1 // SPDX-License-Identifier: GPL-2.0-or-later
2 /*
3 * Copyright (C) 2020 Invensense, Inc.
4 */
5
6 #include <linux/kernel.h>
7 #include <linux/device.h>
8 #include <linux/mutex.h>
9 #include <linux/pm_runtime.h>
10 #include <linux/regmap.h>
11 #include <linux/delay.h>
12
13 #include <linux/iio/buffer.h>
14 #include <linux/iio/common/inv_sensors_timestamp.h>
15 #include <linux/iio/iio.h>
16
17 #include "inv_icm42600.h"
18 #include "inv_icm42600_buffer.h"
19
20 /* FIFO header: 1 byte */
21 #define INV_ICM42600_FIFO_HEADER_MSG BIT(7)
22 #define INV_ICM42600_FIFO_HEADER_ACCEL BIT(6)
23 #define INV_ICM42600_FIFO_HEADER_GYRO BIT(5)
24 #define INV_ICM42600_FIFO_HEADER_TMST_FSYNC GENMASK(3, 2)
25 #define INV_ICM42600_FIFO_HEADER_ODR_ACCEL BIT(1)
26 #define INV_ICM42600_FIFO_HEADER_ODR_GYRO BIT(0)
27
28 struct inv_icm42600_fifo_1sensor_packet {
29 uint8_t header;
30 struct inv_icm42600_fifo_sensor_data data;
31 int8_t temp;
32 } __packed;
33 #define INV_ICM42600_FIFO_1SENSOR_PACKET_SIZE 8
34
35 struct inv_icm42600_fifo_2sensors_packet {
36 uint8_t header;
37 struct inv_icm42600_fifo_sensor_data accel;
38 struct inv_icm42600_fifo_sensor_data gyro;
39 int8_t temp;
40 __be16 timestamp;
41 } __packed;
42 #define INV_ICM42600_FIFO_2SENSORS_PACKET_SIZE 16
43
inv_icm42600_fifo_decode_packet(const void * packet,const void ** accel,const void ** gyro,const int8_t ** temp,const void ** timestamp,unsigned int * odr)44 ssize_t inv_icm42600_fifo_decode_packet(const void *packet, const void **accel,
45 const void **gyro, const int8_t **temp,
46 const void **timestamp, unsigned int *odr)
47 {
48 const struct inv_icm42600_fifo_1sensor_packet *pack1 = packet;
49 const struct inv_icm42600_fifo_2sensors_packet *pack2 = packet;
50 uint8_t header = *((const uint8_t *)packet);
51
52 /* FIFO empty */
53 if (header & INV_ICM42600_FIFO_HEADER_MSG) {
54 *accel = NULL;
55 *gyro = NULL;
56 *temp = NULL;
57 *timestamp = NULL;
58 *odr = 0;
59 return 0;
60 }
61
62 /* handle odr flags */
63 *odr = 0;
64 if (header & INV_ICM42600_FIFO_HEADER_ODR_GYRO)
65 *odr |= INV_ICM42600_SENSOR_GYRO;
66 if (header & INV_ICM42600_FIFO_HEADER_ODR_ACCEL)
67 *odr |= INV_ICM42600_SENSOR_ACCEL;
68
69 /* accel + gyro */
70 if ((header & INV_ICM42600_FIFO_HEADER_ACCEL) &&
71 (header & INV_ICM42600_FIFO_HEADER_GYRO)) {
72 *accel = &pack2->accel;
73 *gyro = &pack2->gyro;
74 *temp = &pack2->temp;
75 *timestamp = &pack2->timestamp;
76 return INV_ICM42600_FIFO_2SENSORS_PACKET_SIZE;
77 }
78
79 /* accel only */
80 if (header & INV_ICM42600_FIFO_HEADER_ACCEL) {
81 *accel = &pack1->data;
82 *gyro = NULL;
83 *temp = &pack1->temp;
84 *timestamp = NULL;
85 return INV_ICM42600_FIFO_1SENSOR_PACKET_SIZE;
86 }
87
88 /* gyro only */
89 if (header & INV_ICM42600_FIFO_HEADER_GYRO) {
90 *accel = NULL;
91 *gyro = &pack1->data;
92 *temp = &pack1->temp;
93 *timestamp = NULL;
94 return INV_ICM42600_FIFO_1SENSOR_PACKET_SIZE;
95 }
96
97 /* invalid packet if here */
98 return -EINVAL;
99 }
100
