1 /*
2 * ImgTec IR Hardware Decoder found in PowerDown Controller.
3 *
4 * Copyright 2010-2014 Imagination Technologies Ltd.
5 *
6 * This program is free software; you can redistribute it and/or modify
7 * it under the terms of the GNU General Public License as published by the
8 * Free Software Foundation; either version 2 of the License, or (at your
9 * option) any later version.
10 *
11 * This ties into the input subsystem using the RC-core. Protocol support is
12 * provided in separate modules which provide the parameters and scancode
13 * translation functions to set up the hardware decoder and interpret the
14 * resulting input.
15 */
16
17 #include <linux/bitops.h>
18 #include <linux/clk.h>
19 #include <linux/interrupt.h>
20 #include <linux/spinlock.h>
21 #include <linux/timer.h>
22 #include <media/rc-core.h>
23 #include "img-ir.h"
24
25 /* Decoders lock (only modified to preprocess them) */
26 static DEFINE_SPINLOCK(img_ir_decoders_lock);
27
28 static bool img_ir_decoders_preprocessed;
29 static struct img_ir_decoder *img_ir_decoders[] = {
30 #ifdef CONFIG_IR_IMG_NEC
31 &img_ir_nec,
32 #endif
33 #ifdef CONFIG_IR_IMG_JVC
34 &img_ir_jvc,
35 #endif
36 #ifdef CONFIG_IR_IMG_SONY
37 &img_ir_sony,
38 #endif
39 #ifdef CONFIG_IR_IMG_SHARP
40 &img_ir_sharp,
41 #endif
42 #ifdef CONFIG_IR_IMG_SANYO
43 &img_ir_sanyo,
44 #endif
45 #ifdef CONFIG_IR_IMG_RC5
46 &img_ir_rc5,
47 #endif
48 #ifdef CONFIG_IR_IMG_RC6
49 &img_ir_rc6,
50 #endif
51 NULL
52 };
53
54 #define IMG_IR_F_FILTER BIT(RC_FILTER_NORMAL) /* enable filtering */
55 #define IMG_IR_F_WAKE BIT(RC_FILTER_WAKEUP) /* enable waking */
56
57 /* code type quirks */
58
59 #define IMG_IR_QUIRK_CODE_BROKEN 0x1 /* Decode is broken */
60 #define IMG_IR_QUIRK_CODE_LEN_INCR 0x2 /* Bit length needs increment */
61 /*
62 * The decoder generates rapid interrupts without actually having
63 * received any new data after an incomplete IR code is decoded.
64 */
65 #define IMG_IR_QUIRK_CODE_IRQ 0x4
66
67 /* functions for preprocessing timings, ensuring max is set */
68
img_ir_timing_preprocess(struct img_ir_timing_range * range,unsigned int unit)69 static void img_ir_timing_preprocess(struct img_ir_timing_range *range,
70 unsigned int unit)
71 {
72 if (range->max < range->min)
73 range->max = range->min;
74 if (unit) {
75 /* multiply by unit and convert to microseconds */
76 range->min = (range->min*unit)/1000;
77 range->max = (range->max*unit + 999)/1000; /* round up */
78 }
79 }
80
img_ir_symbol_timing_preprocess(struct img_ir_symbol_timing * timing,unsigned int unit)81 static void img_ir_symbol_timing_preprocess(struct img_ir_symbol_timing *timing,
82 unsigned int unit)
83 {
84 img_ir_timing_preprocess(&timing->pulse, unit);
85 img_ir_timing_preprocess(&timing->space, unit);
86 }
87
img_ir_timings_preprocess(struct img_ir_timings * timings,unsigned int unit)88 static void img_ir_timings_preprocess(struct img_ir_timings *timings,
89 unsigned int unit)
90 {
91 img_ir_symbol_timing_preprocess(&timings->ldr, unit);
92 img_ir_symbol_timing_preprocess(&timings->s00, unit);
93 img_ir_symbol_timing_preprocess(&timings->s01, unit);
94 img_ir_symbol_timing_preprocess(&timings->s10, unit);
