : This parameter selects the accel foc
1191 * axis to be performed
1193 * input format is {x, y, z, sign}. '1' to enable. '0' to disable
1195 * eg to choose x axis {1, 0, 0, 0}
1196 * eg to choose -x axis {1, 0, 0, 1}
1198 * @param[in] acc_cfg : Accelerometer configuration value
1199 * @param[in] dev : Structure instance of bmi2_dev.
1201 * @return Result of API execution status
1202 * @retval 0 -> Success
1203 * @retval < 0 -> Fail
1205 static int8_t perform_accel_foc(const struct bmi2_accel_foc_g_value *accel_g_value,
1206 const struct bmi2_accel_config *acc_cfg,
1207 struct bmi2_dev *dev);
1210 * @brief This internal sets configurations for performing accelerometer FOC.
1212 * @param[in] dev : Structure instance of bmi2_dev
1214 * @return Result of API execution status
1215 * @retval 0 -> Success
1216 * @retval < 0 -> Fail
1218 static int8_t set_accel_foc_config(struct bmi2_dev *dev);
1221 * @brief This internal API enables/disables the offset compensation for
1222 * filtered and un-filtered accelerometer data.
1224 * @param[in] offset_en : enables/disables offset compensation.
1225 * @param[in] dev : Structure instance of bmi2_dev
1227 * @return Result of API execution status
1228 * @retval 0 -> Success
1229 * @retval < 0 -> Fail
1231 static int8_t set_accel_offset_comp(uint8_t offset_en, struct bmi2_dev *dev);
1234 * @brief This internal API converts the range value into accelerometer
1235 * corresponding integer value.
1237 * @param[in] range_in : Input range value.
1238 * @param[out] range_out : Stores the integer value of range.
1240 * @return None
1241 * @retval None
1243 static void map_accel_range(uint8_t range_in, uint8_t *range_out);
1246 * @brief This internal API compensate the accelerometer data against gravity.
1248 * @param[in] lsb_per_g : LSB value pre 1g.
1249 * @param[in] g_val : G reference value of all axis.
1250 * @param[in] data : Accelerometer data
1251 * @param[out] comp_data : Stores the data that is compensated by taking the
1252 * difference in accelerometer data and lsb_per_g
1253 * value.
1255 * @return None
1256 * @retval None
1258 static void comp_for_gravity(uint16_t lsb_per_g,
1259 const struct bmi2_accel_foc_g_value *g_val,
1260 const struct bmi2_sens_axes_data *data,
1261 struct bmi2_offset_delta *comp_data);
1264 * @brief This internal API scales the compensated accelerometer data according
1265 * to the offset register resolution.
1267 * @param[in] range : G-range of the accelerometer.
1268 * @param[out] comp_data : Data that is compensated by taking the
1269 * difference in accelerometer data and lsb_per_g
1270 * value.
1271 * @param[out] data : Stores offset data
1273 * @return None
1274 * @retval None
1276 static void scale_accel_offset(uint8_t range, const struct bmi2_offset_delta *comp_data,
1277 struct bmi2_accel_offset *data);
1280 * @brief This internal API finds the bit position of 3.9mg according to given
1281 * range and resolution.
1283 * @param[in] range : G-range of the accelerometer.
1285 * @return Result of API execution status
1286 * @retval Bit position of 3.9mg
1288 static int8_t get_bit_pos_3_9mg(uint8_t range);
1291 * @brief This internal API inverts the accelerometer offset data.
1293 * @param[out] offset_data : Stores the inverted offset data
1295 * @return None
1296 * @retval None
1298 static void invert_accel_offset(struct bmi2_accel_offset *offset_data);
1301 * @brief This internal API writes the offset data in the offset compensation
1302 * register.
1304 * @param[in] offset : offset data
1305 * @param[in] dev : Structure instance of bmi2_dev
1307 * @return Result of API execution status
1308 * @retval 0 -> Success
1309 * @retval < 0 -> Fail
1311 static int8_t write_accel_offset(const struct bmi2_accel_offset *offset, struct bmi2_dev *dev);
1314 * @brief This internal API restores the configurations saved before performing
1315 * accelerometer FOC.
1317 * @param[in] acc_cfg : Accelerometer configuration value
1318 * @param[in] acc_en : Accelerometer enable value
1319 * @param[in] aps : Advance power mode value
1320 * @param[in] dev : Structure instance of bmi2_dev
1322 * @return Result of API execution status
1323 * @retval 0 -> Success
1324 * @retval < 0 -> Fail
1326 static int8_t restore_accel_foc_config(struct bmi2_accel_config *acc_cfg,
1327 uint8_t aps,
1328 uint8_t acc_en,
1329 struct bmi2_dev *dev);
1332 * @brief This internal API saves the configurations before performing gyroscope
1333 * FOC.
1335 * @param[out] gyr_cfg : Gyroscope configuration value
1336 * @param[out] gyr_en : Gyroscope enable value
1337 * @param[out] aps : Advance power mode value
1338 * @param[in] dev : Structure instance of bmi2_dev
1340 * @return Result of API execution status
1341 * @retval 0 -> Success
1342 * @retval < 0 -> Fail
1344 static int8_t save_gyro_config(struct bmi2_gyro_config *gyr_cfg, uint8_t *aps, uint8_t *gyr_en, struct bmi2_dev *dev);
1347 * @brief This internal sets configurations for performing gyroscope FOC.
1349 * @param[in] dev : Structure instance of bmi2_dev
1351 * @return Result of API execution status
1352 * @retval 0 -> Success
1353 * @retval < 0 -> Fail
1355 static int8_t set_gyro_foc_config(struct bmi2_dev *dev);
1358 * @brief This internal API inverts the gyroscope offset data.
1360 * @param[out] offset_data : Stores the inverted offset data
1362 * @return None
1363 * @retval None
1365 static void invert_gyro_offset(struct bmi2_sens_axes_data *offset_data);
1368 * @brief This internal API restores the gyroscope configurations saved
1369 * before performing FOC.
1371 * @param[in] gyr_cfg : Gyroscope configuration value
1372 * @param[in] gyr_en : Gyroscope enable value
1373 * @param[in] aps : Advance power mode value
1374 * @param[in] dev : Structure instance of bmi2_dev
1376 * @return Result of API execution status
1377 * @retval 0 -> Success
1378 * @retval < 0 -> Fail
1380 static int8_t restore_gyro_config(struct bmi2_gyro_config *gyr_cfg, uint8_t aps, uint8_t gyr_en, struct bmi2_dev *dev);
1383 * @brief This internal API saturates the gyroscope data value before writing to
1384 * to 10 bit offset register.
1386 * @param[in, out] gyr_off : Gyroscope data to be stored in offset register
1388 * @return None
1389 * @retval None
1391 static void saturate_gyro_data(struct bmi2_sens_axes_data *gyr_off);
1394 * @brief This internal API reads the gyroscope data for x, y and z axis from
1395 * the sensor.
1397 * @param[out] gyro : Buffer to store the gyroscope value.
1398 * @param[in] dev : Structure instance of bmi2_dev.
1400 * @return Result of API execution status
1401 * @retval 0 -> Success
1402 * @retval < 0 -> Fail
1404 static int8_t read_gyro_xyz(struct bmi2_sens_axes_data *gyro, struct bmi2_dev *dev);
1407 * @brief This internal API is used to check the boundary conditions.
1409 * @param[in] dev : Structure instance of bmi2_dev.
1410 * @param[in,out] val : Pointer to the value to be validated.
1411 * @param[in] min : minimum value.
1412 * @param[in] max : maximum value.
1414 * @return Result of API execution status
1415 * @retval 0 -> Success
1416 * @retval < 0 -> Fail
1418 static int8_t check_boundary_val(uint8_t *val, uint8_t min, uint8_t max, struct bmi2_dev *dev);
1421 * @brief This internal API is used to validate the device pointer for
1422 * null conditions.
1424 * @param[in] dev : Structure instance of bmi2_dev.
1426 * @return Result of API execution status
1427 * @retval 0 -> Success
1428 * @retval < 0 -> Fail
1430 static int8_t null_ptr_check(const struct bmi2_dev *dev);
1433 * @brief This updates the result for CRT or gyro self-test.
1435 * @param[in] dev : Structure instance of bmi2_dev.
1437 * @return Result of API execution status
1438 * @retval 0 -> Success
1439 * @retval < 0 -> Fail
1441 static int8_t crt_gyro_st_update_result(struct bmi2_dev *dev);
1444 * @brief This function is to get the st_status status.
1446 * @param[in] *st_status: gets the crt running status
1447 * @param[in] dev : Structure instance of bmi2_dev
1449 * @return Result of API execution status
1450 * @retval 0 -> Success
1451 * @retval < 0 -> Fail
1453 static int8_t get_st_running(uint8_t *st_status, struct bmi2_dev *dev);
1456 * @brief This function is to set crt bit to running.
1458 * @param[in] enable
1459 * @param[in] dev : Structure instance of bmi2_dev
1461 * @return Result of API execution status
1462 * @retval 0 -> Success
1463 * @retval < 0 -> Fail
1465 static int8_t set_st_running(uint8_t st_status, struct bmi2_dev *dev);
1468 * @brief This function is to make the initial changes for CRT.
1469 * Disable the gyro, OIS, aps
1470 * Note: For the purpose of preparing CRT Gyro, OIS and APS are disabled
1472 * @param[in] dev : Structure instance of bmi2_dev
1474 * @return Result of API execution status
1475 * @retval 0 -> Success
1476 * @retval < 0 -> Fail
1478 static int8_t crt_prepare_setup(struct bmi2_dev *dev);
1480 static int8_t do_gtrigger_test(uint8_t gyro_st_crt, struct bmi2_dev *dev);
1483 * @brief This function is to get the rdy for dl bit status
1484 * this will toggle from 0 to 1 and visevers according to the
1485 * dowload status
1487 * @param[in] *rdy_for_dl: gets the rdy_for_dl status
1488 * @param[in] dev : Structure instance of bmi2_dev
1490 * @return Result of API execution status
1491 * @retval 0 -> Success
1492 * @retval < 0 -> Fail
1494 static int8_t get_rdy_for_dl(uint8_t *rdy_for_dl, struct bmi2_dev *dev);
1497 * @brief This function is to write the config file in the given location for crt.
1498 * which inter checks the status of the rdy_for_dl bit and also the crt running, and
1499 * wirtes the given size.
1501 * @param[in] write_len: length of the words to be written
1502 * @param[in] config_file_size: length of the words to be written
1503 * @param[in] start_index: provide the start index from where config file has to written
1504 * @param[in] dev : Structure instance of bmi2_dev
1506 * @return Result of API execution status
1507 * @retval 0 -> Success
1508 * @retval < 0 -> Fail
1510 static int8_t write_crt_config_file(uint16_t write_len,
1511 uint16_t config_file_size,
1512 uint16_t start_index,
1513 struct bmi2_dev *dev);
1516 * @brief This function is to check for rdy_for_dl bit to toggle for CRT process
1518 * @param[in] retry_complete: wait for given time to toggle
1519 * @param[in] download_ready: get the status for rdy_for_dl
1520 * @param[in] dev : Structure instance of bmi2_dev
1522 * @return Result of API execution status
1523 * @retval 0 -> Success
1524 * @retval < 0 -> Fail
1526 static int8_t wait_rdy_for_dl_toggle(uint8_t retry_complete, uint8_t download_ready, struct bmi2_dev *dev);
1529 * @brief This function is to wait till the CRT or gyro self-test process is completed
1531 * @param[in] retry_complete: wait for given time to complete the crt process
1532 * @param[in] dev : Structure instance of bmi2_dev
1534 * @return Result of API execution status
1535 * @retval 0 -> Success
1536 * @retval < 0 -> Fail
1538 static int8_t wait_st_running(uint8_t retry_complete, struct bmi2_dev *dev);
1541 * @brief This function is to complete the crt process if max burst length is not zero
1542 * this checks for the crt status and rdy_for_dl bit to toggle
1544 * @param[in] last_byte_flag: to provide the last toggled state
1545 * @param[in] dev : Structure instance of bmi2_dev
1547 * @return Result of API execution status
1548 * @retval 0 -> Success
1549 * @retval < 0 -> Fail
1551 static int8_t process_crt_download(uint8_t last_byte_flag, struct bmi2_dev *dev);
1554 * @brief This api is used to enable the gyro self-test or crt.
1556 * @param[in] dev : Structure instance of bmi2_dev.
1558 * @return Result of API execution status
1559 * @retval 0 -> Success
1560 * @retval < 0 -> Fail
1562 static int8_t select_self_test(uint8_t gyro_st_crt, struct bmi2_dev *dev);
1565 * @brief This api is used to enable/disable abort.
1567 * @param[in] abort_enable : variable to enable the abort feature.
1568 * @param[in] dev : Structure instance of bmi2_dev.
1570 * @return Result of API execution status
1571 * @retval 0 -> Success
1572 * @retval < 0 -> Fail
1574 static int8_t abort_bmi2(uint8_t abort_enable, struct bmi2_dev *dev);
1577 * @brief This api is use to wait till gyro self-test is completed and update the status of gyro
1578 * self-test.
1580 * @param[in] dev : Structure instance of bmi2_dev.
1582 * @return Result of API execution status
1583 * @retval 0 -> Success
1584 * @retval < 0 -> Fail
1586 static int8_t gyro_self_test_completed(struct bmi2_gyro_self_test_status *gyro_st_result, struct bmi2_dev *dev);
1589 * @brief This api is used to trigger the preparation for system for NVM programming.
1591 * @param[out] nvm_prep : pointer to variable to store the status of nvm_prep_prog.
1592 * @param[in] dev : Structure instance of bmi2_dev.
1594 * @return Result of API execution status
1595 * @retval 0 -> Success
1596 * @retval < 0 -> Fail
1598 static int8_t set_nvm_prep_prog(uint8_t nvm_prep, struct bmi2_dev *dev);
1601 * @brief This api validates accel foc position as per the range
1603 * @param[in] sens_list : Sensor type
1604 * @param[in] accel_g_axis : accel axis to foc. NA for gyro foc
1605 * @param[in] avg_foc_data : average value of sensor sample datas
1606 * @param[in] dev : Structure instance of bmi2_dev.
1608 * @return Result of API execution status
1609 * @retval 0 -> Success
1610 * @retval < 0 -> Fail
1612 static int8_t validate_foc_position(uint8_t sens_list,
1613 const struct bmi2_accel_foc_g_value *accel_g_axis,
1614 struct bmi2_sens_axes_data avg_foc_data,
1615 struct bmi2_dev *dev);
1618 * @brief This api validates accel foc axis given as input
1620 * @param[in] avg_foc_data : average value of sensor sample datas
1621 * @param[in] dev : Structure instance of bmi2_dev.
1623 * @return Result of API execution status
1624 * @retval 0 -> Success
1625 * @retval < 0 -> Fail
1627 static int8_t validate_foc_accel_axis(int16_t avg_foc_data, struct bmi2_dev *dev);
1630 * @brief This api is used to verify the right position of the sensor before doing accel foc
1632 * @param[in] dev : Structure instance of bmi2_dev.
1633 * @param[in] sens_list: Sensor type
1634 * @param[in] accel_g_axis: Accel Foc axis and sign input
1636 * @return Result of API execution status
1637 * @retval 0 -> Success
1638 * @retval < 0 -> Fail
1640 static int8_t verify_foc_position(uint8_t sens_list,
1641 const struct bmi2_accel_foc_g_value *accel_g_axis,
1642 struct bmi2_dev *dev);
1645 * @brief This API reads and provides average for 128 samples of sensor data for foc operation
1646 * gyro.
1648 * @param[in] sens_list : Sensor type.
1649 * @param[in] bmi2_dev: Structure instance of bmi2_dev.
1650 * @param[in] temp_foc_data: to store data samples
1652 * @return Result of API execution status
1653 * @retval 0 -> Success
1654 * @retval < 0 -> Fail
1656 static int8_t get_average_of_sensor_data(uint8_t sens_list,
1657 struct bmi2_foc_temp_value *temp_foc_data,
1658 struct bmi2_dev *dev);
1661 * @brief This internal api gets major and minor version for config file
1663 * @param[out] config_major : Pointer to store the major version
1664 * @param[out] config_minor : Pointer to store the minor version
1665 * @param[in] dev : Structure instance of bmi2_dev
1667 * @return Result of API execution status
1668 * @retval 0 -> Success
1669 * @retval < 0 -> Fail
1671 static int8_t extract_config_file(uint8_t *config_major, uint8_t *config_minor, struct bmi2_dev *dev);
1674 * @brief This internal API is used to map the interrupts to the sensor.
1676 * @param[in] map_int : Structure instance of bmi2_map_int.
1677 * @param[in] type : Type of feature or sensor.
1678 * @param[in] dev : Structure instance of bmi2_dev.
1680 * @return None
1681 * @retval None
1683 static void extract_feat_int_map(struct bmi2_map_int *map_int, uint8_t type, const struct bmi2_dev *dev);
1686 * @brief This internal API selects the sensors/features to be enabled or
1687 * disabled.
1689 * @param[in] sens_list : Pointer to select the sensor.
1690 * @param[in] n_sens : Number of sensors selected.
1691 * @param[out] sensor_sel : Gets the selected sensor.
1693 * @return Result of API execution status
1694 * @retval 0 -> Success
1695 * @retval < 0 -> Fail
1697 static int8_t select_sensor(const uint8_t *sens_list, uint8_t n_sens, uint64_t *sensor_sel);
1700 * @brief This internal API enables the selected sensor/features.
1702 * @param[in] sensor_sel : Selects the desired sensor.
1703 * @param[in, out] dev : Structure instance of bmi2_dev.
1705 * @return Result of API execution status
1706 * @retval 0 -> Success
1707 * @retval < 0 -> Fail
1709 static int8_t sensor_enable(uint64_t sensor_sel, struct bmi2_dev *dev);
1712 * @brief This internal API disables the selected sensor/features.
1714 * @param[in] sensor_sel : Selects the desired sensor.
1715 * @param[in, out] dev : Structure instance of bmi2_dev.
1717 * @return Result of API execution status
1718 * @retval 0 -> Success
1719 * @retval < 0 -> Fail
1721 static int8_t sensor_disable(uint64_t sensor_sel, struct bmi2_dev *dev);
1723 /******************************************************************************/
1724 /*! @name User Interface Definitions */
1725 /******************************************************************************/
1728 * @brief This API is the entry point for bmi2 sensor. It selects between
1729 * I2C/SPI interface, based on user selection. It reads and validates the
1730 * chip-id of the sensor.
1732 int8_t bmi2_sec_init(struct bmi2_dev *dev)
1734 /* Variable to define error */
1735 int8_t rslt;
1737 /* Variable to assign chip id */
1738 uint8_t chip_id = 0;
1740 /* Structure to define the default values for axes re-mapping */
1741 struct bmi2_axes_remap axes_remap = {
1742 .x_axis = BMI2_MAP_X_AXIS, .x_axis_sign = BMI2_POS_SIGN, .y_axis = BMI2_MAP_Y_AXIS,
1743 .y_axis_sign = BMI2_POS_SIGN, .z_axis = BMI2_MAP_Z_AXIS, .z_axis_sign = BMI2_POS_SIGN
1746 /* Null-pointer check */
1747 rslt = null_ptr_check(dev);
1748 if (rslt == BMI2_OK)
1750 /* Perform soft-reset to bring all register values to their
1751 * default values
1753 rslt = bmi2_soft_reset(dev);
1755 if (rslt == BMI2_OK)
1757 /* Read chip-id of the BMI2 sensor */
1758 rslt = bmi2_get_regs(BMI2_CHIP_ID_ADDR, &chip_id, 1, dev);
1760 if (rslt == BMI2_OK)
1762 /* Validate chip-id */
1763 if (chip_id == dev->chip_id)
1765 /* Assign resolution to the structure */
1766 dev->resolution = 16;
1768 /* Set manual enable flag */
1769 dev->aux_man_en = 1;
1771 /* Set the default values for axis
1772 * re-mapping in the device structure
1774 dev->remap = axes_remap;
1776 else
1778 /* Storing the chip-id value read from
1779 * the register to identify the sensor
1781 dev->chip_id = chip_id;
1782 rslt = BMI2_E_DEV_NOT_FOUND;
1788 return rslt;
1792 * @brief This API reads the data from the given register address of bmi2
1793 * sensor.
1795 * @note For most of the registers auto address increment applies, with the
1796 * exception of a few special registers, which trap the address. For e.g.,
1797 * Register address - 0x26, 0x5E.
1799 int8_t bmi2_get_regs(uint8_t reg_addr, uint8_t *data, uint16_t len, struct bmi2_dev *dev)
1801 /* Variable to define error */
1802 int8_t rslt;
1804 /* Variable to define loop */
1805 uint16_t index = 0;
1807 /* Null-pointer check */
1808 rslt = null_ptr_check(dev);
1809 if ((rslt == BMI2_OK) && (data != NULL))
1811 /* Variable to define temporary length */
1812 uint16_t temp_len = len + dev->dummy_byte;
1814 /* Variable to define temporary buffer */
1815 uint8_t temp_buf[temp_len];
1817 /* Configuring reg_addr for SPI Interface */
1818 if (dev->intf == BMI2_SPI_INTF)
1820 reg_addr = (reg_addr | BMI2_SPI_RD_MASK);
1823 dev->intf_rslt = dev->read(reg_addr, temp_buf, temp_len, dev->intf_ptr);
1825 if (dev->aps_status == BMI2_ENABLE)
1827 dev->delay_us(450, dev->intf_ptr);
1829 else
1831 dev->delay_us(2, dev->intf_ptr);
1834 if (dev->intf_rslt == BMI2_INTF_RET_SUCCESS)
1836 /* Read the data from the position next to dummy byte */
1837 while (index < len)
1839 data[index] = temp_buf[index + dev->dummy_byte];
1840 index++;
1843 else
1845 rslt = BMI2_E_COM_FAIL;
1848 else
1850 rslt = BMI2_E_NULL_PTR;
1853 return rslt;
1857 * @brief This API writes data to the given register address of bmi2 sensor.
1859 int8_t bmi2_set_regs(uint8_t reg_addr, const uint8_t *data, uint16_t len, struct bmi2_dev *dev)
1861 /* Variable to define error */
1862 int8_t rslt;
1864 /* Null-pointer check */
1865 rslt = null_ptr_check(dev);
1866 if ((rslt == BMI2_OK) && (data != NULL))
1868 /* Configuring reg_addr for SPI Interface */
1869 if (dev->intf == BMI2_SPI_INTF)
1871 reg_addr = (reg_addr & BMI2_SPI_WR_MASK);
1874 dev->intf_rslt = dev->write(reg_addr, data, len, dev->intf_ptr);
1876 /* Delay for Low power mode of the sensor is 450 us */
1877 if (dev->aps_status == BMI2_ENABLE)
1879 dev->delay_us(450, dev->intf_ptr);
1881 /* Delay for Normal mode of the sensor is 2 us */
1882 else
1884 dev->delay_us(2, dev->intf_ptr);
1887 /* updating the advance power saver flag */
1888 if (reg_addr == BMI2_PWR_CONF_ADDR)
1890 if (*data & BMI2_ADV_POW_EN_MASK)
1892 dev->aps_status = BMI2_ENABLE;
1894 else
1896 dev->aps_status = BMI2_DISABLE;
1900 if (dev->intf_rslt != BMI2_INTF_RET_SUCCESS)
1902 rslt = BMI2_E_COM_FAIL;
1905 else
1907 rslt = BMI2_E_NULL_PTR;
1910 return rslt;
1914 * @brief This API resets bmi2 sensor. All registers are overwritten with
1915 * their default values.
1917 int8_t bmi2_soft_reset(struct bmi2_dev *dev)
1919 /* Variable to define error */
1920 int8_t rslt;
1922 /* Variable to define soft reset value */
1923 uint8_t data = BMI2_SOFT_RESET_CMD;
1925 /* Variable to read the dummy byte */
1926 uint8_t dummy_read = 0;
1928 /* Null-pointer check */
1929 rslt = null_ptr_check(dev);
1930 if (rslt == BMI2_OK)
1932 /* Reset bmi2 device */
1933 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &data, 1, dev);
1934 dev->delay_us(2000, dev->intf_ptr);
1936 /* set APS flag as after soft reset the sensor is on advance power save mode */
1937 dev->aps_status = BMI2_ENABLE;
1939 /* Performing a dummy read to bring interface back to SPI from
1940 * I2C after a soft-reset
1942 if ((rslt == BMI2_OK) && (dev->intf == BMI2_SPI_INTF))
1944 rslt = bmi2_get_regs(BMI2_CHIP_ID_ADDR, &dummy_read, 1, dev);
1947 if (rslt == BMI2_OK)
1949 /* Write the configuration file */
1950 rslt = bmi2_write_config_file(dev);
1953 /* Reset the sensor status flag in the device structure */
1954 if (rslt == BMI2_OK)
1956 dev->sens_en_stat = 0;
1960 return rslt;
1964 * @brief This API is used to get the config file major and minor version information.
1966 int8_t bmi2_get_config_file_version(uint8_t *config_major, uint8_t *config_minor, struct bmi2_dev *dev)
1968 /* Variable to define error */
1969 int8_t rslt;
1971 /* NULL pointer check */
1972 rslt = null_ptr_check(dev);
1973 if ((rslt == BMI2_OK) && (config_major != NULL) && (config_minor != NULL))
1975 /* Extract the config file identification from the dmr page and get the major and minor version */
1976 rslt = extract_config_file(config_major, config_minor, dev);
1978 else
1980 rslt = BMI2_E_NULL_PTR;
1983 return rslt;
1987 * @brief This API enables/disables the advance power save mode in the sensor.
1989 int8_t bmi2_set_adv_power_save(uint8_t enable, struct bmi2_dev *dev)
1991 /* Variable to define error */
1992 int8_t rslt;
1994 /* Variable to store data */
1995 uint8_t reg_data = 0;
1997 /* Null-pointer check */
1998 rslt = null_ptr_check(dev);
1999 if (rslt == BMI2_OK)
2001 rslt = bmi2_get_regs(BMI2_PWR_CONF_ADDR, &reg_data, 1, dev);
2002 if (rslt == BMI2_OK)
2004 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_ADV_POW_EN, enable);
2005 rslt = bmi2_set_regs(BMI2_PWR_CONF_ADDR, &reg_data, 1, dev);
2007 if (rslt != BMI2_OK)
2009 /* Return error if enable/disable APS fails */
2010 rslt = BMI2_E_SET_APS_FAIL;
2013 if (rslt == BMI2_OK)
2015 dev->aps_status = BMI2_GET_BIT_POS0(reg_data, BMI2_ADV_POW_EN);
2020 return rslt;
2024 * @brief This API gets the status of advance power save mode in the sensor.
2026 int8_t bmi2_get_adv_power_save(uint8_t *aps_status, struct bmi2_dev *dev)
2028 /* Variable to define error */
2029 int8_t rslt;
2031 /* Variable to store data */
2032 uint8_t reg_data = 0;
2034 /* Null-pointer check */
2035 rslt = null_ptr_check(dev);
2036 if ((rslt == BMI2_OK) && (aps_status != NULL))
2038 rslt = bmi2_get_regs(BMI2_PWR_CONF_ADDR, &reg_data, 1, dev);
2039 if (rslt == BMI2_OK)
2041 *aps_status = BMI2_GET_BIT_POS0(reg_data, BMI2_ADV_POW_EN);
2042 dev->aps_status = *aps_status;
2045 else
2047 rslt = BMI2_E_NULL_PTR;
2050 return rslt;
2054 * @brief This API loads the configuration file into the bmi2 sensor.
2056 int8_t bmi2_write_config_file(struct bmi2_dev *dev)
2058 /* Variable to define error */
2059 int8_t rslt;
2061 /* Variable to know the load status */
2062 uint8_t load_status = 0;
2064 /* Null-pointer check */
2065 rslt = null_ptr_check(dev);
2066 if ((rslt == BMI2_OK) && (dev->config_size != 0))
2068 /* Bytes written are multiples of 2 */
2069 if ((dev->read_write_len % 2) != 0)
2071 dev->read_write_len = dev->read_write_len - 1;
2074 if (dev->read_write_len < 2)
2076 dev->read_write_len = 2;
2079 /* Write the configuration file */
2080 rslt = write_config_file(dev);
2081 if (rslt == BMI2_OK)
2083 /* Check the configuration load status */
2084 rslt = bmi2_get_internal_status(&load_status, dev);
2086 /* Return error if loading not successful */
2087 if ((rslt == BMI2_OK) && (!(load_status & BMI2_CONFIG_LOAD_SUCCESS)))
2089 rslt = BMI2_E_CONFIG_LOAD;
2093 else
2095 rslt = BMI2_E_NULL_PTR;
2098 return rslt;
2102 * @brief This API sets:
2103 * 1) The input output configuration of the selected interrupt pin:
2104 * INT1 or INT2.
2105 * 2) The interrupt mode: permanently latched or non-latched.
2107 int8_t bmi2_set_int_pin_config(const struct bmi2_int_pin_config *int_cfg, struct bmi2_dev *dev)
2109 /* Variable to define error */
2110 int8_t rslt;
2112 /* Variable to define data array */
2113 uint8_t data_array[3] = { 0 };
2115 /* Variable to store register data */
2116 uint8_t reg_data = 0;
2118 /* Variable to define type of interrupt pin */
2119 uint8_t int_pin = 0;
2121 /* Null-pointer check */
2122 rslt = null_ptr_check(dev);
2123 if ((rslt == BMI2_OK) && (int_cfg != NULL))
2125 /* Copy the pin type to a local variable */
2126 int_pin = int_cfg->pin_type;
2127 if ((int_pin > BMI2_INT_NONE) && (int_pin < BMI2_INT_PIN_MAX))
2129 /* Get the previous configuration data */
2130 rslt = bmi2_get_regs(BMI2_INT1_IO_CTRL_ADDR, data_array, 3, dev);
2131 if (rslt == BMI2_OK)
2133 /* Set interrupt pin 1 configuration */
2134 if ((int_pin == BMI2_INT1) || (int_pin == BMI2_INT_BOTH))
2136 /* Configure active low or high */
2137 reg_data = BMI2_SET_BITS(data_array[0], BMI2_INT_LEVEL, int_cfg->pin_cfg[0].lvl);
2139 /* Configure push-pull or open drain */
2140 reg_data = BMI2_SET_BITS(reg_data, BMI2_INT_OPEN_DRAIN, int_cfg->pin_cfg[0].od);
2142 /* Configure output enable */
2143 reg_data = BMI2_SET_BITS(reg_data, BMI2_INT_OUTPUT_EN, int_cfg->pin_cfg[0].output_en);
2145 /* Configure input enable */
2146 reg_data = BMI2_SET_BITS(reg_data, BMI2_INT_INPUT_EN, int_cfg->pin_cfg[0].input_en);
2148 /* Copy the data to be written in the respective array */
2149 data_array[0] = reg_data;
2152 /* Set interrupt pin 2 configuration */
2153 if ((int_pin == BMI2_INT2) || (int_pin == BMI2_INT_BOTH))
2155 /* Configure active low or high */
2156 reg_data = BMI2_SET_BITS(data_array[1], BMI2_INT_LEVEL, int_cfg->pin_cfg[1].lvl);
2158 /* Configure push-pull or open drain */
2159 reg_data = BMI2_SET_BITS(reg_data, BMI2_INT_OPEN_DRAIN, int_cfg->pin_cfg[1].od);
2161 /* Configure output enable */
2162 reg_data = BMI2_SET_BITS(reg_data, BMI2_INT_OUTPUT_EN, int_cfg->pin_cfg[1].output_en);
2164 /* Configure input enable */
2165 reg_data = BMI2_SET_BITS(reg_data, BMI2_INT_INPUT_EN, int_cfg->pin_cfg[1].input_en);
2167 /* Copy the data to be written in the respective array */
2168 data_array[1] = reg_data;
2171 /* Configure the interrupt mode */
2172 data_array[2] = BMI2_SET_BIT_POS0(data_array[2], BMI2_INT_LATCH, int_cfg->int_latch);
2174 /* Set the configurations simultaneously as
2175 * INT1_IO_CTRL, INT2_IO_CTRL, and INT_LATCH lie
2176 * in consecutive addresses
2178 rslt = bmi2_set_regs(BMI2_INT1_IO_CTRL_ADDR, data_array, 3, dev);
2181 else
2183 rslt = BMI2_E_INVALID_INT_PIN;
2186 else
2188 rslt = BMI2_E_NULL_PTR;
2191 return rslt;
2195 * @brief This API gets:
2196 * 1) The input output configuration of the selected interrupt pin:
2197 * INT1 or INT2.
2198 * 2) The interrupt mode: permanently latched or non-latched.
2200 int8_t bmi2_get_int_pin_config(struct bmi2_int_pin_config *int_cfg, struct bmi2_dev *dev)
2202 /* Variable to define error */
2203 int8_t rslt;
2205 /* Variable to define data array */
2206 uint8_t data_array[3] = { 0 };
2208 /* Variable to define type of interrupt pin */
2209 uint8_t int_pin = 0;
2211 /* Null-pointer check */
2212 rslt = null_ptr_check(dev);
2213 if ((rslt == BMI2_OK) && (int_cfg != NULL))
2215 /* Copy the pin type to a local variable */
2216 int_pin = int_cfg->pin_type;
2218 /* Get the previous configuration data */
2219 rslt = bmi2_get_regs(BMI2_INT1_IO_CTRL_ADDR, data_array, 3, dev);
2220 if (rslt == BMI2_OK)
2222 /* Get interrupt pin 1 configuration */
2223 if ((int_pin == BMI2_INT1) || (int_pin == BMI2_INT_BOTH))
2225 /* Get active low or high */
2226 int_cfg->pin_cfg[0].lvl = BMI2_GET_BITS(data_array[0], BMI2_INT_LEVEL);
2228 /* Get push-pull or open drain */
2229 int_cfg->pin_cfg[0].od = BMI2_GET_BITS(data_array[0], BMI2_INT_OPEN_DRAIN);
2231 /* Get output enable */
2232 int_cfg->pin_cfg[0].output_en = BMI2_GET_BITS(data_array[0], BMI2_INT_OUTPUT_EN);
2234 /* Get input enable */
2235 int_cfg->pin_cfg[0].input_en = BMI2_GET_BITS(data_array[0], BMI2_INT_INPUT_EN);
2238 /* Get interrupt pin 2 configuration */
2239 if ((int_pin == BMI2_INT2) || (int_pin == BMI2_INT_BOTH))
2241 /* Get active low or high */
2242 int_cfg->pin_cfg[1].lvl = BMI2_GET_BITS(data_array[1], BMI2_INT_LEVEL);
2244 /* Get push-pull or open drain */
2245 int_cfg->pin_cfg[1].od = BMI2_GET_BITS(data_array[1], BMI2_INT_OPEN_DRAIN);
2247 /* Get output enable */
2248 int_cfg->pin_cfg[1].output_en = BMI2_GET_BITS(data_array[1], BMI2_INT_OUTPUT_EN);
2250 /* Get input enable */
2251 int_cfg->pin_cfg[1].input_en = BMI2_GET_BITS(data_array[1], BMI2_INT_INPUT_EN);
2254 /* Get interrupt mode */
2255 int_cfg->int_latch = BMI2_GET_BIT_POS0(data_array[2], BMI2_INT_LATCH);
2258 else
2260 rslt = BMI2_E_NULL_PTR;
2263 return rslt;
2267 * @brief This API gets the interrupt status of both feature and data
2268 * interrupts
2270 int8_t bmi2_get_int_status(uint16_t *int_status, struct bmi2_dev *dev)
2272 /* Variable to define error */
2273 int8_t rslt;
2275 /* Array to store data */
2276 uint8_t data_array[2] = { 0 };
2278 /* Null-pointer check */
2279 rslt = null_ptr_check(dev);
2280 if ((rslt == BMI2_OK) && (int_status != NULL))
2282 /* Get the interrupt status */
2283 rslt = bmi2_get_regs(BMI2_INT_STATUS_0_ADDR, data_array, 2, dev);
2284 if (rslt == BMI2_OK)
2286 *int_status = (uint16_t) data_array[0] | ((uint16_t) data_array[1] << 8);
2289 else
2291 rslt = BMI2_E_NULL_PTR;
2294 return rslt;
2298 * @brief This API selects the sensors/features to be enabled.
2300 int8_t bmi2_sensor_enable(const uint8_t *sens_list, uint8_t n_sens, struct bmi2_dev *dev)
2302 /* Variable to define error */
2303 int8_t rslt;
2305 /* Variable to select sensor */
2306 uint64_t sensor_sel = 0;
2308 /* Null-pointer check */
2309 rslt = null_ptr_check(dev);
2310 if ((rslt == BMI2_OK) && (sens_list != NULL))
2312 /* Get the selected sensors */
2313 rslt = select_sensor(sens_list, n_sens, &sensor_sel);
2314 if (rslt == BMI2_OK)
2316 /* Enable the selected sensors */
2317 rslt = sensor_enable(sensor_sel, dev);
2320 else
2322 rslt = BMI2_E_NULL_PTR;
2325 return rslt;
2329 * @brief This API selects the sensors/features to be disabled.