inv_icm42600_buffer_update_fifo_period(struct inv_icm42600_state * st)101 void inv_icm42600_buffer_update_fifo_period(struct inv_icm42600_state *st)
102 {
103 uint32_t period_gyro, period_accel, period;
104
105 if (st->fifo.en & INV_ICM42600_SENSOR_GYRO)
106 period_gyro = inv_icm42600_odr_to_period(st->conf.gyro.odr);
107 else
108 period_gyro = U32_MAX;
109
110 if (st->fifo.en & INV_ICM42600_SENSOR_ACCEL)
111 period_accel = inv_icm42600_odr_to_period(st->conf.accel.odr);
112 else
113 period_accel = U32_MAX;
114
115 if (period_gyro <= period_accel)
116 period = period_gyro;
117 else
118 period = period_accel;
119
120 st->fifo.period = period;
121 }
122
inv_icm42600_buffer_set_fifo_en(struct inv_icm42600_state * st,unsigned int fifo_en)123 int inv_icm42600_buffer_set_fifo_en(struct inv_icm42600_state *st,
124 unsigned int fifo_en)
125 {
126 unsigned int mask, val;
127 int ret;
128
129 /* update only FIFO EN bits */
130 mask = INV_ICM42600_FIFO_CONFIG1_TMST_FSYNC_EN |
131 INV_ICM42600_FIFO_CONFIG1_TEMP_EN |
132 INV_ICM42600_FIFO_CONFIG1_GYRO_EN |
133 INV_ICM42600_FIFO_CONFIG1_ACCEL_EN;
134
135 val = 0;
136 if (fifo_en & INV_ICM42600_SENSOR_GYRO)
137 val |= INV_ICM42600_FIFO_CONFIG1_GYRO_EN;
138 if (fifo_en & INV_ICM42600_SENSOR_ACCEL)
139 val |= INV_ICM42600_FIFO_CONFIG1_ACCEL_EN;
140 if (fifo_en & INV_ICM42600_SENSOR_TEMP)
141 val |= INV_ICM42600_FIFO_CONFIG1_TEMP_EN;
142
143 ret = regmap_update_bits(st->map, INV_ICM42600_REG_FIFO_CONFIG1, mask, val);
144 if (ret)
145 return ret;
146
147 st->fifo.en = fifo_en;
148 inv_icm42600_buffer_update_fifo_period(st);
149
150 return 0;
151 }
152
inv_icm42600_get_packet_size(unsigned int fifo_en)153 static size_t inv_icm42600_get_packet_size(unsigned int fifo_en)
154 {
155 size_t packet_size;
156
157 if ((fifo_en & INV_ICM42600_SENSOR_GYRO) &&
158 (fifo_en & INV_ICM42600_SENSOR_ACCEL))
159 packet_size = INV_ICM42600_FIFO_2SENSORS_PACKET_SIZE;
160 else
161 packet_size = INV_ICM42600_FIFO_1SENSOR_PACKET_SIZE;
162
163 return packet_size;
164 }
165
inv_icm42600_wm_truncate(unsigned int watermark,size_t packet_size)166 static unsigned int inv_icm42600_wm_truncate(unsigned int watermark,
167 size_t packet_size)
168 {
169 size_t wm_size;
170 unsigned int wm;
171
172 wm_size = watermark * packet_size;
173 if (wm_size > INV_ICM42600_FIFO_WATERMARK_MAX)
174 wm_size = INV_ICM42600_FIFO_WATERMARK_MAX;
175
176 wm = wm_size / packet_size;
177
178 return wm;
179 }
180
181 /**
182 * inv_icm42600_buffer_update_watermark - update watermark FIFO threshold
183 * @st: driver internal state
184 *
185 * Returns 0 on success, a negative error code otherwise.
186 *
187 * FIFO watermark threshold is computed based on the required watermark values
188 * set for gyro and accel sensors. Since watermark is all about acceptable data
189 * latency, use the smallest setting between the 2. It means choosing the
190 * smallest latency but this is not as simple as choosing the smallest watermark
191 * value. Latency depends on watermark and ODR. It requires several steps:
192 * 1) compute gyro and accel latencies and choose the smallest value.