95 img_ir_symbol_timing_preprocess(&timings->s11, unit);
96 /* default s10 and s11 to s00 and s01 if no leader */
97 if (unit)
98 /* multiply by unit and convert to microseconds (round up) */
99 timings->ft.ft_min = (timings->ft.ft_min*unit + 999)/1000;
100 }
101
102 /* functions for filling empty fields with defaults */
103
img_ir_timing_defaults(struct img_ir_timing_range * range,struct img_ir_timing_range * defaults)104 static void img_ir_timing_defaults(struct img_ir_timing_range *range,
105 struct img_ir_timing_range *defaults)
106 {
107 if (!range->min)
108 range->min = defaults->min;
109 if (!range->max)
110 range->max = defaults->max;
111 }
112
img_ir_symbol_timing_defaults(struct img_ir_symbol_timing * timing,struct img_ir_symbol_timing * defaults)113 static void img_ir_symbol_timing_defaults(struct img_ir_symbol_timing *timing,
114 struct img_ir_symbol_timing *defaults)
115 {
116 img_ir_timing_defaults(&timing->pulse, &defaults->pulse);
117 img_ir_timing_defaults(&timing->space, &defaults->space);
118 }
119
img_ir_timings_defaults(struct img_ir_timings * timings,struct img_ir_timings * defaults)120 static void img_ir_timings_defaults(struct img_ir_timings *timings,
121 struct img_ir_timings *defaults)
122 {
123 img_ir_symbol_timing_defaults(&timings->ldr, &defaults->ldr);
124 img_ir_symbol_timing_defaults(&timings->s00, &defaults->s00);
125 img_ir_symbol_timing_defaults(&timings->s01, &defaults->s01);
126 img_ir_symbol_timing_defaults(&timings->s10, &defaults->s10);
127 img_ir_symbol_timing_defaults(&timings->s11, &defaults->s11);
128 if (!timings->ft.ft_min)
129 timings->ft.ft_min = defaults->ft.ft_min;
130 }
131
132 /* functions for converting timings to register values */
133
134 /**
135 * img_ir_control() - Convert control struct to control register value.
136 * @control: Control data
137 *
138 * Returns: The control register value equivalent of @control.
139 */
img_ir_control(const struct img_ir_control * control)140 static u32 img_ir_control(const struct img_ir_control *control)
141 {
142 u32 ctrl = control->code_type << IMG_IR_CODETYPE_SHIFT;
143 if (control->decoden)
144 ctrl |= IMG_IR_DECODEN;
145 if (control->hdrtog)
146 ctrl |= IMG_IR_HDRTOG;
147 if (control->ldrdec)
148 ctrl |= IMG_IR_LDRDEC;
149 if (control->decodinpol)
150 ctrl |= IMG_IR_DECODINPOL;
151 if (control->bitorien)
152 ctrl |= IMG_IR_BITORIEN;
153 if (control->d1validsel)
154 ctrl |= IMG_IR_D1VALIDSEL;
155 if (control->bitinv)
156 ctrl |= IMG_IR_BITINV;
157 if (control->decodend2)
158 ctrl |= IMG_IR_DECODEND2;
159 if (control->bitoriend2)
160 ctrl |= IMG_IR_BITORIEND2;
161 if (control->bitinvd2)
162 ctrl |= IMG_IR_BITINVD2;
163 return ctrl;
164 }
165
166 /**
167 * img_ir_timing_range_convert() - Convert microsecond range.
168 * @out: Output timing range in clock cycles with a shift.
169 * @in: Input timing range in microseconds.
170 * @tolerance: Tolerance as a fraction of 128 (roughly percent).
171 * @clock_hz: IR clock rate in Hz.
172 * @shift: Shift of output units.
173 *
174 * Converts min and max from microseconds to IR clock cycles, applies a
175 * tolerance, and shifts for the register, rounding in the right direction.
176 * Note that in and out can safely be the same object.