2331 int8_t bmi2_sensor_disable(const uint8_t *sens_list, uint8_t n_sens, struct bmi2_dev *dev)
2333 /* Variable to define error */
2334 int8_t rslt;
2336 /* Variable to select sensor */
2337 uint64_t sensor_sel = 0;
2339 /* Null-pointer check */
2340 rslt = null_ptr_check(dev);
2341 if ((rslt == BMI2_OK) && (sens_list != NULL))
2343 /* Get the selected sensors */
2344 rslt = select_sensor(sens_list, n_sens, &sensor_sel);
2345 if (rslt == BMI2_OK)
2347 /* Disable the selected sensors */
2348 rslt = sensor_disable(sensor_sel, dev);
2351 else
2353 rslt = BMI2_E_NULL_PTR;
2356 return rslt;
2360 * @brief This API sets the sensor/feature configuration.
2362 int8_t bmi2_set_sensor_config(struct bmi2_sens_config *sens_cfg, uint8_t n_sens, struct bmi2_dev *dev)
2364 /* Variable to define error */
2365 int8_t rslt;
2367 /* Variable to define loop */
2368 uint8_t loop;
2370 /* Variable to get the status of advance power save */
2371 uint8_t aps_stat = 0;
2373 /* Null-pointer check */
2374 rslt = null_ptr_check(dev);
2375 if ((rslt == BMI2_OK) && (sens_cfg != NULL))
2377 /* Get status of advance power save mode */
2378 aps_stat = dev->aps_status;
2380 for (loop = 0; loop < n_sens; loop++)
2382 /* Disable Advance power save if enabled for auxiliary
2383 * and feature configurations
2385 if (aps_stat == BMI2_ENABLE)
2387 /* Disable advance power save if
2388 * enabled
2390 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
2393 if (rslt == BMI2_OK)
2395 switch (sens_cfg[loop].type)
2397 /* Set accelerometer configuration */
2398 case BMI2_ACCEL:
2399 rslt = set_accel_config(&sens_cfg[loop].cfg.acc, dev);
2400 break;
2402 /* Set gyroscope configuration */
2403 case BMI2_GYRO:
2404 rslt = set_gyro_config(&sens_cfg[loop].cfg.gyr, dev);
2405 break;
2407 /* Set auxiliary configuration */
2408 case BMI2_AUX:
2409 rslt = set_aux_config(&sens_cfg[loop].cfg.aux, dev);
2410 break;
2412 /* Set gyroscope user gain configuration */
2413 case BMI2_GYRO_GAIN_UPDATE:
2414 rslt = set_gyro_user_gain_config(&sens_cfg[loop].cfg.gyro_gain_update, dev);
2415 break;
2417 default:
2418 rslt = BMI2_E_INVALID_SENSOR;
2419 break;
2423 /* Return error if any of the set configurations fail */
2424 if (rslt != BMI2_OK)
2426 break;
2430 /* Enable Advance power save if disabled while configuring and
2431 * not when already disabled
2433 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
2435 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
2438 else
2440 rslt = BMI2_E_NULL_PTR;
2443 return rslt;
2447 * @brief This API gets the sensor/feature configuration.
2449 int8_t bmi2_get_sensor_config(struct bmi2_sens_config *sens_cfg, uint8_t n_sens, struct bmi2_dev *dev)
2451 /* Variable to define error */
2452 int8_t rslt;
2454 /* Variable to define loop */
2455 uint8_t loop;
2457 /* Variable to get the status of advance power save */
2458 uint8_t aps_stat = 0;
2460 /* Null-pointer check */
2461 rslt = null_ptr_check(dev);
2462 if ((rslt == BMI2_OK) && (sens_cfg != NULL))
2464 /* Get status of advance power save mode */
2465 aps_stat = dev->aps_status;
2466 for (loop = 0; loop < n_sens; loop++)
2468 /* Disable Advance power save if enabled for auxiliary
2469 * and feature configurations
2471 if ((sens_cfg[loop].type >= BMI2_MAIN_SENS_MAX_NUM) || (sens_cfg[loop].type == BMI2_AUX))
2474 if (aps_stat == BMI2_ENABLE)
2476 /* Disable advance power save if
2477 * enabled
2479 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
2483 if (rslt == BMI2_OK)
2485 switch (sens_cfg[loop].type)
2487 /* Get accelerometer configuration */
2488 case BMI2_ACCEL:
2489 rslt = get_accel_config(&sens_cfg[loop].cfg.acc, dev);
2490 break;
2492 /* Get gyroscope configuration */
2493 case BMI2_GYRO:
2494 rslt = get_gyro_config(&sens_cfg[loop].cfg.gyr, dev);
2495 break;
2497 /* Get auxiliary configuration */
2498 case BMI2_AUX:
2499 rslt = get_aux_config(&sens_cfg[loop].cfg.aux, dev);
2500 break;
2502 /* Get gyroscope user gain configuration */
2503 case BMI2_GYRO_GAIN_UPDATE:
2504 rslt = get_gyro_gain_update_config(&sens_cfg[loop].cfg.gyro_gain_update, dev);
2505 break;
2507 default:
2508 rslt = BMI2_E_INVALID_SENSOR;
2509 break;
2513 /* Return error if any of the get configurations fail */
2514 if (rslt != BMI2_OK)
2516 break;
2520 /* Enable Advance power save if disabled while configuring and
2521 * not when already disabled
2523 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
2525 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
2528 else
2530 rslt = BMI2_E_NULL_PTR;
2533 return rslt;
2537 * @brief This API gets the sensor/feature data for accelerometer, gyroscope,
2538 * auxiliary sensor, step counter, high-g, gyroscope user-gain update,
2539 * orientation, gyroscope cross sensitivity and error status for NVM and VFRM.
2541 int8_t bmi2_get_sensor_data(struct bmi2_sensor_data *sensor_data, uint8_t n_sens, struct bmi2_dev *dev)
2543 /* Variable to define error */
2544 int8_t rslt;
2546 /* Variable to define loop */
2547 uint8_t loop;
2549 /* Variable to get the status of advance power save */
2550 uint8_t aps_stat = 0;
2552 /* Null-pointer check */
2553 rslt = null_ptr_check(dev);
2554 if ((rslt == BMI2_OK) && (sensor_data != NULL))
2556 /* Get status of advance power save mode */
2557 aps_stat = dev->aps_status;
2558 for (loop = 0; loop < n_sens; loop++)
2560 /* Disable Advance power save if enabled for feature
2561 * configurations
2563 if (sensor_data[loop].type >= BMI2_MAIN_SENS_MAX_NUM)
2565 if (aps_stat == BMI2_ENABLE)
2567 /* Disable advance power save if
2568 * enabled
2570 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
2574 if (rslt == BMI2_OK)
2576 switch (sensor_data[loop].type)
2578 case BMI2_ACCEL:
2580 /* Get accelerometer data */
2581 rslt = get_accel_sensor_data(&sensor_data[loop].sens_data.acc, BMI2_ACC_X_LSB_ADDR, dev);
2582 break;
2583 case BMI2_GYRO:
2585 /* Get gyroscope data */
2586 rslt = get_gyro_sensor_data(&sensor_data[loop].sens_data.gyr, BMI2_GYR_X_LSB_ADDR, dev);
2587 break;
2588 case BMI2_AUX:
2590 /* Get auxiliary sensor data in data mode */
2591 rslt = read_aux_data_mode(sensor_data[loop].sens_data.aux_data, dev);
2592 break;
2594 case BMI2_GYRO_CROSS_SENSE:
2596 /* Get Gyroscope cross sense value of z axis */
2597 rslt = get_gyro_cross_sense(&sensor_data[loop].sens_data.correction_factor_zx, dev);
2598 break;
2600 case BMI2_GYRO_GAIN_UPDATE:
2602 /* Get saturation status of gyroscope user gain update */
2603 rslt = get_gyro_gain_update_status(&sensor_data[loop].sens_data.gyro_user_gain_status, dev);
2604 break;
2605 default:
2606 rslt = BMI2_E_INVALID_SENSOR;
2607 break;
2610 /* Return error if any of the get sensor data fails */
2611 if (rslt != BMI2_OK)
2613 break;
2617 /* Enable Advance power save if disabled while
2618 * configuring and not when already disabled
2620 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
2622 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
2626 else
2628 rslt = BMI2_E_NULL_PTR;
2631 return rslt;
2635 * @brief This API sets the FIFO configuration in the sensor.
2637 int8_t bmi2_set_fifo_config(uint16_t config, uint8_t enable, struct bmi2_dev *dev)
2639 int8_t rslt;
2640 uint8_t data[2] = { 0 };
2641 uint8_t max_burst_len = 0;
2643 /* Variable to store data of FIFO configuration register 0 */
2644 uint8_t fifo_config_0 = (uint8_t)(config & BMI2_FIFO_CONFIG_0_MASK);
2646 /* Variable to store data of FIFO configuration register 1 */
2647 uint8_t fifo_config_1 = (uint8_t)((config & BMI2_FIFO_CONFIG_1_MASK) >> 8);
2649 rslt = null_ptr_check(dev);
2650 if (rslt == BMI2_OK)
2652 rslt = bmi2_get_regs(BMI2_FIFO_CONFIG_0_ADDR, data, BMI2_FIFO_CONFIG_LENGTH, dev);
2653 if (rslt == BMI2_OK)
2655 /* Get data to set FIFO configuration register 0 */
2656 if (fifo_config_0 > 0)
2658 if (enable == BMI2_ENABLE)
2660 data[0] = data[0] | fifo_config_0;
2662 else
2664 data[0] = data[0] & (~fifo_config_0);
2668 /* Get data to set FIFO configuration register 1 */
2669 if (enable == BMI2_ENABLE)
2671 data[1] = data[1] | fifo_config_1;
2672 if (dev->variant_feature & BMI2_CRT_RTOSK_ENABLE)
2675 /* Burst length is needed for CRT
2676 * FIFO enable will reset the default values
2677 * So configure the max burst length again.
2679 rslt = get_maxburst_len(&max_burst_len, dev);
2680 if (rslt == BMI2_OK && max_burst_len == 0)
2682 rslt = set_maxburst_len(BMI2_CRT_MIN_BURST_WORD_LENGTH, dev);
2686 else
2688 data[1] = data[1] & (~fifo_config_1);
2691 /* Set the FIFO configurations */
2692 if (rslt == BMI2_OK)
2694 rslt = bmi2_set_regs(BMI2_FIFO_CONFIG_0_ADDR, data, 2, dev);
2699 return rslt;
2703 * @brief This API reads the FIFO configuration from the sensor.
2705 int8_t bmi2_get_fifo_config(uint16_t *fifo_config, struct bmi2_dev *dev)
2707 /* Variable to define error */
2708 int8_t rslt;
2710 /* Array to store data */
2711 uint8_t data[2] = { 0 };
2713 /* Null-pointer check */
2714 rslt = null_ptr_check(dev);
2715 if ((rslt == BMI2_OK) && (fifo_config != NULL))
2717 /* Get the FIFO configuration value */
2718 rslt = bmi2_get_regs(BMI2_FIFO_CONFIG_0_ADDR, data, BMI2_FIFO_CONFIG_LENGTH, dev);
2719 if (rslt == BMI2_OK)
2721 (*fifo_config) = (uint16_t)((uint16_t) data[0] & BMI2_FIFO_CONFIG_0_MASK);
2722 (*fifo_config) |= (uint16_t)(((uint16_t) data[1] << 8) & BMI2_FIFO_CONFIG_1_MASK);
2725 else
2727 rslt = BMI2_E_NULL_PTR;
2730 return rslt;
2734 * @brief This API reads the FIFO data.
2736 int8_t bmi2_read_fifo_data(struct bmi2_fifo_frame *fifo, struct bmi2_dev *dev)
2738 /* Variable to define error */
2739 int8_t rslt;
2741 /* Array to store FIFO configuration data */
2742 uint8_t config_data[2] = { 0 };
2744 /* Variable to define FIFO address */
2745 uint8_t addr = BMI2_FIFO_DATA_ADDR;
2747 /* Null-pointer check */
2748 rslt = null_ptr_check(dev);
2749 if ((rslt == BMI2_OK) && (fifo != NULL))
2751 /* Clear the FIFO data structure */
2752 reset_fifo_frame_structure(fifo, dev);
2754 /* Read FIFO data */
2755 rslt = bmi2_get_regs(addr, fifo->data, fifo->length, dev);
2757 if (rslt == BMI2_OK)
2760 /* Get the set FIFO frame configurations */
2761 rslt = bmi2_get_regs(BMI2_FIFO_CONFIG_0_ADDR, config_data, 2, dev);
2762 if (rslt == BMI2_OK)
2764 /* Get FIFO header status */
2765 fifo->header_enable = (uint8_t)((config_data[1]) & (BMI2_FIFO_HEADER_EN >> 8));
2767 /* Get sensor enable status, of which the data is to be read */
2768 fifo->data_enable =
2769 (uint16_t)(((config_data[0]) | ((uint16_t) config_data[1] << 8)) & BMI2_FIFO_ALL_EN);
2772 else
2774 rslt = BMI2_E_COM_FAIL;
2777 else
2779 rslt = BMI2_E_NULL_PTR;
2782 return rslt;
2786 * @brief This API parses and extracts the accelerometer frames from FIFO data
2787 * read by the "bmi2_read_fifo_data" API and stores it in the "accel_data"
2788 * structure instance.
2790 int8_t bmi2_extract_accel(struct bmi2_sens_axes_data *accel_data,
2791 uint16_t *accel_length,
2792 struct bmi2_fifo_frame *fifo,
2793 const struct bmi2_dev *dev)
2795 /* Variable to define error */
2796 int8_t rslt;
2798 /* Variable to index the bytes */
2799 uint16_t data_index = 0;
2801 /* Variable to index accelerometer frames */
2802 uint16_t accel_index = 0;
2804 /* Variable to store the number of bytes to be read */
2805 uint16_t data_read_length = 0;
2807 /* Variable to define the data enable byte */
2808 uint8_t data_enable = 0;
2810 /* Null-pointer check */
2811 rslt = null_ptr_check(dev);
2812 if ((rslt == BMI2_OK) && (accel_data != NULL) && (accel_length != NULL) && (fifo != NULL))
2814 /* Parsing the FIFO data in header-less mode */
2815 if (fifo->header_enable == 0)
2818 /* Get the number of accelerometer bytes to be read */
2819 rslt = parse_fifo_accel_len(&data_index, &data_read_length, accel_length, fifo);
2821 /* Convert word to byte since all sensor enables are in a byte */
2822 data_enable = (uint8_t)(fifo->data_enable >> 8);
2823 for (; (data_index < data_read_length) && (rslt != BMI2_W_FIFO_EMPTY);)
2825 /* Unpack frame to get the accelerometer data */
2826 rslt = unpack_accel_frame(accel_data, &data_index, &accel_index, data_enable, fifo, dev);
2828 if (rslt != BMI2_W_FIFO_EMPTY)
2830 /* Check for the availability of next two bytes of FIFO data */
2831 rslt = check_empty_fifo(&data_index, fifo);
2835 /* Update number of accelerometer frames to be read */
2836 (*accel_length) = accel_index;
2838 /* Update the accelerometer byte index */
2839 fifo->acc_byte_start_idx = data_index;
2841 else
2843 /* Parsing the FIFO data in header mode */
2844 rslt = extract_accel_header_mode(accel_data, accel_length, fifo, dev);
2847 else
2849 rslt = BMI2_E_NULL_PTR;
2852 return rslt;
2856 * @brief This API parses and extracts the gyroscope frames from FIFO data
2857 * read by the "bmi2_read_fifo_data" API and stores it in the "gyro_data"
2858 * structure instance.
2860 int8_t bmi2_extract_gyro(struct bmi2_sens_axes_data *gyro_data,
2861 uint16_t *gyro_length,
2862 struct bmi2_fifo_frame *fifo,
2863 const struct bmi2_dev *dev)
2865 /* Variable to define error */
2866 int8_t rslt;
2868 /* Variable to index the bytes */
2869 uint16_t data_index = 0;
2871 /* Variable to index gyroscope frames */
2872 uint16_t gyro_index = 0;
2874 /* Variable to store the number of bytes to be read */
2875 uint16_t data_read_length = 0;
2877 /* Variable to define the data enable byte */
2878 uint8_t data_enable = 0;
2880 /* Null-pointer check */
2881 rslt = null_ptr_check(dev);
2882 if ((rslt == BMI2_OK) && (gyro_data != NULL) && (gyro_length != NULL) && (fifo != NULL))
2884 /* Parsing the FIFO data in header-less mode */
2885 if (fifo->header_enable == 0)
2887 /* Get the number of gyro bytes to be read */
2888 rslt = parse_fifo_gyro_len(&data_index, &data_read_length, gyro_length, fifo);
2890 /* Convert word to byte since all sensor enables are in a byte */
2891 data_enable = (uint8_t)(fifo->data_enable >> 8);
2892 for (; (data_index < data_read_length) && (rslt != BMI2_W_FIFO_EMPTY);)
2894 /* Unpack frame to get gyroscope data */
2895 rslt = unpack_gyro_frame(gyro_data, &data_index, &gyro_index, data_enable, fifo, dev);
2896 if (rslt != BMI2_W_FIFO_EMPTY)
2898 /* Check for the availability of next two bytes of FIFO data */
2899 rslt = check_empty_fifo(&data_index, fifo);
2903 /* Update number of gyroscope frames to be read */
2904 (*gyro_length) = gyro_index;
2906 /* Update the gyroscope byte index */
2907 fifo->acc_byte_start_idx = data_index;
2909 else
2911 /* Parsing the FIFO data in header mode */
2912 rslt = extract_gyro_header_mode(gyro_data, gyro_length, fifo, dev);
2915 else
2917 rslt = BMI2_E_NULL_PTR;
2920 return rslt;
2924 * @brief This API parses and extracts the auxiliary frames from FIFO data
2925 * read by the "bmi2_read_fifo_data" API and stores it in "aux_data" buffer.
2927 int8_t bmi2_extract_aux(struct bmi2_aux_fifo_data *aux,
2928 uint16_t *aux_length,
2929 struct bmi2_fifo_frame *fifo,
2930 const struct bmi2_dev *dev)
2932 /* Variable to define error */
2933 int8_t rslt;
2935 /* Variable to index the bytes */
2936 uint16_t data_index = 0;
2938 /* Variable to index auxiliary frames */
2939 uint16_t aux_index = 0;
2941 /* Variable to store the number of bytes to be read */
2942 uint16_t data_read_length = 0;
2944 /* Variable to define the data enable byte */
2945 uint8_t data_enable = 0;
2947 /* Null-pointer check */
2948 rslt = null_ptr_check(dev);
2949 if ((rslt == BMI2_OK) && (aux != NULL) && (aux_length != NULL) && (fifo != NULL))
2951 /* Parsing the FIFO data in header-less mode */
2952 if (fifo->header_enable == 0)
2954 rslt = parse_fifo_aux_len(&data_index, &data_read_length, aux_length, fifo);
2956 /* Convert word to byte since all sensor enables are in
2957 * a byte
2959 data_enable = (uint8_t)(fifo->data_enable >> 8);
2960 for (; (data_index < data_read_length) && (rslt != BMI2_W_FIFO_EMPTY);)
2962 /* Unpack frame to get auxiliary data */
2963 rslt = unpack_aux_frame(aux, &data_index, &aux_index, data_enable, fifo, dev);
2964 if (rslt != BMI2_W_FIFO_EMPTY)
2966 /* Check for the availability of next
2967 * two bytes of FIFO data
2969 rslt = check_empty_fifo(&data_index, fifo);
2973 /* Update number of auxiliary frames to be read */
2974 *aux_length = aux_index;
2976 /* Update the auxiliary byte index */
2977 fifo->aux_byte_start_idx = data_index;
2979 else
2981 /* Parsing the FIFO data in header mode */
2982 rslt = extract_aux_header_mode(aux, aux_length, fifo, dev);
2985 else
2987 rslt = BMI2_E_NULL_PTR;
2990 return rslt;
2994 * @brief This API writes the available sensor specific commands to the sensor.
2996 int8_t bmi2_set_command_register(uint8_t command, struct bmi2_dev *dev)
2998 /* Variable to define error */
2999 int8_t rslt;
3001 /* Null-pointer check */
3002 rslt = null_ptr_check(dev);
3003 if (rslt == BMI2_OK)
3005 /* Set the command in the command register */
3006 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &command, 1, dev);
3009 return rslt;
3013 * @brief This API sets the FIFO self wake up functionality in the sensor.
3015 int8_t bmi2_set_fifo_self_wake_up(uint8_t fifo_self_wake_up, struct bmi2_dev *dev)
3017 /* Variable to define error */
3018 int8_t rslt;
3020 /* Variable to store data */
3021 uint8_t data = 0;
3023 /* Null-pointer check */
3024 rslt = null_ptr_check(dev);
3025 if (rslt == BMI2_OK)
3027 /* Set FIFO self wake-up */
3028 rslt = bmi2_get_regs(BMI2_PWR_CONF_ADDR, &data, 1, dev);
3029 if (rslt == BMI2_OK)
3031 data = BMI2_SET_BITS(data, BMI2_FIFO_SELF_WAKE_UP, fifo_self_wake_up);
3032 rslt = bmi2_set_regs(BMI2_PWR_CONF_ADDR, &data, 1, dev);
3036 return rslt;
3040 * @brief This API gets the status of FIFO self wake up functionality from
3041 * the sensor.
3043 int8_t bmi2_get_fifo_self_wake_up(uint8_t *fifo_self_wake_up, struct bmi2_dev *dev)
3045 /* Variable to define error */
3046 int8_t rslt;
3048 /* Variable to store data */
3049 uint8_t data = 0;
3051 /* Null-pointer check */
3052 rslt = null_ptr_check(dev);
3053 if ((rslt == BMI2_OK) && (fifo_self_wake_up != NULL))
3055 /* Get the status of FIFO self wake-up */
3056 rslt = bmi2_get_regs(BMI2_PWR_CONF_ADDR, &data, 1, dev);
3057 if (rslt == BMI2_OK)
3059 (*fifo_self_wake_up) = BMI2_GET_BITS(data, BMI2_FIFO_SELF_WAKE_UP);
3062 else
3064 rslt = BMI2_E_NULL_PTR;
3067 return rslt;
3071 * @brief This API sets the FIFO water-mark level in the sensor.
3073 int8_t bmi2_set_fifo_wm(uint16_t fifo_wm, struct bmi2_dev *dev)
3075 /* Variable to define error */
3076 int8_t rslt;
3078 /* Array to store data */
3079 uint8_t data[2] = { 0 };
3081 /* Null-pointer check */
3082 rslt = null_ptr_check(dev);
3083 if (rslt == BMI2_OK)
3085 /* Get LSB value of FIFO water-mark */
3086 data[0] = BMI2_GET_LSB(fifo_wm);
3088 /* Get MSB value of FIFO water-mark */
3089 data[1] = BMI2_GET_MSB(fifo_wm);
3091 /* Set the FIFO water-mark level */
3092 rslt = bmi2_set_regs(BMI2_FIFO_WTM_0_ADDR, data, 2, dev);
3095 return rslt;
3099 * @brief This API reads the FIFO water mark level set in the sensor.
3101 int8_t bmi2_get_fifo_wm(uint16_t *fifo_wm, struct bmi2_dev *dev)
3103 /* Variable to define error */
3104 int8_t rslt;
3106 /* Array to to store data */
3107 uint8_t data[2] = { 0 };
3109 /* Null-pointer check */
3110 rslt = null_ptr_check(dev);
3111 if ((rslt == BMI2_OK) && (fifo_wm != NULL))
3113 /* Read the FIFO water mark level */
3114 rslt = bmi2_get_regs(BMI2_FIFO_WTM_0_ADDR, data, BMI2_FIFO_WM_LENGTH, dev);
3115 if (rslt == BMI2_OK)
3117 (*fifo_wm) = (uint16_t)((uint16_t) data[1] << 8) | (data[0]);
3120 else
3122 rslt = BMI2_E_NULL_PTR;
3125 return rslt;
3129 * @brief This API sets either filtered or un-filtered FIFO accelerometer or
3130 * gyroscope data.
3132 int8_t bmi2_set_fifo_filter_data(uint8_t sens_sel, uint8_t fifo_filter_data, struct bmi2_dev *dev)
3134 /* Variable to define error */
3135 int8_t rslt;
3137 /* Variable to store data */
3138 uint8_t data = 0;
3140 /* Null-pointer check */
3141 rslt = null_ptr_check(dev);
3142 if (rslt == BMI2_OK)
3144 switch (sens_sel)
3146 case BMI2_ACCEL:
3148 /* Validate filter mode */
3149 if (fifo_filter_data <= BMI2_MAX_VALUE_FIFO_FILTER)
3151 /* Set the accelerometer FIFO filter data */
3152 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3153 if (rslt == BMI2_OK)
3155 data = BMI2_SET_BITS(data, BMI2_ACC_FIFO_FILT_DATA, fifo_filter_data);
3156 rslt = bmi2_set_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3159 else
3161 rslt = BMI2_E_OUT_OF_RANGE;
3164 break;
3165 case BMI2_GYRO:
3167 /* Validate filter mode */
3168 if (fifo_filter_data <= BMI2_MAX_VALUE_FIFO_FILTER)
3170 /* Set the gyroscope FIFO filter data */
3171 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3172 if (rslt == BMI2_OK)
3174 data = BMI2_SET_BITS(data, BMI2_GYR_FIFO_FILT_DATA, fifo_filter_data);
3175 rslt = bmi2_set_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3178 else
3180 rslt = BMI2_E_OUT_OF_RANGE;
3183 break;
3184 default:
3185 rslt = BMI2_E_INVALID_SENSOR;
3186 break;
3190 return rslt;
3194 * @brief This API gets the FIFO accelerometer or gyroscope filter data.
3196 int8_t bmi2_get_fifo_filter_data(uint8_t sens_sel, uint8_t *fifo_filter_data, struct bmi2_dev *dev)
3198 /* Variable to define error */
3199 int8_t rslt;
3201 /* Variable to store FIFO filter mode */
3202 uint8_t data = 0;
3204 /* Null-pointer check */
3205 rslt = null_ptr_check(dev);
3206 if ((rslt == BMI2_OK) && (fifo_filter_data != NULL))
3208 switch (sens_sel)
3210 case BMI2_ACCEL:
3212 /* Read the accelerometer FIFO filter data */
3213 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3214 if (rslt == BMI2_OK)
3216 (*fifo_filter_data) = BMI2_GET_BITS(data, BMI2_ACC_FIFO_FILT_DATA);
3219 break;
3220 case BMI2_GYRO:
3222 /* Read the gyroscope FIFO filter data */
3223 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3224 if (rslt == BMI2_OK)
3226 (*fifo_filter_data) = BMI2_GET_BITS(data, BMI2_GYR_FIFO_FILT_DATA);
3229 break;
3230 default:
3231 rslt = BMI2_E_INVALID_SENSOR;
3232 break;
3235 else
3237 rslt = BMI2_E_NULL_PTR;
3240 return rslt;
3244 * @brief This API sets the down-sampling rates for accelerometer or gyroscope
3245 * FIFO data.
3247 int8_t bmi2_set_fifo_down_sample(uint8_t sens_sel, uint8_t fifo_down_samp, struct bmi2_dev *dev)
3249 /* Variable to define error */
3250 int8_t rslt;
3252 /* Variable to store sampling rate */
3253 uint8_t data = 0;
3255 /* Null-pointer check */
3256 rslt = null_ptr_check(dev);
3257 if (rslt == BMI2_OK)
3259 switch (sens_sel)
3261 case BMI2_ACCEL:
3263 /* Set the accelerometer FIFO down sampling rate */
3264 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3265 if (rslt == BMI2_OK)
3267 data = BMI2_SET_BITS(data, BMI2_ACC_FIFO_DOWNS, fifo_down_samp);
3268 rslt = bmi2_set_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3271 break;
3272 case BMI2_GYRO:
3274 /* Set the gyroscope FIFO down sampling rate */
3275 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3276 if (rslt == BMI2_OK)
3278 data = BMI2_SET_BIT_POS0(data, BMI2_GYR_FIFO_DOWNS, fifo_down_samp);
3279 rslt = bmi2_set_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3282 break;
3283 default:
3284 rslt = BMI2_E_INVALID_SENSOR;
3285 break;
3289 return rslt;
3293 * @brief This API reads the down sampling rates which is configured for
3294 * accelerometer or gyroscope FIFO data.
3296 int8_t bmi2_get_fifo_down_sample(uint8_t sens_sel, uint8_t *fifo_down_samp, struct bmi2_dev *dev)
3298 /* Variable to define error */
3299 int8_t rslt;
3301 /* Variable to store sampling rate */
3302 uint8_t data = 0;
3304 /* Null-pointer check */
3305 rslt = null_ptr_check(dev);
3306 if ((rslt == BMI2_OK) && (fifo_down_samp != NULL))
3308 switch (sens_sel)
3310 case BMI2_ACCEL:
3312 /* Read the accelerometer FIFO down data sampling rate */
3313 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3314 if (rslt == BMI2_OK)
3316 (*fifo_down_samp) = BMI2_GET_BITS(data, BMI2_ACC_FIFO_DOWNS);
3319 break;
3320 case BMI2_GYRO:
3322 /* Read the gyroscope FIFO down data sampling rate */
3323 rslt = bmi2_get_regs(BMI2_FIFO_DOWNS_ADDR, &data, 1, dev);
3324 if (rslt == BMI2_OK)
3326 (*fifo_down_samp) = BMI2_GET_BIT_POS0(data, BMI2_GYR_FIFO_DOWNS);
3329 break;
3330 default:
3331 rslt = BMI2_E_INVALID_SENSOR;
3332 break;
3335 else
3337 rslt = BMI2_E_NULL_PTR;
3340 return rslt;
3344 * @brief This API gets the length of FIFO data available in the sensor in
3345 * bytes.
3347 int8_t bmi2_get_fifo_length(uint16_t *fifo_length, struct bmi2_dev *dev)
3349 /* Variable to define error */
3350 int8_t rslt;
3352 /* Variable to define byte index */
3353 uint8_t index = 0;
3355 /* Array to store FIFO data length */
3356 uint8_t data[BMI2_FIFO_DATA_LENGTH] = { 0 };
3358 /* Null-pointer check */
3359 rslt = null_ptr_check(dev);
3360 if ((rslt == BMI2_OK) && (fifo_length != NULL))
3362 /* Read FIFO length */
3363 rslt = bmi2_get_regs(BMI2_FIFO_LENGTH_0_ADDR, data, BMI2_FIFO_DATA_LENGTH, dev);
3364 if (rslt == BMI2_OK)
3366 /* Get the MSB byte index */
3367 index = BMI2_FIFO_LENGTH_MSB_BYTE;
3369 /* Get the MSB byte of FIFO length */
3370 data[index] = BMI2_GET_BIT_POS0(data[index], BMI2_FIFO_BYTE_COUNTER_MSB);
3372 /* Get total FIFO length */
3373 (*fifo_length) = ((data[index] << 8) | data[index - 1]);
3376 else
3378 rslt = BMI2_E_NULL_PTR;
3381 return rslt;
3385 * @brief This API reads the user-defined bytes of data from the given register
3386 * address of auxiliary sensor in manual mode.
3388 * @note Change of BMI2_AUX_RD_ADDR is only allowed if AUX is not busy.
3390 int8_t bmi2_read_aux_man_mode(uint8_t reg_addr, uint8_t *aux_data, uint16_t len, struct bmi2_dev *dev)
3392 /* Variable to define error */
3393 int8_t rslt;
3395 /* Variable to store burst length */
3396 uint8_t burst_len = 0;
3398 /* Variable to define APS status */
3399 uint8_t aps_stat = 0;
3401 /* Null-pointer check */
3402 rslt = null_ptr_check(dev);
3403 if ((rslt == BMI2_OK) && (aux_data != NULL))
3405 /* Validate if manual mode */
3406 if (dev->aux_man_en)
3408 /* Get status of advance power save mode */
3409 aps_stat = dev->aps_status;
3410 if (aps_stat == BMI2_ENABLE)
3412 /* Disable APS if enabled */
3413 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
3416 if (rslt == BMI2_OK)
3418 /* Map the register value set to that of burst
3419 * length
3421 rslt = map_read_len(&burst_len, dev);
3422 if (rslt == BMI2_OK)
3424 /* Read auxiliary data */
3425 rslt = read_aux_data(reg_addr, aux_data, len, burst_len, dev);
3429 /* Enable Advance power save if disabled for reading
3430 * data and not when already disabled
3432 if ((rslt == BMI2_OK) && (aps_stat == BMI2_ENABLE))
3434 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
3437 else
3439 rslt = BMI2_E_AUX_INVALID_CFG;
3442 else
3444 rslt = BMI2_E_NULL_PTR;
3447 return rslt;
3451 * @brief This API writes the user-defined bytes of data and the address of
3452 * auxiliary sensor where data is to be written in manual mode.
3454 * @note Change of BMI2_AUX_WR_ADDR is only allowed if AUX is not busy.
3456 int8_t bmi2_write_aux_man_mode(uint8_t reg_addr, const uint8_t *aux_data, uint16_t len, struct bmi2_dev *dev)
3458 /* Variable to define error */
3459 int8_t rslt;
3461 /* Variable to define loop */
3462 uint8_t loop = 0;
3464 /* Variable to define APS status */
3465 uint8_t aps_stat = 0;
3467 /* Null-pointer check */
3468 rslt = null_ptr_check(dev);
3469 if ((rslt == BMI2_OK) && (aux_data != NULL))
3471 /* Validate if manual mode */
3472 if (dev->aux_man_en)
3474 /* Get status of advance power save mode */
3475 aps_stat = dev->aps_status;
3476 if (aps_stat == BMI2_ENABLE)
3478 /* Disable APS if enabled */
3479 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
3482 /* Byte write data in the corresponding address */
3483 if (rslt == BMI2_OK)
3485 for (; ((loop < len) && (rslt == BMI2_OK)); loop++)
3487 rslt = write_aux_data((reg_addr + loop), aux_data[loop], dev);
3488 dev->delay_us(1000, dev->intf_ptr);
3492 /* Enable Advance power save if disabled for writing
3493 * data and not when already disabled
3495 if ((rslt == BMI2_OK) && (aps_stat == BMI2_ENABLE))
3497 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
3500 else
3502 rslt = BMI2_E_AUX_INVALID_CFG;
3505 else
3507 rslt = BMI2_E_NULL_PTR;
3510 return rslt;
3514 * @brief This API writes the user-defined bytes of data and the address of
3515 * auxiliary sensor where data is to be written, from an interleaved input,
3516 * in manual mode.
3518 * @note Change of BMI2_AUX_WR_ADDR is only allowed if AUX is not busy.
3520 int8_t bmi2_write_aux_interleaved(uint8_t reg_addr, const uint8_t *aux_data, uint16_t len, struct bmi2_dev *dev)
3522 /* Variable to define error */
3523 int8_t rslt;
3525 /* Variable to define loop */
3526 uint8_t loop = 1;
3528 /* Variable to define APS status */
3529 uint8_t aps_stat = 0;
3531 /* Null-pointer check */
3532 rslt = null_ptr_check(dev);
3533 if ((rslt == BMI2_OK) && (aux_data != NULL))
3535 /* Validate if manual mode */
3536 if (dev->aux_man_en)
3538 /* Get status of advance power save mode */
3539 aps_stat = dev->aps_status;
3540 if (aps_stat == BMI2_ENABLE)
3542 /* Disable APS if enabled */
3543 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
3546 if (rslt == BMI2_OK)
3548 /* Write the start register address extracted
3549 * from the interleaved data
3551 rslt = write_aux_data(reg_addr, aux_data[0], dev);
3553 /* Extract the remaining address and data from
3554 * the interleaved data and write it in the
3555 * corresponding addresses byte by byte
3557 for (; ((loop < len) && (rslt == BMI2_OK)); loop += 2)
3559 rslt = write_aux_data(aux_data[loop], aux_data[loop + 1], dev);
3560 dev->delay_us(1000, dev->intf_ptr);
3563 /* Enable Advance power save if disabled for
3564 * writing data and not when already disabled
3566 if ((rslt == BMI2_OK) && (aps_stat == BMI2_ENABLE))
3568 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
3572 else
3574 rslt = BMI2_E_AUX_INVALID_CFG;
3577 else
3579 rslt = BMI2_E_NULL_PTR;
3582 return rslt;
3586 * @brief This API gets the data ready status of accelerometer, gyroscope,
3587 * auxiliary, command decoder and busy status of auxiliary.
3589 int8_t bmi2_get_status(uint8_t *status, struct bmi2_dev *dev)
3591 /* Variable to define error */
3592 int8_t rslt;
3594 /* Null-pointer check */
3595 rslt = null_ptr_check(dev);
3596 if ((rslt == BMI2_OK) && (status != NULL))
3598 rslt = bmi2_get_regs(BMI2_STATUS_ADDR, status, 1, dev);
3600 else
3602 rslt = BMI2_E_NULL_PTR;
3605 return rslt;
3609 * @brief This API enables/disables OIS interface.