193 * 2) adapt the choosen latency so that it is a multiple of both gyro and accel
194 * ones. Otherwise it is possible that you don't meet a requirement. (for
195 * example with gyro @100Hz wm 4 and accel @100Hz with wm 6, choosing the
196 * value of 4 will not meet accel latency requirement because 6 is not a
197 * multiple of 4. You need to use the value 2.)
198 * 3) Since all periods are multiple of each others, watermark is computed by
199 * dividing this computed latency by the smallest period, which corresponds
200 * to the FIFO frequency. Beware that this is only true because we are not
201 * using 500Hz frequency which is not a multiple of the others.
202 */
inv_icm42600_buffer_update_watermark(struct inv_icm42600_state * st)203 int inv_icm42600_buffer_update_watermark(struct inv_icm42600_state *st)
204 {
205 size_t packet_size, wm_size;
206 unsigned int wm_gyro, wm_accel, watermark;
207 uint32_t period_gyro, period_accel, period;
208 uint32_t latency_gyro, latency_accel, latency;
209 bool restore;
210 __le16 raw_wm;
211 int ret;
212
213 packet_size = inv_icm42600_get_packet_size(st->fifo.en);
214
215 /* compute sensors latency, depending on sensor watermark and odr */
216 wm_gyro = inv_icm42600_wm_truncate(st->fifo.watermark.gyro, packet_size);
217 wm_accel = inv_icm42600_wm_truncate(st->fifo.watermark.accel, packet_size);
218 /* use us for odr to avoid overflow using 32 bits values */
219 period_gyro = inv_icm42600_odr_to_period(st->conf.gyro.odr) / 1000UL;
220 period_accel = inv_icm42600_odr_to_period(st->conf.accel.odr) / 1000UL;
221 latency_gyro = period_gyro * wm_gyro;
222 latency_accel = period_accel * wm_accel;
223
224 /* 0 value for watermark means that the sensor is turned off */
225 if (latency_gyro == 0) {
226 watermark = wm_accel;
227 } else if (latency_accel == 0) {
228 watermark = wm_gyro;
229 } else {
230 /* compute the smallest latency that is a multiple of both */
231 if (latency_gyro <= latency_accel)
232 latency = latency_gyro - (latency_accel % latency_gyro);
233 else
234 latency = latency_accel - (latency_gyro % latency_accel);
235 /* use the shortest period */
236 if (period_gyro <= period_accel)
237 period = period_gyro;
238 else
239 period = period_accel;
240 /* all this works because periods are multiple of each others */
241 watermark = latency / period;
242 if (watermark < 1)
243 watermark = 1;
244 }
245
246 /* compute watermark value in bytes */
247 wm_size = watermark * packet_size;
248
249 /* changing FIFO watermark requires to turn off watermark interrupt */
250 ret = regmap_update_bits_check(st->map, INV_ICM42600_REG_INT_SOURCE0,
251 INV_ICM42600_INT_SOURCE0_FIFO_THS_INT1_EN,
252 0, &restore);
253 if (ret)
254 return ret;
255
256 raw_wm = INV_ICM42600_FIFO_WATERMARK_VAL(wm_size);
257 memcpy(st->buffer, &raw_wm, sizeof(raw_wm));
258 ret = regmap_bulk_write(st->map, INV_ICM42600_REG_FIFO_WATERMARK,
259 st->buffer, sizeof(raw_wm));
260 if (ret)
261 return ret;
262
263 /* restore watermark interrupt */
264 if (restore) {
265 ret = regmap_update_bits(st->map, INV_ICM42600_REG_INT_SOURCE0,
266 INV_ICM42600_INT_SOURCE0_FIFO_THS_INT1_EN,
267 INV_ICM42600_INT_SOURCE0_FIFO_THS_INT1_EN);
268 if (ret)
269 return ret;
270 }
271
272 return 0;
273 }
274
inv_icm42600_buffer_preenable(struct iio_dev * indio_dev)275 static int inv_icm42600_buffer_preenable(struct iio_dev *indio_dev)
276 {
277 struct inv_icm42600_state *st = iio_device_get_drvdata(indio_dev);
278 struct device *dev = regmap_get_device(st->map);
279 struct inv_sensors_timestamp *ts = iio_priv(indio_dev);
280
281 pm_runtime_get_sync(dev);
282
283 mutex_lock(&st->lock);
284 inv_sensors_timestamp_reset(ts);
285 mutex_unlock(&st->lock);
286
287 return 0;
288 }
289
290 /*
291 * update_scan_mode callback is turning sensors on and setting data FIFO enable
292 * bits.