177 */
img_ir_timing_range_convert(struct img_ir_timing_range * out,const struct img_ir_timing_range * in,unsigned int tolerance,unsigned long clock_hz,unsigned int shift)178 static void img_ir_timing_range_convert(struct img_ir_timing_range *out,
179 const struct img_ir_timing_range *in,
180 unsigned int tolerance,
181 unsigned long clock_hz,
182 unsigned int shift)
183 {
184 unsigned int min = in->min;
185 unsigned int max = in->max;
186 /* add a tolerance */
187 min = min - (min*tolerance >> 7);
188 max = max + (max*tolerance >> 7);
189 /* convert from microseconds into clock cycles */
190 min = min*clock_hz / 1000000;
191 max = (max*clock_hz + 999999) / 1000000; /* round up */
192 /* apply shift and copy to output */
193 out->min = min >> shift;
194 out->max = (max + ((1 << shift) - 1)) >> shift; /* round up */
195 }
196
197 /**
198 * img_ir_symbol_timing() - Convert symbol timing struct to register value.
199 * @timing: Symbol timing data
200 * @tolerance: Timing tolerance where 0-128 represents 0-100%
201 * @clock_hz: Frequency of source clock in Hz
202 * @pd_shift: Shift to apply to symbol period
203 * @w_shift: Shift to apply to symbol width
204 *
205 * Returns: Symbol timing register value based on arguments.
206 */
img_ir_symbol_timing(const struct img_ir_symbol_timing * timing,unsigned int tolerance,unsigned long clock_hz,unsigned int pd_shift,unsigned int w_shift)207 static u32 img_ir_symbol_timing(const struct img_ir_symbol_timing *timing,
208 unsigned int tolerance,
209 unsigned long clock_hz,
210 unsigned int pd_shift,
211 unsigned int w_shift)
212 {
213 struct img_ir_timing_range hw_pulse, hw_period;
214 /* we calculate period in hw_period, then convert in place */
215 hw_period.min = timing->pulse.min + timing->space.min;
216 hw_period.max = timing->pulse.max + timing->space.max;
217 img_ir_timing_range_convert(&hw_period, &hw_period,
218 tolerance, clock_hz, pd_shift);
219 img_ir_timing_range_convert(&hw_pulse, &timing->pulse,
220 tolerance, clock_hz, w_shift);
221 /* construct register value */
222 return (hw_period.max << IMG_IR_PD_MAX_SHIFT) |
223 (hw_period.min << IMG_IR_PD_MIN_SHIFT) |
224 (hw_pulse.max << IMG_IR_W_MAX_SHIFT) |
225 (hw_pulse.min << IMG_IR_W_MIN_SHIFT);
226 }
227
228 /**
229 * img_ir_free_timing() - Convert free time timing struct to register value.
230 * @timing: Free symbol timing data
231 * @clock_hz: Source clock frequency in Hz
232 *
233 * Returns: Free symbol timing register value.
234 */
img_ir_free_timing(const struct img_ir_free_timing * timing,unsigned long clock_hz)235 static u32 img_ir_free_timing(const struct img_ir_free_timing *timing,
236 unsigned long clock_hz)
237 {
238 unsigned int minlen, maxlen, ft_min;
239 /* minlen is only 5 bits, and round minlen to multiple of 2 */
240 if (timing->minlen < 30)
241 minlen = timing->minlen & -2;
242 else
243 minlen = 30;
244 /* maxlen has maximum value of 48, and round maxlen to multiple of 2 */
245 if (timing->maxlen < 48)
246 maxlen = (timing->maxlen + 1) & -2;
247 else
248 maxlen = 48;
249 /* convert and shift ft_min, rounding upwards */
250 ft_min = (timing->ft_min*clock_hz + 999999) / 1000000;
251 ft_min = (ft_min + 7) >> 3;
252 /* construct register value */
253 return (maxlen << IMG_IR_MAXLEN_SHIFT) |
254 (minlen << IMG_IR_MINLEN_SHIFT) |
255 (ft_min << IMG_IR_FT_MIN_SHIFT);
256 }
257
258 /**
259 * img_ir_free_timing_dynamic() - Update free time register value.
260 * @st_ft: Static free time register value from img_ir_free_timing.
261 * @filter: Current filter which may additionally restrict min/max len.
262 *
263 * Returns: Updated free time register value based on the current filter.