3611 int8_t bmi2_set_ois_interface(uint8_t enable, struct bmi2_dev *dev)
3613 /* Variable to define error */
3614 int8_t rslt;
3616 /* Variable to store data */
3617 uint8_t reg_data = 0;
3619 /* Null-pointer check */
3620 rslt = null_ptr_check(dev);
3621 if (rslt == BMI2_OK)
3623 rslt = bmi2_get_regs(BMI2_IF_CONF_ADDR, &reg_data, 1, dev);
3624 if (rslt == BMI2_OK)
3626 /* Enable/Disable OIS interface */
3627 reg_data = BMI2_SET_BITS(reg_data, BMI2_OIS_IF_EN, enable);
3628 if (enable)
3630 /* Disable auxiliary interface if OIS is enabled */
3631 reg_data = BMI2_SET_BIT_VAL0(reg_data, BMI2_AUX_IF_EN);
3634 /* Set the OIS interface configurations */
3635 rslt = bmi2_set_regs(BMI2_IF_CONF_ADDR, &reg_data, 1, dev);
3639 return rslt;
3643 * @brief This API can be used to write sync commands like ODR, sync period,
3644 * frequency and phase, resolution ratio, sync time and delay time.
3646 int8_t bmi2_write_sync_commands(const uint8_t *command, uint8_t n_comm, struct bmi2_dev *dev)
3648 /* Variable to define error */
3649 int8_t rslt;
3651 /* Null-pointer check */
3652 rslt = null_ptr_check(dev);
3653 if ((rslt == BMI2_OK) && (command != NULL))
3655 rslt = bmi2_set_regs(BMI2_SYNC_COMMAND_ADDR, command, n_comm, dev);
3657 else
3659 rslt = BMI2_E_NULL_PTR;
3662 return rslt;
3666 * @brief This API performs self-test to check the proper functionality of the
3667 * accelerometer sensor.
3669 int8_t bmi2_perform_accel_self_test(struct bmi2_dev *dev)
3671 /* Variable to define error */
3672 int8_t rslt;
3674 /* Variable to store self-test result */
3675 int8_t st_rslt = 0;
3677 /* Structure to define positive accelerometer axes */
3678 struct bmi2_sens_axes_data positive = { 0, 0, 0, 0 };
3680 /* Structure to define negative accelerometer axes */
3681 struct bmi2_sens_axes_data negative = { 0, 0, 0, 0 };
3683 /* Structure for difference of accelerometer values in g */
3684 struct bmi2_selftest_delta_limit accel_data_diff = { 0, 0, 0 };
3686 /* Structure for difference of accelerometer values in mg */
3687 struct bmi2_selftest_delta_limit accel_data_diff_mg = { 0, 0, 0 };
3689 /* Initialize the polarity of self-test as positive */
3690 int8_t sign = BMI2_ENABLE;
3692 /* Null-pointer check */
3693 rslt = null_ptr_check(dev);
3694 if (rslt == BMI2_OK)
3696 /* Sets the configuration required before enabling self-test */
3697 rslt = pre_self_test_config(dev);
3699 /* Wait for greater than 2 milliseconds */
3700 dev->delay_us(3000, dev->intf_ptr);
3701 if (rslt == BMI2_OK)
3705 /* Select positive first, then negative polarity
3706 * after enabling self-test
3708 rslt = self_test_config((uint8_t) sign, dev);
3709 if (rslt == BMI2_OK)
3711 /* Wait for greater than 50 milli-sec */
3712 dev->delay_us(51000, dev->intf_ptr);
3714 /* If polarity is positive */
3715 if (sign == BMI2_ENABLE)
3717 /* Read and store positive acceleration value */
3718 rslt = read_accel_xyz(&positive, dev);
3720 /* If polarity is negative */
3721 else if (sign == BMI2_DISABLE)
3723 /* Read and store negative acceleration value */
3724 rslt = read_accel_xyz(&negative, dev);
3727 else
3729 /* Break if error */
3730 break;
3733 /* Break if error */
3734 if (rslt != BMI2_OK)
3736 break;
3739 /* Turn the polarity of self-test negative */
3740 sign--;
3741 } while (sign >= 0);
3742 if (rslt == BMI2_OK)
3744 /* Subtract -ve acceleration values from that of +ve values */
3745 accel_data_diff.x = (positive.x) - (negative.x);
3746 accel_data_diff.y = (positive.y) - (negative.y);
3747 accel_data_diff.z = (positive.z) - (negative.z);
3749 /* Convert differences of acceleration values
3750 * from 'g' to 'mg'
3752 convert_lsb_g(&accel_data_diff, &accel_data_diff_mg, dev);
3754 /* Validate self-test for acceleration values
3755 * in mg and get the self-test result
3757 st_rslt = validate_self_test(&accel_data_diff_mg);
3759 /* Trigger a soft reset after performing self-test */
3760 rslt = bmi2_soft_reset(dev);
3762 /* Return the self-test result */
3763 if (rslt == BMI2_OK)
3765 rslt = st_rslt;
3771 return rslt;
3775 * @brief This API maps/unmaps feature interrupts to that of interrupt pins.
3777 int8_t bmi2_map_feat_int(uint8_t type, enum bmi2_hw_int_pin hw_int_pin, struct bmi2_dev *dev)
3779 /* Variable to define error */
3780 int8_t rslt;
3782 /* Variable to define the value of feature interrupts */
3783 uint8_t feat_int = 0;
3785 /* Array to store the interrupt mask bits */
3786 uint8_t data_array[2] = { 0 };
3788 /* Structure to define map the interrupts */
3789 struct bmi2_map_int map_int = { 0 };
3791 /* Null-pointer check */
3792 rslt = null_ptr_check(dev);
3793 if (rslt == BMI2_OK)
3795 /* Read interrupt map1 and map2 and register */
3796 rslt = bmi2_get_regs(BMI2_INT1_MAP_FEAT_ADDR, data_array, 2, dev);
3798 if (rslt == BMI2_OK)
3800 /* Get the value of the feature interrupt to be mapped */
3801 extract_feat_int_map(&map_int, type, dev);
3803 feat_int = map_int.sens_map_int;
3805 /* Map the interrupts */
3806 rslt = map_feat_int(data_array, hw_int_pin, feat_int);
3808 /* Map the interrupts to INT1 and INT2 map register */
3809 if (rslt == BMI2_OK)
3811 rslt = bmi2_set_regs(BMI2_INT1_MAP_FEAT_ADDR, &data_array[0], 1, dev);
3812 if (rslt == BMI2_OK)
3814 rslt = bmi2_set_regs(BMI2_INT2_MAP_FEAT_ADDR, &data_array[1], 1, dev);
3819 else
3821 rslt = BMI2_E_NULL_PTR;
3824 return rslt;
3828 * @brief This API maps/un-maps data interrupts to that of interrupt pins.
3830 int8_t bmi2_map_data_int(uint8_t data_int, enum bmi2_hw_int_pin int_pin, struct bmi2_dev *dev)
3832 /* Variable to define error */
3833 int8_t rslt;
3835 /* Variable to mask interrupt pin 1 - lower nibble */
3836 uint8_t int1_mask = data_int;
3838 /* Variable to mask interrupt pin 2 - higher nibble */
3839 uint8_t int2_mask = (uint8_t)(data_int << 4);
3841 /* Variable to store register data */
3842 uint8_t reg_data = 0;
3844 /* Read interrupt map1 and map2 and register */
3845 rslt = bmi2_get_regs(BMI2_INT_MAP_DATA_ADDR, &reg_data, 1, dev);
3846 if (rslt == BMI2_OK)
3848 if (int_pin < BMI2_INT_PIN_MAX)
3850 switch (int_pin)
3852 case BMI2_INT_NONE:
3854 /* Un-Map the corresponding data
3855 * interrupt to both interrupt pin 1 and 2
3857 reg_data &= ~(int1_mask | int2_mask);
3858 break;
3859 case BMI2_INT1:
3861 /* Map the corresponding data interrupt to
3862 * interrupt pin 1
3864 reg_data |= int1_mask;
3865 break;
3866 case BMI2_INT2:
3868 /* Map the corresponding data interrupt to
3869 * interrupt pin 2
3871 reg_data |= int2_mask;
3872 break;
3873 case BMI2_INT_BOTH:
3875 /* Map the corresponding data
3876 * interrupt to both interrupt pin 1 and 2
3878 reg_data |= (int1_mask | int2_mask);
3879 break;
3880 default:
3881 break;
3884 /* Set the interrupts in the map register */
3885 rslt = bmi2_set_regs(BMI2_INT_MAP_DATA_ADDR, &reg_data, 1, dev);
3887 else
3889 /* Return error if invalid pin selection */
3890 rslt = BMI2_E_INVALID_INT_PIN;
3894 return rslt;
3898 * @brief This API gets the re-mapped x, y and z axes from the sensor and
3899 * updates the values in the device structure.
3901 int8_t bmi2_get_remap_axes(struct bmi2_remap *remapped_axis, struct bmi2_dev *dev)
3903 /* Variable to define error */
3904 int8_t rslt;
3906 /* Initialize the local structure for axis re-mapping */
3907 struct bmi2_axes_remap remap = { 0, 0, 0, 0, 0, 0 };
3909 /* Null-pointer check */
3910 rslt = null_ptr_check(dev);
3911 if ((rslt == BMI2_OK) && (remapped_axis != NULL))
3913 /* Get the re-mapped axes from the sensor */
3914 rslt = get_remap_axes(&remap, dev);
3915 if (rslt == BMI2_OK)
3917 /* Store the re-mapped x-axis value in device structure
3918 * and its user-value in the interface structure
3920 switch (remap.x_axis)
3922 case BMI2_MAP_X_AXIS:
3924 /* If mapped to x-axis */
3925 dev->remap.x_axis = BMI2_MAP_X_AXIS;
3926 remapped_axis->x = BMI2_X;
3927 break;
3928 case BMI2_MAP_Y_AXIS:
3930 /* If mapped to y-axis */
3931 dev->remap.x_axis = BMI2_MAP_Y_AXIS;
3932 remapped_axis->x = BMI2_Y;
3933 break;
3934 case BMI2_MAP_Z_AXIS:
3936 /* If mapped to z-axis */
3937 dev->remap.x_axis = BMI2_MAP_Z_AXIS;
3938 remapped_axis->x = BMI2_Z;
3939 break;
3940 default:
3941 break;
3944 /* Store the re-mapped x-axis sign in device structure
3945 * and its user-value in the interface structure
3947 if (remap.x_axis_sign)
3949 /* If x-axis is mapped to -ve sign */
3950 dev->remap.x_axis_sign = BMI2_NEG_SIGN;
3951 remapped_axis->x |= BMI2_AXIS_SIGN;
3953 else
3955 dev->remap.x_axis_sign = BMI2_POS_SIGN;
3958 /* Store the re-mapped y-axis value in device structure
3959 * and its user-value in the interface structure
3961 switch (remap.y_axis)
3963 case BMI2_MAP_X_AXIS:
3965 /* If mapped to x-axis */
3966 dev->remap.y_axis = BMI2_MAP_X_AXIS;
3967 remapped_axis->y = BMI2_X;
3968 break;
3969 case BMI2_MAP_Y_AXIS:
3971 /* If mapped to y-axis */
3972 dev->remap.y_axis = BMI2_MAP_Y_AXIS;
3973 remapped_axis->y = BMI2_Y;
3974 break;
3975 case BMI2_MAP_Z_AXIS:
3977 /* If mapped to z-axis */
3978 dev->remap.y_axis = BMI2_MAP_Z_AXIS;
3979 remapped_axis->y = BMI2_Z;
3980 break;
3981 default:
3982 break;
3985 /* Store the re-mapped y-axis sign in device structure
3986 * and its user-value in the interface structure
3988 if (remap.y_axis_sign)
3990 /* If y-axis is mapped to -ve sign */
3991 dev->remap.y_axis_sign = BMI2_NEG_SIGN;
3992 remapped_axis->y |= BMI2_AXIS_SIGN;
3994 else
3996 dev->remap.y_axis_sign = BMI2_POS_SIGN;
3999 /* Store the re-mapped z-axis value in device structure
4000 * and its user-value in the interface structure
4002 switch (remap.z_axis)
4004 case BMI2_MAP_X_AXIS:
4006 /* If mapped to x-axis */
4007 dev->remap.z_axis = BMI2_MAP_X_AXIS;
4008 remapped_axis->z = BMI2_X;
4009 break;
4010 case BMI2_MAP_Y_AXIS:
4012 /* If mapped to y-axis */
4013 dev->remap.z_axis = BMI2_MAP_Y_AXIS;
4014 remapped_axis->z = BMI2_Y;
4015 break;
4016 case BMI2_MAP_Z_AXIS:
4018 /* If mapped to z-axis */
4019 dev->remap.z_axis = BMI2_MAP_Z_AXIS;
4020 remapped_axis->z = BMI2_Z;
4021 break;
4022 default:
4023 break;
4026 /* Store the re-mapped z-axis sign in device structure
4027 * and its user-value in the interface structure
4029 if (remap.z_axis_sign)
4031 /* If z-axis is mapped to -ve sign */
4032 dev->remap.z_axis_sign = BMI2_NEG_SIGN;
4033 remapped_axis->z |= BMI2_AXIS_SIGN;
4035 else
4037 dev->remap.z_axis_sign = BMI2_POS_SIGN;
4041 else
4043 rslt = BMI2_E_NULL_PTR;
4046 return rslt;
4050 * @brief This API sets the re-mapped x, y and z axes to the sensor and
4051 * updates the them in the device structure.
4053 int8_t bmi2_set_remap_axes(const struct bmi2_remap *remapped_axis, struct bmi2_dev *dev)
4055 /* Variable to define error */
4056 int8_t rslt;
4058 /* Variable to store all the re-mapped axes */
4059 uint8_t remap_axes = 0;
4061 /* Variable to store the re-mapped x-axes */
4062 uint8_t remap_x = 0;
4064 /* Variable to store the re-mapped y-axes */
4065 uint8_t remap_y = 0;
4067 /* Variable to store the re-mapped z-axes */
4068 uint8_t remap_z = 0;
4070 /* Initialize the local structure for axis re-mapping */
4071 struct bmi2_axes_remap remap = { 0, 0, 0, 0, 0, 0 };
4073 /* Null-pointer check */
4074 rslt = null_ptr_check(dev);
4075 if ((rslt == BMI2_OK) && (remapped_axis != NULL))
4077 /* Check whether all the axes are re-mapped */
4078 remap_axes = remapped_axis->x | remapped_axis->y | remapped_axis->z;
4080 /* If all the axes are re-mapped */
4081 if ((remap_axes & BMI2_AXIS_MASK) == BMI2_AXIS_MASK)
4083 /* Get the re-mapped value of x, y and z axis */
4084 remap_x = remapped_axis->x & BMI2_AXIS_MASK;
4085 remap_y = remapped_axis->y & BMI2_AXIS_MASK;
4086 remap_z = remapped_axis->z & BMI2_AXIS_MASK;
4088 /* Store the value of re-mapped x-axis in both
4089 * device structure and the local structure
4091 switch (remap_x)
4093 case BMI2_X:
4095 /* If mapped to x-axis */
4096 dev->remap.x_axis = BMI2_MAP_X_AXIS;
4097 remap.x_axis = BMI2_MAP_X_AXIS;
4098 break;
4099 case BMI2_Y:
4101 /* If mapped to y-axis */
4102 dev->remap.x_axis = BMI2_MAP_Y_AXIS;
4103 remap.x_axis = BMI2_MAP_Y_AXIS;
4104 break;
4105 case BMI2_Z:
4107 /* If mapped to z-axis */
4108 dev->remap.x_axis = BMI2_MAP_Z_AXIS;
4109 remap.x_axis = BMI2_MAP_Z_AXIS;
4110 break;
4111 default:
4112 break;
4115 /* Store the re-mapped x-axis sign in the device
4116 * structure and its value in local structure
4118 if (remapped_axis->x & BMI2_AXIS_SIGN)
4120 /* If x-axis is mapped to -ve sign */
4121 dev->remap.x_axis_sign = BMI2_NEG_SIGN;
4122 remap.x_axis_sign = BMI2_MAP_NEGATIVE;
4124 else
4126 dev->remap.x_axis_sign = BMI2_POS_SIGN;
4127 remap.x_axis_sign = BMI2_MAP_POSITIVE;
4130 /* Store the value of re-mapped y-axis in both
4131 * device structure and the local structure
4133 switch (remap_y)
4135 case BMI2_X:
4137 /* If mapped to x-axis */
4138 dev->remap.y_axis = BMI2_MAP_X_AXIS;
4139 remap.y_axis = BMI2_MAP_X_AXIS;
4140 break;
4141 case BMI2_Y:
4143 /* If mapped to y-axis */
4144 dev->remap.y_axis = BMI2_MAP_Y_AXIS;
4145 remap.y_axis = BMI2_MAP_Y_AXIS;
4146 break;
4147 case BMI2_Z:
4149 /* If mapped to z-axis */
4150 dev->remap.y_axis = BMI2_MAP_Z_AXIS;
4151 remap.y_axis = BMI2_MAP_Z_AXIS;
4152 break;
4153 default:
4154 break;
4157 /* Store the re-mapped y-axis sign in the device
4158 * structure and its value in local structure
4160 if (remapped_axis->y & BMI2_AXIS_SIGN)
4162 /* If y-axis is mapped to -ve sign */
4163 dev->remap.y_axis_sign = BMI2_NEG_SIGN;
4164 remap.y_axis_sign = BMI2_MAP_NEGATIVE;
4166 else
4168 dev->remap.y_axis_sign = BMI2_POS_SIGN;
4169 remap.y_axis_sign = BMI2_MAP_POSITIVE;
4172 /* Store the value of re-mapped z-axis in both
4173 * device structure and the local structure
4175 switch (remap_z)
4177 case BMI2_X:
4179 /* If mapped to x-axis */
4180 dev->remap.z_axis = BMI2_MAP_X_AXIS;
4181 remap.z_axis = BMI2_MAP_X_AXIS;
4182 break;
4183 case BMI2_Y:
4185 /* If mapped to y-axis */
4186 dev->remap.z_axis = BMI2_MAP_Y_AXIS;
4187 remap.z_axis = BMI2_MAP_Y_AXIS;
4188 break;
4189 case BMI2_Z:
4191 /* If mapped to z-axis */
4192 dev->remap.z_axis = BMI2_MAP_Z_AXIS;
4193 remap.z_axis = BMI2_MAP_Z_AXIS;
4194 break;
4195 default:
4196 break;
4199 /* Store the re-mapped z-axis sign in the device
4200 * structure and its value in local structure
4202 if (remapped_axis->z & BMI2_AXIS_SIGN)
4204 /* If z-axis is mapped to -ve sign */
4205 dev->remap.z_axis_sign = BMI2_NEG_SIGN;
4206 remap.z_axis_sign = BMI2_MAP_NEGATIVE;
4208 else
4210 dev->remap.z_axis_sign = BMI2_POS_SIGN;
4211 remap.z_axis_sign = BMI2_MAP_POSITIVE;
4214 /* Set the re-mapped axes in the sensor */
4215 rslt = set_remap_axes(&remap, dev);
4217 else
4219 rslt = BMI2_E_REMAP_ERROR;
4222 else
4224 rslt = BMI2_E_NULL_PTR;
4227 return rslt;
4231 * @brief This API enables/disables gyroscope offset compensation. It adds the
4232 * offsets defined in the offset register with gyroscope data.
4234 int8_t bmi2_set_gyro_offset_comp(uint8_t enable, struct bmi2_dev *dev)
4236 /* Variable to define error */
4237 int8_t rslt;
4239 /* Variable to define register data */
4240 uint8_t reg_data = 0;
4242 /* Null-pointer check */
4243 rslt = null_ptr_check(dev);
4244 if (rslt == BMI2_OK)
4246 /* Get the status of gyroscope offset enable */
4247 rslt = bmi2_get_regs(BMI2_GYR_OFF_COMP_6_ADDR, &reg_data, 1, dev);
4248 if (rslt == BMI2_OK)
4250 reg_data = BMI2_SET_BITS(reg_data, BMI2_GYR_OFF_COMP_EN, enable);
4252 /* Enable/Disable gyroscope offset compensation */
4253 rslt = bmi2_set_regs(BMI2_GYR_OFF_COMP_6_ADDR, &reg_data, 1, dev);
4256 else
4258 rslt = BMI2_E_NULL_PTR;
4261 return rslt;
4265 * @brief This API reads the gyroscope bias values for each axis which is used
4266 * for gyroscope offset compensation.
4268 int8_t bmi2_read_gyro_offset_comp_axes(struct bmi2_sens_axes_data *gyr_off_comp_axes, struct bmi2_dev *dev)
4270 /* Variable to define error */
4271 int8_t rslt;
4273 /* Variable to define register data */
4274 uint8_t reg_data[4] = { 0 };
4276 /* Variable to store LSB value of offset compensation for x-axis */
4277 uint8_t gyr_off_lsb_x;
4279 /* Variable to store LSB value of offset compensation for y-axis */
4280 uint8_t gyr_off_lsb_y;
4282 /* Variable to store LSB value of offset compensation for z-axis */
4283 uint8_t gyr_off_lsb_z;
4285 /* Variable to store MSB value of offset compensation for x-axis */
4286 uint8_t gyr_off_msb_x;
4288 /* Variable to store MSB value of offset compensation for y-axis */
4289 uint8_t gyr_off_msb_y;
4291 /* Variable to store MSB value of offset compensation for z-axis */
4292 uint8_t gyr_off_msb_z;
4294 /* Null-pointer check */
4295 rslt = null_ptr_check(dev);
4296 if ((rslt == BMI2_OK) && (gyr_off_comp_axes != NULL))
4298 /* Get the gyroscope compensated offset values */
4299 rslt = bmi2_get_regs(BMI2_GYR_OFF_COMP_3_ADDR, reg_data, 4, dev);
4300 if (rslt == BMI2_OK)
4302 /* Get LSB and MSB values of offset compensation for
4303 * x, y and z axis
4305 gyr_off_lsb_x = reg_data[0];
4306 gyr_off_lsb_y = reg_data[1];
4307 gyr_off_lsb_z = reg_data[2];
4308 gyr_off_msb_x = reg_data[3] & BMI2_GYR_OFF_COMP_MSB_X_MASK;
4309 gyr_off_msb_y = reg_data[3] & BMI2_GYR_OFF_COMP_MSB_Y_MASK;
4310 gyr_off_msb_z = reg_data[3] & BMI2_GYR_OFF_COMP_MSB_Z_MASK;
4312 /* Gyroscope offset compensation value for x-axis */
4313 gyr_off_comp_axes->x = (int16_t)(((uint16_t) gyr_off_msb_x << 8) | gyr_off_lsb_x);
4315 /* Gyroscope offset compensation value for y-axis */
4316 gyr_off_comp_axes->y = (int16_t)(((uint16_t) gyr_off_msb_y << 6) | gyr_off_lsb_y);
4318 /* Gyroscope offset compensation value for z-axis */
4319 gyr_off_comp_axes->z = (int16_t)(((uint16_t) gyr_off_msb_z << 4) | gyr_off_lsb_z);
4322 else
4324 rslt = BMI2_E_NULL_PTR;
4327 return rslt;
4331 * @brief This API writes the gyroscope bias values for each axis which is used
4332 * for gyroscope offset compensation.
4334 int8_t bmi2_write_gyro_offset_comp_axes(const struct bmi2_sens_axes_data *gyr_off_comp_axes, struct bmi2_dev *dev)
4336 /* Variable to define error */
4337 int8_t rslt;
4339 /* Variable to define register data */
4340 uint8_t reg_data[4] = { 0 };
4342 /* Variable to store MSB value of offset compensation for x-axis */
4343 uint8_t gyr_off_msb_x;
4345 /* Variable to store MSB value of offset compensation for y-axis */
4346 uint8_t gyr_off_msb_y;
4348 /* Variable to store MSB value of offset compensation for z-axis */
4349 uint8_t gyr_off_msb_z;
4351 /* Null-pointer check */
4352 rslt = null_ptr_check(dev);
4353 if ((rslt == BMI2_OK) && (gyr_off_comp_axes != NULL))
4355 /* Get the MSB values of gyroscope compensated offset values */
4356 rslt = bmi2_get_regs(BMI2_GYR_OFF_COMP_6_ADDR, &reg_data[3], 1, dev);
4357 if (rslt == BMI2_OK)
4359 /* Get MSB value of x-axis from user-input */
4360 gyr_off_msb_x = (uint8_t)((gyr_off_comp_axes->x & BMI2_GYR_OFF_COMP_MSB_MASK) >> 8);
4362 /* Get MSB value of y-axis from user-input */
4363 gyr_off_msb_y = (uint8_t)((gyr_off_comp_axes->y & BMI2_GYR_OFF_COMP_MSB_MASK) >> 8);
4365 /* Get MSB value of z-axis from user-input */
4366 gyr_off_msb_z = (uint8_t)((gyr_off_comp_axes->z & BMI2_GYR_OFF_COMP_MSB_MASK) >> 8);
4368 /* Get LSB value of x-axis from user-input */
4369 reg_data[0] = (uint8_t)(gyr_off_comp_axes->x & BMI2_GYR_OFF_COMP_LSB_MASK);
4371 /* Get LSB value of y-axis from user-input */
4372 reg_data[1] = (uint8_t)(gyr_off_comp_axes->y & BMI2_GYR_OFF_COMP_LSB_MASK);
4374 /* Get LSB value of z-axis from user-input */
4375 reg_data[2] = (uint8_t)(gyr_off_comp_axes->z & BMI2_GYR_OFF_COMP_LSB_MASK);
4377 /* Get MSB value of x-axis to be set */
4378 reg_data[3] = BMI2_SET_BIT_POS0(reg_data[3], BMI2_GYR_OFF_COMP_MSB_X, gyr_off_msb_x);
4380 /* Get MSB value of y-axis to be set */
4381 reg_data[3] = BMI2_SET_BITS(reg_data[3], BMI2_GYR_OFF_COMP_MSB_Y, gyr_off_msb_y);
4383 /* Get MSB value of z-axis to be set */
4384 reg_data[3] = BMI2_SET_BITS(reg_data[3], BMI2_GYR_OFF_COMP_MSB_Z, gyr_off_msb_z);
4386 /* Set the offset compensation values of axes */
4387 rslt = bmi2_set_regs(BMI2_GYR_OFF_COMP_3_ADDR, reg_data, 4, dev);
4390 else
4392 rslt = BMI2_E_NULL_PTR;
4395 return rslt;
4399 * @brief This API updates the cross sensitivity coefficient between gyroscope's
4400 * X and Z axes.
4402 int8_t bmi2_get_gyro_cross_sense(struct bmi2_dev *dev)
4404 /* Variable to define error */
4405 int8_t rslt = BMI2_OK;
4406 struct bmi2_sensor_data data;
4408 /* Check if the feature is supported by this variant */
4409 if (dev->variant_feature & BMI2_GYRO_CROSS_SENS_ENABLE)
4411 rslt = null_ptr_check(dev);
4412 if (rslt == BMI2_OK)
4414 /* Select the feature whose data is to be acquired */
4415 data.type = BMI2_GYRO_CROSS_SENSE;
4417 /* Get the respective data */
4418 rslt = bmi2_get_sensor_data(&data, 1, dev);
4419 if (rslt == BMI2_OK)
4421 /* Update the gyroscope cross sense value of z axis
4422 * in the device structure
4424 dev->gyr_cross_sens_zx = data.sens_data.correction_factor_zx;
4427 else
4429 rslt = BMI2_E_NULL_PTR;
4433 return rslt;
4437 * @brief This API gets Error bits and message indicating internal status.
4439 int8_t bmi2_get_internal_status(uint8_t *int_stat, struct bmi2_dev *dev)
4441 /* Variable to define error */
4442 int8_t rslt;
4444 /* Null-pointer check */
4445 rslt = null_ptr_check(dev);
4446 if ((rslt == BMI2_OK) && (int_stat != NULL))
4448 /* Delay to read the internal status */
4449 dev->delay_us(20000, dev->intf_ptr);
4451 /* Get the error bits and message */
4452 rslt = bmi2_get_regs(BMI2_INTERNAL_STATUS_ADDR, int_stat, 1, dev);
4454 else
4456 rslt = BMI2_E_NULL_PTR;
4459 return rslt;
4462 /*! @cond DOXYGEN_SUPRESS */
4464 /* Suppressing doxygen warnings triggered for same static function names present across various sensor variant
4465 * directories */
4468 * @brief This API verifies and allows only the correct position to do Fast Offset Compensation for
4469 * accelerometer & gyro.
4471 static int8_t verify_foc_position(uint8_t sens_list,
4472 const struct bmi2_accel_foc_g_value *accel_g_axis,
4473 struct bmi2_dev *dev)
4475 int8_t rslt;
4477 struct bmi2_sens_axes_data avg_foc_data = { 0 };
4478 struct bmi2_foc_temp_value temp_foc_data = { 0 };
4480 rslt = null_ptr_check(dev);
4481 if (rslt == BMI2_OK)
4483 /* Enable sensor */
4484 rslt = bmi2_sensor_enable(&sens_list, 1, dev);
4487 if (rslt == BMI2_OK)
4490 rslt = get_average_of_sensor_data(sens_list, &temp_foc_data, dev);
4491 if (rslt == BMI2_OK)
4493 if (sens_list == BMI2_ACCEL)
4496 /* Taking modulus to make negative values as positive */
4497 if ((accel_g_axis->x == 1) && (accel_g_axis->sign == 1))
4499 temp_foc_data.x = temp_foc_data.x * -1;
4501 else if ((accel_g_axis->y == 1) && (accel_g_axis->sign == 1))
4503 temp_foc_data.y = temp_foc_data.y * -1;
4505 else if ((accel_g_axis->z == 1) && (accel_g_axis->sign == 1))
4507 temp_foc_data.z = temp_foc_data.z * -1;
4511 /* Typecasting into 16bit */
4512 avg_foc_data.x = (int16_t)(temp_foc_data.x);
4513 avg_foc_data.y = (int16_t)(temp_foc_data.y);
4514 avg_foc_data.z = (int16_t)(temp_foc_data.z);
4516 rslt = validate_foc_position(sens_list, accel_g_axis, avg_foc_data, dev);
4520 return rslt;
4523 /*! @endcond */
4526 * @brief This API performs Fast Offset Compensation for accelerometer.
4528 int8_t bmi2_perform_accel_foc(const struct bmi2_accel_foc_g_value *accel_g_value, struct bmi2_dev *dev)
4530 /* Variable to define error */
4531 int8_t rslt;
4533 /* Structure to define the accelerometer configurations */
4534 struct bmi2_accel_config acc_cfg = { 0, 0, 0, 0 };
4536 /* Variable to store status of advance power save */
4537 uint8_t aps = 0;
4539 /* Variable to store status of accelerometer enable */
4540 uint8_t acc_en = 0;
4542 /* Null-pointer check */
4543 rslt = null_ptr_check(dev);
4544 if ((rslt == BMI2_OK) && (accel_g_value != NULL))
4546 /* Check for input validity */
4547 if ((((BMI2_ABS(accel_g_value->x)) + (BMI2_ABS(accel_g_value->y)) + (BMI2_ABS(accel_g_value->z))) == 1) &&
4548 ((accel_g_value->sign == 1) || (accel_g_value->sign == 0)))
4550 rslt = verify_foc_position(BMI2_ACCEL, accel_g_value, dev);
4551 if (rslt == BMI2_OK)
4554 /* Save accelerometer configurations, accelerometer
4555 * enable status and advance power save status
4557 rslt = save_accel_foc_config(&acc_cfg, &aps, &acc_en, dev);
4560 /* Set configurations for FOC */
4561 if (rslt == BMI2_OK)
4563 rslt = set_accel_foc_config(dev);
4566 /* Perform accelerometer FOC */
4567 if (rslt == BMI2_OK)
4569 rslt = perform_accel_foc(accel_g_value, &acc_cfg, dev);
4572 /* Restore the saved configurations */
4573 if (rslt == BMI2_OK)
4575 rslt = restore_accel_foc_config(&acc_cfg, aps, acc_en, dev);
4578 else
4580 rslt = BMI2_E_INVALID_INPUT;
4583 else
4585 rslt = BMI2_E_NULL_PTR;
4588 return rslt;
4592 * @brief This API performs Fast Offset Compensation for gyroscope.
4594 int8_t bmi2_perform_gyro_foc(struct bmi2_dev *dev)
4596 /* Variable to define error */
4597 int8_t rslt;
4599 /* Structure to define the gyroscope configurations */
4600 struct bmi2_gyro_config gyr_cfg = { 0, 0, 0, 0, 0, 0 };
4602 /* Variable to store status of advance power save */
4603 uint8_t aps = 0;
4605 /* Variable to store status of gyroscope enable */
4606 uint8_t gyr_en = 0;
4608 /* Array of structure to store gyroscope data */
4609 struct bmi2_sens_axes_data gyr_value[128];
4611 /* Structure to store gyroscope data temporarily */
4612 struct bmi2_foc_temp_value temp = { 0, 0, 0 };
4614 /* Variable to store status read from the status register */
4615 uint8_t reg_status = 0;
4617 /* Variable to define count */
4618 uint8_t loop = 0;
4620 /* Structure to store the offset values to be stored in the register */
4621 struct bmi2_sens_axes_data gyro_offset = { 0, 0, 0, 0 };
4623 /* Null-pointer check */
4624 rslt = null_ptr_check(dev);
4625 if (rslt == BMI2_OK)
4627 /* Argument2 is not applicable for gyro */
4628 rslt = verify_foc_position(BMI2_GYRO, 0, dev);
4629 if (rslt == BMI2_OK)
4631 /* Save gyroscope configurations, gyroscope enable
4632 * status and advance power save status
4634 rslt = save_gyro_config(&gyr_cfg, &aps, &gyr_en, dev);
4636 /* Set configurations for gyroscope FOC */
4637 if (rslt == BMI2_OK)
4639 rslt = set_gyro_foc_config(dev);
4642 /* Perform FOC */
4643 if (rslt == BMI2_OK)
4645 for (loop = 0; loop < 128; loop++)
4647 /* Giving a delay of more than 40ms since ODR is configured as 25Hz */
4648 dev->delay_us(50000, dev->intf_ptr);
4650 /* Get gyroscope data ready interrupt status */
4651 rslt = bmi2_get_status(&reg_status, dev);
4653 /* Read 128 samples of gyroscope data on data ready interrupt */
4654 if ((rslt == BMI2_OK) && (reg_status & BMI2_DRDY_GYR))
4656 rslt = read_gyro_xyz(&gyr_value[loop], dev);
4657 if (rslt == BMI2_OK)
4659 /* Store the data in a temporary structure */
4660 temp.x = temp.x + (int32_t)gyr_value[loop].x;
4661 temp.y = temp.y + (int32_t)gyr_value[loop].y;
4662 temp.z = temp.z + (int32_t)gyr_value[loop].z;
4666 if (rslt != BMI2_OK)
4668 break;
4670 else if ((reg_status & BMI2_DRDY_GYR) != BMI2_DRDY_GYR)
4672 rslt = BMI2_E_INVALID_STATUS;
4673 break;
4677 if (rslt == BMI2_OK)
4679 /* Take average of x, y and z data for lesser
4680 * noise. It is same as offset data since lsb/dps
4681 * is same for both data and offset register
4683 gyro_offset.x = (int16_t)(temp.x / 128);
4684 gyro_offset.y = (int16_t)(temp.y / 128);
4685 gyro_offset.z = (int16_t)(temp.z / 128);
4687 /* Saturate gyroscope data since the offset
4688 * registers are of 10 bit value where as the
4689 * gyroscope data is of 16 bit value
4691 saturate_gyro_data(&gyro_offset);
4693 /* Invert the gyroscope offset data */
4694 invert_gyro_offset(&gyro_offset);
4696 /* Write offset data in the gyroscope offset
4697 * compensation register
4699 rslt = bmi2_write_gyro_offset_comp_axes(&gyro_offset, dev);
4702 /* Enable gyroscope offset compensation */
4703 if (rslt == BMI2_OK)
4705 rslt = bmi2_set_gyro_offset_comp(BMI2_ENABLE, dev);
4708 /* Restore the saved gyroscope configurations */
4709 if (rslt == BMI2_OK)
4711 rslt = restore_gyro_config(&gyr_cfg, aps, gyr_en, dev);
4717 return rslt;
4721 * @brief This API is used to get the feature configuration from the
4722 * selected page.