293 */
inv_icm42600_buffer_postenable(struct iio_dev * indio_dev)294 static int inv_icm42600_buffer_postenable(struct iio_dev *indio_dev)
295 {
296 struct inv_icm42600_state *st = iio_device_get_drvdata(indio_dev);
297 int ret;
298
299 mutex_lock(&st->lock);
300
301 /* exit if FIFO is already on */
302 if (st->fifo.on) {
303 ret = 0;
304 goto out_on;
305 }
306
307 /* set FIFO threshold interrupt */
308 ret = regmap_update_bits(st->map, INV_ICM42600_REG_INT_SOURCE0,
309 INV_ICM42600_INT_SOURCE0_FIFO_THS_INT1_EN,
310 INV_ICM42600_INT_SOURCE0_FIFO_THS_INT1_EN);
311 if (ret)
312 goto out_unlock;
313
314 /* flush FIFO data */
315 ret = regmap_write(st->map, INV_ICM42600_REG_SIGNAL_PATH_RESET,
316 INV_ICM42600_SIGNAL_PATH_RESET_FIFO_FLUSH);
317 if (ret)
318 goto out_unlock;
319
320 /* set FIFO in streaming mode */
321 ret = regmap_write(st->map, INV_ICM42600_REG_FIFO_CONFIG,
322 INV_ICM42600_FIFO_CONFIG_STREAM);
323 if (ret)
324 goto out_unlock;
325
326 /* workaround: first read of FIFO count after reset is always 0 */
327 ret = regmap_bulk_read(st->map, INV_ICM42600_REG_FIFO_COUNT, st->buffer, 2);
328 if (ret)
329 goto out_unlock;
330
331 out_on:
332 /* increase FIFO on counter */
333 st->fifo.on++;
334 out_unlock:
335 mutex_unlock(&st->lock);
336 return ret;
337 }
338
inv_icm42600_buffer_predisable(struct iio_dev * indio_dev)339 static int inv_icm42600_buffer_predisable(struct iio_dev *indio_dev)
340 {
341 struct inv_icm42600_state *st = iio_device_get_drvdata(indio_dev);
342 int ret;
343
344 mutex_lock(&st->lock);
345
346 /* exit if there are several sensors using the FIFO */
347 if (st->fifo.on > 1) {
348 ret = 0;
349 goto out_off;
350 }
351
352 /* set FIFO in bypass mode */
353 ret = regmap_write(st->map, INV_ICM42600_REG_FIFO_CONFIG,
354 INV_ICM42600_FIFO_CONFIG_BYPASS);
355 if (ret)
356 goto out_unlock;
357
358 /* flush FIFO data */
359 ret = regmap_write(st->map, INV_ICM42600_REG_SIGNAL_PATH_RESET,
360 INV_ICM42600_SIGNAL_PATH_RESET_FIFO_FLUSH);
361 if (ret)
362 goto out_unlock;
363
364 /* disable FIFO threshold interrupt */
365 ret = regmap_update_bits(st->map, INV_ICM42600_REG_INT_SOURCE0,
366 INV_ICM42600_INT_SOURCE0_FIFO_THS_INT1_EN, 0);
367 if (ret)
368 goto out_unlock;
369
370 out_off:
371 /* decrease FIFO on counter */
372 st->fifo.on--;
373 out_unlock:
374 mutex_unlock(&st->lock);
375 return ret;
376 }
377
inv_icm42600_buffer_postdisable(struct iio_dev * indio_dev)378 static int inv_icm42600_buffer_postdisable(struct iio_dev *indio_dev)
379 {
380 struct inv_icm42600_state *st = iio_device_get_drvdata(indio_dev);
381 struct device *dev = regmap_get_device(st->map);
382 unsigned int sensor;
383 unsigned int *watermark;
384 struct inv_icm42600_sensor_conf conf = INV_ICM42600_SENSOR_CONF_INIT;
385 unsigned int sleep_temp = 0;
386 unsigned int sleep_sensor = 0;
387 unsigned int sleep;
388 int ret;
389
390 if (indio_dev == st->indio_gyro) {
391 sensor = INV_ICM42600_SENSOR_GYRO;
392 watermark = &st->fifo.watermark.gyro;
393 } else if (indio_dev == st->indio_accel) {