264 */
img_ir_free_timing_dynamic(u32 st_ft,struct img_ir_filter * filter)265 static u32 img_ir_free_timing_dynamic(u32 st_ft, struct img_ir_filter *filter)
266 {
267 unsigned int minlen, maxlen, newminlen, newmaxlen;
268
269 /* round minlen, maxlen to multiple of 2 */
270 newminlen = filter->minlen & -2;
271 newmaxlen = (filter->maxlen + 1) & -2;
272 /* extract min/max len from register */
273 minlen = (st_ft & IMG_IR_MINLEN) >> IMG_IR_MINLEN_SHIFT;
274 maxlen = (st_ft & IMG_IR_MAXLEN) >> IMG_IR_MAXLEN_SHIFT;
275 /* if the new values are more restrictive, update the register value */
276 if (newminlen > minlen) {
277 st_ft &= ~IMG_IR_MINLEN;
278 st_ft |= newminlen << IMG_IR_MINLEN_SHIFT;
279 }
280 if (newmaxlen < maxlen) {
281 st_ft &= ~IMG_IR_MAXLEN;
282 st_ft |= newmaxlen << IMG_IR_MAXLEN_SHIFT;
283 }
284 return st_ft;
285 }
286
287 /**
288 * img_ir_timings_convert() - Convert timings to register values
289 * @regs: Output timing register values
290 * @timings: Input timing data
291 * @tolerance: Timing tolerance where 0-128 represents 0-100%
292 * @clock_hz: Source clock frequency in Hz
293 */
img_ir_timings_convert(struct img_ir_timing_regvals * regs,const struct img_ir_timings * timings,unsigned int tolerance,unsigned int clock_hz)294 static void img_ir_timings_convert(struct img_ir_timing_regvals *regs,
295 const struct img_ir_timings *timings,
296 unsigned int tolerance,
297 unsigned int clock_hz)
298 {
299 /* leader symbol timings are divided by 16 */
300 regs->ldr = img_ir_symbol_timing(&timings->ldr, tolerance, clock_hz,
301 4, 4);
302 /* other symbol timings, pd fields only are divided by 2 */
303 regs->s00 = img_ir_symbol_timing(&timings->s00, tolerance, clock_hz,
304 1, 0);
305 regs->s01 = img_ir_symbol_timing(&timings->s01, tolerance, clock_hz,
306 1, 0);
307 regs->s10 = img_ir_symbol_timing(&timings->s10, tolerance, clock_hz,
308 1, 0);
309 regs->s11 = img_ir_symbol_timing(&timings->s11, tolerance, clock_hz,
310 1, 0);
311 regs->ft = img_ir_free_timing(&timings->ft, clock_hz);
312 }
313
314 /**
315 * img_ir_decoder_preprocess() - Preprocess timings in decoder.
316 * @decoder: Decoder to be preprocessed.
317 *
318 * Ensures that the symbol timing ranges are valid with respect to ordering, and
319 * does some fixed conversion on them.
320 */
img_ir_decoder_preprocess(struct img_ir_decoder * decoder)321 static void img_ir_decoder_preprocess(struct img_ir_decoder *decoder)
322 {
323 /* default tolerance */
324 if (!decoder->tolerance)
325 decoder->tolerance = 10; /* percent */
326 /* and convert tolerance to fraction out of 128 */
327 decoder->tolerance = decoder->tolerance * 128 / 100;
328
329 /* fill in implicit fields */
330 img_ir_timings_preprocess(&decoder->timings, decoder->unit);
331
332 /* do the same for repeat timings if applicable */
333 if (decoder->repeat) {
334 img_ir_timings_preprocess(&decoder->rtimings, decoder->unit);
335 img_ir_timings_defaults(&decoder->rtimings, &decoder->timings);
336 }
337 }
338
339 /**
340 * img_ir_decoder_convert() - Generate internal timings in decoder.
341 * @decoder: Decoder to be converted to internal timings.
342 * @timings: Timing register values.
343 * @clock_hz: IR clock rate in Hz.
344 *
345 * Fills out the repeat timings and timing register values for a specific clock
346 * rate.