4724 int8_t bmi2_get_feat_config(uint8_t sw_page, uint8_t *feat_config, struct bmi2_dev *dev)
4726 /* Variable to define error */
4727 int8_t rslt;
4729 /* Variable to define bytes remaining to read */
4730 uint8_t bytes_remain = BMI2_FEAT_SIZE_IN_BYTES;
4732 /* Variable to define the read-write length */
4733 uint8_t read_write_len = 0;
4735 /* Variable to define the feature configuration address */
4736 uint8_t addr = BMI2_FEATURES_REG_ADDR;
4738 /* Variable to define index */
4739 uint8_t index = 0;
4741 if ((feat_config == NULL) || (dev == NULL))
4743 rslt = BMI2_E_NULL_PTR;
4745 else
4747 /* Check whether the page is valid */
4748 if (sw_page < dev->page_max)
4750 /* Switch page */
4751 rslt = bmi2_set_regs(BMI2_FEAT_PAGE_ADDR, &sw_page, 1, dev);
4753 /* If user length is less than feature length */
4754 if ((rslt == BMI2_OK) && (dev->read_write_len < BMI2_FEAT_SIZE_IN_BYTES))
4756 /* Read-write should be even */
4757 if ((dev->read_write_len % 2) != 0)
4759 dev->read_write_len--;
4762 while (bytes_remain > 0)
4764 if (bytes_remain >= dev->read_write_len)
4766 /* Read from the page */
4767 rslt = bmi2_get_regs(addr, &feat_config[index], dev->read_write_len, dev);
4769 /* Update index */
4770 index += (uint8_t) dev->read_write_len;
4772 /* Update address */
4773 addr += (uint8_t) dev->read_write_len;
4775 /* Update read-write length */
4776 read_write_len += (uint8_t) dev->read_write_len;
4778 else
4780 /* Read from the page */
4781 rslt = bmi2_get_regs(addr, (uint8_t *) (feat_config + index), (uint16_t) bytes_remain, dev);
4783 /* Update read-write length */
4784 read_write_len += bytes_remain;
4787 /* Remaining bytes */
4788 bytes_remain = BMI2_FEAT_SIZE_IN_BYTES - read_write_len;
4790 if (rslt != BMI2_OK)
4792 break;
4796 else if (rslt == BMI2_OK)
4798 /* Get configuration from the page */
4799 rslt = bmi2_get_regs(BMI2_FEATURES_REG_ADDR, feat_config, BMI2_FEAT_SIZE_IN_BYTES, dev);
4802 else
4804 rslt = BMI2_E_INVALID_PAGE;
4808 return rslt;
4812 * @brief This API is used to extract the input feature configuration
4813 * details from the look-up table.
4815 uint8_t bmi2_extract_input_feat_config(struct bmi2_feature_config *feat_config, uint8_t type,
4816 const struct bmi2_dev *dev)
4818 /* Variable to define loop */
4819 uint8_t loop = 0;
4821 /* Variable to set flag */
4822 uint8_t feat_found = BMI2_FALSE;
4824 /* Search for the input feature from the input configuration array */
4825 while (loop < dev->input_sens)
4827 if (dev->feat_config[loop].type == type)
4829 *feat_config = dev->feat_config[loop];
4830 feat_found = BMI2_TRUE;
4831 break;
4834 loop++;
4837 /* Return flag */
4838 return feat_found;
4841 /***************************************************************************/
4843 /*! Local Function Definitions
4844 ****************************************************************************/
4846 /*! @cond DOXYGEN_SUPRESS */
4848 /* Suppressing doxygen warnings triggered for same static function names present across various sensor variant
4849 * directories */
4852 * @brief This internal API writes the configuration file.
4854 static int8_t write_config_file(struct bmi2_dev *dev)
4856 /* Variable to define error */
4857 int8_t rslt;
4859 /* Variable to update the configuration file index */
4860 uint16_t index = 0;
4862 /* config file size */
4863 uint16_t config_size = dev->config_size;
4865 /* Variable to get the remainder */
4866 uint8_t remain = (uint8_t)(config_size % dev->read_write_len);
4868 /* Variable to get the balance bytes */
4869 uint16_t bal_byte = 0;
4871 /* Variable to define temporary read/write length */
4872 uint16_t read_write_len = 0;
4874 /* Disable advanced power save mode */
4875 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
4876 if (rslt == BMI2_OK)
4878 /* Disable loading of the configuration */
4879 rslt = set_config_load(BMI2_DISABLE, dev);
4880 if (rslt == BMI2_OK)
4882 if (!remain)
4884 /* Write the configuration file */
4885 for (index = 0; (index < config_size) && (rslt == BMI2_OK); index += dev->read_write_len)
4887 rslt = upload_file((dev->config_file_ptr + index), index, dev->read_write_len, dev);
4890 else
4892 /* Get the balance bytes */
4893 bal_byte = (uint16_t) config_size - (uint16_t) remain;
4895 /* Write the configuration file for the balancem bytes */
4896 for (index = 0; (index < bal_byte) && (rslt == BMI2_OK); index += dev->read_write_len)
4898 rslt = upload_file((dev->config_file_ptr + index), index, dev->read_write_len, dev);
4901 if (rslt == BMI2_OK)
4903 /* Update length in a temporary variable */
4904 read_write_len = dev->read_write_len;
4906 /* Write the remaining bytes in 2 bytes length */
4907 dev->read_write_len = 2;
4909 /* Write the configuration file for the remaining bytes */
4910 for (index = bal_byte;
4911 (index < config_size) && (rslt == BMI2_OK);
4912 index += dev->read_write_len)
4914 rslt = upload_file((dev->config_file_ptr + index), index, dev->read_write_len, dev);
4917 /* Restore the user set length back from the temporary variable */
4918 dev->read_write_len = read_write_len;
4922 if (rslt == BMI2_OK)
4924 /* Enable loading of the configuration */
4925 rslt = set_config_load(BMI2_ENABLE, dev);
4927 /* Wait till ASIC is initialized */
4928 dev->delay_us(150000, dev->intf_ptr);
4929 if (rslt == BMI2_OK)
4931 /* Enable advanced power save mode */
4932 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
4938 return rslt;
4942 * @brief This internal API enables/disables the loading of the configuration
4943 * file.
4945 static int8_t set_config_load(uint8_t enable, struct bmi2_dev *dev)
4947 /* Variable to define error */
4948 int8_t rslt;
4950 /* Variable to store data */
4951 uint8_t reg_data = 0;
4953 rslt = bmi2_get_regs(BMI2_INIT_CTRL_ADDR, &reg_data, 1, dev);
4954 if (rslt == BMI2_OK)
4956 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_CONF_LOAD_EN, enable);
4957 rslt = bmi2_set_regs(BMI2_INIT_CTRL_ADDR, &reg_data, 1, dev);
4960 return rslt;
4964 * @brief This internal API loads the configuration file.
4966 static int8_t upload_file(const uint8_t *config_data, uint16_t index, uint16_t write_len, struct bmi2_dev *dev)
4968 /* Variable to define error */
4969 int8_t rslt;
4971 /* Array to store address */
4972 uint8_t addr_array[2] = { 0 };
4974 if (config_data != NULL)
4976 /* Store 0 to 3 bits of address in first byte */
4977 addr_array[0] = (uint8_t)((index / 2) & 0x0F);
4979 /* Store 4 to 11 bits of address in the second byte */
4980 addr_array[1] = (uint8_t)((index / 2) >> 4);
4982 /* Write the 2 bytes of address in consecutive locations */
4983 rslt = bmi2_set_regs(BMI2_INIT_ADDR_0, addr_array, 2, dev);
4984 if (rslt == BMI2_OK)
4986 /* Burst write configuration file data corresponding to user set length */
4987 rslt = bmi2_set_regs(BMI2_INIT_DATA_ADDR, (uint8_t *)config_data, write_len, dev);
4990 else
4992 rslt = BMI2_E_NULL_PTR;
4995 return rslt;
4999 * @brief This internal API validates bandwidth and performance mode of the
5000 * accelerometer set by the user.
5002 static int8_t validate_bw_perf_mode(uint8_t *bandwidth, uint8_t *perf_mode, struct bmi2_dev *dev)
5004 /* Variable to define error */
5005 int8_t rslt;
5007 /* Validate and auto-correct performance mode */
5008 rslt = check_boundary_val(perf_mode, BMI2_POWER_OPT_MODE, BMI2_PERF_OPT_MODE, dev);
5009 if (rslt == BMI2_OK)
5011 /* Validate and auto-correct bandwidth parameter */
5012 if (*perf_mode == BMI2_PERF_OPT_MODE)
5014 /* Validate for continuous filter mode */
5015 rslt = check_boundary_val(bandwidth, BMI2_ACC_OSR4_AVG1, BMI2_ACC_CIC_AVG8, dev);
5017 else
5019 /* Validate for CIC averaging mode */
5020 rslt = check_boundary_val(bandwidth, BMI2_ACC_OSR4_AVG1, BMI2_ACC_RES_AVG128, dev);
5024 return rslt;
5028 * @brief This internal API validates ODR and range of the accelerometer set by
5029 * the user.
5031 static int8_t validate_odr_range(uint8_t *odr, uint8_t *range, struct bmi2_dev *dev)
5033 /* Variable to define error */
5034 int8_t rslt;
5036 /* Validate and auto correct ODR */
5037 rslt = check_boundary_val(odr, BMI2_ACC_ODR_0_78HZ, BMI2_ACC_ODR_1600HZ, dev);
5038 if (rslt == BMI2_OK)
5040 /* Validate and auto correct Range */
5041 rslt = check_boundary_val(range, BMI2_ACC_RANGE_2G, BMI2_ACC_RANGE_16G, dev);
5044 return rslt;
5048 * @brief This internal API validates bandwidth, performance mode, low power/
5049 * high performance mode, ODR, and range set by the user.
5051 static int8_t validate_gyro_config(struct bmi2_gyro_config *config, struct bmi2_dev *dev)
5053 /* Variable to define error */
5054 int8_t rslt;
5056 /* Validate and auto-correct performance mode */
5057 rslt = check_boundary_val(&config->filter_perf, BMI2_POWER_OPT_MODE, BMI2_PERF_OPT_MODE, dev);
5058 if (rslt == BMI2_OK)
5060 /* Validate and auto-correct bandwidth parameter */
5061 rslt = check_boundary_val(&config->bwp, BMI2_GYR_OSR4_MODE, BMI2_GYR_CIC_MODE, dev);
5062 if (rslt == BMI2_OK)
5064 /* Validate and auto-correct low power/high-performance parameter */
5065 rslt = check_boundary_val(&config->noise_perf, BMI2_POWER_OPT_MODE, BMI2_PERF_OPT_MODE, dev);
5066 if (rslt == BMI2_OK)
5068 /* Validate and auto-correct ODR parameter */
5069 rslt = check_boundary_val(&config->odr, BMI2_GYR_ODR_25HZ, BMI2_GYR_ODR_3200HZ, dev);
5070 if (rslt == BMI2_OK)
5072 /* Validate and auto-correct OIS range */
5073 rslt = check_boundary_val(&config->ois_range, BMI2_GYR_OIS_250, BMI2_GYR_OIS_2000, dev);
5074 if (rslt == BMI2_OK)
5076 /* Validate and auto-correct range parameter */
5077 rslt = check_boundary_val(&config->range, BMI2_GYR_RANGE_2000, BMI2_GYR_RANGE_125, dev);
5084 return rslt;
5088 * @brief This internal API shows the error status when illegal sensor
5089 * configuration is set.
5091 static int8_t cfg_error_status(struct bmi2_dev *dev)
5093 /* Variable to define error */
5094 int8_t rslt;
5096 /* Variable to store data */
5097 uint8_t reg_data;
5099 /* Get error status of the set sensor configuration */
5100 rslt = bmi2_get_regs(BMI2_EVENT_ADDR, &reg_data, 1, dev);
5101 if (rslt == BMI2_OK)
5103 reg_data = BMI2_GET_BITS(reg_data, BMI2_EVENT_FLAG);
5104 switch (reg_data)
5106 case BMI2_NO_ERROR:
5107 rslt = BMI2_OK;
5108 break;
5109 case BMI2_ACC_ERROR:
5110 rslt = BMI2_E_ACC_INVALID_CFG;
5111 break;
5112 case BMI2_GYR_ERROR:
5113 rslt = BMI2_E_GYRO_INVALID_CFG;
5114 break;
5115 case BMI2_ACC_GYR_ERROR:
5116 rslt = BMI2_E_ACC_GYR_INVALID_CFG;
5117 break;
5118 default:
5119 break;
5123 return rslt;
5127 * @brief This internal API:
5128 * 1) Enables/Disables auxiliary interface.
5129 * 2) Sets auxiliary interface configurations like I2C address, manual/auto
5130 * mode enable, manual burst read length, AUX burst read length and AUX read
5131 * address.
5132 * 3)It maps/un-maps data interrupts to that of hardware interrupt line.
5134 static int8_t set_aux_config(struct bmi2_aux_config *config, struct bmi2_dev *dev)
5136 /* Variable to define error */
5137 int8_t rslt;
5139 /* Validate auxiliary configurations */
5140 rslt = validate_aux_config(config, dev);
5141 if (rslt == BMI2_OK)
5143 /* Enable/Disable auxiliary interface */
5144 rslt = set_aux_interface(config, dev);
5145 if (rslt == BMI2_OK)
5147 /* Set the auxiliary interface configurations */
5148 rslt = config_aux_interface(config, dev);
5149 if (rslt == BMI2_OK)
5151 /* Set read out offset and ODR */
5152 rslt = config_aux(config, dev);
5157 return rslt;
5161 * @brief This internal API sets gyroscope user-gain configurations like gain
5162 * update value for x, y and z-axis.
5164 static int8_t set_gyro_user_gain_config(const struct bmi2_gyro_user_gain_config *config, struct bmi2_dev *dev)
5166 /* Variable to define error */
5167 int8_t rslt;
5169 /* Array to define the feature configuration */
5170 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
5172 /* Variable to define the array offset */
5173 uint8_t idx = 0;
5175 /* Variable to define index */
5176 uint8_t index = 0;
5178 /* Variable to set flag */
5179 uint8_t feat_found;
5181 /* Initialize feature configuration for user-gain */
5182 struct bmi2_feature_config user_gain_config = { 0, 0, 0 };
5184 /* Copy the feature configuration address to a local pointer */
5185 uint16_t *data_p = (uint16_t *) (void *)feat_config;
5187 /* Search for user-gain feature and extract its configuration details */
5188 feat_found = bmi2_extract_input_feat_config(&user_gain_config, BMI2_GYRO_GAIN_UPDATE, dev);
5189 if (feat_found)
5191 /* Get the configuration from the page where user-gain feature resides */
5192 rslt = bmi2_get_feat_config(user_gain_config.page, feat_config, dev);
5193 if (rslt == BMI2_OK)
5195 /* Define the offset in bytes for user-gain select */
5196 idx = user_gain_config.start_addr;
5198 /* Get offset in words since all the features are set in words length */
5199 idx = idx / 2;
5201 /* Set ratio_x */
5202 *(data_p + idx) = BMI2_SET_BIT_POS0(*(data_p + idx), BMI2_GYR_USER_GAIN_RATIO_X, config->ratio_x);
5204 /* Increment offset by 1 word to set ratio_y */
5205 idx++;
5207 /* Set ratio_y */
5208 *(data_p + idx) = BMI2_SET_BIT_POS0(*(data_p + idx), BMI2_GYR_USER_GAIN_RATIO_Y, config->ratio_y);
5210 /* Increment offset by 1 word to set ratio_z */
5211 idx++;
5213 /* Set ratio_z */
5214 *(data_p + idx) = BMI2_SET_BIT_POS0(*(data_p + idx), BMI2_GYR_USER_GAIN_RATIO_Z, config->ratio_z);
5216 /* Increment offset by 1 more word to get the total length in words */
5217 idx++;
5219 /* Get total length in bytes to copy from local pointer to the array */
5220 idx = (uint8_t)(idx * 2) - user_gain_config.start_addr;
5222 /* Copy the bytes to be set back to the array */
5223 for (index = 0; index < idx; index++)
5225 feat_config[user_gain_config.start_addr +
5226 index] = *((uint8_t *) data_p + user_gain_config.start_addr + index);
5229 /* Set the configuration back to the page */
5230 rslt = bmi2_set_regs(BMI2_FEATURES_REG_ADDR, feat_config, BMI2_FEAT_SIZE_IN_BYTES, dev);
5233 else
5235 rslt = BMI2_E_INVALID_SENSOR;
5238 return rslt;
5242 * @brief This internal API enables/disables auxiliary interface.
5244 static int8_t set_aux_interface(const struct bmi2_aux_config *config, struct bmi2_dev *dev)
5246 /* Variable to define error */
5247 int8_t rslt;
5249 /* Variable to store data */
5250 uint8_t reg_data;
5252 rslt = bmi2_get_regs(BMI2_IF_CONF_ADDR, &reg_data, 1, dev);
5253 if (rslt == BMI2_OK)
5255 reg_data = BMI2_SET_BITS(reg_data, BMI2_AUX_IF_EN, config->aux_en);
5257 /* Enable/Disable auxiliary interface */
5258 rslt = bmi2_set_regs(BMI2_IF_CONF_ADDR, &reg_data, 1, dev);
5261 return rslt;
5265 * @brief This internal API sets auxiliary configurations like manual/auto mode
5266 * FCU write command enable and read burst length for both data and manual mode.
5268 * @note Auxiliary sensor should not be busy when configuring aux_i2c_addr,
5269 * man_rd_burst_len, aux_rd_burst_len and aux_rd_addr.
5271 static int8_t config_aux_interface(const struct bmi2_aux_config *config, struct bmi2_dev *dev)
5273 /* Variable to define error */
5274 int8_t rslt;
5276 /* Variable to store data */
5277 uint8_t reg_data[2] = { 0 };
5279 /* Variable to store status */
5280 uint8_t status = 0;
5282 /* Variable to define count */
5283 uint8_t count = 0;
5285 rslt = bmi2_get_regs(BMI2_AUX_DEV_ID_ADDR, reg_data, 2, dev);
5286 if (rslt == BMI2_OK)
5288 /* Set I2C address for AUX sensor */
5289 reg_data[0] = BMI2_SET_BITS(reg_data[0], BMI2_AUX_SET_I2C_ADDR, config->i2c_device_addr);
5291 /* Set the AUX IF to either manual or auto mode */
5292 reg_data[1] = BMI2_SET_BITS(reg_data[1], BMI2_AUX_MAN_MODE_EN, config->manual_en);
5294 /* Enables FCU write command on AUX IF for auxiliary sensors that need a trigger */
5295 reg_data[1] = BMI2_SET_BITS(reg_data[1], BMI2_AUX_FCU_WR_EN, config->fcu_write_en);
5297 /* Set the burst read length for manual mode */
5298 reg_data[1] = BMI2_SET_BITS(reg_data[1], BMI2_AUX_MAN_READ_BURST, config->man_rd_burst);
5300 /* Set the burst read length for data mode */
5301 reg_data[1] = BMI2_SET_BIT_POS0(reg_data[1], BMI2_AUX_READ_BURST, config->aux_rd_burst);
5302 for (;;)
5304 /* Check if auxiliary sensor is busy */
5305 rslt = bmi2_get_status(&status, dev);
5306 if ((rslt == BMI2_OK) && (!(status & BMI2_AUX_BUSY)))
5308 /* Set the configurations if AUX is not busy */
5309 rslt = bmi2_set_regs(BMI2_AUX_DEV_ID_ADDR, reg_data, 2, dev);
5310 dev->delay_us(1000, dev->intf_ptr);
5311 if (rslt == BMI2_OK)
5313 /* If data mode */
5314 if (!config->manual_en)
5316 /* Disable manual enable flag in device structure */
5317 dev->aux_man_en = 0;
5319 /* Set the read address of the AUX sensor */
5320 rslt = bmi2_set_regs(BMI2_AUX_RD_ADDR, (uint8_t *) &config->read_addr, 1, dev);
5321 dev->delay_us(1000, dev->intf_ptr);
5323 else
5325 /* Enable manual enable flag in device structure */
5326 dev->aux_man_en = 1;
5328 /* Update manual read burst length in device structure */
5329 dev->aux_man_rd_burst_len = config->man_rd_burst;
5333 /* Break after setting the register */
5334 break;
5337 /* Increment count after every 10 seconds */
5338 dev->delay_us(10000, dev->intf_ptr);
5339 count++;
5341 /* Break after 2 seconds if AUX still busy - since slowest ODR is 0.78Hz*/
5342 if (count > 20)
5344 rslt = BMI2_E_AUX_BUSY;
5345 break;
5350 return rslt;
5354 * @brief This internal API triggers read out offset and sets ODR of the
5355 * auxiliary sensor.
5357 static int8_t config_aux(const struct bmi2_aux_config *config, struct bmi2_dev *dev)
5359 /* Variable to define error */
5360 int8_t rslt;
5362 /* Variable to store data */
5363 uint8_t reg_data;
5365 rslt = bmi2_get_regs(BMI2_AUX_CONF_ADDR, &reg_data, 1, dev);
5366 if (rslt == BMI2_OK)
5368 /* Trigger read out offset */
5369 reg_data = BMI2_SET_BITS(reg_data, BMI2_AUX_OFFSET_READ_OUT, config->offset);
5371 /* Set ODR */
5372 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_AUX_ODR_EN, config->odr);
5374 /* Set auxiliary configuration register */
5375 rslt = bmi2_set_regs(BMI2_AUX_CONF_ADDR, &reg_data, 1, dev);
5376 dev->delay_us(1000, dev->intf_ptr);
5379 return rslt;
5383 * @brief This internal API checks the busy status of auxiliary sensor and sets
5384 * the auxiliary register addresses when not busy.
5386 static int8_t set_if_aux_not_busy(uint8_t reg_addr, uint8_t reg_data, struct bmi2_dev *dev)
5388 /* Variable to define error */
5389 int8_t rslt;
5391 /* Variable to get status of AUX_BUSY */
5392 uint8_t status = 0;
5394 /* Variable to define count for time-out */
5395 uint8_t count = 0;
5397 for (;;)
5399 /* Check if AUX is busy */
5400 rslt = bmi2_get_status(&status, dev);
5402 /* Set the registers if not busy */
5403 if ((rslt == BMI2_OK) && (!(status & BMI2_AUX_BUSY)))
5405 rslt = bmi2_set_regs(reg_addr, &reg_data, 1, dev);
5406 dev->delay_us(1000, dev->intf_ptr);
5408 /* Break after setting the register */
5409 break;
5412 /* Increment count after every 10 seconds */
5413 dev->delay_us(10000, dev->intf_ptr);
5414 count++;
5416 /* Break after 2 seconds if AUX still busy - since slowest ODR is 0.78Hz*/
5417 if (count > 20)
5419 rslt = BMI2_E_AUX_BUSY;
5420 break;
5424 return rslt;
5428 * @brief This internal API validates auxiliary configuration set by the user.
5430 static int8_t validate_aux_config(struct bmi2_aux_config *config, struct bmi2_dev *dev)
5432 /* Variable to define error */
5433 int8_t rslt;
5435 /* Validate ODR for auxiliary sensor */
5436 rslt = check_boundary_val(&config->odr, BMI2_AUX_ODR_0_78HZ, BMI2_AUX_ODR_800HZ, dev);
5438 return rslt;
5442 * @brief This internal API gets accelerometer configurations like ODR,
5443 * bandwidth, performance mode and g-range.
5445 static int8_t get_accel_config(struct bmi2_accel_config *config, struct bmi2_dev *dev)
5447 /* Variable to define error */
5448 int8_t rslt;
5450 /* Array to store data */
5451 uint8_t data_array[2] = { 0 };
5453 /* Null-pointer check */
5454 rslt = null_ptr_check(dev);
5455 if ((rslt == BMI2_OK) && (config != NULL))
5457 /* Read the sensor configuration details */
5458 rslt = bmi2_get_regs(BMI2_ACC_CONF_ADDR, data_array, 2, dev);
5459 if (rslt == BMI2_OK)
5461 /* Get accelerometer performance mode */
5462 config->filter_perf = BMI2_GET_BITS(data_array[0], BMI2_ACC_FILTER_PERF_MODE);
5464 /* Get accelerometer bandwidth */
5465 config->bwp = BMI2_GET_BITS(data_array[0], BMI2_ACC_BW_PARAM);
5467 /* Get accelerometer ODR */
5468 config->odr = BMI2_GET_BIT_POS0(data_array[0], BMI2_ACC_ODR);
5470 /* Get accelerometer range */
5471 config->range = BMI2_GET_BIT_POS0(data_array[1], BMI2_ACC_RANGE);
5474 else
5476 rslt = BMI2_E_NULL_PTR;
5479 return rslt;
5483 * @brief This internal API gets gyroscope configurations like ODR, bandwidth,
5484 * low power/high performance mode, performance mode and range.
5486 static int8_t get_gyro_config(struct bmi2_gyro_config *config, struct bmi2_dev *dev)
5488 /* Variable to define error */
5489 int8_t rslt;
5491 /* Array to store data */
5492 uint8_t data_array[2] = { 0 };
5494 /* Null-pointer check */
5495 rslt = null_ptr_check(dev);
5496 if ((rslt == BMI2_OK) && (config != NULL))
5498 /* Read the sensor configuration details */
5499 rslt = bmi2_get_regs(BMI2_GYR_CONF_ADDR, data_array, 2, dev);
5500 if (rslt == BMI2_OK)
5502 /* Get gyroscope performance mode */
5503 config->filter_perf = BMI2_GET_BITS(data_array[0], BMI2_GYR_FILTER_PERF_MODE);
5505 /* Get gyroscope noise performance mode */
5506 config->noise_perf = BMI2_GET_BITS(data_array[0], BMI2_GYR_NOISE_PERF_MODE);
5508 /* Get gyroscope bandwidth */
5509 config->bwp = BMI2_GET_BITS(data_array[0], BMI2_GYR_BW_PARAM);
5511 /* Get gyroscope ODR */
5512 config->odr = BMI2_GET_BIT_POS0(data_array[0], BMI2_GYR_ODR);
5514 /* Get gyroscope OIS range */
5515 config->ois_range = BMI2_GET_BITS(data_array[1], BMI2_GYR_OIS_RANGE);
5517 /* Get gyroscope range */
5518 config->range = BMI2_GET_BIT_POS0(data_array[1], BMI2_GYR_RANGE);
5521 else
5523 rslt = BMI2_E_NULL_PTR;
5526 return rslt;
5530 * @brief This internal API:
5531 * 1) Gets the status of auxiliary interface enable.
5532 * 2) Gets auxiliary interface configurations like I2C address, manual/auto
5533 * mode enable, manual burst read length, AUX burst read length and AUX read
5534 * address.
5535 * 3) Gets ODR and offset.
5537 static int8_t get_aux_config(struct bmi2_aux_config *config, struct bmi2_dev *dev)
5539 /* Variable to define error */
5540 int8_t rslt;
5542 /* Null-pointer check */
5543 rslt = null_ptr_check(dev);
5544 if ((rslt == BMI2_OK) && (config != NULL))
5546 /* Get enable status of auxiliary interface */
5547 rslt = get_aux_interface(config, dev);
5548 if (rslt == BMI2_OK)
5550 /* Get the auxiliary interface configurations */
5551 rslt = get_aux_interface_config(config, dev);
5552 if (rslt == BMI2_OK)
5554 /* Get read out offset and ODR */
5555 rslt = get_aux_cfg(config, dev);
5559 else
5561 rslt = BMI2_E_NULL_PTR;
5564 return rslt;
5568 * @brief This internal API gets gyroscope user-gain configurations like gain
5569 * update value for x, y and z-axis.
5571 static int8_t get_gyro_gain_update_config(struct bmi2_gyro_user_gain_config *config, struct bmi2_dev *dev)
5573 /* Variable to define error */
5574 int8_t rslt;
5576 /* Array to define the feature configuration */
5577 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
5579 /* Variable to define the array offset */
5580 uint8_t idx = 0;
5582 /* Variable to define LSB */
5583 uint16_t lsb = 0;
5585 /* Variable to define MSB */
5586 uint16_t msb = 0;
5588 /* Variable to define a word */
5589 uint16_t lsb_msb = 0;
5591 /* Variable to set flag */
5592 uint8_t feat_found;
5594 /* Initialize feature configuration for user-gain */
5595 struct bmi2_feature_config user_gain_config = { 0, 0, 0 };
5597 /* Search for user-gain feature and extract its configuration details */
5598 feat_found = bmi2_extract_input_feat_config(&user_gain_config, BMI2_GYRO_GAIN_UPDATE, dev);
5599 if (feat_found)
5601 /* Get the configuration from the page where user-gain feature resides */
5602 rslt = bmi2_get_feat_config(user_gain_config.page, feat_config, dev);
5603 if (rslt == BMI2_OK)
5605 /* Define the offset in bytes for user-gain select */
5606 idx = user_gain_config.start_addr;
5608 /* Get word to calculate ratio_x */
5609 lsb = (uint16_t) feat_config[idx++];
5610 msb = ((uint16_t) feat_config[idx++] << 8);
5611 lsb_msb = lsb | msb;
5613 /* Get ratio_x */
5614 config->ratio_x = lsb_msb & BMI2_GYR_USER_GAIN_RATIO_X_MASK;
5616 /* Get word to calculate ratio_y */
5617 lsb = (uint16_t) feat_config[idx++];
5618 msb = ((uint16_t) feat_config[idx++] << 8);
5619 lsb_msb = lsb | msb;
5621 /* Get ratio_y */
5622 config->ratio_y = lsb_msb & BMI2_GYR_USER_GAIN_RATIO_Y_MASK;
5624 /* Get word to calculate ratio_z */
5625 lsb = (uint16_t) feat_config[idx++];
5626 msb = ((uint16_t) feat_config[idx++] << 8);
5627 lsb_msb = lsb | msb;
5629 /* Get ratio_z */
5630 config->ratio_z = lsb_msb & BMI2_GYR_USER_GAIN_RATIO_Z_MASK;
5633 else
5635 rslt = BMI2_E_INVALID_SENSOR;
5638 return rslt;
5642 * @brief This internal API gets the enable status of auxiliary interface.
5644 static int8_t get_aux_interface(struct bmi2_aux_config *config, struct bmi2_dev *dev)
5646 /* Variable to define error */
5647 int8_t rslt;
5649 /* Variable to store data */
5650 uint8_t reg_data;
5652 /* Get the enable status of auxiliary interface */
5653 rslt = bmi2_get_regs(BMI2_IF_CONF_ADDR, &reg_data, 1, dev);
5654 if (rslt == BMI2_OK)
5656 config->aux_en = BMI2_GET_BITS(reg_data, BMI2_AUX_IF_EN);
5659 return rslt;
5663 * @brief This internal API gets auxiliary configurations like manual/auto mode
5664 * FCU write command enable and read burst length for both data and manual mode.
5666 static int8_t get_aux_interface_config(struct bmi2_aux_config *config, struct bmi2_dev *dev)
5668 /* Variable to define error */
5669 int8_t rslt;
5671 /* Variable to store data */
5672 uint8_t reg_data[2] = { 0 };
5674 rslt = bmi2_get_regs(BMI2_AUX_DEV_ID_ADDR, reg_data, 2, dev);
5675 if (rslt == BMI2_OK)
5677 /* Get I2C address for auxiliary sensor */
5678 config->i2c_device_addr = BMI2_GET_BITS(reg_data[0], BMI2_AUX_SET_I2C_ADDR);
5680 /* Get the AUX IF to either manual or auto mode */
5681 config->manual_en = BMI2_GET_BITS(reg_data[1], BMI2_AUX_MAN_MODE_EN);
5683 /* Enables FCU write command on AUX IF for auxiliary sensors that need a trigger */
5684 config->fcu_write_en = BMI2_GET_BITS(reg_data[1], BMI2_AUX_FCU_WR_EN);
5686 /* Get the burst read length for manual mode */
5687 config->man_rd_burst = BMI2_GET_BITS(reg_data[1], BMI2_AUX_MAN_READ_BURST);
5689 /* Get the burst read length for data mode */
5690 config->aux_rd_burst = BMI2_GET_BIT_POS0(reg_data[1], BMI2_AUX_READ_BURST);
5692 /* If data mode, get the read address of the auxiliary sensor from where data is to be read */
5693 if (!config->manual_en)
5695 rslt = bmi2_get_regs(BMI2_AUX_RD_ADDR, &config->read_addr, 1, dev);
5699 return rslt;
5703 * @brief This internal API gets read out offset and ODR of the auxiliary
5704 * sensor.
5706 static int8_t get_aux_cfg(struct bmi2_aux_config *config, struct bmi2_dev *dev)
5708 /* Variable to define error */
5709 int8_t rslt;
5711 /* Variable to store data */
5712 uint8_t reg_data;
5714 rslt = bmi2_get_regs(BMI2_AUX_CONF_ADDR, &reg_data, 1, dev);
5715 if (rslt == BMI2_OK)
5717 /* Get read out offset */
5718 config->offset = BMI2_GET_BITS(reg_data, BMI2_AUX_OFFSET_READ_OUT);
5720 /* Get ODR */
5721 config->odr = BMI2_GET_BIT_POS0(reg_data, BMI2_AUX_ODR_EN);
5724 return rslt;
5728 * @brief This internal API maps/un-maps feature interrupts to that of interrupt
5729 * pins.
5731 static int8_t map_feat_int(uint8_t *reg_data_array, enum bmi2_hw_int_pin int_pin, uint8_t int_mask)
5733 /* Variable to define error */
5734 int8_t rslt = BMI2_OK;
5736 /* Check for NULL error */
5737 if (reg_data_array != NULL)
5739 /* Check validity on interrupt pin selection */
5740 if (int_pin < BMI2_INT_PIN_MAX)
5742 switch (int_pin)
5744 case BMI2_INT_NONE:
5746 /* Un-Map the corresponding feature interrupt to interrupt pin 1 and 2 */
5747 reg_data_array[0] &= ~(int_mask);
5748 reg_data_array[1] &= ~(int_mask);
5749 break;
5750 case BMI2_INT1:
5752 /* Map the corresponding feature interrupt to interrupt pin 1 */
5753 reg_data_array[0] |= int_mask;
5755 /* Un-map the corresponding feature interrupt to interrupt pin 2 */
5756 reg_data_array[1] &= ~(int_mask);
5757 break;
5758 case BMI2_INT2:
5760 /* Map the corresponding feature interrupt to interrupt pin 2 */
5761 reg_data_array[1] |= int_mask;
5763 /* Un-map the corresponding feature interrupt to interrupt pin 1 */
5764 reg_data_array[0] &= ~(int_mask);
5765 break;
5766 case BMI2_INT_BOTH:
5768 /* Map the corresponding feature interrupt to interrupt pin 1 and 2 */
5769 reg_data_array[0] |= int_mask;
5770 reg_data_array[1] |= int_mask;
5771 break;
5772 default:
5773 break;
5776 else
5778 /* Return error if invalid pin selection */
5779 rslt = BMI2_E_INVALID_INT_PIN;
5782 else
5784 rslt = BMI2_E_NULL_PTR;
5787 return rslt;
5791 * @brief This internal API gets the accelerometer data from the register.
5793 static int8_t get_accel_sensor_data(struct bmi2_sens_axes_data *data, uint8_t reg_addr, struct bmi2_dev *dev)
5795 /* Variable to define error */
5796 int8_t rslt;
5798 /* Array to define data stored in register */
5799 uint8_t reg_data[BMI2_ACC_GYR_NUM_BYTES] = { 0 };
5801 /* Read the sensor data */
5802 rslt = bmi2_get_regs(reg_addr, reg_data, BMI2_ACC_GYR_NUM_BYTES, dev);
5803 if (rslt == BMI2_OK)
5805 /* Get accelerometer data from the register */
5806 get_acc_gyr_data(data, reg_data);
5808 /* Get the re-mapped accelerometer data */
5809 get_remapped_data(data, dev);
5812 return rslt;
5816 * @brief This internal API gets the gyroscope data from the register.
5818 static int8_t get_gyro_sensor_data(struct bmi2_sens_axes_data *data, uint8_t reg_addr, struct bmi2_dev *dev)
5820 /* Variable to define error */
5821 int8_t rslt;
5823 /* Array to define data stored in register */
5824 uint8_t reg_data[BMI2_ACC_GYR_NUM_BYTES] = { 0 };
5826 /* Read the sensor data */
5827 rslt = bmi2_get_regs(reg_addr, reg_data, BMI2_ACC_GYR_NUM_BYTES, dev);
5828 if (rslt == BMI2_OK)
5830 /* Get gyroscope data from the register */
5831 get_acc_gyr_data(data, reg_data);
5833 /* Get the compensated gyroscope data */
5834 comp_gyro_cross_axis_sensitivity(data, dev);
5836 /* Get the re-mapped gyroscope data */
5837 get_remapped_data(data, dev);
5841 return rslt;
5845 * @brief This internal API gets the accelerometer/gyroscope data.
5847 static void get_acc_gyr_data(struct bmi2_sens_axes_data *data, const uint8_t *reg_data)
5849 /* Variables to store msb value */
5850 uint8_t msb;
5852 /* Variables to store lsb value */
5853 uint8_t lsb;
5855 /* Variables to store both msb and lsb value */
5856 uint16_t msb_lsb;
5858 /* Variables to define index */
5859 uint8_t index = 0;
5861 /* Read x-axis data */
5862 lsb = reg_data[index++];
5863 msb = reg_data[index++];
5864 msb_lsb = ((uint16_t) msb << 8) | (uint16_t) lsb;
5865 data->x = (int16_t) msb_lsb;
5867 /* Read y-axis data */
5868 lsb = reg_data[index++];
5869 msb = reg_data[index++];
5870 msb_lsb = ((uint16_t) msb << 8) | (uint16_t) lsb;
5871 data->y = (int16_t) msb_lsb;
5873 /* Read z-axis data */
5874 lsb = reg_data[index++];
5875 msb = reg_data[index++];
5876 msb_lsb = ((uint16_t) msb << 8) | (uint16_t) lsb;
5877 data->z = (int16_t) msb_lsb;
5881 * @brief This internal API gets the re-mapped accelerometer/gyroscope data.