394 sensor = INV_ICM42600_SENSOR_ACCEL;
395 watermark = &st->fifo.watermark.accel;
396 } else {
397 return -EINVAL;
398 }
399
400 mutex_lock(&st->lock);
401
402 ret = inv_icm42600_buffer_set_fifo_en(st, st->fifo.en & ~sensor);
403 if (ret)
404 goto out_unlock;
405
406 *watermark = 0;
407 ret = inv_icm42600_buffer_update_watermark(st);
408 if (ret)
409 goto out_unlock;
410
411 conf.mode = INV_ICM42600_SENSOR_MODE_OFF;
412 if (sensor == INV_ICM42600_SENSOR_GYRO)
413 ret = inv_icm42600_set_gyro_conf(st, &conf, &sleep_sensor);
414 else
415 ret = inv_icm42600_set_accel_conf(st, &conf, &sleep_sensor);
416 if (ret)
417 goto out_unlock;
418
419 /* if FIFO is off, turn temperature off */
420 if (!st->fifo.on)
421 ret = inv_icm42600_set_temp_conf(st, false, &sleep_temp);
422
423 out_unlock:
424 mutex_unlock(&st->lock);
425
426 /* sleep maximum required time */
427 if (sleep_sensor > sleep_temp)
428 sleep = sleep_sensor;
429 else
430 sleep = sleep_temp;
431 if (sleep)
432 msleep(sleep);
433
434 pm_runtime_mark_last_busy(dev);
435 pm_runtime_put_autosuspend(dev);
436
437 return ret;
438 }
439
440 const struct iio_buffer_setup_ops inv_icm42600_buffer_ops = {
441 .preenable = inv_icm42600_buffer_preenable,
442 .postenable = inv_icm42600_buffer_postenable,
443 .predisable = inv_icm42600_buffer_predisable,
444 .postdisable = inv_icm42600_buffer_postdisable,
445 };
446
inv_icm42600_buffer_fifo_read(struct inv_icm42600_state * st,unsigned int max)447 int inv_icm42600_buffer_fifo_read(struct inv_icm42600_state *st,
448 unsigned int max)
449 {
450 size_t max_count;
451 __be16 *raw_fifo_count;
452 ssize_t i, size;
453 const void *accel, *gyro, *timestamp;
454 const int8_t *temp;
455 unsigned int odr;
456 int ret;
457
458 /* reset all samples counters */
459 st->fifo.count = 0;
460 st->fifo.nb.gyro = 0;
461 st->fifo.nb.accel = 0;
462 st->fifo.nb.total = 0;
463
464 /* compute maximum FIFO read size */
465 if (max == 0)
466 max_count = sizeof(st->fifo.data);
467 else
468 max_count = max * inv_icm42600_get_packet_size(st->fifo.en);
469
470 /* read FIFO count value */
471 raw_fifo_count = (__be16 *)st->buffer;
472 ret = regmap_bulk_read(st->map, INV_ICM42600_REG_FIFO_COUNT,
473 raw_fifo_count, sizeof(*raw_fifo_count));
474 if (ret)
475 return ret;
476 st->fifo.count = be16_to_cpup(raw_fifo_count);
477
478 /* check and clamp FIFO count value */
479 if (st->fifo.count == 0)
480 return 0;
481 if (st->fifo.count > max_count)
482 st->fifo.count = max_count;
483
484 /* read all FIFO data in internal buffer */
485 ret = regmap_noinc_read(st->map, INV_ICM42600_REG_FIFO_DATA,
486 st->fifo.data, st->fifo.count);
487 if (ret)
488 return ret;
489
490 /* compute number of samples for each sensor */
491 for (i = 0; i < st->fifo.count; i += size) {
492 size = inv_icm42600_fifo_decode_packet(&st->fifo.data[i],
493 &accel, &gyro, &temp, ×tamp, &odr);
494 if (size <= 0)
495 break;
496 if (gyro != NULL && inv_icm42600_fifo_is_data_valid(gyro))
497 st->fifo.nb.gyro++;