347 */
img_ir_decoder_convert(const struct img_ir_decoder * decoder,struct img_ir_reg_timings * reg_timings,unsigned int clock_hz)348 static void img_ir_decoder_convert(const struct img_ir_decoder *decoder,
349 struct img_ir_reg_timings *reg_timings,
350 unsigned int clock_hz)
351 {
352 /* calculate control value */
353 reg_timings->ctrl = img_ir_control(&decoder->control);
354
355 /* fill in implicit fields and calculate register values */
356 img_ir_timings_convert(®_timings->timings, &decoder->timings,
357 decoder->tolerance, clock_hz);
358
359 /* do the same for repeat timings if applicable */
360 if (decoder->repeat)
361 img_ir_timings_convert(®_timings->rtimings,
362 &decoder->rtimings, decoder->tolerance,
363 clock_hz);
364 }
365
366 /**
367 * img_ir_write_timings() - Write timings to the hardware now
368 * @priv: IR private data
369 * @regs: Timing register values to write
370 * @type: RC filter type (RC_FILTER_*)
371 *
372 * Write timing register values @regs to the hardware, taking into account the
373 * current filter which may impose restrictions on the length of the expected
374 * data.
375 */
img_ir_write_timings(struct img_ir_priv * priv,struct img_ir_timing_regvals * regs,enum rc_filter_type type)376 static void img_ir_write_timings(struct img_ir_priv *priv,
377 struct img_ir_timing_regvals *regs,
378 enum rc_filter_type type)
379 {
380 struct img_ir_priv_hw *hw = &priv->hw;
381
382 /* filter may be more restrictive to minlen, maxlen */
383 u32 ft = regs->ft;
384 if (hw->flags & BIT(type))
385 ft = img_ir_free_timing_dynamic(regs->ft, &hw->filters[type]);
386 /* write to registers */
387 img_ir_write(priv, IMG_IR_LEAD_SYMB_TIMING, regs->ldr);
388 img_ir_write(priv, IMG_IR_S00_SYMB_TIMING, regs->s00);
389 img_ir_write(priv, IMG_IR_S01_SYMB_TIMING, regs->s01);
390 img_ir_write(priv, IMG_IR_S10_SYMB_TIMING, regs->s10);
391 img_ir_write(priv, IMG_IR_S11_SYMB_TIMING, regs->s11);
392 img_ir_write(priv, IMG_IR_FREE_SYMB_TIMING, ft);
393 dev_dbg(priv->dev, "timings: ldr=%#x, s=[%#x, %#x, %#x, %#x], ft=%#x\n",
394 regs->ldr, regs->s00, regs->s01, regs->s10, regs->s11, ft);
395 }
396
img_ir_write_filter(struct img_ir_priv * priv,struct img_ir_filter * filter)397 static void img_ir_write_filter(struct img_ir_priv *priv,
398 struct img_ir_filter *filter)
399 {
400 if (filter) {
401 dev_dbg(priv->dev, "IR filter=%016llx & %016llx\n",
402 (unsigned long long)filter->data,
403 (unsigned long long)filter->mask);
404 img_ir_write(priv, IMG_IR_IRQ_MSG_DATA_LW, (u32)filter->data);
405 img_ir_write(priv, IMG_IR_IRQ_MSG_DATA_UP, (u32)(filter->data
406 >> 32));
407 img_ir_write(priv, IMG_IR_IRQ_MSG_MASK_LW, (u32)filter->mask);
408 img_ir_write(priv, IMG_IR_IRQ_MSG_MASK_UP, (u32)(filter->mask
409 >> 32));
410 } else {
411 dev_dbg(priv->dev, "IR clearing filter\n");
412 img_ir_write(priv, IMG_IR_IRQ_MSG_MASK_LW, 0);
413 img_ir_write(priv, IMG_IR_IRQ_MSG_MASK_UP, 0);
414 }
415 }
416
417 /* caller must have lock */
_img_ir_set_filter(struct img_ir_priv * priv,struct img_ir_filter * filter)418 static void _img_ir_set_filter(struct img_ir_priv *priv,
419 struct img_ir_filter *filter)
420 {
421 struct img_ir_priv_hw *hw = &priv->hw;
422 u32 irq_en, irq_on;
423
424 irq_en = img_ir_read(priv, IMG_IR_IRQ_ENABLE);
425 if (filter) {
426 /* Only use the match interrupt */