5883 static void get_remapped_data(struct bmi2_sens_axes_data *data, const struct bmi2_dev *dev)
5885 /* Array to defined the re-mapped sensor data */
5886 int16_t remap_data[3] = { 0 };
5887 int16_t pos_multiplier = INT16_C(1);
5888 int16_t neg_multiplier = INT16_C(-1);
5890 /* Fill the array with the un-mapped sensor data */
5891 remap_data[0] = data->x;
5892 remap_data[1] = data->y;
5893 remap_data[2] = data->z;
5895 /* Get the re-mapped x axis data */
5896 if (dev->remap.x_axis_sign == BMI2_POS_SIGN)
5898 data->x = (int16_t)(remap_data[dev->remap.x_axis] * pos_multiplier);
5900 else
5902 data->x = (int16_t)(remap_data[dev->remap.x_axis] * neg_multiplier);
5905 /* Get the re-mapped y axis data */
5906 if (dev->remap.y_axis_sign == BMI2_POS_SIGN)
5908 data->y = (int16_t)(remap_data[dev->remap.y_axis] * pos_multiplier);
5910 else
5912 data->y = (int16_t)(remap_data[dev->remap.y_axis] * neg_multiplier);
5915 /* Get the re-mapped z axis data */
5916 if (dev->remap.z_axis_sign == BMI2_POS_SIGN)
5918 data->z = (int16_t)(remap_data[dev->remap.z_axis] * pos_multiplier);
5920 else
5922 data->z = (int16_t)(remap_data[dev->remap.z_axis] * neg_multiplier);
5927 * @brief This internal API reads the user-defined bytes of data from the given
5928 * register address of auxiliary sensor in manual mode.
5930 static int8_t read_aux_data(uint8_t reg_addr, uint8_t *aux_data, uint16_t len, uint8_t burst_len, struct bmi2_dev *dev)
5932 /* Variable to define error */
5933 int8_t rslt = BMI2_OK;
5935 /* Array to store the register data */
5936 uint8_t reg_data[15] = { 0 };
5938 /* Variable to define number of bytes to read */
5939 uint16_t read_length = 0;
5941 /* Variable to define loop */
5942 uint8_t loop = 0;
5944 /* Variable to define counts to get the correct array index */
5945 uint8_t count = 0;
5947 /* Variable to define index for the array */
5948 uint8_t idx = 0;
5950 while (len > 0)
5952 /* Set the read address if AUX is not busy */
5953 rslt = set_if_aux_not_busy(BMI2_AUX_RD_ADDR, reg_addr, dev);
5954 if (rslt == BMI2_OK)
5956 /* Read data from bmi2 data register */
5957 rslt = bmi2_get_regs(BMI2_AUX_X_LSB_ADDR, reg_data, (uint16_t) burst_len, dev);
5958 dev->delay_us(1000, dev->intf_ptr);
5959 if (rslt == BMI2_OK)
5961 /* Get number of bytes to be read */
5962 if (len < burst_len)
5964 read_length = (uint8_t) len;
5966 else
5968 read_length = burst_len;
5971 /* Update array index and store the data */
5972 for (loop = 0; loop < read_length; loop++)
5974 idx = loop + count;
5975 aux_data[idx] = reg_data[loop];
5980 /* Update address for the next read */
5981 reg_addr += burst_len;
5983 /* Update count for the array index */
5984 count += burst_len;
5986 /* Update no of bytes left to read */
5987 len -= read_length;
5990 return rslt;
5994 * @brief This internal API writes AUX write address and the user-defined bytes
5995 * of data to the AUX sensor in manual mode.
5997 * @note Change of BMI2_AUX_WR_ADDR is only allowed if AUX is not busy.
5999 static int8_t write_aux_data(uint8_t reg_addr, uint8_t reg_data, struct bmi2_dev *dev)
6001 /* Variable to define error */
6002 int8_t rslt;
6004 /* Write data to be written to the AUX sensor in bmi2 register */
6005 rslt = bmi2_set_regs(BMI2_AUX_WR_DATA_ADDR, &reg_data, 1, dev);
6006 if (rslt == BMI2_OK)
6008 /* Write the AUX address where data is to be stored when AUX is not busy */
6009 rslt = set_if_aux_not_busy(BMI2_AUX_WR_ADDR, reg_addr, dev);
6012 return rslt;
6016 * @brief This internal API reads the user-defined bytes of data from the given
6017 * register address of auxiliary sensor in data mode.
6019 static int8_t read_aux_data_mode(uint8_t *aux_data, struct bmi2_dev *dev)
6021 /* Variable to define error */
6022 int8_t rslt;
6024 /* Variables to define loop */
6025 uint8_t count = 0;
6027 /* Variables to define index */
6028 uint8_t index = 0;
6030 /* Array to define data stored in register */
6031 uint8_t reg_data[BMI2_AUX_NUM_BYTES] = { 0 };
6033 /* Check if data mode */
6034 if (!dev->aux_man_en)
6036 /* Read the auxiliary sensor data */
6037 rslt = bmi2_get_regs(BMI2_AUX_X_LSB_ADDR, reg_data, BMI2_AUX_NUM_BYTES, dev);
6038 if (rslt == BMI2_OK)
6040 /* Get the 8 bytes of auxiliary data */
6043 *(aux_data + count++) = *(reg_data + index++);
6044 } while (count < BMI2_AUX_NUM_BYTES);
6047 else
6049 rslt = BMI2_E_AUX_INVALID_CFG;
6052 return rslt;
6056 * @brief This internal API maps the actual burst read length with that of the
6057 * register value set by user.
6059 static int8_t map_read_len(uint8_t *len, const struct bmi2_dev *dev)
6061 /* Variable to define error */
6062 int8_t rslt = BMI2_OK;
6064 /* Get the burst read length against the values set by the user */
6065 switch (dev->aux_man_rd_burst_len)
6067 case BMI2_AUX_READ_LEN_0:
6068 *len = 1;
6069 break;
6070 case BMI2_AUX_READ_LEN_1:
6071 *len = 2;
6072 break;
6073 case BMI2_AUX_READ_LEN_2:
6074 *len = 6;
6075 break;
6076 case BMI2_AUX_READ_LEN_3:
6077 *len = 8;
6078 break;
6079 default:
6080 rslt = BMI2_E_AUX_INVALID_CFG;
6081 break;
6084 return rslt;
6088 * @brief This internal API computes the number of bytes of accelerometer FIFO
6089 * data which is to be parsed in header-less mode.
6091 static int8_t parse_fifo_accel_len(uint16_t *start_idx,
6092 uint16_t *len,
6093 const uint16_t *acc_count,
6094 const struct bmi2_fifo_frame *fifo)
6096 /* Variable to define error */
6097 int8_t rslt = BMI2_OK;
6099 /* Data start index */
6100 (*start_idx) = fifo->acc_byte_start_idx;
6102 /* If only accelerometer is enabled */
6103 if (fifo->data_enable == BMI2_FIFO_ACC_EN)
6105 /* Number of bytes to be read */
6106 (*len) = (uint16_t)((*acc_count) * BMI2_FIFO_ACC_LENGTH);
6108 /* If only accelerometer and auxiliary are enabled */
6109 else if (fifo->data_enable == (BMI2_FIFO_ACC_EN | BMI2_FIFO_AUX_EN))
6111 /* Number of bytes to be read */
6112 (*len) = (uint16_t)((*acc_count) * BMI2_FIFO_ACC_AUX_LENGTH);
6114 /* If only accelerometer and gyroscope are enabled */
6115 else if (fifo->data_enable == (BMI2_FIFO_ACC_EN | BMI2_FIFO_GYR_EN))
6117 /* Number of bytes to be read */
6118 (*len) = (uint16_t)((*acc_count) * BMI2_FIFO_ACC_GYR_LENGTH);
6120 /* If only accelerometer, gyroscope and auxiliary are enabled */
6121 else if (fifo->data_enable == (BMI2_FIFO_ACC_EN | BMI2_FIFO_GYR_EN | BMI2_FIFO_AUX_EN))
6123 /* Number of bytes to be read */
6124 (*len) = (uint16_t)((*acc_count) * BMI2_FIFO_ALL_LENGTH);
6126 else
6128 /* Move the data index to the last byte to mark completion when
6129 * no sensors or sensors apart from accelerometer are enabled
6131 (*start_idx) = fifo->length;
6133 /* FIFO is empty */
6134 rslt = BMI2_W_FIFO_EMPTY;
6137 /* If more data is requested than available */
6138 if ((*len) > fifo->length)
6140 (*len) = fifo->length;
6143 return rslt;
6147 * @brief This internal API is used to parse the accelerometer data from the
6148 * FIFO in header mode.
6150 static int8_t extract_accel_header_mode(struct bmi2_sens_axes_data *acc,
6151 uint16_t *accel_length,
6152 struct bmi2_fifo_frame *fifo,
6153 const struct bmi2_dev *dev)
6155 /* Variable to define error */
6156 int8_t rslt = BMI2_OK;
6158 /* Variable to define header frame */
6159 uint8_t frame_header = 0;
6161 /* Variable to index the data bytes */
6162 uint16_t data_index;
6164 /* Variable to index accelerometer frames */
6165 uint16_t accel_index = 0;
6167 /* Variable to indicate accelerometer frames read */
6168 uint16_t frame_to_read = *accel_length;
6170 for (data_index = fifo->acc_byte_start_idx; data_index < fifo->length;)
6172 /* Get frame header byte */
6173 frame_header = fifo->data[data_index] & BMI2_FIFO_TAG_INTR_MASK;
6175 /* Parse virtual header if S4S is enabled */
6176 parse_if_virtual_header(&frame_header, &data_index, fifo);
6178 /* Index shifted to next byte where data starts */
6179 data_index++;
6180 switch (frame_header)
6182 /* If header defines accelerometer frame */
6183 case BMI2_FIFO_HEADER_ACC_FRM:
6184 case BMI2_FIFO_HEADER_AUX_ACC_FRM:
6185 case BMI2_FIFO_HEADER_GYR_ACC_FRM:
6186 case BMI2_FIFO_HEADER_ALL_FRM:
6188 /* Unpack from normal frames */
6189 rslt = unpack_accel_frame(acc, &data_index, &accel_index, frame_header, fifo, dev);
6190 break;
6192 /* If header defines only gyroscope frame */
6193 case BMI2_FIFO_HEADER_GYR_FRM:
6194 rslt = move_next_frame(&data_index, fifo->gyr_frm_len, fifo);
6195 break;
6197 /* If header defines only auxiliary frame */
6198 case BMI2_FIFO_HEADER_AUX_FRM:
6199 rslt = move_next_frame(&data_index, fifo->aux_frm_len, fifo);
6200 break;
6202 /* If header defines only auxiliary and gyroscope frame */
6203 case BMI2_FIFO_HEADER_AUX_GYR_FRM:
6204 rslt = move_next_frame(&data_index, fifo->aux_gyr_frm_len, fifo);
6205 break;
6207 /* If header defines sensor time frame */
6208 case BMI2_FIFO_HEADER_SENS_TIME_FRM:
6209 rslt = unpack_sensortime_frame(&data_index, fifo);
6210 break;
6212 /* If header defines skip frame */
6213 case BMI2_FIFO_HEADER_SKIP_FRM:
6214 rslt = unpack_skipped_frame(&data_index, fifo);
6215 break;
6217 /* If header defines Input configuration frame */
6218 case BMI2_FIFO_HEADER_INPUT_CFG_FRM:
6219 rslt = move_next_frame(&data_index, BMI2_FIFO_INPUT_CFG_LENGTH, fifo);
6220 break;
6222 /* If header defines invalid frame or end of valid data */
6223 case BMI2_FIFO_HEAD_OVER_READ_MSB:
6225 /* Move the data index to the last byte to mark completion */
6226 data_index = fifo->length;
6228 /* FIFO is empty */
6229 rslt = BMI2_W_FIFO_EMPTY;
6230 break;
6231 case BMI2_FIFO_VIRT_ACT_RECOG_FRM:
6232 rslt = move_next_frame(&data_index, BMI2_FIFO_VIRT_ACT_DATA_LENGTH, fifo);
6233 break;
6234 default:
6236 /* Move the data index to the last byte in case of invalid values */
6237 data_index = fifo->length;
6239 /* FIFO is empty */
6240 rslt = BMI2_W_FIFO_EMPTY;
6241 break;
6244 /* Break if Number of frames to be read is complete or FIFO is mpty */
6245 if ((frame_to_read == accel_index) || (rslt == BMI2_W_FIFO_EMPTY))
6247 break;
6251 /* Update the accelerometer frame index */
6252 (*accel_length) = accel_index;
6254 /* Update the accelerometer byte index */
6255 fifo->acc_byte_start_idx = data_index;
6257 return rslt;
6261 * @brief This internal API is used to parse the accelerometer data from the
6262 * FIFO data in both header and header-less mode. It updates the current data
6263 * byte to be parsed.
6265 static int8_t unpack_accel_frame(struct bmi2_sens_axes_data *acc,
6266 uint16_t *idx,
6267 uint16_t *acc_idx,
6268 uint8_t frame,
6269 const struct bmi2_fifo_frame *fifo,
6270 const struct bmi2_dev *dev)
6272 /* Variable to define error */
6273 int8_t rslt = BMI2_OK;
6275 switch (frame)
6277 /* If frame contains only accelerometer data */
6278 case BMI2_FIFO_HEADER_ACC_FRM:
6279 case BMI2_FIFO_HEAD_LESS_ACC_FRM:
6281 /* Partially read, then skip the data */
6282 if (((*idx) + fifo->acc_frm_len) > fifo->length)
6284 /* Update the data index as complete*/
6285 (*idx) = fifo->length;
6287 /* FIFO is empty */
6288 rslt = BMI2_W_FIFO_EMPTY;
6289 break;
6292 /* Get the accelerometer data */
6293 unpack_accel_data(&acc[(*acc_idx)], *idx, fifo, dev);
6295 /* Update data index */
6296 (*idx) = (*idx) + BMI2_FIFO_ACC_LENGTH;
6298 /* Get virtual sensor time if S4S is enabled */
6299 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6301 unpack_virt_sensor_time(&acc[(*acc_idx)], idx, fifo);
6304 /* Update accelerometer frame index */
6305 (*acc_idx)++;
6307 /* More frames could be read */
6308 rslt = BMI2_W_PARTIAL_READ;
6309 break;
6311 /* If frame contains accelerometer and gyroscope data */
6312 case BMI2_FIFO_HEADER_GYR_ACC_FRM:
6313 case BMI2_FIFO_HEAD_LESS_GYR_ACC_FRM:
6315 /* Partially read, then skip the data */
6316 if (((*idx) + fifo->acc_gyr_frm_len) > fifo->length)
6318 /* Move the data index to the last byte */
6319 (*idx) = fifo->length;
6321 /* FIFO is empty */
6322 rslt = BMI2_W_FIFO_EMPTY;
6323 break;
6326 /* Get the accelerometer data */
6327 unpack_accel_data(&acc[(*acc_idx)], ((*idx) + BMI2_FIFO_GYR_LENGTH), fifo, dev);
6329 /* Update data index */
6330 (*idx) = (*idx) + BMI2_FIFO_ACC_GYR_LENGTH;
6332 /* Get virtual sensor time if S4S is enabled */
6333 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6335 unpack_virt_sensor_time(&acc[(*acc_idx)], idx, fifo);
6338 /* Update accelerometer frame index */
6339 (*acc_idx)++;
6341 /* More frames could be read */
6342 rslt = BMI2_W_PARTIAL_READ;
6343 break;
6345 /* If frame contains accelerometer and auxiliary data */
6346 case BMI2_FIFO_HEADER_AUX_ACC_FRM:
6347 case BMI2_FIFO_HEAD_LESS_AUX_ACC_FRM:
6349 /* Partially read, then skip the data */
6350 if (((*idx) + fifo->acc_aux_frm_len) > fifo->length)
6352 /* Move the data index to the last byte */
6353 (*idx) = fifo->length;
6355 /* FIFO is empty */
6356 rslt = BMI2_W_FIFO_EMPTY;
6357 break;
6360 /* Get the accelerometer data */
6361 unpack_accel_data(&acc[(*acc_idx)], ((*idx) + BMI2_FIFO_AUX_LENGTH), fifo, dev);
6363 /* Update data index */
6364 (*idx) = (*idx) + BMI2_FIFO_ACC_AUX_LENGTH;
6366 /* Get virtual sensor time if S4S is enabled */
6367 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6369 unpack_virt_sensor_time(&acc[(*acc_idx)], idx, fifo);
6372 /* Update accelerometer frame index */
6373 (*acc_idx)++;
6375 /* More frames could be read */
6376 rslt = BMI2_W_PARTIAL_READ;
6377 break;
6379 /* If frame contains accelerometer, gyroscope and auxiliary data */
6380 case BMI2_FIFO_HEADER_ALL_FRM:
6381 case BMI2_FIFO_HEAD_LESS_ALL_FRM:
6383 /* Partially read, then skip the data*/
6384 if ((*idx + fifo->all_frm_len) > fifo->length)
6386 /* Move the data index to the last byte */
6387 (*idx) = fifo->length;
6389 /* FIFO is empty */
6390 rslt = BMI2_W_FIFO_EMPTY;
6391 break;
6394 /* Get the accelerometer data */
6395 unpack_accel_data(&acc[(*acc_idx)], ((*idx) + BMI2_FIFO_GYR_AUX_LENGTH), fifo, dev);
6397 /* Update data index */
6398 (*idx) = (*idx) + BMI2_FIFO_ALL_LENGTH;
6400 /* Get virtual sensor time if S4S is enabled */
6401 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6403 unpack_virt_sensor_time(&acc[(*acc_idx)], idx, fifo);
6406 /* Update accelerometer frame index */
6407 (*acc_idx)++;
6409 /* More frames could be read */
6410 rslt = BMI2_W_PARTIAL_READ;
6411 break;
6413 /* If frame contains gyroscope and auxiliary data */
6414 case BMI2_FIFO_HEADER_AUX_GYR_FRM:
6415 case BMI2_FIFO_HEAD_LESS_GYR_AUX_FRM:
6417 /* Update data index */
6418 (*idx) = (*idx) + fifo->aux_gyr_frm_len;
6420 /* More frames could be read */
6421 rslt = BMI2_W_PARTIAL_READ;
6422 break;
6424 /* If frame contains only auxiliary data */
6425 case BMI2_FIFO_HEADER_AUX_FRM:
6426 case BMI2_FIFO_HEAD_LESS_AUX_FRM:
6428 /* Update data index */
6429 (*idx) = (*idx) + fifo->aux_frm_len;
6431 /* More frames could be read */
6432 rslt = BMI2_W_PARTIAL_READ;
6433 break;
6435 /* If frame contains only gyroscope data */
6436 case BMI2_FIFO_HEADER_GYR_FRM:
6437 case BMI2_FIFO_HEAD_LESS_GYR_FRM:
6439 /* Update data index */
6440 (*idx) = (*idx) + fifo->gyr_frm_len;
6442 /* More frames could be read */
6443 rslt = BMI2_W_PARTIAL_READ;
6444 break;
6445 default:
6447 /* Move the data index to the last byte in case of invalid values */
6448 (*idx) = fifo->length;
6450 /* FIFO is empty */
6451 rslt = BMI2_W_FIFO_EMPTY;
6452 break;
6455 return rslt;
6459 * @brief This internal API is used to parse accelerometer data from the
6460 * FIFO data.
6462 static void unpack_accel_data(struct bmi2_sens_axes_data *acc,
6463 uint16_t data_start_index,
6464 const struct bmi2_fifo_frame *fifo,
6465 const struct bmi2_dev *dev)
6467 /* Variables to store LSB value */
6468 uint16_t data_lsb;
6470 /* Variables to store MSB value */
6471 uint16_t data_msb;
6473 /* Accelerometer raw x data */
6474 data_lsb = fifo->data[data_start_index++];
6475 data_msb = fifo->data[data_start_index++];
6476 acc->x = (int16_t)((data_msb << 8) | data_lsb);
6478 /* Accelerometer raw y data */
6479 data_lsb = fifo->data[data_start_index++];
6480 data_msb = fifo->data[data_start_index++];
6481 acc->y = (int16_t)((data_msb << 8) | data_lsb);
6483 /* Accelerometer raw z data */
6484 data_lsb = fifo->data[data_start_index++];
6485 data_msb = fifo->data[data_start_index++];
6486 acc->z = (int16_t)((data_msb << 8) | data_lsb);
6488 /* Get the re-mapped accelerometer data */
6489 get_remapped_data(acc, dev);
6493 * @brief This internal API computes the number of bytes of gyroscope FIFO data
6494 * which is to be parsed in header-less mode.
6496 static int8_t parse_fifo_gyro_len(uint16_t *start_idx,
6497 uint16_t(*len),
6498 const uint16_t *gyr_count,
6499 const struct bmi2_fifo_frame *fifo)
6501 /* Variable to define error */
6502 int8_t rslt = BMI2_OK;
6504 /* Data start index */
6505 (*start_idx) = fifo->gyr_byte_start_idx;
6507 /* If only gyroscope is enabled */
6508 if (fifo->data_enable == BMI2_FIFO_GYR_EN)
6510 /* Number of bytes to be read */
6511 (*len) = (uint16_t)((*gyr_count) * BMI2_FIFO_GYR_LENGTH);
6513 /* If only gyroscope and auxiliary are enabled */
6514 else if (fifo->data_enable == (BMI2_FIFO_GYR_EN | BMI2_FIFO_AUX_EN))
6516 /* Number of bytes to be read */
6517 (*len) = (uint16_t)((*gyr_count) * BMI2_FIFO_GYR_AUX_LENGTH);
6519 /* If only accelerometer and gyroscope are enabled */
6520 else if (fifo->data_enable == (BMI2_FIFO_ACC_EN | BMI2_FIFO_GYR_EN))
6522 /* Number of bytes to be read */
6523 (*len) = (uint16_t)((*gyr_count) * BMI2_FIFO_ACC_GYR_LENGTH);
6525 /* If only accelerometer, gyroscope and auxiliary are enabled */
6526 else if (fifo->data_enable == (BMI2_FIFO_GYR_EN | BMI2_FIFO_AUX_EN | BMI2_FIFO_ACC_EN))
6528 /* Number of bytes to be read */
6529 (*len) = (uint16_t)((*gyr_count) * BMI2_FIFO_ALL_LENGTH);
6531 else
6533 /* Move the data index to the last byte to mark completion when
6534 * no sensors or sensors apart from gyroscope are enabled
6536 (*start_idx) = fifo->length;
6538 /* FIFO is empty */
6539 rslt = BMI2_W_FIFO_EMPTY;
6542 /* If more data is requested than available */
6543 if (((*len)) > fifo->length)
6545 (*len) = fifo->length;
6548 return rslt;
6552 * @brief This internal API is used to parse the gyroscope data from the
6553 * FIFO data in header mode.
6555 static int8_t extract_gyro_header_mode(struct bmi2_sens_axes_data *gyr,
6556 uint16_t *gyro_length,
6557 struct bmi2_fifo_frame *fifo,
6558 const struct bmi2_dev *dev)
6560 /* Variable to define error */
6561 int8_t rslt = BMI2_OK;
6563 /* Variable to define header frame */
6564 uint8_t frame_header = 0;
6566 /* Variable to index the data bytes */
6567 uint16_t data_index;
6569 /* Variable to index gyroscope frames */
6570 uint16_t gyro_index = 0;
6572 /* Variable to indicate gyroscope frames read */
6573 uint16_t frame_to_read = (*gyro_length);
6575 for (data_index = fifo->gyr_byte_start_idx; data_index < fifo->length;)
6577 /* Get frame header byte */
6578 frame_header = fifo->data[data_index] & BMI2_FIFO_TAG_INTR_MASK;
6580 /* Parse virtual header if S4S is enabled */
6581 parse_if_virtual_header(&frame_header, &data_index, fifo);
6583 /* Index shifted to next byte where data starts */
6584 data_index++;
6585 switch (frame_header)
6587 /* If header defines gyroscope frame */
6588 case BMI2_FIFO_HEADER_GYR_FRM:
6589 case BMI2_FIFO_HEADER_GYR_ACC_FRM:
6590 case BMI2_FIFO_HEADER_AUX_GYR_FRM:
6591 case BMI2_FIFO_HEADER_ALL_FRM:
6593 /* Unpack from normal frames */
6594 rslt = unpack_gyro_frame(gyr, &data_index, &gyro_index, frame_header, fifo, dev);
6595 break;
6597 /* If header defines only accelerometer frame */
6598 case BMI2_FIFO_HEADER_ACC_FRM:
6599 rslt = move_next_frame(&data_index, fifo->acc_frm_len, fifo);
6600 break;
6602 /* If header defines only auxiliary frame */
6603 case BMI2_FIFO_HEADER_AUX_FRM:
6604 rslt = move_next_frame(&data_index, fifo->aux_frm_len, fifo);
6605 break;
6607 /* If header defines only auxiliary and accelerometer frame */
6608 case BMI2_FIFO_HEADER_AUX_ACC_FRM:
6609 rslt = move_next_frame(&data_index, fifo->acc_aux_frm_len, fifo);
6610 break;
6612 /* If header defines sensor time frame */
6613 case BMI2_FIFO_HEADER_SENS_TIME_FRM:
6614 rslt = unpack_sensortime_frame(&data_index, fifo);
6615 break;
6617 /* If header defines skip frame */
6618 case BMI2_FIFO_HEADER_SKIP_FRM:
6619 rslt = unpack_skipped_frame(&data_index, fifo);
6620 break;
6622 /* If header defines Input configuration frame */
6623 case BMI2_FIFO_HEADER_INPUT_CFG_FRM:
6624 rslt = move_next_frame(&data_index, BMI2_FIFO_INPUT_CFG_LENGTH, fifo);
6625 break;
6627 /* If header defines invalid frame or end of valid data */
6628 case BMI2_FIFO_HEAD_OVER_READ_MSB:
6630 /* Move the data index to the last byte */
6631 data_index = fifo->length;
6633 /* FIFO is empty */
6634 rslt = BMI2_W_FIFO_EMPTY;
6635 break;
6636 case BMI2_FIFO_VIRT_ACT_RECOG_FRM:
6637 rslt = move_next_frame(&data_index, BMI2_FIFO_VIRT_ACT_DATA_LENGTH, fifo);
6638 break;
6639 default:
6641 /* Move the data index to the last byte in case of invalid values */
6642 data_index = fifo->length;
6644 /* FIFO is empty */
6645 rslt = BMI2_W_FIFO_EMPTY;
6646 break;
6649 /* Break if number of frames to be read is complete or FIFO is empty */
6650 if ((frame_to_read == gyro_index) || (rslt == BMI2_W_FIFO_EMPTY))
6652 break;
6656 /* Update the gyroscope frame index */
6657 (*gyro_length) = gyro_index;
6659 /* Update the gyroscope byte index */
6660 fifo->gyr_byte_start_idx = data_index;
6662 return rslt;
6666 * @brief This internal API is used to parse the gyroscope data from the FIFO
6667 * data in both header and header-less mode. It updates the current data byte to
6668 * be parsed.
6670 static int8_t unpack_gyro_frame(struct bmi2_sens_axes_data *gyr,
6671 uint16_t *idx,
6672 uint16_t *gyr_idx,
6673 uint8_t frame,
6674 const struct bmi2_fifo_frame *fifo,
6675 const struct bmi2_dev *dev)
6677 /* Variable to define error */
6678 int8_t rslt = BMI2_OK;
6680 switch (frame)
6682 /* If frame contains only gyroscope data */
6683 case BMI2_FIFO_HEADER_GYR_FRM:
6684 case BMI2_FIFO_HEAD_LESS_GYR_FRM:
6686 /* Partially read, then skip the data */
6687 if (((*idx) + fifo->gyr_frm_len) > fifo->length)
6689 /* Update the data index as complete*/
6690 (*idx) = fifo->length;
6692 /* FIFO is empty */
6693 rslt = BMI2_W_FIFO_EMPTY;
6694 break;
6697 /* Get the gyroscope data */
6698 unpack_gyro_data(&gyr[(*gyr_idx)], *idx, fifo, dev);
6700 /* Update data index */
6701 (*idx) = (*idx) + BMI2_FIFO_GYR_LENGTH;
6703 /* Get virtual sensor time if S4S is enabled */
6704 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6706 unpack_virt_sensor_time(&gyr[(*gyr_idx)], idx, fifo);
6709 /* Update gyroscope frame index */
6710 (*gyr_idx)++;
6712 /* More frames could be read */
6713 rslt = BMI2_W_PARTIAL_READ;
6714 break;
6716 /* If frame contains accelerometer and gyroscope data */
6717 case BMI2_FIFO_HEADER_GYR_ACC_FRM:
6718 case BMI2_FIFO_HEAD_LESS_GYR_ACC_FRM:
6720 /* Partially read, then skip the data */
6721 if (((*idx) + fifo->acc_gyr_frm_len) > fifo->length)
6723 /* Move the data index to the last byte */
6724 (*idx) = fifo->length;
6726 /* FIFO is empty */
6727 rslt = BMI2_W_FIFO_EMPTY;
6728 break;
6731 /* Get the gyroscope data */
6732 unpack_gyro_data(&gyr[(*gyr_idx)], (*idx), fifo, dev);
6734 /* Update data index */
6735 (*idx) = (*idx) + BMI2_FIFO_ACC_GYR_LENGTH;
6737 /* Get virtual sensor time if S4S is enabled */
6738 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6740 unpack_virt_sensor_time(&gyr[(*gyr_idx)], idx, fifo);
6743 /* Update gyroscope frame index */
6744 (*gyr_idx)++;
6746 /* More frames could be read */
6747 rslt = BMI2_W_PARTIAL_READ;
6748 break;
6750 /* If frame contains gyroscope and auxiliary data */
6751 case BMI2_FIFO_HEADER_AUX_GYR_FRM:
6752 case BMI2_FIFO_HEAD_LESS_GYR_AUX_FRM:
6754 /* Partially read, then skip the data */
6755 if (((*idx) + fifo->aux_gyr_frm_len) > fifo->length)
6757 /* Move the data index to the last byte */
6758 (*idx) = fifo->length;
6760 /* FIFO is empty */
6761 rslt = BMI2_W_FIFO_EMPTY;
6762 break;
6765 /* Get the gyroscope data */
6766 unpack_gyro_data(&gyr[(*gyr_idx)], ((*idx) + BMI2_FIFO_AUX_LENGTH), fifo, dev);
6768 /* Update data index */
6769 (*idx) = (*idx) + BMI2_FIFO_GYR_AUX_LENGTH;
6771 /* Get virtual sensor time if S4S is enabled */
6772 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6774 unpack_virt_sensor_time(&gyr[(*gyr_idx)], idx, fifo);
6777 /* Update gyroscope frame index */
6778 (*gyr_idx)++;
6780 /* More frames could be read */
6781 rslt = BMI2_W_PARTIAL_READ;
6782 break;
6784 /* If frame contains accelerometer, gyroscope and auxiliary data */
6785 case BMI2_FIFO_HEADER_ALL_FRM:
6786 case BMI2_FIFO_HEAD_LESS_ALL_FRM:
6788 /* Partially read, then skip the data*/
6789 if ((*idx + fifo->all_frm_len) > fifo->length)
6791 /* Move the data index to the last byte */
6792 (*idx) = fifo->length;
6794 /* FIFO is empty */
6795 rslt = BMI2_W_FIFO_EMPTY;
6796 break;
6799 /* Get the gyroscope data */
6800 unpack_gyro_data(&gyr[(*gyr_idx)], ((*idx) + BMI2_FIFO_AUX_LENGTH), fifo, dev);
6802 /* Update data index */
6803 (*idx) = (*idx) + BMI2_FIFO_ALL_LENGTH;
6805 /* Get virtual sensor time if S4S is enabled */
6806 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
6808 unpack_virt_sensor_time(&gyr[(*gyr_idx)], idx, fifo);
6811 /* Update gyroscope frame index */
6812 (*gyr_idx)++;
6814 /* More frames could be read */
6815 rslt = BMI2_W_PARTIAL_READ;
6816 break;
6818 /* If frame contains accelerometer and auxiliary data */
6819 case BMI2_FIFO_HEADER_AUX_ACC_FRM:
6820 case BMI2_FIFO_HEAD_LESS_AUX_ACC_FRM:
6822 /* Update data index */
6823 (*idx) = (*idx) + fifo->acc_aux_frm_len;
6825 /* More frames could be read */
6826 rslt = BMI2_W_PARTIAL_READ;
6827 break;
6829 /* If frame contains only auxiliary data */
6830 case BMI2_FIFO_HEADER_AUX_FRM:
6831 case BMI2_FIFO_HEAD_LESS_AUX_FRM:
6833 /* Update data index */
6834 (*idx) = (*idx) + fifo->aux_frm_len;
6836 /* More frames could be read */
6837 rslt = BMI2_W_PARTIAL_READ;
6838 break;
6840 /* If frame contains only accelerometer data */
6841 case BMI2_FIFO_HEADER_ACC_FRM:
6842 case BMI2_FIFO_HEAD_LESS_ACC_FRM:
6844 /* Update data index */
6845 (*idx) = (*idx) + fifo->acc_frm_len;
6847 /* More frames could be read */
6848 rslt = BMI2_W_PARTIAL_READ;
6849 break;
6850 default:
6852 /* Move the data index to the last byte in case of invalid values */
6853 (*idx) = fifo->length;
6855 /* FIFO is empty */
6856 rslt = BMI2_W_FIFO_EMPTY;
6857 break;
6860 return rslt;
6864 * @brief This internal API is used to parse gyroscope data from the FIFO data.
6866 static void unpack_gyro_data(struct bmi2_sens_axes_data *gyr,
6867 uint16_t data_start_index,
6868 const struct bmi2_fifo_frame *fifo,
6869 const struct bmi2_dev *dev)
6871 /* Variables to store LSB value */
6872 uint16_t data_lsb;
6874 /* Variables to store MSB value */
6875 uint16_t data_msb;
6877 /* Gyroscope raw x data */
6878 data_lsb = fifo->data[data_start_index++];
6879 data_msb = fifo->data[data_start_index++];
6880 gyr->x = (int16_t)((data_msb << 8) | data_lsb);
6882 /* Gyroscope raw y data */
6883 data_lsb = fifo->data[data_start_index++];
6884 data_msb = fifo->data[data_start_index++];
6885 gyr->y = (int16_t)((data_msb << 8) | data_lsb);
6887 /* Gyroscope raw z data */
6888 data_lsb = fifo->data[data_start_index++];
6889 data_msb = fifo->data[data_start_index++];
6890 gyr->z = (int16_t)((data_msb << 8) | data_lsb);
6892 /* Get the compensated gyroscope data */
6893 comp_gyro_cross_axis_sensitivity(gyr, dev);
6895 /* Get the re-mapped gyroscope data */
6896 get_remapped_data(gyr, dev);
6900 * @brief This API computes the number of bytes of auxiliary FIFO data which is
6901 * to be parsed in header-less mode.
6903 static int8_t parse_fifo_aux_len(uint16_t *start_idx,
6904 uint16_t(*len),
6905 const uint16_t *aux_count,
6906 const struct bmi2_fifo_frame *fifo)
6908 /* Variable to define error */
6909 int8_t rslt = BMI2_OK;
6911 /* Data start index */
6912 *start_idx = fifo->aux_byte_start_idx;
6914 /* If only auxiliary is enabled */
6915 if (fifo->data_enable == BMI2_FIFO_AUX_EN)
6917 /* Number of bytes to be read */
6918 (*len) = (uint16_t)((*aux_count) * BMI2_FIFO_AUX_LENGTH);
6920 /* If only accelerometer and auxiliary are enabled */
6921 else if (fifo->data_enable == (BMI2_FIFO_AUX_EN | BMI2_FIFO_ACC_EN))
6923 /* Number of bytes to be read */
6924 (*len) = (uint16_t)((*aux_count) * BMI2_FIFO_ACC_AUX_LENGTH);
6926 /* If only accelerometer and gyroscope are enabled */
6927 else if (fifo->data_enable == (BMI2_FIFO_AUX_EN | BMI2_FIFO_GYR_EN))
6929 /* Number of bytes to be read */
6930 (*len) = (uint16_t)((*aux_count) * BMI2_FIFO_GYR_AUX_LENGTH);
6932 /* If only accelerometer, gyroscope and auxiliary are enabled */
6933 else if (fifo->data_enable == (BMI2_FIFO_AUX_EN | BMI2_FIFO_GYR_EN | BMI2_FIFO_ACC_EN))
6935 /* Number of bytes to be read */
6936 (*len) = (uint16_t)((*aux_count) * BMI2_FIFO_ALL_LENGTH);
6938 else
6940 /* Move the data index to the last byte to mark completion when
6941 * no sensors or sensors apart from gyroscope are enabled
6943 (*start_idx) = fifo->length;
6945 /* FIFO is empty */
6946 rslt = BMI2_W_FIFO_EMPTY;
6949 /* If more data is requested than available */
6950 if (((*len)) > fifo->length)
6952 (*len) = fifo->length;
6955 return rslt;
6959 * @brief This API is used to parse the auxiliary data from the FIFO data in
6960 * header mode.