498 if (accel != NULL && inv_icm42600_fifo_is_data_valid(accel))
499 st->fifo.nb.accel++;
500 st->fifo.nb.total++;
501 }
502
503 return 0;
504 }
505
inv_icm42600_buffer_fifo_parse(struct inv_icm42600_state * st)506 int inv_icm42600_buffer_fifo_parse(struct inv_icm42600_state *st)
507 {
508 struct inv_sensors_timestamp *ts;
509 int ret;
510
511 if (st->fifo.nb.total == 0)
512 return 0;
513
514 /* handle gyroscope timestamp and FIFO data parsing */
515 ts = iio_priv(st->indio_gyro);
516 inv_sensors_timestamp_interrupt(ts, st->fifo.period, st->fifo.nb.total,
517 st->fifo.nb.gyro, st->timestamp.gyro);
518 if (st->fifo.nb.gyro > 0) {
519 ret = inv_icm42600_gyro_parse_fifo(st->indio_gyro);
520 if (ret)
521 return ret;
522 }
523
524 /* handle accelerometer timestamp and FIFO data parsing */
525 ts = iio_priv(st->indio_accel);
526 inv_sensors_timestamp_interrupt(ts, st->fifo.period, st->fifo.nb.total,
527 st->fifo.nb.accel, st->timestamp.accel);
528 if (st->fifo.nb.accel > 0) {
529 ret = inv_icm42600_accel_parse_fifo(st->indio_accel);
530 if (ret)
531 return ret;
532 }
533
534 return 0;
535 }
536
inv_icm42600_buffer_hwfifo_flush(struct inv_icm42600_state * st,unsigned int count)537 int inv_icm42600_buffer_hwfifo_flush(struct inv_icm42600_state *st,
538 unsigned int count)
539 {
540 struct inv_sensors_timestamp *ts;
541 int64_t gyro_ts, accel_ts;
542 int ret;
543
544 gyro_ts = iio_get_time_ns(st->indio_gyro);
545 accel_ts = iio_get_time_ns(st->indio_accel);
546
547 ret = inv_icm42600_buffer_fifo_read(st, count);
548 if (ret)
549 return ret;
550
551 if (st->fifo.nb.total == 0)
552 return 0;
553
554 if (st->fifo.nb.gyro > 0) {
555 ts = iio_priv(st->indio_gyro);
556 inv_sensors_timestamp_interrupt(ts, st->fifo.period,
557 st->fifo.nb.total, st->fifo.nb.gyro,
558 gyro_ts);
559 ret = inv_icm42600_gyro_parse_fifo(st->indio_gyro);
560 if (ret)
561 return ret;
562 }
563
564 if (st->fifo.nb.accel > 0) {
565 ts = iio_priv(st->indio_accel);
566 inv_sensors_timestamp_interrupt(ts, st->fifo.period,
567 st->fifo.nb.total, st->fifo.nb.accel,
568 accel_ts);
569 ret = inv_icm42600_accel_parse_fifo(st->indio_accel);
570 if (ret)
571 return ret;
572 }
573
574 return 0;
575 }
576
inv_icm42600_buffer_init(struct inv_icm42600_state * st)577 int inv_icm42600_buffer_init(struct inv_icm42600_state *st)
578 {
579 unsigned int val;
580 int ret;
581
582 /*
583 * Default FIFO configuration (bits 7 to 5)
584 * - use invalid value
585 * - FIFO count in bytes
586 * - FIFO count in big endian
587 */
588 val = INV_ICM42600_INTF_CONFIG0_FIFO_COUNT_ENDIAN;
589 ret = regmap_update_bits(st->map, INV_ICM42600_REG_INTF_CONFIG0,
590 GENMASK(7, 5), val);
591 if (ret)
592 return ret;
593
594 /*
595 * Enable FIFO partial read and continuous watermark interrupt.
596 * Disable all FIFO EN bits.
597 */
598 val = INV_ICM42600_FIFO_CONFIG1_RESUME_PARTIAL_RD |
599 INV_ICM42600_FIFO_CONFIG1_WM_GT_TH;
600 return regmap_update_bits(st->map, INV_ICM42600_REG_FIFO_CONFIG1,
601 GENMASK(6, 5) | GENMASK(3, 0), val);
602 }
603