427 hw->filters[RC_FILTER_NORMAL] = *filter;
428 hw->flags |= IMG_IR_F_FILTER;
429 irq_on = IMG_IR_IRQ_DATA_MATCH;
430 irq_en &= ~(IMG_IR_IRQ_DATA_VALID | IMG_IR_IRQ_DATA2_VALID);
431 } else {
432 /* Only use the valid interrupt */
433 hw->flags &= ~IMG_IR_F_FILTER;
434 irq_en &= ~IMG_IR_IRQ_DATA_MATCH;
435 irq_on = IMG_IR_IRQ_DATA_VALID | IMG_IR_IRQ_DATA2_VALID;
436 }
437 irq_en |= irq_on;
438
439 img_ir_write_filter(priv, filter);
440 /* clear any interrupts we're enabling so we don't handle old ones */
441 img_ir_write(priv, IMG_IR_IRQ_CLEAR, irq_on);
442 img_ir_write(priv, IMG_IR_IRQ_ENABLE, irq_en);
443 }
444
445 /* caller must have lock */
_img_ir_set_wake_filter(struct img_ir_priv * priv,struct img_ir_filter * filter)446 static void _img_ir_set_wake_filter(struct img_ir_priv *priv,
447 struct img_ir_filter *filter)
448 {
449 struct img_ir_priv_hw *hw = &priv->hw;
450 if (filter) {
451 /* Enable wake, and copy filter for later */
452 hw->filters[RC_FILTER_WAKEUP] = *filter;
453 hw->flags |= IMG_IR_F_WAKE;
454 } else {
455 /* Disable wake */
456 hw->flags &= ~IMG_IR_F_WAKE;
457 }
458 }
459
460 /* Callback for setting scancode filter */
img_ir_set_filter(struct rc_dev * dev,enum rc_filter_type type,struct rc_scancode_filter * sc_filter)461 static int img_ir_set_filter(struct rc_dev *dev, enum rc_filter_type type,
462 struct rc_scancode_filter *sc_filter)
463 {
464 struct img_ir_priv *priv = dev->priv;
465 struct img_ir_priv_hw *hw = &priv->hw;
466 struct img_ir_filter filter, *filter_ptr = &filter;
467 int ret = 0;
468
469 dev_dbg(priv->dev, "IR scancode %sfilter=%08x & %08x\n",
470 type == RC_FILTER_WAKEUP ? "wake " : "",
471 sc_filter->data,
472 sc_filter->mask);
473
474 spin_lock_irq(&priv->lock);
475
476 /* filtering can always be disabled */
477 if (!sc_filter->mask) {
478 filter_ptr = NULL;
479 goto set_unlock;
480 }
481
482 /* current decoder must support scancode filtering */
483 if (!hw->decoder || !hw->decoder->filter) {
484 ret = -EINVAL;
485 goto unlock;
486 }
487
488 /* convert scancode filter to raw filter */
489 filter.minlen = 0;
490 filter.maxlen = ~0;
491 ret = hw->decoder->filter(sc_filter, &filter, hw->enabled_protocols);
492 if (ret)
493 goto unlock;
494 dev_dbg(priv->dev, "IR raw %sfilter=%016llx & %016llx\n",
495 type == RC_FILTER_WAKEUP ? "wake " : "",
496 (unsigned long long)filter.data,
497 (unsigned long long)filter.mask);
498
499 set_unlock:
500 /* apply raw filters */
501 switch (type) {
502 case RC_FILTER_NORMAL:
503 _img_ir_set_filter(priv, filter_ptr);
504 break;
505 case RC_FILTER_WAKEUP:
506 _img_ir_set_wake_filter(priv, filter_ptr);
507 break;
508 default:
509 ret = -EINVAL;
510 }
511
512 unlock:
513 spin_unlock_irq(&priv->lock);
514 return ret;
515 }
516
img_ir_set_normal_filter(struct rc_dev * dev,struct rc_scancode_filter * sc_filter)517 static int img_ir_set_normal_filter(struct rc_dev *dev,
518 struct rc_scancode_filter *sc_filter)
519 {
520 return img_ir_set_filter(dev, RC_FILTER_NORMAL, sc_filter);
521 }
522
img_ir_set_wakeup_filter(struct rc_dev * dev,struct rc_scancode_filter * sc_filter)523 static int img_ir_set_wakeup_filter(struct rc_dev *dev,
524 struct rc_scancode_filter *sc_filter)
525 {
526 return img_ir_set_filter(dev, RC_FILTER_WAKEUP, sc_filter);
527 }
528
529 /**
530 * img_ir_set_decoder() - Set the current decoder.