6962 static int8_t extract_aux_header_mode(struct bmi2_aux_fifo_data *aux,
6963 uint16_t *aux_len,
6964 struct bmi2_fifo_frame *fifo,
6965 const struct bmi2_dev *dev)
6967 /* Variable to define error */
6968 int8_t rslt = BMI2_OK;
6970 /* Variable to define header frame */
6971 uint8_t frame_header = 0;
6973 /* Variable to index the data bytes */
6974 uint16_t data_index;
6976 /* Variable to index gyroscope frames */
6977 uint16_t aux_index = 0;
6979 /* Variable to indicate auxiliary frames read */
6980 uint16_t frame_to_read = *aux_len;
6982 for (data_index = fifo->aux_byte_start_idx; data_index < fifo->length;)
6984 /* Get frame header byte */
6985 frame_header = fifo->data[data_index] & BMI2_FIFO_TAG_INTR_MASK;
6987 /* Parse virtual header if S4S is enabled */
6988 parse_if_virtual_header(&frame_header, &data_index, fifo);
6990 /* Index shifted to next byte where data starts */
6991 data_index++;
6992 switch (frame_header)
6994 /* If header defines auxiliary frame */
6995 case BMI2_FIFO_HEADER_AUX_FRM:
6996 case BMI2_FIFO_HEADER_AUX_ACC_FRM:
6997 case BMI2_FIFO_HEADER_AUX_GYR_FRM:
6998 case BMI2_FIFO_HEADER_ALL_FRM:
7000 /* Unpack from normal frames */
7001 rslt = unpack_aux_frame(aux, &data_index, &aux_index, frame_header, fifo, dev);
7002 break;
7004 /* If header defines only accelerometer frame */
7005 case BMI2_FIFO_HEADER_ACC_FRM:
7006 rslt = move_next_frame(&data_index, fifo->acc_frm_len, fifo);
7007 break;
7009 /* If header defines only gyroscope frame */
7010 case BMI2_FIFO_HEADER_GYR_FRM:
7011 rslt = move_next_frame(&data_index, fifo->gyr_frm_len, fifo);
7012 break;
7014 /* If header defines only gyroscope and accelerometer frame */
7015 case BMI2_FIFO_HEADER_GYR_ACC_FRM:
7016 rslt = move_next_frame(&data_index, fifo->acc_gyr_frm_len, fifo);
7017 break;
7019 /* If header defines sensor time frame */
7020 case BMI2_FIFO_HEADER_SENS_TIME_FRM:
7021 rslt = unpack_sensortime_frame(&data_index, fifo);
7022 break;
7024 /* If header defines skip frame */
7025 case BMI2_FIFO_HEADER_SKIP_FRM:
7026 rslt = unpack_skipped_frame(&data_index, fifo);
7027 break;
7029 /* If header defines Input configuration frame */
7030 case BMI2_FIFO_HEADER_INPUT_CFG_FRM:
7031 rslt = move_next_frame(&data_index, BMI2_FIFO_INPUT_CFG_LENGTH, fifo);
7032 break;
7034 /* If header defines invalid frame or end of valid data */
7035 case BMI2_FIFO_HEAD_OVER_READ_MSB:
7037 /* Move the data index to the last byte */
7038 data_index = fifo->length;
7040 /* FIFO is empty */
7041 rslt = BMI2_W_FIFO_EMPTY;
7042 break;
7043 case BMI2_FIFO_VIRT_ACT_RECOG_FRM:
7044 rslt = move_next_frame(&data_index, BMI2_FIFO_VIRT_ACT_DATA_LENGTH, fifo);
7045 break;
7046 default:
7048 /* Move the data index to the last byte in case
7049 * of invalid values
7051 data_index = fifo->length;
7053 /* FIFO is empty */
7054 rslt = BMI2_W_FIFO_EMPTY;
7055 break;
7058 /* Break if number of frames to be read is complete or FIFO is
7059 * empty
7061 if ((frame_to_read == aux_index) || (rslt == BMI2_W_FIFO_EMPTY))
7063 break;
7067 /* Update the gyroscope frame index */
7068 (*aux_len) = aux_index;
7070 /* Update the gyroscope byte index */
7071 fifo->aux_byte_start_idx = data_index;
7073 return rslt;
7077 * @brief This API is used to parse the auxiliary frame from the FIFO data in
7078 * both header mode and header-less mode and update the data_index value which
7079 * is used to store the index of the current data byte which is parsed.
7081 static int8_t unpack_aux_frame(struct bmi2_aux_fifo_data *aux,
7082 uint16_t *idx,
7083 uint16_t *aux_idx,
7084 uint8_t frame,
7085 const struct bmi2_fifo_frame *fifo,
7086 const struct bmi2_dev *dev)
7088 /* Variable to define error */
7089 int8_t rslt = BMI2_OK;
7091 switch (frame)
7093 /* If frame contains only auxiliary data */
7094 case BMI2_FIFO_HEADER_AUX_FRM:
7095 case BMI2_FIFO_HEAD_LESS_AUX_FRM:
7097 /* Partially read, then skip the data */
7098 if (((*idx) + fifo->aux_frm_len) > fifo->length)
7100 /* Update the data index as complete*/
7101 (*idx) = fifo->length;
7103 /* FIFO is empty */
7104 rslt = BMI2_W_FIFO_EMPTY;
7105 break;
7108 /* Get the auxiliary data */
7109 unpack_aux_data(&aux[(*aux_idx)], (*idx), fifo);
7111 /* Update data index */
7112 (*idx) = (*idx) + BMI2_FIFO_AUX_LENGTH;
7114 /* Get virtual sensor time if S4S is enabled */
7115 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
7117 unpack_virt_aux_sensor_time(&aux[(*aux_idx)], idx, fifo);
7120 /* Update auxiliary frame index */
7121 (*aux_idx)++;
7123 /* More frames could be read */
7124 rslt = BMI2_W_PARTIAL_READ;
7125 break;
7127 /* If frame contains accelerometer and auxiliary data */
7128 case BMI2_FIFO_HEADER_AUX_ACC_FRM:
7129 case BMI2_FIFO_HEAD_LESS_AUX_ACC_FRM:
7131 /* Partially read, then skip the data */
7132 if (((*idx) + fifo->acc_aux_frm_len) > fifo->length)
7134 /* Move the data index to the last byte */
7135 (*idx) = fifo->length;
7137 /* FIFO is empty */
7138 rslt = BMI2_W_FIFO_EMPTY;
7139 break;
7142 /* Get the auxiliary data */
7143 unpack_aux_data(&aux[(*aux_idx)], (*idx), fifo);
7145 /* Update data index */
7146 (*idx) = (*idx) + BMI2_FIFO_ACC_AUX_LENGTH;
7148 /* Get virtual sensor time if S4S is enabled */
7149 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
7151 unpack_virt_aux_sensor_time(&aux[(*aux_idx)], idx, fifo);
7154 /* Update auxiliary frame index */
7155 (*aux_idx)++;
7157 /* More frames could be read */
7158 rslt = BMI2_W_PARTIAL_READ;
7159 break;
7161 /* If frame contains gyroscope and auxiliary data */
7162 case BMI2_FIFO_HEADER_AUX_GYR_FRM:
7163 case BMI2_FIFO_HEAD_LESS_GYR_AUX_FRM:
7165 /* Partially read, then skip the data */
7166 if (((*idx) + fifo->aux_gyr_frm_len) > fifo->length)
7168 /* Move the data index to the last byte */
7169 (*idx) = fifo->length;
7171 /* FIFO is empty */
7172 rslt = BMI2_W_FIFO_EMPTY;
7173 break;
7176 /* Get the auxiliary data */
7177 unpack_aux_data(&aux[(*aux_idx)], (*idx), fifo);
7179 /* Update data index */
7180 (*idx) = (*idx) + BMI2_FIFO_GYR_AUX_LENGTH;
7182 /* Get virtual sensor time if S4S is enabled */
7183 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
7185 unpack_virt_aux_sensor_time(&aux[(*aux_idx)], idx, fifo);
7188 /* Update auxiliary frame index */
7189 (*aux_idx)++;
7191 /* More frames could be read */
7192 rslt = BMI2_W_PARTIAL_READ;
7193 break;
7195 /* If frame contains accelerometer, gyroscope and auxiliary data */
7196 case BMI2_FIFO_HEADER_ALL_FRM:
7197 case BMI2_FIFO_HEAD_LESS_ALL_FRM:
7199 /* Partially read, then skip the data */
7200 if ((*idx + fifo->all_frm_len) > fifo->length)
7202 /* Move the data index to the last byte */
7203 (*idx) = fifo->length;
7205 /* FIFO is empty */
7206 rslt = BMI2_W_FIFO_EMPTY;
7207 break;
7210 /* Get the auxiliary data */
7211 unpack_aux_data(&aux[(*aux_idx)], (*idx), fifo);
7213 /* Update data index */
7214 (*idx) = (*idx) + BMI2_FIFO_ALL_LENGTH;
7216 /* Get virtual sensor time if S4S is enabled */
7217 if (dev->sens_en_stat & BMI2_EXT_SENS_SEL)
7219 unpack_virt_aux_sensor_time(&aux[(*aux_idx)], idx, fifo);
7222 /* Update auxiliary frame index */
7223 (*aux_idx)++;
7225 /* More frames could be read */
7226 rslt = BMI2_W_PARTIAL_READ;
7227 break;
7229 /* If frame contains only accelerometer data */
7230 case BMI2_FIFO_HEADER_ACC_FRM:
7231 case BMI2_FIFO_HEAD_LESS_ACC_FRM:
7233 /* Update data index */
7234 (*idx) = (*idx) + fifo->acc_frm_len;
7236 /* More frames could be read */
7237 rslt = BMI2_W_PARTIAL_READ;
7238 break;
7240 /* If frame contains only gyroscope data */
7241 case BMI2_FIFO_HEADER_GYR_FRM:
7242 case BMI2_FIFO_HEAD_LESS_GYR_FRM:
7244 /* Update data index */
7245 (*idx) = (*idx) + fifo->gyr_frm_len;
7247 /* More frames could be read */
7248 rslt = BMI2_W_PARTIAL_READ;
7249 break;
7251 /* If frame contains accelerometer and gyroscope data */
7252 case BMI2_FIFO_HEADER_GYR_ACC_FRM:
7253 case BMI2_FIFO_HEAD_LESS_GYR_ACC_FRM:
7255 /* Update data index */
7256 (*idx) = (*idx) + fifo->acc_gyr_frm_len;
7258 /* More frames could be read */
7259 rslt = BMI2_W_PARTIAL_READ;
7260 break;
7261 default:
7263 /* Move the data index to the last byte in case of
7264 * invalid values
7266 (*idx) = fifo->length;
7268 /* FIFO is empty */
7269 rslt = BMI2_W_FIFO_EMPTY;
7270 break;
7273 return rslt;
7277 * @brief This internal API is used to parse auxiliary data from the FIFO data.
7279 static void unpack_aux_data(struct bmi2_aux_fifo_data *aux,
7280 uint16_t data_start_index,
7281 const struct bmi2_fifo_frame *fifo)
7283 /* Variables to store index */
7284 uint16_t idx = 0;
7286 /* Get auxiliary data */
7287 for (; idx < 8; idx++)
7289 aux->data[idx] = fifo->data[data_start_index++];
7294 * @brief This internal API parses virtual frame header from the FIFO data.
7296 static void parse_if_virtual_header(uint8_t *frame_header, uint16_t *data_index, const struct bmi2_fifo_frame *fifo)
7298 /* Variable to extract virtual header byte */
7299 uint8_t virtual_header_mode;
7301 /* Extract virtual header mode from the frame header */
7302 virtual_header_mode = BMI2_GET_BITS(*frame_header, BMI2_FIFO_VIRT_FRM_MODE);
7304 /* If the extracted header byte is a virtual header */
7305 if (virtual_header_mode == BMI2_FIFO_VIRT_FRM_MODE)
7307 /* If frame header is not activity recognition header */
7308 if (*frame_header != 0xC8)
7310 /* Index shifted to next byte where sensor frame is present */
7311 (*data_index) = (*data_index) + 1;
7313 /* Get the sensor frame header */
7314 *frame_header = fifo->data[*data_index] & BMI2_FIFO_TAG_INTR_MASK;
7320 * @brief This internal API gets sensor time from the accelerometer and
7321 * gyroscope virtual frames and updates in the data structure.
7323 static void unpack_virt_sensor_time(struct bmi2_sens_axes_data *sens, uint16_t *idx, const struct bmi2_fifo_frame *fifo)
7325 /* Variables to define 3 bytes of sensor time */
7326 uint32_t sensor_time_byte3;
7327 uint16_t sensor_time_byte2;
7328 uint8_t sensor_time_byte1;
7330 /* Get sensor time from the FIFO data */
7331 sensor_time_byte3 = (uint32_t)(fifo->data[(*idx) + BMI2_SENSOR_TIME_MSB_BYTE] << 16);
7332 sensor_time_byte2 = (uint16_t) fifo->data[(*idx) + BMI2_SENSOR_TIME_XLSB_BYTE] << 8;
7333 sensor_time_byte1 = fifo->data[(*idx)];
7335 /* Store sensor time in the sensor data structure */
7336 sens->virt_sens_time = (uint32_t)(sensor_time_byte3 | sensor_time_byte2 | sensor_time_byte1);
7338 /* Move the data index by 3 bytes */
7339 (*idx) = (*idx) + BMI2_SENSOR_TIME_LENGTH;
7343 * @brief This internal API gets sensor time from the auxiliary virtual
7344 * frames and updates in the data structure.
7346 static void unpack_virt_aux_sensor_time(struct bmi2_aux_fifo_data *aux,
7347 uint16_t *idx,
7348 const struct bmi2_fifo_frame *fifo)
7350 /* Variables to define 3 bytes of sensor time */
7351 uint32_t sensor_time_byte3;
7352 uint16_t sensor_time_byte2;
7353 uint8_t sensor_time_byte1;
7355 /* Get sensor time from the FIFO data */
7356 sensor_time_byte3 = (uint32_t)(fifo->data[(*idx) + BMI2_SENSOR_TIME_MSB_BYTE] << 16);
7357 sensor_time_byte2 = (uint16_t) fifo->data[(*idx) + BMI2_SENSOR_TIME_XLSB_BYTE] << 8;
7358 sensor_time_byte1 = fifo->data[(*idx)];
7360 /* Store sensor time in the sensor data structure */
7361 aux->virt_sens_time = (uint32_t)(sensor_time_byte3 | sensor_time_byte2 | sensor_time_byte1);
7363 /* Move the data index by 3 bytes */
7364 (*idx) = (*idx) + BMI2_SENSOR_TIME_LENGTH;
7368 * @brief This internal API is used to reset the FIFO related configurations in
7369 * the FIFO frame structure for the next FIFO read.
7371 static void reset_fifo_frame_structure(struct bmi2_fifo_frame *fifo, const struct bmi2_dev *dev)
7373 /* Reset FIFO data structure */
7374 fifo->acc_byte_start_idx = 0;
7375 fifo->aux_byte_start_idx = 0;
7376 fifo->gyr_byte_start_idx = 0;
7377 fifo->sensor_time = 0;
7378 fifo->skipped_frame_count = 0;
7379 fifo->act_recog_byte_start_idx = 0;
7381 /* If S4S is enabled */
7382 if ((dev->sens_en_stat & BMI2_EXT_SENS_SEL) == BMI2_EXT_SENS_SEL)
7384 fifo->acc_frm_len = BMI2_FIFO_VIRT_ACC_LENGTH;
7385 fifo->gyr_frm_len = BMI2_FIFO_VIRT_GYR_LENGTH;
7386 fifo->aux_frm_len = BMI2_FIFO_VIRT_AUX_LENGTH;
7387 fifo->acc_gyr_frm_len = BMI2_FIFO_VIRT_ACC_GYR_LENGTH;
7388 fifo->acc_aux_frm_len = BMI2_FIFO_VIRT_ACC_AUX_LENGTH;
7389 fifo->aux_gyr_frm_len = BMI2_FIFO_VIRT_GYR_AUX_LENGTH;
7390 fifo->all_frm_len = BMI2_FIFO_VIRT_ALL_LENGTH;
7392 /* If S4S is not enabled */
7394 else
7396 fifo->acc_frm_len = BMI2_FIFO_ACC_LENGTH;
7397 fifo->gyr_frm_len = BMI2_FIFO_GYR_LENGTH;
7398 fifo->aux_frm_len = BMI2_FIFO_AUX_LENGTH;
7399 fifo->acc_gyr_frm_len = BMI2_FIFO_ACC_GYR_LENGTH;
7400 fifo->acc_aux_frm_len = BMI2_FIFO_ACC_AUX_LENGTH;
7401 fifo->aux_gyr_frm_len = BMI2_FIFO_GYR_AUX_LENGTH;
7402 fifo->all_frm_len = BMI2_FIFO_ALL_LENGTH;
7407 * @brief This API internal checks whether the FIFO data read is an empty frame.
7408 * If empty frame, index is moved to the last byte.
7410 static int8_t check_empty_fifo(uint16_t *data_index, const struct bmi2_fifo_frame *fifo)
7412 /* Variables to define error */
7413 int8_t rslt = BMI2_OK;
7415 /* Validate data index */
7416 if (((*data_index) + 6) < fifo->length)
7418 /* Check if FIFO is empty */
7419 if (((fifo->data[(*data_index)] == BMI2_FIFO_MSB_CONFIG_CHECK) &&
7420 (fifo->data[(*data_index) + 1] == BMI2_FIFO_LSB_CONFIG_CHECK)) &&
7421 ((fifo->data[(*data_index) + 2] == BMI2_FIFO_MSB_CONFIG_CHECK) &&
7422 (fifo->data[(*data_index) + 3] == BMI2_FIFO_LSB_CONFIG_CHECK)) &&
7423 ((fifo->data[(*data_index) + 4] == BMI2_FIFO_MSB_CONFIG_CHECK) &&
7424 (fifo->data[(*data_index) + 5] == BMI2_FIFO_LSB_CONFIG_CHECK)))
7426 /* Move the data index to the last byte to mark completion */
7427 (*data_index) = fifo->length;
7429 /* FIFO is empty */
7430 rslt = BMI2_W_FIFO_EMPTY;
7432 else
7434 /* More frames could be read */
7435 rslt = BMI2_W_PARTIAL_READ;
7439 return rslt;
7443 * @brief This internal API is used to move the data index ahead of the
7444 * current_frame_length parameter when unnecessary FIFO data appears while
7445 * extracting the user specified data.
7447 static int8_t move_next_frame(uint16_t *data_index, uint8_t current_frame_length, const struct bmi2_fifo_frame *fifo)
7449 /* Variables to define error */
7450 int8_t rslt = BMI2_OK;
7452 /* Validate data index */
7453 if (((*data_index) + current_frame_length) > fifo->length)
7455 /* Move the data index to the last byte */
7456 (*data_index) = fifo->length;
7458 /* FIFO is empty */
7459 rslt = BMI2_W_FIFO_EMPTY;
7461 else
7463 /* Move the data index to next frame */
7464 (*data_index) = (*data_index) + current_frame_length;
7466 /* More frames could be read */
7467 rslt = BMI2_W_PARTIAL_READ;
7470 return rslt;
7474 * @brief This internal API is used to parse and store the sensor time from the
7475 * FIFO data.
7477 static int8_t unpack_sensortime_frame(uint16_t *data_index, struct bmi2_fifo_frame *fifo)
7479 /* Variables to define error */
7480 int8_t rslt = BMI2_OK;
7482 /* Variables to define 3 bytes of sensor time */
7483 uint32_t sensor_time_byte3 = 0;
7484 uint16_t sensor_time_byte2 = 0;
7485 uint8_t sensor_time_byte1 = 0;
7487 /* Validate data index */
7488 if (((*data_index) + BMI2_SENSOR_TIME_LENGTH) > fifo->length)
7490 /* Move the data index to the last byte */
7491 (*data_index) = fifo->length;
7493 /* FIFO is empty */
7494 rslt = BMI2_W_FIFO_EMPTY;
7496 else
7498 /* Get sensor time from the FIFO data */
7499 sensor_time_byte3 = fifo->data[(*data_index) + BMI2_SENSOR_TIME_MSB_BYTE] << 16;
7500 sensor_time_byte2 = fifo->data[(*data_index) + BMI2_SENSOR_TIME_XLSB_BYTE] << 8;
7501 sensor_time_byte1 = fifo->data[(*data_index)];
7503 /* Update sensor time in the FIFO structure */
7504 fifo->sensor_time = (uint32_t)(sensor_time_byte3 | sensor_time_byte2 | sensor_time_byte1);
7506 /* Move the data index by 3 bytes */
7507 (*data_index) = (*data_index) + BMI2_SENSOR_TIME_LENGTH;
7509 /* More frames could be read */
7510 rslt = BMI2_W_PARTIAL_READ;
7513 return rslt;
7517 * @brief This internal API is used to parse and store the skipped frame count
7518 * from the FIFO data.
7520 static int8_t unpack_skipped_frame(uint16_t *data_index, struct bmi2_fifo_frame *fifo)
7522 /* Variables to define error */
7523 int8_t rslt = BMI2_OK;
7525 /* Validate data index */
7526 if ((*data_index) >= fifo->length)
7528 /* Update the data index to the last byte */
7529 (*data_index) = fifo->length;
7531 /* FIFO is empty */
7532 rslt = BMI2_W_FIFO_EMPTY;
7534 else
7536 /* Update skipped frame count in the FIFO structure */
7537 fifo->skipped_frame_count = fifo->data[(*data_index)];
7539 /* Move the data index by 1 byte */
7540 (*data_index) = (*data_index) + 1;
7542 /* More frames could be read */
7543 rslt = BMI2_W_PARTIAL_READ;
7546 return rslt;
7550 * @brief This internal API enables and configures the accelerometer which is
7551 * needed for self-test operation. It also sets the amplitude for the self-test.
7553 static int8_t pre_self_test_config(struct bmi2_dev *dev)
7555 /* Variable to define error */
7556 int8_t rslt;
7558 /* Structure to define sensor configurations */
7559 struct bmi2_sens_config sens_cfg;
7561 /* List the sensors to be selected */
7562 uint8_t sens_sel = BMI2_ACCEL;
7564 /* Enable accelerometer */
7565 rslt = bmi2_sensor_enable(&sens_sel, 1, dev);
7566 dev->delay_us(1000, dev->intf_ptr);
7568 /* Enable self-test amplitude */
7569 if (rslt == BMI2_OK)
7571 rslt = set_accel_self_test_amp(BMI2_ENABLE, dev);
7574 if (rslt == BMI2_OK)
7576 /* Select accelerometer for sensor configurations */
7577 sens_cfg.type = BMI2_ACCEL;
7579 /* Get the default values */
7580 rslt = bmi2_get_sensor_config(&sens_cfg, 1, dev);
7581 if (rslt == BMI2_OK)
7583 /* Set the configurations required for self-test */
7584 sens_cfg.cfg.acc.odr = BMI2_ACC_ODR_1600HZ;
7585 sens_cfg.cfg.acc.bwp = BMI2_ACC_NORMAL_AVG4;
7586 sens_cfg.cfg.acc.filter_perf = BMI2_PERF_OPT_MODE;
7587 sens_cfg.cfg.acc.range = BMI2_ACC_RANGE_16G;
7589 /* Set accelerometer configurations */
7590 rslt = bmi2_set_sensor_config(&sens_cfg, 1, dev);
7594 return rslt;
7598 * @brief This internal API performs the steps needed for self-test operation
7599 * before reading the accelerometer self-test data.
7601 static int8_t self_test_config(uint8_t sign, struct bmi2_dev *dev)
7603 /* Variable to define error */
7604 int8_t rslt;
7606 /* Enable the accelerometer self-test feature */
7607 rslt = set_accel_self_test_enable(BMI2_ENABLE, dev);
7608 if (rslt == BMI2_OK)
7610 /* Selects the sign of accelerometer self-test excitation */
7611 rslt = set_acc_self_test_sign(sign, dev);
7614 return rslt;
7618 * @brief This internal API enables or disables the accelerometer self-test
7619 * feature in the sensor.
7621 static int8_t set_accel_self_test_enable(uint8_t enable, struct bmi2_dev *dev)
7623 /* Variable to define error */
7624 int8_t rslt;
7626 /* Variable to define data */
7627 uint8_t data = 0;
7629 /* Enable/Disable self-test feature */
7630 rslt = bmi2_get_regs(BMI2_ACC_SELF_TEST_ADDR, &data, 1, dev);
7631 if (rslt == BMI2_OK)
7633 data = BMI2_SET_BIT_POS0(data, BMI2_ACC_SELF_TEST_EN, enable);
7634 rslt = bmi2_set_regs(BMI2_ACC_SELF_TEST_ADDR, &data, 1, dev);
7637 return rslt;
7641 * @brief This internal API selects the sign for accelerometer self-test
7642 * excitation.
7644 static int8_t set_acc_self_test_sign(uint8_t sign, struct bmi2_dev *dev)
7646 /* Variable to define error */
7647 int8_t rslt;
7649 /* Variable to define data */
7650 uint8_t data = 0;
7652 /* Select the sign for self-test excitation */
7653 rslt = bmi2_get_regs(BMI2_ACC_SELF_TEST_ADDR, &data, 1, dev);
7654 if (rslt == BMI2_OK)
7656 data = BMI2_SET_BITS(data, BMI2_ACC_SELF_TEST_SIGN, sign);
7657 rslt = bmi2_set_regs(BMI2_ACC_SELF_TEST_ADDR, &data, 1, dev);
7660 return rslt;
7664 * @brief This internal API sets the amplitude of the accelerometer self-test
7665 * deflection in the sensor.
7667 static int8_t set_accel_self_test_amp(uint8_t amp, struct bmi2_dev *dev)
7669 /* Variable to define error */
7670 int8_t rslt;
7672 /* Variable to define data */
7673 uint8_t data = 0;
7675 /* Select amplitude of the self-test deflection */
7676 rslt = bmi2_get_regs(BMI2_ACC_SELF_TEST_ADDR, &data, 1, dev);
7677 if (rslt == BMI2_OK)
7679 data = BMI2_SET_BITS(data, BMI2_ACC_SELF_TEST_AMP, amp);
7680 rslt = bmi2_set_regs(BMI2_ACC_SELF_TEST_ADDR, &data, 1, dev);
7683 return rslt;
7687 * @brief This internal API reads the accelerometer data for x,y and z axis from
7688 * the sensor. The data units is in LSB format.
7690 static int8_t read_accel_xyz(struct bmi2_sens_axes_data *accel, struct bmi2_dev *dev)
7692 /* Variable to define error */
7693 int8_t rslt;
7695 /* Variable to define LSB */
7696 uint16_t lsb = 0;
7698 /* Variable to define MSB */
7699 uint16_t msb = 0;
7701 /* Array to define data buffer */
7702 uint8_t data[BMI2_ACC_GYR_NUM_BYTES] = { 0 };
7704 rslt = bmi2_get_regs(BMI2_ACC_X_LSB_ADDR, data, BMI2_ACC_GYR_NUM_BYTES, dev);
7705 if (rslt == BMI2_OK)
7707 /* Accelerometer data x axis */
7708 msb = data[1];
7709 lsb = data[0];
7710 accel->x = (int16_t)((msb << 8) | lsb);
7712 /* Accelerometer data y axis */
7713 msb = data[3];
7714 lsb = data[2];
7715 accel->y = (int16_t)((msb << 8) | lsb);
7717 /* Accelerometer data z axis */
7718 msb = data[5];
7719 lsb = data[4];
7720 accel->z = (int16_t)((msb << 8) | lsb);
7723 return rslt;
7727 * @brief This internal API reads the gyroscope data for x, y and z axis from
7728 * the sensor. The data units is in LSB format.
7730 static int8_t read_gyro_xyz(struct bmi2_sens_axes_data *gyro, struct bmi2_dev *dev)
7732 /* Variable to define error */
7733 int8_t rslt;
7735 /* Variable to define LSB */
7736 uint16_t lsb = 0;
7738 /* Variable to define MSB */
7739 uint16_t msb = 0;
7741 /* Array to define data buffer */
7742 uint8_t data[BMI2_ACC_GYR_NUM_BYTES] = { 0 };
7744 rslt = bmi2_get_regs(BMI2_GYR_X_LSB_ADDR, data, BMI2_ACC_GYR_NUM_BYTES, dev);
7745 if (rslt == BMI2_OK)
7747 /* Gyroscope data x axis */
7748 msb = data[1];
7749 lsb = data[0];
7750 gyro->x = (int16_t)((msb << 8) | lsb);
7752 /* Gyroscope data y axis */
7753 msb = data[3];
7754 lsb = data[2];
7755 gyro->y = (int16_t)((msb << 8) | lsb);
7757 /* Gyroscope data z axis */
7758 msb = data[5];
7759 lsb = data[4];
7760 gyro->z = (int16_t)((msb << 8) | lsb);
7763 return rslt;
7767 * @brief This internal API converts LSB value of accelerometer axes to form
7768 * 'g' to 'mg' for self-test.
7770 static void convert_lsb_g(const struct bmi2_selftest_delta_limit *acc_data_diff,
7771 struct bmi2_selftest_delta_limit *acc_data_diff_mg,
7772 const struct bmi2_dev *dev)
7774 /* Variable to define LSB/g value of axes */
7775 uint32_t lsb_per_g;
7777 /* Range considered for self-test is +/-16g */
7778 uint8_t range = BMI2_ACC_SELF_TEST_RANGE;
7780 /* lsb_per_g for the respective resolution and 16g range */
7781 lsb_per_g = (uint32_t)(power(2, dev->resolution) / (2 * range));
7783 /* Accelerometer x value in mg */
7784 acc_data_diff_mg->x = (acc_data_diff->x / (int32_t) lsb_per_g) * 1000;
7786 /* Accelerometer y value in mg */
7787 acc_data_diff_mg->y = (acc_data_diff->y / (int32_t) lsb_per_g) * 1000;
7789 /* Accelerometer z value in mg */
7790 acc_data_diff_mg->z = (acc_data_diff->z / (int32_t) lsb_per_g) * 1000;
7794 * @brief This internal API is used to calculate the power of a value.
7796 static int32_t power(int16_t base, uint8_t resolution)
7798 /* Initialize loop */
7799 uint8_t loop = 1;
7801 /* Initialize variable to store the power of 2 value */
7802 int32_t value = 1;
7804 for (; loop <= resolution; loop++)
7806 value = (int32_t)(value * base);
7809 return value;
7813 * @brief This internal API validates the accelerometer self-test data and
7814 * decides the result of self-test operation.
7816 static int8_t validate_self_test(const struct bmi2_selftest_delta_limit *accel_data_diff)
7818 /* Variable to define error */
7819 int8_t rslt;
7821 /* As per the data sheet, The actually measured signal differences should be significantly
7822 * larger than the minimum differences for each axis in order for the self-test to pass.
7824 if ((accel_data_diff->x > BMI2_ST_ACC_X_SIG_MIN_DIFF) && (accel_data_diff->y < BMI2_ST_ACC_Y_SIG_MIN_DIFF) &&
7825 (accel_data_diff->z > BMI2_ST_ACC_Z_SIG_MIN_DIFF))
7827 /* Self-test pass */
7828 rslt = BMI2_OK;
7830 else
7832 /* Self-test fail*/
7833 rslt = BMI2_E_SELF_TEST_FAIL;
7836 return rslt;
7840 * @brief This internal API gets the re-mapped x, y and z axes from the sensor.
7842 static int8_t get_remap_axes(struct bmi2_axes_remap *remap, struct bmi2_dev *dev)
7844 /* Variable to define error */
7845 int8_t rslt = BMI2_OK;
7847 /* Array to define the feature configuration */
7848 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
7850 /* Variable to define the array offset */
7851 uint8_t idx = 0;
7853 /* Variable to set flag */
7854 uint8_t feat_found;
7856 /* Initialize feature configuration for axis re-mapping */
7857 struct bmi2_feature_config remap_config = { 0, 0, 0 };
7859 /* Variable to get the status of advance power save */
7860 uint8_t aps_stat;
7862 /* Get status of advance power save mode */
7863 aps_stat = dev->aps_status;
7864 if (aps_stat == BMI2_ENABLE)
7866 /* Disable advance power save if enabled */
7867 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
7870 if (rslt == BMI2_OK)
7872 /* Search for axis re-mapping and extract its configuration details */
7873 feat_found = bmi2_extract_input_feat_config(&remap_config, BMI2_AXIS_MAP, dev);
7874 if (feat_found)
7876 rslt = bmi2_get_feat_config(remap_config.page, feat_config, dev);
7877 if (rslt == BMI2_OK)
7879 /* Define the offset for axis re-mapping */
7880 idx = remap_config.start_addr;
7882 /* Get the re-mapped x-axis */
7883 remap->x_axis = BMI2_GET_BIT_POS0(feat_config[idx], BMI2_X_AXIS);
7885 /* Get the re-mapped x-axis polarity */
7886 remap->x_axis_sign = BMI2_GET_BITS(feat_config[idx], BMI2_X_AXIS_SIGN);
7888 /* Get the re-mapped y-axis */
7889 remap->y_axis = BMI2_GET_BITS(feat_config[idx], BMI2_Y_AXIS);
7891 /* Get the re-mapped y-axis polarity */
7892 remap->y_axis_sign = BMI2_GET_BITS(feat_config[idx], BMI2_Y_AXIS_SIGN);
7894 /* Get the re-mapped z-axis */
7895 remap->z_axis = BMI2_GET_BITS(feat_config[idx], BMI2_Z_AXIS);
7897 /* Increment byte to fetch the next data */
7898 idx++;
7900 /* Get the re-mapped z-axis polarity */
7901 remap->z_axis_sign = BMI2_GET_BIT_POS0(feat_config[idx], BMI2_Z_AXIS_SIGN);
7904 else
7906 rslt = BMI2_E_INVALID_SENSOR;
7909 /* Enable Advance power save if disabled while configuring and
7910 * not when already disabled
7912 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
7914 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
7918 return rslt;
7922 * @brief This internal API sets the re-mapped x, y and z axes in the sensor.
7924 static int8_t set_remap_axes(const struct bmi2_axes_remap *remap, struct bmi2_dev *dev)
7926 /* Variable to define error */
7927 int8_t rslt = BMI2_OK;
7929 /* Array to define the feature configuration */
7930 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
7932 /* Variable to define the array offset */
7933 uint8_t idx = 0;
7935 /* Variable to define the register address */
7936 uint8_t reg_addr = 0;
7938 /* Variable to set the re-mapped x-axes in the sensor */
7939 uint8_t x_axis = 0;
7941 /* Variable to set the re-mapped y-axes in the sensor */
7942 uint8_t y_axis = 0;
7944 /* Variable to set the re-mapped z-axes in the sensor */
7945 uint8_t z_axis = 0;
7947 /* Variable to set the re-mapped x-axes sign in the sensor */
7948 uint8_t x_axis_sign = 0;
7950 /* Variable to set the re-mapped y-axes sign in the sensor */
7951 uint8_t y_axis_sign = 0;
7953 /* Variable to set the re-mapped z-axes sign in the sensor */
7954 uint8_t z_axis_sign = 0;
7956 /* Variable to set flag */
7957 uint8_t feat_found;
7959 /* Initialize feature configuration for axis re-mapping */
7960 struct bmi2_feature_config remap_config = { 0, 0, 0 };
7962 /* Variable to get the status of advance power save */
7963 uint8_t aps_stat;
7965 /* Get status of advance power save mode */
7966 aps_stat = dev->aps_status;
7967 if (aps_stat == BMI2_ENABLE)
7969 /* Disable advance power save if enabled */
7970 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
7973 if (rslt == BMI2_OK)
7975 /* Search for axis-re-mapping and extract its configuration details */
7976 feat_found = bmi2_extract_input_feat_config(&remap_config, BMI2_AXIS_MAP, dev);
7977 if (feat_found)
7979 /* Get the configuration from the page where axis re-mapping feature resides */
7980 rslt = bmi2_get_feat_config(remap_config.page, feat_config, dev);
7981 if (rslt == BMI2_OK)
7983 /* Define the offset in bytes */
7984 idx = remap_config.start_addr;
7986 /* Set the value of re-mapped x-axis */
7987 x_axis = remap->x_axis & BMI2_X_AXIS_MASK;
7989 /* Set the value of re-mapped x-axis sign */
7990 x_axis_sign = ((remap->x_axis_sign << BMI2_X_AXIS_SIGN_POS) & BMI2_X_AXIS_SIGN_MASK);
7992 /* Set the value of re-mapped y-axis */
7993 y_axis = ((remap->y_axis << BMI2_Y_AXIS_POS) & BMI2_Y_AXIS_MASK);
7995 /* Set the value of re-mapped y-axis sign */
7996 y_axis_sign = ((remap->y_axis_sign << BMI2_Y_AXIS_SIGN_POS) & BMI2_Y_AXIS_SIGN_MASK);
7998 /* Set the value of re-mapped z-axis */
7999 z_axis = ((remap->z_axis << BMI2_Z_AXIS_POS) & BMI2_Z_AXIS_MASK);
8001 /* Set the value of re-mapped z-axis sign */
8002 z_axis_sign = remap->z_axis_sign & BMI2_Z_AXIS_SIGN_MASK;
8004 /* Arrange axes in the first byte */
8005 feat_config[idx] = x_axis | x_axis_sign | y_axis | y_axis_sign | z_axis;
8007 /* Increment the index */
8008 idx++;
8010 /* Cannot OR in the second byte since it holds
8011 * gyroscope self-offset correction bit
8013 feat_config[idx] = BMI2_SET_BIT_POS0(feat_config[idx], BMI2_Z_AXIS_SIGN, z_axis_sign);
8015 /* Update the register address */
8016 reg_addr = BMI2_FEATURES_REG_ADDR + remap_config.start_addr;
8018 /* Set the configuration back to the page */
8019 rslt = bmi2_set_regs(reg_addr, &feat_config[remap_config.start_addr], 2, dev);
8022 else
8024 rslt = BMI2_E_INVALID_SENSOR;
8027 /* Enable Advance power save if disabled while configuring and
8028 * not when already disabled
8030 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
8032 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
8036 return rslt;
8040 * @brief This internal API corrects the gyroscope cross-axis sensitivity
8041 * between the z and the x axis.
8043 static void comp_gyro_cross_axis_sensitivity(struct bmi2_sens_axes_data *gyr_data, const struct bmi2_dev *dev)
8045 /* Get the compensated gyroscope x-axis */
8046 gyr_data->x = gyr_data->x - (int16_t)(((int32_t) dev->gyr_cross_sens_zx * (int32_t) gyr_data->z) / 512);
8050 * @brief This internal API is used to validate the boundary conditions.
8052 static int8_t check_boundary_val(uint8_t *val, uint8_t min, uint8_t max, struct bmi2_dev *dev)
8054 /* Variable to define error */
8055 int8_t rslt = BMI2_OK;
8057 if (val != NULL)
8059 /* Check if value is below minimum value */
8060 if (*val < min)
8062 /* Auto correct the invalid value to minimum value */
8063 *val = min;
8064 dev->info |= BMI2_I_MIN_VALUE;
8067 /* Check if value is above maximum value */
8068 if (*val > max)
8070 /* Auto correct the invalid value to maximum value */
8071 *val = max;
8072 dev->info |= BMI2_I_MAX_VALUE;
8075 else
8077 rslt = BMI2_E_NULL_PTR;
8080 return rslt;
8084 * @brief This internal API saves the configurations before performing FOC.
8086 static int8_t save_accel_foc_config(struct bmi2_accel_config *acc_cfg,
8087 uint8_t *aps,
8088 uint8_t *acc_en,
8089 struct bmi2_dev *dev)
8091 /* Variable to define error */
8092 int8_t rslt;
8094 /* Variable to get the status from PWR_CTRL register */
8095 uint8_t pwr_ctrl_data = 0;
8097 /* Get accelerometer configurations to be saved */
8098 rslt = get_accel_config(acc_cfg, dev);
8099 if (rslt == BMI2_OK)
8101 /* Get accelerometer enable status to be saved */
8102 rslt = bmi2_get_regs(BMI2_PWR_CTRL_ADDR, &pwr_ctrl_data, 1, dev);
8103 *acc_en = BMI2_GET_BITS(pwr_ctrl_data, BMI2_ACC_EN);
8105 /* Get advance power save mode to be saved */
8106 if (rslt == BMI2_OK)
8108 rslt = bmi2_get_adv_power_save(aps, dev);
8112 return rslt;
8116 * @brief This internal sets configurations for performing accelerometer FOC.
8118 static int8_t set_accel_foc_config(struct bmi2_dev *dev)
8120 /* Variable to define error */
8121 int8_t rslt;
8123 /* Variable to select the sensor */
8124 uint8_t sens_list = BMI2_ACCEL;
8126 /* Variable to set the accelerometer configuration value */
8127 uint8_t acc_conf_data = BMI2_FOC_ACC_CONF_VAL;
8129 /* Disabling offset compensation */
8130 rslt = set_accel_offset_comp(BMI2_DISABLE, dev);
8131 if (rslt == BMI2_OK)
8133 /* Set accelerometer configurations to 50Hz, continuous mode, CIC mode */
8134 rslt = bmi2_set_regs(BMI2_ACC_CONF_ADDR, &acc_conf_data, 1, dev);
8135 if (rslt == BMI2_OK)
8137 /* Set accelerometer to normal mode by enabling it */
8138 rslt = bmi2_sensor_enable(&sens_list, 1, dev);
8140 if (rslt == BMI2_OK)
8142 /* Disable advance power save mode */
8143 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
8148 return rslt;
8152 * @brief This internal API performs Fast Offset Compensation for accelerometer.
8154 static int8_t perform_accel_foc(const struct bmi2_accel_foc_g_value *accel_g_value,
8155 const struct bmi2_accel_config *acc_cfg,
8156 struct bmi2_dev *dev)
8158 /* Variable to define error */
8159 int8_t rslt = BMI2_E_INVALID_STATUS;
8161 /* Variable to define count */
8162 uint8_t loop;
8164 /* Variable to store status read from the status register */
8165 uint8_t reg_status = 0;
8167 /* Array of structure to store accelerometer data */
8168 struct bmi2_sens_axes_data accel_value[128] = { { 0 } };
8170 /* Structure to store accelerometer data temporarily */
8171 struct bmi2_foc_temp_value temp = { 0, 0, 0 };
8173 /* Structure to store the average of accelerometer data */
8174 struct bmi2_sens_axes_data accel_avg = { 0, 0, 0, 0 };
8176 /* Variable to define LSB per g value */
8177 uint16_t lsb_per_g = 0;
8179 /* Variable to define range */
8180 uint8_t range = 0;
8182 /* Structure to store accelerometer data deviation from ideal value */
8183 struct bmi2_offset_delta delta = { 0, 0, 0 };
8185 /* Structure to store accelerometer offset values */
8186 struct bmi2_accel_offset offset = { 0, 0, 0 };
8188 /* Variable tries max 5 times for interrupt then generates timeout */
8189 uint8_t try_cnt;
8191 for (loop = 0; loop < 128; loop++)
8193 try_cnt = 5;
8194 while (try_cnt && (!(reg_status & BMI2_DRDY_ACC)))
8196 /* 20ms delay for 50Hz ODR */
8197 dev->delay_us(20000, dev->intf_ptr);
8198 rslt = bmi2_get_status(&reg_status, dev);
8199 try_cnt--;
8202 if ((rslt == BMI2_OK) && (reg_status & BMI2_DRDY_ACC))
8204 rslt = read_accel_xyz(&accel_value[loop], dev);
8207 if (rslt == BMI2_OK)
8209 rslt = read_accel_xyz(&accel_value[loop], dev);
8212 if (rslt == BMI2_OK)
8214 /* Store the data in a temporary structure */
8215 temp.x = temp.x + (int32_t)accel_value[loop].x;
8216 temp.y = temp.y + (int32_t)accel_value[loop].y;
8217 temp.z = temp.z + (int32_t)accel_value[loop].z;
8219 else
8221 break;
8225 if (rslt == BMI2_OK)
8227 /* Take average of x, y and z data for lesser noise */
8228 accel_avg.x = (int16_t)(temp.x / 128);
8229 accel_avg.y = (int16_t)(temp.y / 128);
8230 accel_avg.z = (int16_t)(temp.z / 128);
8232 /* Get the exact range value */
8233 map_accel_range(acc_cfg->range, &range);
8235 /* Get the smallest possible measurable acceleration level given the range and
8236 * resolution */
8237 lsb_per_g = (uint16_t)(power(2, dev->resolution) / (2 * range));
8239 /* Compensate acceleration data against gravity */
8240 comp_for_gravity(lsb_per_g, accel_g_value, &accel_avg, &delta);
8242 /* Scale according to offset register resolution */
8243 scale_accel_offset(range, &delta, &offset);
8245 /* Invert the accelerometer offset data */
8246 invert_accel_offset(&offset);
8248 /* Write offset data in the offset compensation register */
8249 rslt = write_accel_offset(&offset, dev);
8251 /* Enable offset compensation */
8252 if (rslt == BMI2_OK)
8254 rslt = set_accel_offset_comp(BMI2_ENABLE, dev);
8258 return rslt;
8262 * @brief This internal API enables/disables the offset compensation for
8263 * filtered and un-filtered accelerometer data.
8265 static int8_t set_accel_offset_comp(uint8_t offset_en, struct bmi2_dev *dev)
8267 /* Variable to define error */
8268 int8_t rslt;
8270 /* Variable to store data */
8271 uint8_t data = 0;
8273 /* Enable/Disable offset compensation */
8274 rslt = bmi2_get_regs(BMI2_NV_CONF_ADDR, &data, 1, dev);
8275 if (rslt == BMI2_OK)
8277 data = BMI2_SET_BITS(data, BMI2_NV_ACC_OFFSET, offset_en);
8278 rslt = bmi2_set_regs(BMI2_NV_CONF_ADDR, &data, 1, dev);
8281 return rslt;
8285 * @brief This internal API converts the accelerometer range value into
8286 * corresponding integer value.
8288 static void map_accel_range(uint8_t range_in, uint8_t *range_out)
8290 switch (range_in)
8292 case BMI2_ACC_RANGE_2G:
8293 *range_out = 2;
8294 break;
8295 case BMI2_ACC_RANGE_4G:
8296 *range_out = 4;
8297 break;
8298 case BMI2_ACC_RANGE_8G:
8299 *range_out = 8;
8300 break;
8301 case BMI2_ACC_RANGE_16G:
8302 *range_out = 16;
8303 break;
8304 default:
8306 /* By default RANGE 8G is set */
8307 *range_out = 8;
8308 break;
8313 * @brief This internal API compensate the accelerometer data against gravity.
8315 static void comp_for_gravity(uint16_t lsb_per_g,
8316 const struct bmi2_accel_foc_g_value *g_val,
8317 const struct bmi2_sens_axes_data *data,
8318 struct bmi2_offset_delta *comp_data)
8320 /* Array to store the accelerometer values in LSB */
8321 int16_t accel_value_lsb[3] = { 0 };
8323 /* Convert g-value to LSB */
8324 accel_value_lsb[BMI2_X_AXIS] = (int16_t)(lsb_per_g * g_val->x);
8325 accel_value_lsb[BMI2_Y_AXIS] = (int16_t)(lsb_per_g * g_val->y);
8326 accel_value_lsb[BMI2_Z_AXIS] = (int16_t)(lsb_per_g * g_val->z);
8328 /* Get the compensated values for X, Y and Z axis */
8329 comp_data->x = (data->x - accel_value_lsb[BMI2_X_AXIS]);
8330 comp_data->y = (data->y - accel_value_lsb[BMI2_Y_AXIS]);
8331 comp_data->z = (data->z - accel_value_lsb[BMI2_Z_AXIS]);
8335 * @brief This internal API scales the compensated accelerometer data according
8336 * to the offset register resolution.
8338 * @note The bit position is always greater than 0 since accelerometer data is
8339 * 16 bit wide.
8341 static void scale_accel_offset(uint8_t range, const struct bmi2_offset_delta *comp_data, struct bmi2_accel_offset *data)
8343 /* Variable to store the position of bit having 3.9mg resolution */
8344 int8_t bit_pos_3_9mg;
8346 /* Variable to store the position previous of bit having 3.9mg resolution */
8347 int8_t bit_pos_3_9mg_prev_bit;
8349 /* Variable to store the round-off value */
8350 uint8_t round_off;
8352 /* Find the bit position of 3.9mg */
8353 bit_pos_3_9mg = get_bit_pos_3_9mg(range);
8355 /* Round off, consider if the next bit is high */
8356 bit_pos_3_9mg_prev_bit = bit_pos_3_9mg - 1;
8357 round_off = (uint8_t)(power(2, ((uint8_t) bit_pos_3_9mg_prev_bit)));
8359 /* Scale according to offset register resolution */
8360 data->x = (uint8_t)((comp_data->x + round_off) / power(2, ((uint8_t) bit_pos_3_9mg)));
8361 data->y = (uint8_t)((comp_data->y + round_off) / power(2, ((uint8_t) bit_pos_3_9mg)));
8362 data->z = (uint8_t)((comp_data->z + round_off) / power(2, ((uint8_t) bit_pos_3_9mg)));
8366 * @brief This internal API finds the bit position of 3.9mg according to given
8367 * range and resolution.
8369 static int8_t get_bit_pos_3_9mg(uint8_t range)
8371 /* Variable to store the bit position of 3.9mg resolution */
8372 int8_t bit_pos_3_9mg;
8374 /* Variable to shift the bits according to the resolution */
8375 uint32_t divisor = 1;
8377 /* Scaling factor to get the bit position of 3.9 mg resolution */
8378 int16_t scale_factor = -1;
8380 /* Variable to store temporary value */
8381 uint16_t temp;
8383 /* Shift left by the times of resolution */
8384 divisor = divisor << 16;
8386 /* Get the bit position to be shifted */
8387 temp = (uint16_t)(divisor / (range * 256));
8389 /* Get the scaling factor until bit position is shifted to last bit */
8390 while (temp != 1)
8392 scale_factor++;
8393 temp = temp >> 1;
8396 /* Scaling factor is the bit position of 3.9 mg resolution */
8397 bit_pos_3_9mg = (int8_t) scale_factor;
8399 return bit_pos_3_9mg;
8403 * @brief This internal API inverts the accelerometer offset data.
8405 static void invert_accel_offset(struct bmi2_accel_offset *offset_data)
8407 /* Get the offset data */
8408 offset_data->x = (uint8_t)((offset_data->x) * (-1));
8409 offset_data->y = (uint8_t)((offset_data->y) * (-1));
8410 offset_data->z = (uint8_t)((offset_data->z) * (-1));
8414 * @brief This internal API writes the offset data in the offset compensation
8415 * register.
8417 static int8_t write_accel_offset(const struct bmi2_accel_offset *offset, struct bmi2_dev *dev)
8419 /* Variable to define error */
8420 int8_t rslt;
8422 /* Array to store the offset data */
8423 uint8_t data_array[3] = { 0 };
8425 data_array[0] = offset->x;
8426 data_array[1] = offset->y;
8427 data_array[2] = offset->z;
8429 /* Offset values are written in the offset register */
8430 rslt = bmi2_set_regs(BMI2_ACC_OFF_COMP_0_ADDR, data_array, 3, dev);
8432 return rslt;
8436 * @brief This internal API restores the configurations saved before performing
8437 * accelerometer FOC.
8439 static int8_t restore_accel_foc_config(struct bmi2_accel_config *acc_cfg,
8440 uint8_t aps,
8441 uint8_t acc_en,
8442 struct bmi2_dev *dev)
8444 /* Variable to define error */
8445 int8_t rslt;
8447 /* Variable to get the status from PWR_CTRL register */
8448 uint8_t pwr_ctrl_data = 0;
8450 /* Restore the saved accelerometer configurations */
8451 rslt = set_accel_config(acc_cfg, dev);
8452 if (rslt == BMI2_OK)
8454 /* Restore the saved accelerometer enable status */
8455 rslt = bmi2_get_regs(BMI2_PWR_CTRL_ADDR, &pwr_ctrl_data, 1, dev);
8456 if (rslt == BMI2_OK)
8458 pwr_ctrl_data = BMI2_SET_BITS(pwr_ctrl_data, BMI2_ACC_EN, acc_en);
8459 rslt = bmi2_set_regs(BMI2_PWR_CTRL_ADDR, &pwr_ctrl_data, 1, dev);
8461 /* Restore the saved advance power save */
8462 if (rslt == BMI2_OK)
8464 rslt = bmi2_set_adv_power_save(aps, dev);
8469 return rslt;
8473 * @brief This internal API sets accelerometer configurations like ODR,
8474 * bandwidth, performance mode and g-range.
8476 static int8_t set_accel_config(struct bmi2_accel_config *config, struct bmi2_dev *dev)
8478 /* Variable to define error */
8479 int8_t rslt;
8481 /* Variable to store data */
8482 uint8_t reg_data;
8484 /* Array to store the default value of accelerometer configuration
8485 * reserved registers
8487 uint8_t data_array[2] = { 0 };
8489 /* Validate bandwidth and performance mode */
8490 rslt = validate_bw_perf_mode(&config->bwp, &config->filter_perf, dev);
8491 if (rslt == BMI2_OK)
8493 /* Validate ODR and range */
8494 rslt = validate_odr_range(&config->odr, &config->range, dev);
8495 if (rslt == BMI2_OK)
8497 /* Set accelerometer performance mode */
8498 reg_data = BMI2_SET_BITS(data_array[0], BMI2_ACC_FILTER_PERF_MODE, config->filter_perf);
8500 /* Set accelerometer bandwidth */
8501 reg_data = BMI2_SET_BITS(reg_data, BMI2_ACC_BW_PARAM, config->bwp);
8503 /* Set accelerometer ODR */
8504 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_ACC_ODR, config->odr);
8506 /* Copy the register data to the array */
8507 data_array[0] = reg_data;
8509 /* Set accelerometer range */
8510 reg_data = BMI2_SET_BIT_POS0(data_array[1], BMI2_ACC_RANGE, config->range);
8512 /* Copy the register data to the array */
8513 data_array[1] = reg_data;
8515 /* Write accelerometer configuration to ACC_CONFand
8516 * ACC_RANGE registers simultaneously as they lie in consecutive places
8518 rslt = bmi2_set_regs(BMI2_ACC_CONF_ADDR, data_array, 2, dev);
8520 /* Get error status to check for invalid configurations */
8521 if (rslt == BMI2_OK)
8523 rslt = cfg_error_status(dev);
8528 return rslt;
8532 * @brief This internal API sets gyroscope configurations like ODR, bandwidth,
8533 * low power/high performance mode, performance mode and range. It also
8534 * maps/un-maps data interrupts to that of hardware interrupt line.
8536 static int8_t set_gyro_config(struct bmi2_gyro_config *config, struct bmi2_dev *dev)
8538 /* Variable to define error */
8539 int8_t rslt;
8541 /* Variable to store data */
8542 uint8_t reg_data;
8544 /* Array to store the default value of gyroscope configuration reserved registers */
8545 uint8_t data_array[2] = { 0 };
8547 /* Validate gyroscope configurations */
8548 rslt = validate_gyro_config(config, dev);
8549 if (rslt == BMI2_OK)
8551 /* Set gyroscope performance mode */
8552 reg_data = BMI2_SET_BITS(data_array[0], BMI2_GYR_FILTER_PERF_MODE, config->filter_perf);
8554 /* Set gyroscope noise performance mode */
8555 reg_data = BMI2_SET_BITS(reg_data, BMI2_GYR_NOISE_PERF_MODE, config->noise_perf);
8557 /* Set gyroscope bandwidth */
8558 reg_data = BMI2_SET_BITS(reg_data, BMI2_GYR_BW_PARAM, config->bwp);
8560 /* Set gyroscope ODR */
8561 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_GYR_ODR, config->odr);
8563 /* Copy the register data to the array */
8564 data_array[0] = reg_data;
8566 /* Set gyroscope OIS range */
8567 reg_data = BMI2_SET_BITS(data_array[1], BMI2_GYR_OIS_RANGE, config->ois_range);
8569 /* Set gyroscope range */
8570 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_GYR_RANGE, config->range);
8572 /* Copy the register data to the array */
8573 data_array[1] = reg_data;
8575 /* Write accelerometer configuration to GYR_CONF and GYR_RANGE
8576 * registers simultaneously as they lie in consecutive places
8578 rslt = bmi2_set_regs(BMI2_GYR_CONF_ADDR, data_array, 2, dev);
8580 /* Get error status to check for invalid configurations */
8581 if (rslt == BMI2_OK)
8583 rslt = cfg_error_status(dev);
8587 return rslt;
8591 * @brief This internal API saves the configurations before performing gyroscope
8592 * FOC.
8594 static int8_t save_gyro_config(struct bmi2_gyro_config *gyr_cfg, uint8_t *aps, uint8_t *gyr_en, struct bmi2_dev *dev)
8596 /* Variable to define error */
8597 int8_t rslt;
8599 /* Variable to get the status from PWR_CTRL register */
8600 uint8_t pwr_ctrl_data = 0;
8602 /* Get gyroscope configurations to be saved */
8603 rslt = get_gyro_config(gyr_cfg, dev);
8604 if (rslt == BMI2_OK)
8606 /* Get gyroscope enable status to be saved */
8607 rslt = bmi2_get_regs(BMI2_PWR_CTRL_ADDR, &pwr_ctrl_data, 1, dev);
8608 *gyr_en = BMI2_GET_BITS(pwr_ctrl_data, BMI2_GYR_EN);
8610 /* Get advance power save mode to be saved */
8611 if (rslt == BMI2_OK)
8613 rslt = bmi2_get_adv_power_save(aps, dev);
8617 return rslt;
8621 * @brief This internal sets configurations for performing gyroscope FOC.
8623 static int8_t set_gyro_foc_config(struct bmi2_dev *dev)
8625 int8_t rslt;
8627 /* Variable to select the sensor */
8628 uint8_t sens_list = BMI2_GYRO;
8630 /* Array to set the gyroscope configuration value (ODR, Performance mode
8631 * and bandwidth) and gyroscope range
8633 uint8_t gyr_conf_data[2] = { BMI2_FOC_GYR_CONF_VAL, BMI2_GYR_RANGE_2000 };
8635 /* Disabling gyroscope offset compensation */
8636 rslt = bmi2_set_gyro_offset_comp(BMI2_DISABLE, dev);
8637 if (rslt == BMI2_OK)
8639 /* Set gyroscope configurations to 25Hz, continuous mode,
8640 * CIC mode, and 2000 dps range
8642 rslt = bmi2_set_regs(BMI2_GYR_CONF_ADDR, gyr_conf_data, 2, dev);
8643 if (rslt == BMI2_OK)
8645 /* Set gyroscope to normal mode by enabling it */
8646 rslt = bmi2_sensor_enable(&sens_list, 1, dev);
8648 if (rslt == BMI2_OK)
8650 /* Disable advance power save mode */
8651 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
8656 return rslt;
8660 * @brief This internal API inverts the gyroscope offset data.
8662 static void invert_gyro_offset(struct bmi2_sens_axes_data *offset_data)
8664 /* Invert the values */
8665 offset_data->x = (int16_t)((offset_data->x) * (-1));
8666 offset_data->y = (int16_t)((offset_data->y) * (-1));
8667 offset_data->z = (int16_t)((offset_data->z) * (-1));
8671 * @brief This internal API restores the gyroscope configurations saved
8672 * before performing FOC.
8674 static int8_t restore_gyro_config(struct bmi2_gyro_config *gyr_cfg, uint8_t aps, uint8_t gyr_en, struct bmi2_dev *dev)
8676 int8_t rslt;
8677 uint8_t pwr_ctrl_data = 0;
8679 /* Restore the saved gyroscope configurations */
8680 rslt = set_gyro_config(gyr_cfg, dev);
8681 if (rslt == BMI2_OK)
8683 /* Restore the saved gyroscope enable status */
8684 rslt = bmi2_get_regs(BMI2_PWR_CTRL_ADDR, &pwr_ctrl_data, 1, dev);
8685 if (rslt == BMI2_OK)
8687 pwr_ctrl_data = BMI2_SET_BITS(pwr_ctrl_data, BMI2_GYR_EN, gyr_en);
8688 rslt = bmi2_set_regs(BMI2_PWR_CTRL_ADDR, &pwr_ctrl_data, 1, dev);
8690 /* Restore the saved advance power save */
8691 if (rslt == BMI2_OK)
8693 rslt = bmi2_set_adv_power_save(aps, dev);
8698 return rslt;
8702 * @brief This internal API saturates the gyroscope data value before writing to
8703 * to 10 bit offset register.
8705 static void saturate_gyro_data(struct bmi2_sens_axes_data *gyr_off)
8707 if (gyr_off->x > 511)
8709 gyr_off->x = 511;
8712 if (gyr_off->x < -512)
8714 gyr_off->x = -512;
8717 if (gyr_off->y > 511)
8719 gyr_off->y = 511;
8722 if (gyr_off->y < -512)
8724 gyr_off->y = -512;
8727 if (gyr_off->z > 511)
8729 gyr_off->z = 511;
8732 if (gyr_off->z < -512)
8734 gyr_off->z = -512;
8739 * @brief This internal API is used to validate the device structure pointer for
8740 * null conditions.
8742 static int8_t null_ptr_check(const struct bmi2_dev *dev)
8744 int8_t rslt = BMI2_OK;
8746 if ((dev == NULL) || (dev->read == NULL) || (dev->write == NULL) || (dev->delay_us == NULL))
8748 /* Device structure pointer is not valid */
8749 rslt = BMI2_E_NULL_PTR;
8752 return rslt;
8756 * @brief This internal API is to get the status of st_status from gry_crt_conf register
8758 static int8_t get_st_running(uint8_t *st_status, struct bmi2_dev *dev)
8760 int8_t rslt;
8761 uint8_t reg_data = 0;
8763 rslt = null_ptr_check(dev);
8764 if (rslt == BMI2_OK)
8766 /* Get the status of crt running */
8767 rslt = bmi2_get_regs(BMI2_GYR_CRT_CONF_ADDR, &reg_data, 1, dev);
8768 if (rslt == BMI2_OK)
8770 (*st_status) = BMI2_GET_BITS(reg_data, BMI2_GYR_CRT_RUNNING);
8773 else
8775 rslt = BMI2_E_NULL_PTR;
8778 return rslt;
8782 * @brief This API enables/disables the CRT running.
8784 static int8_t set_st_running(uint8_t st_status, struct bmi2_dev *dev)
8786 int8_t rslt;
8787 uint8_t reg_data = 0;
8789 rslt = null_ptr_check(dev);
8790 if (rslt == BMI2_OK)
8792 rslt = bmi2_get_regs(BMI2_GYR_CRT_CONF_ADDR, &reg_data, 1, dev);
8793 if (rslt == BMI2_OK)
8795 reg_data = BMI2_SET_BITS(reg_data, BMI2_GYR_CRT_RUNNING, st_status);
8796 rslt = bmi2_set_regs(BMI2_GYR_CRT_CONF_ADDR, &reg_data, 1, dev);
8800 return rslt;
8804 * @brief This API gets the status of rdy for dl bit.
8806 static int8_t get_rdy_for_dl(uint8_t *rdy_for_dl, struct bmi2_dev *dev)
8808 int8_t rslt;
8809 uint8_t reg_data = 0;
8811 rslt = null_ptr_check(dev);
8812 if (rslt == BMI2_OK)
8814 /* Get the status of rdy_fo_dl */
8815 rslt = bmi2_get_regs(BMI2_GYR_CRT_CONF_ADDR, &reg_data, 1, dev);
8816 if (rslt == BMI2_OK)
8818 (*rdy_for_dl) = BMI2_GET_BITS(reg_data, BMI2_GYR_RDY_FOR_DL);
8821 else
8823 rslt = BMI2_E_NULL_PTR;
8826 return rslt;
8830 * @brief This API does the crt process if max burst length is not zero.
8832 static int8_t process_crt_download(uint8_t last_byte_flag, struct bmi2_dev *dev)
8834 int8_t rslt;
8835 uint8_t rdy_for_dl = 0;
8836 uint8_t cmd = BMI2_G_TRIGGER_CMD;
8838 rslt = null_ptr_check(dev);
8839 if (rslt == BMI2_OK)
8841 rslt = get_rdy_for_dl(&rdy_for_dl, dev);
8844 /* Trigger next CRT command */
8845 if (rslt == BMI2_OK)
8847 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &cmd, 1, dev);
8850 if ((!last_byte_flag) && (rslt == BMI2_OK))
8852 rslt = wait_rdy_for_dl_toggle(BMI2_CRT_READY_FOR_DOWNLOAD_RETRY, rdy_for_dl, dev);
8855 return rslt;
8859 * @brief This API to write the 2kb size of crt configuration
8861 static int8_t write_crt_config_file(uint16_t write_len,
8862 uint16_t config_file_size,
8863 uint16_t start_index,
8864 struct bmi2_dev *dev)
8866 int8_t rslt = BMI2_OK;
8867 uint16_t index = 0;
8868 uint8_t last_byte_flag = 0;
8869 uint8_t remain = (uint8_t)(config_file_size % write_len);
8870 uint16_t balance_byte = 0;
8872 if (!remain)
8875 /* Write the configuration file */
8876 for (index = start_index;
8877 (index < (start_index + config_file_size)) && (rslt == BMI2_OK);
8878 index += write_len)
8880 rslt = upload_file((dev->config_file_ptr + index), index, write_len, dev);
8881 if (index >= ((start_index + config_file_size) - (write_len)))
8883 last_byte_flag = 1;
8886 if (rslt == BMI2_OK)
8888 rslt = process_crt_download(last_byte_flag, dev);
8892 else
8894 /* Get the balance bytes */
8895 balance_byte = (uint16_t)start_index + (uint16_t)config_file_size - (uint16_t)remain;
8897 /* Write the configuration file for the balance bytes */
8898 for (index = start_index; (index < balance_byte) && (rslt == BMI2_OK); index += write_len)
8900 rslt = upload_file((dev->config_file_ptr + index), index, write_len, dev);
8901 if (rslt == BMI2_OK)
8903 rslt = process_crt_download(last_byte_flag, dev);
8907 if (rslt == BMI2_OK)
8909 /* Write the remaining bytes in 2 bytes length */
8910 write_len = 2;
8911 rslt = set_maxburst_len(write_len, dev);
8913 /* Write the configuration file for the remaining bytes */
8914 for (index = balance_byte;
8915 (index < (start_index + config_file_size)) && (rslt == BMI2_OK);
8916 index += write_len)
8918 rslt = upload_file((dev->config_file_ptr + index), index, write_len, dev);
8919 if (index < ((start_index + config_file_size) - write_len))
8921 last_byte_flag = 1;
8924 if (rslt == BMI2_OK)
8926 rslt = process_crt_download(last_byte_flag, dev);
8932 return rslt;
8936 * @brief This API is to wait till the rdy for dl bit toggles after every pack of bytes.
8938 static int8_t wait_rdy_for_dl_toggle(uint8_t retry_complete, uint8_t download_ready, struct bmi2_dev *dev)
8940 int8_t rslt = BMI2_OK;
8941 uint8_t dl_ready = 0;
8942 uint8_t st_status = 0;
8944 while ((rslt == BMI2_OK) && (retry_complete--))
8946 rslt = get_rdy_for_dl(&dl_ready, dev);
8947 if (download_ready != dl_ready)
8949 break;
8952 dev->delay_us(BMI2_CRT_READY_FOR_DOWNLOAD_US, dev->intf_ptr);
8955 if ((rslt == BMI2_OK) && (download_ready == dl_ready))
8957 rslt = BMI2_E_CRT_READY_FOR_DL_FAIL_ABORT;
8960 if (rslt == BMI2_OK)
8962 rslt = get_st_running(&st_status, dev);
8963 if ((rslt == BMI2_OK) && (st_status == 0))
8965 rslt = BMI2_E_ST_ALREADY_RUNNING;
8969 return rslt;
8973 * @brief This API is to wait till crt status complete.
8975 static int8_t wait_st_running(uint8_t retry_complete, struct bmi2_dev *dev)
8977 uint8_t st_status = 1;
8978 int8_t rslt = BMI2_OK;
8980 while (retry_complete--)
8982 rslt = get_st_running(&st_status, dev);
8983 if ((rslt == BMI2_OK) && (st_status == 0))
8985 break;
8988 dev->delay_us(BMI2_CRT_WAIT_RUNNING_US, dev->intf_ptr);
8991 if ((rslt == BMI2_OK) && (st_status == 1))
8993 rslt = BMI2_E_ST_ALREADY_RUNNING;
8996 return rslt;
9000 * @brief This api is used to perform gyroscope self-test.
9002 int8_t bmi2_do_gyro_st(struct bmi2_dev *dev)
9004 int8_t rslt;
9006 rslt = do_gtrigger_test(BMI2_SELECT_GYRO_SELF_TEST, dev);
9008 return rslt;
9012 * @brief This API is to run the CRT process for both max burst length 0 and non zero condition.
9014 int8_t bmi2_do_crt(struct bmi2_dev *dev)
9016 int8_t rslt;
9018 rslt = do_gtrigger_test(BMI2_SELECT_CRT, dev);
9020 return rslt;
9024 * @brief This API is to run the crt process for both max burst length 0 and non zero condition.
9026 static int8_t do_gtrigger_test(uint8_t gyro_st_crt, struct bmi2_dev *dev)
9028 int8_t rslt;
9029 int8_t rslt_crt = BMI2_OK;
9030 uint8_t st_status = 0;
9031 uint8_t max_burst_length = 0;
9032 uint8_t download_ready = 0;
9033 uint8_t cmd = BMI2_G_TRIGGER_CMD;
9034 struct bmi2_gyro_self_test_status gyro_st_result = { 0 };
9036 /* Variable to get the status of advance power save */
9037 uint8_t aps_stat = 0;
9039 rslt = null_ptr_check(dev);
9040 if (rslt == BMI2_OK)
9042 /* Check if the variant supports this feature */
9043 if (dev->variant_feature & BMI2_CRT_RTOSK_ENABLE)
9045 /* Get status of advance power save mode */
9046 aps_stat = dev->aps_status;
9047 if (aps_stat == BMI2_ENABLE)
9049 /* Disable advance power save if enabled */
9050 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
9053 /* Get max burst length */
9054 if (rslt == BMI2_OK)
9056 rslt = get_maxburst_len(&max_burst_length, dev);
9059 /* Checking for CRT running status */
9060 if (rslt == BMI2_OK)
9062 rslt = get_st_running(&st_status, dev);
9065 /* CRT is not running and Max burst length is zero */
9066 if (st_status == 0)
9068 if (rslt == BMI2_OK)
9070 rslt = set_st_running(BMI2_ENABLE, dev);
9073 /* Preparing the setup */
9074 if (rslt == BMI2_OK)
9076 rslt = crt_prepare_setup(dev);
9079 /* Enable the gyro self-test, CRT */
9080 if (rslt == BMI2_OK)
9082 rslt = select_self_test(gyro_st_crt, dev);
9085 /* Check if FIFO is unchanged by checking the max burst length */
9086 if ((rslt == BMI2_OK) && (max_burst_length == 0))
9088 /* Trigger CRT */
9089 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &cmd, 1, dev);
9090 if (rslt == BMI2_OK)
9092 /* Wait until st_status = 0 or time out is 2 seconds */
9093 rslt = wait_st_running(BMI2_CRT_WAIT_RUNNING_RETRY_EXECUTION, dev);
9095 /* CRT Running wait & check is successful */
9096 if (rslt == BMI2_OK)
9098 rslt = crt_gyro_st_update_result(dev);
9102 else
9104 /* FIFO may be used */
9105 if (rslt == BMI2_OK)
9107 if (dev->read_write_len < 2)
9109 dev->read_write_len = 2;
9112 if (dev->read_write_len > (BMI2_CRT_MAX_BURST_WORD_LENGTH * 2))
9114 dev->read_write_len = BMI2_CRT_MAX_BURST_WORD_LENGTH * 2;
9117 /* Reset the max burst length to default value */
9118 rslt = set_maxburst_len(dev->read_write_len, dev);
9121 if (rslt == BMI2_OK)
9123 rslt = get_rdy_for_dl(&download_ready, dev);
9126 /* Trigger CRT */
9127 if (rslt == BMI2_OK)
9129 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &cmd, 1, dev);
9132 /* Wait till either ready for download toggle or crt running = 0 */
9133 if (rslt == BMI2_OK)
9135 rslt = wait_rdy_for_dl_toggle(BMI2_CRT_READY_FOR_DOWNLOAD_RETRY, download_ready, dev);
9136 if (rslt == BMI2_OK)
9138 rslt = write_crt_config_file(dev->read_write_len, BMI2_CRT_CONFIG_FILE_SIZE, 0x1800, dev);
9141 if (rslt == BMI2_OK)
9143 rslt = wait_st_running(BMI2_CRT_WAIT_RUNNING_RETRY_EXECUTION, dev);
9144 rslt_crt = crt_gyro_st_update_result(dev);
9145 if (rslt == BMI2_OK)
9147 rslt = rslt_crt;
9153 else
9155 rslt = BMI2_E_ST_ALREADY_RUNNING;
9158 if (rslt == BMI2_OK)
9160 if (gyro_st_crt == BMI2_SELECT_GYRO_SELF_TEST)
9162 rslt = gyro_self_test_completed(&gyro_st_result, dev);
9166 /* Enable Advance power save if disabled while configuring and
9167 * not when already disabled
9169 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
9171 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
9176 return rslt;
9180 * @brief This API to set up environment for processing the crt.
9182 static int8_t crt_prepare_setup(struct bmi2_dev *dev)
9184 int8_t rslt;
9186 /* Variable to select the sensor */
9187 uint8_t sens_list = BMI2_GYRO;
9189 rslt = null_ptr_check(dev);
9191 if (rslt == BMI2_OK)
9193 /* Disable gyroscope */
9194 rslt = bmi2_sensor_disable(&sens_list, 1, dev);
9197 /* Disable FIFO for all sensors */
9198 if (rslt == BMI2_OK)
9200 rslt = bmi2_set_fifo_config(BMI2_FIFO_ALL_EN, BMI2_DISABLE, dev);
9203 if (rslt == BMI2_OK)
9205 /* Enable accelerometer */
9206 sens_list = BMI2_ACCEL;
9207 rslt = bmi2_sensor_enable(&sens_list, 1, dev);
9210 if (rslt == BMI2_OK)
9212 /* Disable Abort after 1 msec */
9213 dev->delay_us(1000, dev->intf_ptr);
9214 rslt = abort_bmi2(BMI2_DISABLE, dev);
9217 return rslt;
9221 * @brief This API is to update the CRT or gyro self-test final result.
9223 static int8_t crt_gyro_st_update_result(struct bmi2_dev *dev)
9225 int8_t rslt;
9226 struct bmi2_gyr_user_gain_status user_gain_stat = { 0, 0, 0, 0 };
9228 rslt = null_ptr_check(dev);
9230 /* CRT status has to be read from the config register map */
9231 if (rslt == BMI2_OK)
9233 rslt = get_gyro_gain_update_status(&user_gain_stat, dev);
9236 if (rslt == BMI2_OK)
9238 switch (user_gain_stat.g_trigger_status)
9240 case BMI2_G_TRIGGER_NO_ERROR:
9242 /* CRT is successful - Reset the Max Burst Length */
9243 rslt = set_maxburst_len(0, dev);
9244 break;
9246 case BMI2_G_TRIGGER_DL_ERROR:
9248 /* CRT is Download Error - Keep non zero value for Max Burst Length */
9249 rslt = set_maxburst_len(dev->read_write_len, dev);
9250 if (rslt == BMI2_OK)
9252 rslt = BMI2_E_DL_ERROR;
9255 break;
9256 case BMI2_G_TRIGGER_ABORT_ERROR:
9258 /* Command is aborted either by host via the block bit or due to motion
9259 * detection. Keep non zero value for Max Burst Length
9261 rslt = set_maxburst_len(dev->read_write_len, dev);
9262 if (rslt == BMI2_OK)
9264 rslt = BMI2_E_ABORT_ERROR;
9267 break;
9269 case BMI2_G_TRIGGER_PRECON_ERROR:
9271 /* Pre-condition to start the feature was not completed. */
9272 rslt = BMI2_E_PRECON_ERROR;
9273 break;
9275 default:
9276 rslt = BMI2_E_INVALID_STATUS;
9278 break;
9282 return rslt;
9286 * @brief This internal API gets the max burst length.
9288 static int8_t get_maxburst_len(uint8_t *max_burst_len, struct bmi2_dev *dev)
9290 int8_t rslt = BMI2_OK;
9291 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
9292 uint8_t idx = 0;
9293 uint8_t feat_found = 0;
9294 struct bmi2_feature_config maxburst_length_bytes = { 0, 0, 0 };
9295 uint8_t aps_stat;
9297 if ((dev->variant_feature & BMI2_CRT_IN_FIFO_NOT_REQ) != 0)
9299 *max_burst_len = 0;
9301 return BMI2_OK;
9304 /* Get status of advance power save mode */
9305 aps_stat = dev->aps_status;
9306 if (aps_stat == BMI2_ENABLE)
9308 /* Disable advance power save if enabled */
9309 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
9312 if (rslt == BMI2_OK)
9314 /* Search for max burst length */
9315 feat_found = bmi2_extract_input_feat_config(&maxburst_length_bytes, BMI2_MAX_BURST_LEN, dev);
9316 if (feat_found)
9318 rslt = bmi2_get_feat_config(maxburst_length_bytes.page, feat_config, dev);
9319 if (rslt == BMI2_OK)
9321 /* Define the offset for max burst length */
9322 idx = maxburst_length_bytes.start_addr;
9324 /* Get the max burst length */
9325 *max_burst_len = feat_config[idx];
9328 else
9330 rslt = BMI2_E_INVALID_SENSOR;
9333 /* Enable Advance power save if disabled while configuring and
9334 * not when already disabled
9336 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
9338 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
9342 return rslt;
9346 * @brief This internal API sets the max burst length.
9348 static int8_t set_maxburst_len(const uint16_t write_len_byte, struct bmi2_dev *dev)
9350 int8_t rslt = BMI2_OK;
9351 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
9352 uint8_t idx = 0;
9353 uint8_t reg_addr = 0;
9354 uint8_t max_burst_len = 0;
9355 uint8_t feat_found = 0;
9356 struct bmi2_feature_config maxburst_length_bytes = { 0, 0, 0 };
9357 uint8_t aps_stat;
9358 uint16_t burst_len = write_len_byte / 2;
9360 /* for variant that support crt outside fifo, do not modify the max burst len */
9361 if ((dev->variant_feature & BMI2_CRT_IN_FIFO_NOT_REQ) != 0)
9363 return BMI2_OK;
9366 /* Max burst length is only 1 byte */
9367 if (burst_len > BMI2_CRT_MAX_BURST_WORD_LENGTH)
9369 max_burst_len = UINT8_C(0xFF);
9371 else
9373 max_burst_len = (uint8_t)burst_len;
9376 /* Get status of advance power save mode */
9377 aps_stat = dev->aps_status;
9378 if (aps_stat == BMI2_ENABLE)
9380 /* Disable advance power save if enabled */
9381 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
9384 if (rslt == BMI2_OK)
9386 /* Search for axis-re-mapping and extract its configuration details */
9387 feat_found = bmi2_extract_input_feat_config(&maxburst_length_bytes, BMI2_MAX_BURST_LEN, dev);
9388 if (feat_found)
9390 /* Get the configuration from the page where axis
9391 * re-mapping feature resides
9393 rslt = bmi2_get_feat_config(maxburst_length_bytes.page, feat_config, dev);
9394 if (rslt == BMI2_OK)
9396 /* Define the offset in bytes */
9397 idx = maxburst_length_bytes.start_addr;
9399 /* update Max burst length */
9400 feat_config[idx] = max_burst_len;
9402 /* Update the register address */
9403 reg_addr = BMI2_FEATURES_REG_ADDR + maxburst_length_bytes.start_addr;
9405 /* Set the configuration back to the page */
9406 rslt = bmi2_set_regs(reg_addr, &feat_config[maxburst_length_bytes.start_addr], 2, dev);
9409 else
9411 rslt = BMI2_E_INVALID_SENSOR;
9414 /* Enable Advance power save if disabled while configuring and
9415 * not when already disabled
9417 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
9419 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
9423 return rslt;
9427 * @brief This api is used to trigger the preparation for system for NVM programming.
9429 static int8_t set_nvm_prep_prog(uint8_t nvm_prep, struct bmi2_dev *dev)
9431 /* Variable to define error */
9432 int8_t rslt = BMI2_OK;
9434 /* Array to define the feature configuration */
9435 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
9437 /* Variable to define the array offset */
9438 uint8_t idx = 0;
9440 /* Variable to set flag */
9441 uint8_t feat_found;
9442 uint8_t reg_addr = 0;
9444 /* Initialize feature configuration for nvm preparation*/
9445 struct bmi2_feature_config nvm_config = { 0, 0, 0 };
9447 /* Search for bmi2 gyro self offset correction feature as nvm program preparation feature is
9448 * present in the same Word and extract its configuration details
9450 feat_found = bmi2_extract_input_feat_config(&nvm_config, BMI2_NVM_PROG_PREP, dev);
9451 if (feat_found)
9453 /* Get the configuration from the page where nvm preparation feature enable feature
9454 * resides */
9455 rslt = bmi2_get_feat_config(nvm_config.page, feat_config, dev);
9456 if (rslt == BMI2_OK)
9458 /* Define the offset for nvm preparation feature enable */
9459 idx = nvm_config.start_addr;
9461 /* update nvm_prog_prep enable bit */
9462 feat_config[idx] = BMI2_SET_BITS(feat_config[idx], BMI2_NVM_PREP_FEATURE_EN, nvm_prep);
9464 /* Update the register address */
9465 reg_addr = BMI2_FEATURES_REG_ADDR + nvm_config.start_addr - 1;
9467 /* Set the configuration back to the page */
9468 rslt = bmi2_set_regs(reg_addr, &feat_config[nvm_config.start_addr - 1], 2, dev);
9471 else
9473 rslt = BMI2_E_INVALID_SENSOR;
9476 return rslt;
9480 * @brief This api is used to enable the CRT.
9482 static int8_t select_self_test(uint8_t gyro_st_crt, struct bmi2_dev *dev)
9484 int8_t rslt;
9486 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
9488 uint8_t idx = 0;
9490 uint8_t feat_found;
9491 uint8_t reg_addr = 0;
9493 struct bmi2_feature_config gyro_self_test_crt_config = { 0, 0, 0 };
9495 /* Search for bmi2 crt gyro self-test feature and extract its configuration details */
9496 feat_found = bmi2_extract_input_feat_config(&gyro_self_test_crt_config, BMI2_CRT_GYRO_SELF_TEST, dev);
9497 if (feat_found)
9499 /* Get the configuration from the page where gyro self-test and crt enable feature
9500 * resides */
9501 rslt = bmi2_get_feat_config(gyro_self_test_crt_config.page, feat_config, dev);
9502 if (rslt == BMI2_OK)
9504 /* Define the offset in bytes */
9505 idx = gyro_self_test_crt_config.start_addr;
9507 /* update the gyro self-test crt enable bit */
9508 feat_config[idx] = BMI2_SET_BIT_POS0(feat_config[idx], BMI2_GYRO_SELF_TEST_CRT_EN, gyro_st_crt);
9510 /* Update the register address */
9511 reg_addr = BMI2_FEATURES_REG_ADDR + (gyro_self_test_crt_config.start_addr - 1);
9513 /* Set the configuration back to the page */
9514 rslt = bmi2_set_regs(reg_addr, &feat_config[gyro_self_test_crt_config.start_addr - 1], 2, dev);
9517 else
9519 rslt = BMI2_E_INVALID_SENSOR;
9522 return rslt;
9526 * @brief This api is used to abort ongoing crt or gyro self-test.
9528 int8_t bmi2_abort_crt_gyro_st(struct bmi2_dev *dev)
9530 int8_t rslt = BMI2_OK;
9531 uint8_t aps_stat;
9532 uint8_t st_running = 0;
9533 uint8_t cmd = BMI2_G_TRIGGER_CMD;
9535 /* Get status of advance power save mode */
9536 aps_stat = dev->aps_status;
9537 if (aps_stat == BMI2_ENABLE)
9539 /* Disable advance power save if enabled */
9540 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
9543 /* Checking for ST running status */
9544 if (rslt == BMI2_OK)
9546 rslt = get_st_running(&st_running, dev);
9547 if (rslt == BMI2_OK)
9549 /* ST is not running */
9550 if (st_running == 0)
9552 rslt = BMI2_E_ST_NOT_RUNING;
9557 if (rslt == BMI2_OK)
9559 rslt = abort_bmi2(BMI2_ENABLE, dev);
9562 /* send the g trigger command */
9563 if (rslt == BMI2_OK)
9565 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &cmd, 1, dev);
9568 if (rslt == BMI2_OK)
9570 /* wait until st_status = 0 or time out is 2 seconds */
9571 rslt = wait_st_running(BMI2_CRT_WAIT_RUNNING_RETRY_EXECUTION, dev);
9574 /* Check G trigger status for error */
9575 if (rslt == BMI2_OK)
9577 rslt = crt_gyro_st_update_result(dev);
9578 if (rslt == BMI2_E_ABORT_ERROR)
9580 rslt = BMI2_OK;
9582 else
9584 rslt = BMI2_E_ABORT_ERROR;
9588 /* Enable Advance power save if disabled while configuring and
9589 * not when already disabled
9591 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
9593 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
9596 return rslt;
9600 * @brief This api is used to enable/disable abort.
9602 static int8_t abort_bmi2(uint8_t abort_enable, struct bmi2_dev *dev)
9604 /* Variable to define error */
9605 int8_t rslt;
9607 /* Array to define the feature configuration */
9608 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
9610 /* Variable to define the array offset */
9611 uint8_t idx = 0;
9613 /* Variable to set flag */
9614 uint8_t feat_found;
9615 uint8_t reg_addr = 0;
9617 /* Initialize feature configuration for blocking a feature */
9618 struct bmi2_feature_config block_config = { 0, 0, 0 };
9620 /* Search for bmi2 Abort feature and extract its configuration details */
9621 feat_found = bmi2_extract_input_feat_config(&block_config, BMI2_ABORT_CRT_GYRO_SELF_TEST, dev);
9622 if (feat_found)
9624 /* Get the configuration from the page where abort(block) feature resides */
9625 rslt = bmi2_get_feat_config(block_config.page, feat_config, dev);
9626 if (rslt == BMI2_OK)
9628 /* Define the offset in bytes */
9629 idx = block_config.start_addr;
9631 /* update the gyro self-test crt abort enable bit */
9632 feat_config[idx] = BMI2_SET_BITS(feat_config[idx], BMI2_ABORT_FEATURE_EN, abort_enable);
9634 /* Update the register address */
9635 reg_addr = BMI2_FEATURES_REG_ADDR + (block_config.start_addr - 1);
9637 /* Set the configuration back to the page */
9638 rslt = bmi2_set_regs(reg_addr, &feat_config[block_config.start_addr - 1], 2, dev);
9641 else
9643 rslt = BMI2_E_INVALID_SENSOR;
9646 return rslt;
9650 * @brief This api is use to wait till gyro self-test is completed and update the status of gyro
9651 * self-test.
9653 static int8_t gyro_self_test_completed(struct bmi2_gyro_self_test_status *gyro_st_result, struct bmi2_dev *dev)
9655 int8_t rslt;
9656 uint8_t reg_data;
9658 rslt = bmi2_get_regs(BMI2_GYR_SELF_TEST_AXES_ADDR, &reg_data, 1, dev);
9659 if (rslt == BMI2_OK)
9661 gyro_st_result->gyr_st_axes_done = BMI2_GET_BIT_POS0(reg_data, BMI2_GYR_ST_AXES_DONE);
9662 if (gyro_st_result->gyr_st_axes_done == 0x01)
9664 gyro_st_result->gyr_axis_x_ok = BMI2_GET_BITS(reg_data, BMI2_GYR_AXIS_X_OK);
9665 gyro_st_result->gyr_axis_y_ok = BMI2_GET_BITS(reg_data, BMI2_GYR_AXIS_Y_OK);
9666 gyro_st_result->gyr_axis_z_ok = BMI2_GET_BITS(reg_data, BMI2_GYR_AXIS_Z_OK);
9668 else
9670 rslt = BMI2_E_SELF_TEST_NOT_DONE;
9674 return rslt;
9678 * @brief This api validates accel foc position as per the range
9680 static int8_t validate_foc_position(uint8_t sens_list,
9681 const struct bmi2_accel_foc_g_value *accel_g_axis,
9682 struct bmi2_sens_axes_data avg_foc_data,
9683 struct bmi2_dev *dev)
9685 int8_t rslt = BMI2_E_INVALID_INPUT;
9687 if (sens_list == BMI2_ACCEL)
9689 if (accel_g_axis->x == 1)
9691 rslt = validate_foc_accel_axis(avg_foc_data.x, dev);
9693 else if (accel_g_axis->y == 1)
9695 rslt = validate_foc_accel_axis(avg_foc_data.y, dev);
9697 else
9699 rslt = validate_foc_accel_axis(avg_foc_data.z, dev);
9702 else if (sens_list == BMI2_GYRO)
9704 if (((avg_foc_data.x >= BMI2_GYRO_FOC_NOISE_LIMIT_NEGATIVE) &&
9705 (avg_foc_data.x <= BMI2_GYRO_FOC_NOISE_LIMIT_POSITIVE)) &&
9706 ((avg_foc_data.y >= BMI2_GYRO_FOC_NOISE_LIMIT_NEGATIVE) &&
9707 (avg_foc_data.y <= BMI2_GYRO_FOC_NOISE_LIMIT_POSITIVE)) &&
9708 ((avg_foc_data.z >= BMI2_GYRO_FOC_NOISE_LIMIT_NEGATIVE) &&
9709 (avg_foc_data.z <= BMI2_GYRO_FOC_NOISE_LIMIT_POSITIVE)))
9711 rslt = BMI2_OK;
9713 else
9715 rslt = BMI2_E_INVALID_FOC_POSITION;
9719 return rslt;
9723 * @brief This api validates depends on accel foc access input
9725 static int8_t validate_foc_accel_axis(int16_t avg_foc_data, struct bmi2_dev *dev)
9727 struct bmi2_sens_config sens_cfg = { 0 };
9728 uint8_t range;
9729 int8_t rslt;
9731 sens_cfg.type = BMI2_ACCEL;
9732 rslt = bmi2_get_sensor_config(&sens_cfg, 1, dev);
9733 range = sens_cfg.cfg.acc.range;
9735 /* reference LSB value of 16G */
9736 if ((range == BMI2_ACC_RANGE_2G) && (avg_foc_data > BMI2_ACC_2G_MIN_NOISE_LIMIT) &&
9737 (avg_foc_data < BMI2_ACC_2G_MAX_NOISE_LIMIT))
9739 rslt = BMI2_OK;
9741 /* reference LSB value of 16G */
9742 else if ((range == BMI2_ACC_RANGE_4G) && (avg_foc_data > BMI2_ACC_4G_MIN_NOISE_LIMIT) &&
9743 (avg_foc_data < BMI2_ACC_4G_MAX_NOISE_LIMIT))
9745 rslt = BMI2_OK;
9747 /* reference LSB value of 16G */
9748 else if ((range == BMI2_ACC_RANGE_8G) && (avg_foc_data > BMI2_ACC_8G_MIN_NOISE_LIMIT) &&
9749 (avg_foc_data < BMI2_ACC_8G_MAX_NOISE_LIMIT))
9751 rslt = BMI2_OK;
9753 /* reference LSB value of 16G */
9754 else if ((range == BMI2_ACC_RANGE_16G) && (avg_foc_data > BMI2_ACC_16G_MIN_NOISE_LIMIT) &&
9755 (avg_foc_data < BMI2_ACC_16G_MAX_NOISE_LIMIT))
9757 rslt = BMI2_OK;
9759 else
9761 rslt = BMI2_E_INVALID_FOC_POSITION;
9764 return rslt;
9767 /*! @brief This api is used for programming the non volatile memory(nvm) */
9768 int8_t bmi2_nvm_prog(struct bmi2_dev *dev)
9770 int8_t rslt = BMI2_OK;
9772 /* Variable to get the status of advance power save */
9773 uint8_t aps_stat;
9774 uint8_t status;
9775 uint8_t cmd_rdy;
9776 uint8_t reg_data;
9777 uint8_t write_timeout = 100;
9779 /* Get status of advance power save mode */
9780 aps_stat = dev->aps_status;
9781 if (aps_stat == BMI2_ENABLE)
9783 /* Disable advance power save if enabled */
9784 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
9787 /* Check the Write status and proceed only if there is no ongoing write cycle */
9788 if (rslt == BMI2_OK)
9790 rslt = bmi2_get_status(&status, dev);
9792 cmd_rdy = BMI2_GET_BITS(status, BMI2_CMD_RDY);
9793 if (cmd_rdy)
9795 rslt = set_nvm_prep_prog(BMI2_ENABLE, dev);
9796 if (rslt == BMI2_OK)
9798 dev->delay_us(40000, dev->intf_ptr);
9800 /* Set the NVM_CONF.nvm_prog_en bit in order to enable the NVM
9801 * programming */
9802 reg_data = BMI2_NVM_UNLOCK_ENABLE;
9803 rslt = bmi2_set_regs(BMI2_NVM_CONF_ADDR, &reg_data, 1, dev);
9804 if (rslt == BMI2_OK)
9806 /* Send NVM prog command to command register */
9807 reg_data = BMI2_NVM_PROG_CMD;
9808 rslt = bmi2_set_regs(BMI2_CMD_REG_ADDR, &reg_data, 1, dev);
9811 /* Wait till write operation is completed */
9812 if (rslt == BMI2_OK)
9814 while (write_timeout--)
9816 rslt = bmi2_get_status(&status, dev);
9817 if (rslt == BMI2_OK)
9819 cmd_rdy = BMI2_GET_BITS(status, BMI2_CMD_RDY);
9821 /* Nvm is complete once cmd_rdy is 1, break if 1 */
9822 if (cmd_rdy)
9824 break;
9827 /* Wait till cmd_rdy becomes 1 indicating
9828 * nvm process completes */
9829 dev->delay_us(20000, dev->intf_ptr);
9834 if ((rslt == BMI2_OK) && (cmd_rdy != BMI2_TRUE))
9836 rslt = BMI2_E_WRITE_CYCLE_ONGOING;
9840 else
9842 rslt = BMI2_E_WRITE_CYCLE_ONGOING;
9846 if (rslt == BMI2_OK)
9848 /* perform soft reset */
9849 rslt = bmi2_soft_reset(dev);
9852 /* Enable Advance power save if disabled while configuring and not when already disabled */
9853 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
9855 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
9858 return rslt;
9862 * @brief This API reads and provides average for 128 samples of sensor data for foc operation
9863 * gyro.
9865 static int8_t get_average_of_sensor_data(uint8_t sens_list,
9866 struct bmi2_foc_temp_value *temp_foc_data,
9867 struct bmi2_dev *dev)
9869 int8_t rslt = 0;
9870 struct bmi2_sensor_data sensor_data = { 0 };
9871 uint8_t sample_count = 0;
9872 uint8_t datardy_try_cnt;
9873 uint8_t drdy_status = 0;
9874 uint8_t sensor_drdy = 0;
9876 sensor_data.type = sens_list;
9877 if (sens_list == BMI2_ACCEL)
9879 sensor_drdy = BMI2_DRDY_ACC;
9881 else
9883 sensor_drdy = BMI2_DRDY_GYR;
9886 /* Read sensor values before FOC */
9887 while (sample_count < BMI2_FOC_SAMPLE_LIMIT)
9889 datardy_try_cnt = 5;
9892 dev->delay_us(20000, dev->intf_ptr);
9893 rslt = bmi2_get_status(&drdy_status, dev);
9894 datardy_try_cnt--;
9895 } while ((rslt == BMI2_OK) && (!(drdy_status & sensor_drdy)) && (datardy_try_cnt));
9897 if ((rslt != BMI2_OK) || (datardy_try_cnt == 0))
9899 rslt = BMI2_E_DATA_RDY_INT_FAILED;
9900 break;
9903 rslt = bmi2_get_sensor_data(&sensor_data, 1, dev);
9905 if (rslt == BMI2_OK)
9907 if (sensor_data.type == BMI2_ACCEL)
9909 temp_foc_data->x += sensor_data.sens_data.acc.x;
9910 temp_foc_data->y += sensor_data.sens_data.acc.y;
9911 temp_foc_data->z += sensor_data.sens_data.acc.z;
9913 else if (sensor_data.type == BMI2_GYRO)
9915 temp_foc_data->x += sensor_data.sens_data.gyr.x;
9916 temp_foc_data->y += sensor_data.sens_data.gyr.y;
9917 temp_foc_data->z += sensor_data.sens_data.gyr.z;
9920 else
9922 break;
9925 sample_count++;
9928 if (rslt == BMI2_OK)
9930 temp_foc_data->x = (temp_foc_data->x / BMI2_FOC_SAMPLE_LIMIT);
9931 temp_foc_data->y = (temp_foc_data->y / BMI2_FOC_SAMPLE_LIMIT);
9932 temp_foc_data->z = (temp_foc_data->z / BMI2_FOC_SAMPLE_LIMIT);
9935 return rslt;
9939 * @brief This internal API extract the identification feature from the DMR page
9940 * and retrieve the config file major and minor version.
9942 static int8_t extract_config_file(uint8_t *config_major, uint8_t *config_minor, struct bmi2_dev *dev)
9944 /* Variable to define the result */
9945 int8_t rslt = BMI2_OK;
9947 /* Variable to define the array offset */
9948 uint8_t idx = 0;
9950 /* Variable to define LSB */
9951 uint16_t lsb = 0;
9953 /* Variable to define MSB */
9954 uint16_t msb = 0;
9956 /* Variable to define a word */
9957 uint16_t lsb_msb = 0;
9959 /* Variable to set flag */
9960 uint8_t feat_found;
9962 /* Variable to define advance power save mode status */
9963 uint8_t aps_stat;
9965 /* Array to define the feature configuration */
9966 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
9968 /* Initialize feature configuration for config file identification */
9969 struct bmi2_feature_config config_id = { 0, 0, 0 };
9971 /* Check the power mode status */
9972 aps_stat = dev->aps_status;
9973 if (aps_stat == BMI2_ENABLE)
9975 /* Disable advance power save if enabled */
9976 rslt = bmi2_set_adv_power_save(BMI2_DISABLE, dev);
9979 if (rslt == BMI2_OK)
9981 /* Search for config file identification feature and extract its configuration
9982 * details */
9983 feat_found = bmi2_extract_input_feat_config(&config_id, BMI2_CONFIG_ID, dev);
9984 if (feat_found)
9986 /* Get the configuration from the page where config file identification
9987 * feature resides */
9988 rslt = bmi2_get_feat_config(config_id.page, feat_config, dev);
9989 if (rslt == BMI2_OK)
9991 /* Define the offset for config file identification */
9992 idx = config_id.start_addr;
9994 /* Get word to calculate config file identification */
9995 lsb = (uint16_t) feat_config[idx++];
9996 msb = ((uint16_t) feat_config[idx++] << 8);
9997 lsb_msb = lsb | msb;
9999 /* Get major and minor version */
10000 *config_major = BMI2_GET_BITS(lsb_msb, BMI2_CONFIG_MAJOR);
10001 *config_minor = BMI2_GET_BIT_POS0(lsb, BMI2_CONFIG_MINOR);
10005 /* Enable Advance power save if disabled while configuring and
10006 * not when already disabled
10008 if ((aps_stat == BMI2_ENABLE) && (rslt == BMI2_OK))
10010 rslt = bmi2_set_adv_power_save(BMI2_ENABLE, dev);
10013 else
10015 rslt = BMI2_E_INVALID_SENSOR;
10018 return rslt;
10022 *@brief This internal API is used to map the interrupts to the sensor.
10024 static void extract_feat_int_map(struct bmi2_map_int *map_int, uint8_t type, const struct bmi2_dev *dev)
10026 /* Variable to define loop */
10027 uint8_t loop = 0;
10029 /* Search for the interrupts from the input configuration array */
10030 while (loop < dev->sens_int_map)
10032 if (dev->map_int[loop].type == type)
10034 *map_int = dev->map_int[loop];
10035 break;
10038 loop++;
10043 * @brief This internal API gets the saturation status for the gyroscope user
10044 * gain update.
10046 static int8_t get_gyro_gain_update_status(struct bmi2_gyr_user_gain_status *user_gain_stat, struct bmi2_dev *dev)
10048 /* Variable to define error */
10049 int8_t rslt;
10051 /* Array to define the feature configuration */
10052 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
10054 /* Variables to define index */
10055 uint8_t idx = 0;
10057 /* Variable to set flag */
10058 uint8_t feat_found;
10060 /* Initialize feature output for gyroscope user gain status */
10061 struct bmi2_feature_config user_gain_cfg = { 0, 0, 0 };
10063 /* Search for gyroscope user gain status output feature and extract its
10064 * configuration details
10066 feat_found = extract_output_feat_config(&user_gain_cfg, BMI2_GYRO_GAIN_UPDATE, dev);
10067 if (feat_found)
10069 /* Get the feature output configuration for gyroscope user gain status */
10070 rslt = bmi2_get_feat_config(user_gain_cfg.page, feat_config, dev);
10071 if (rslt == BMI2_OK)
10073 /* Define the offset in bytes for gyroscope user gain status */
10074 idx = user_gain_cfg.start_addr;
10076 /* Get the saturation status for x-axis */
10077 user_gain_stat->sat_x = BMI2_GET_BIT_POS0(feat_config[idx], BMI2_GYR_USER_GAIN_SAT_STAT_X);
10079 /* Get the saturation status for y-axis */
10080 user_gain_stat->sat_y = BMI2_GET_BITS(feat_config[idx], BMI2_GYR_USER_GAIN_SAT_STAT_Y);
10082 /* Get the saturation status for z-axis */
10083 user_gain_stat->sat_z = BMI2_GET_BITS(feat_config[idx], BMI2_GYR_USER_GAIN_SAT_STAT_Z);
10085 /* Get g trigger status */
10086 user_gain_stat->g_trigger_status = BMI2_GET_BITS(feat_config[idx], BMI2_G_TRIGGER_STAT);
10089 else
10091 rslt = BMI2_E_INVALID_SENSOR;
10094 return rslt;
10098 * @brief This internal API is used to extract the output feature configuration
10099 * details from the look-up table.
10101 static uint8_t extract_output_feat_config(struct bmi2_feature_config *feat_output,
10102 uint8_t type,
10103 const struct bmi2_dev *dev)
10105 /* Variable to define loop */
10106 uint8_t loop = 0;
10108 /* Variable to set flag */
10109 uint8_t feat_found = BMI2_FALSE;
10111 /* Search for the output feature from the output configuration array */
10112 while (loop < dev->out_sens)
10114 if (dev->feat_output[loop].type == type)
10116 *feat_output = dev->feat_output[loop];
10117 feat_found = BMI2_TRUE;
10118 break;
10121 loop++;
10124 /* Return flag */
10125 return feat_found;
10129 * @brief This internal API gets the cross sensitivity coefficient between
10130 * gyroscope's X and Z axes.
10132 static int8_t get_gyro_cross_sense(int16_t *cross_sense, struct bmi2_dev *dev)
10134 /* Variable to define error */
10135 int8_t rslt;
10137 /* Array to define the feature configuration */
10138 uint8_t feat_config[BMI2_FEAT_SIZE_IN_BYTES] = { 0 };
10140 /* Variable to define index */
10141 uint8_t idx = 0;
10143 /* Variable to set flag */
10144 uint8_t feat_found;
10146 uint8_t corr_fact_zx;
10148 /* Initialize feature output for gyroscope cross sensitivity */
10149 struct bmi2_feature_config cross_sense_out_config = { 0, 0, 0 };
10151 if (dev->variant_feature & BMI2_MAXIMUM_FIFO_VARIANT)
10153 /* For maximum_fifo variant fetch the correction factor from GPIO0 */
10154 rslt = bmi2_get_regs(BMI2_GYR_CAS_GPIO0_ADDR, &corr_fact_zx, 1, dev);
10155 if (rslt == BMI2_OK)
10157 /* Get the gyroscope cross sensitivity coefficient */
10158 if (corr_fact_zx & BMI2_GYRO_CROSS_AXES_SENSE_SIGN_BIT_MASK)
10160 *cross_sense = (int16_t)(((int16_t)corr_fact_zx) - 128);
10162 else
10164 *cross_sense = (int16_t)(corr_fact_zx);
10168 else
10170 /* Search for gyroscope cross sensitivity feature and extract its configuration details */
10171 feat_found = extract_output_feat_config(&cross_sense_out_config, BMI2_GYRO_CROSS_SENSE, dev);
10172 if (feat_found)
10174 /* Get the feature output configuration for gyroscope cross sensitivity
10175 * feature */
10176 rslt = bmi2_get_feat_config(cross_sense_out_config.page, feat_config, dev);
10177 if (rslt == BMI2_OK)
10179 /* Define the offset in bytes for gyroscope cross sensitivity output */
10180 idx = cross_sense_out_config.start_addr;
10182 /* discard the MSB as GYR_CAS is of only 7 bit */
10183 feat_config[idx] = feat_config[idx] & BMI2_GYRO_CROSS_AXES_SENSE_MASK;
10185 /* Get the gyroscope cross sensitivity coefficient */
10186 if (feat_config[idx] & BMI2_GYRO_CROSS_AXES_SENSE_SIGN_BIT_MASK)
10188 *cross_sense = (int16_t)(((int16_t)feat_config[idx]) - 128);
10190 else
10192 *cross_sense = (int16_t)(feat_config[idx]);
10196 else
10198 rslt = BMI2_E_INVALID_SENSOR;
10202 return rslt;
10206 * @brief This internal API selects the sensor/features to be enabled or
10207 * disabled.
10209 static int8_t select_sensor(const uint8_t *sens_list, uint8_t n_sens, uint64_t *sensor_sel)
10211 /* Variable to define error */
10212 int8_t rslt = BMI2_OK;
10214 /* Variable to define loop */
10215 uint8_t count;
10217 for (count = 0; count < n_sens; count++)
10219 switch (sens_list[count])
10221 case BMI2_ACCEL:
10222 *sensor_sel |= BMI2_ACCEL_SENS_SEL;
10223 break;
10224 case BMI2_GYRO:
10225 *sensor_sel |= BMI2_GYRO_SENS_SEL;
10226 break;
10227 case BMI2_AUX:
10228 *sensor_sel |= BMI2_AUX_SENS_SEL;
10229 break;
10230 case BMI2_TEMP:
10231 *sensor_sel |= BMI2_TEMP_SENS_SEL;
10232 break;
10233 default:
10234 rslt = BMI2_E_INVALID_SENSOR;
10235 break;
10239 return rslt;
10243 * @brief This internal API enables the selected sensor/features.
10245 static int8_t sensor_enable(uint64_t sensor_sel, struct bmi2_dev *dev)
10247 /* Variable to define error */
10248 int8_t rslt;
10250 /* Variable to store register values */
10251 uint8_t reg_data = 0;
10253 rslt = bmi2_get_regs(BMI2_PWR_CTRL_ADDR, &reg_data, 1, dev);
10254 if (rslt == BMI2_OK)
10256 /* Enable accelerometer */
10257 if (sensor_sel & BMI2_ACCEL_SENS_SEL)
10259 reg_data = BMI2_SET_BITS(reg_data, BMI2_ACC_EN, BMI2_ENABLE);
10262 /* Enable gyroscope */
10263 if (sensor_sel & BMI2_GYRO_SENS_SEL)
10265 reg_data = BMI2_SET_BITS(reg_data, BMI2_GYR_EN, BMI2_ENABLE);
10268 /* Enable auxiliary sensor */
10269 if (sensor_sel & BMI2_AUX_SENS_SEL)
10271 reg_data = BMI2_SET_BIT_POS0(reg_data, BMI2_AUX_EN, BMI2_ENABLE);
10274 /* Enable temperature sensor */
10275 if (sensor_sel & BMI2_TEMP_SENS_SEL)
10277 reg_data = BMI2_SET_BITS(reg_data, BMI2_TEMP_EN, BMI2_ENABLE);
10280 /* Enable the sensors that are set in the power control register */
10281 if (sensor_sel & BMI2_MAIN_SENSORS)
10283 rslt = bmi2_set_regs(BMI2_PWR_CTRL_ADDR, &reg_data, 1, dev);
10287 return rslt;
10291 * @brief This internal API disables the selected sensors/features.
10293 static int8_t sensor_disable(uint64_t sensor_sel, struct bmi2_dev *dev)
10295 /* Variable to define error */
10296 int8_t rslt;
10298 /* Variable to store register values */
10299 uint8_t reg_data = 0;
10301 rslt = bmi2_get_regs(BMI2_PWR_CTRL_ADDR, &reg_data, 1, dev);
10302 if (rslt == BMI2_OK)
10304 /* Disable accelerometer */
10305 if (sensor_sel & BMI2_ACCEL_SENS_SEL)
10307 reg_data = BMI2_SET_BIT_VAL0(reg_data, BMI2_ACC_EN);
10310 /* Disable gyroscope */
10311 if (sensor_sel & BMI2_GYRO_SENS_SEL)
10313 reg_data = BMI2_SET_BIT_VAL0(reg_data, BMI2_GYR_EN);
10316 /* Disable auxiliary sensor */
10317 if (sensor_sel & BMI2_AUX_SENS_SEL)
10319 reg_data = BMI2_SET_BIT_VAL0(reg_data, BMI2_AUX_EN);
10322 /* Disable temperature sensor */
10323 if (sensor_sel & BMI2_TEMP_SENS_SEL)
10325 reg_data = BMI2_SET_BIT_VAL0(reg_data, BMI2_TEMP_EN);
10328 /* Enable the sensors that are set in the power control register */
10329 if (sensor_sel & BMI2_MAIN_SENSORS)
10331 rslt = bmi2_set_regs(BMI2_PWR_CTRL_ADDR, &reg_data, 1, dev);
10335 return rslt;
10338 /*! @endcond */