531 * @priv: IR private data.
532 * @decoder: Decoder to use with immediate effect.
533 * @proto: Protocol bitmap (or 0 to use decoder->type).
534 */
img_ir_set_decoder(struct img_ir_priv * priv,const struct img_ir_decoder * decoder,u64 proto)535 static void img_ir_set_decoder(struct img_ir_priv *priv,
536 const struct img_ir_decoder *decoder,
537 u64 proto)
538 {
539 struct img_ir_priv_hw *hw = &priv->hw;
540 struct rc_dev *rdev = hw->rdev;
541 u32 ir_status, irq_en;
542 spin_lock_irq(&priv->lock);
543
544 /*
545 * First record that the protocol is being stopped so that the end timer
546 * isn't restarted while we're trying to stop it.
547 */
548 hw->stopping = true;
549
550 /*
551 * Release the lock to stop the end timer, since the end timer handler
552 * acquires the lock and we don't want to deadlock waiting for it.
553 */
554 spin_unlock_irq(&priv->lock);
555 del_timer_sync(&hw->end_timer);
556 del_timer_sync(&hw->suspend_timer);
557 spin_lock_irq(&priv->lock);
558
559 hw->stopping = false;
560
561 /* switch off and disable interrupts */
562 img_ir_write(priv, IMG_IR_CONTROL, 0);
563 irq_en = img_ir_read(priv, IMG_IR_IRQ_ENABLE);
564 img_ir_write(priv, IMG_IR_IRQ_ENABLE, irq_en & IMG_IR_IRQ_EDGE);
565 img_ir_write(priv, IMG_IR_IRQ_CLEAR, IMG_IR_IRQ_ALL & ~IMG_IR_IRQ_EDGE);
566
567 /* ack any data already detected */
568 ir_status = img_ir_read(priv, IMG_IR_STATUS);
569 if (ir_status & (IMG_IR_RXDVAL | IMG_IR_RXDVALD2)) {
570 ir_status &= ~(IMG_IR_RXDVAL | IMG_IR_RXDVALD2);
571 img_ir_write(priv, IMG_IR_STATUS, ir_status);
572 }
573
574 /* always read data to clear buffer if IR wakes the device */
575 img_ir_read(priv, IMG_IR_DATA_LW);
576 img_ir_read(priv, IMG_IR_DATA_UP);
577
578 /* switch back to normal mode */
579 hw->mode = IMG_IR_M_NORMAL;
580
581 /* clear the wakeup scancode filter */
582 rdev->scancode_wakeup_filter.data = 0;
583 rdev->scancode_wakeup_filter.mask = 0;
584
585 /* clear raw filters */
586 _img_ir_set_filter(priv, NULL);
587 _img_ir_set_wake_filter(priv, NULL);
588
589 /* clear the enabled protocols */
590 hw->enabled_protocols = 0;
591
592 /* switch decoder */
593 hw->decoder = decoder;
594 if (!decoder)
595 goto unlock;
596
597 /* set the enabled protocols */
598 if (!proto)
599 proto = decoder->type;
600 hw->enabled_protocols = proto;
601
602 /* write the new timings */
603 img_ir_decoder_convert(decoder, &hw->reg_timings, hw->clk_hz);
604 img_ir_write_timings(priv, &hw->reg_timings.timings, RC_FILTER_NORMAL);
605
606 /* set up and enable */
607 img_ir_write(priv, IMG_IR_CONTROL, hw->reg_timings.ctrl);
608
609
610 unlock:
611 spin_unlock_irq(&priv->lock);
612 }
613
614 /**
615 * img_ir_decoder_compatable() - Find whether a decoder will work with a device.
616 * @priv: IR private data.
617 * @dec: Decoder to check.
618 *
619 * Returns: true if @dec is compatible with the device @priv refers to.
620 */
img_ir_decoder_compatible(struct img_ir_priv * priv,const struct img_ir_decoder * dec)621 static bool img_ir_decoder_compatible(struct img_ir_priv *priv,
622 const struct img_ir_decoder *dec)
623 {
624 unsigned int ct;
625
626 /* don't accept decoders using code types which aren't supported */
627 ct = dec->control.code_type;
628 if (priv->hw.ct_quirks[ct] & IMG_IR_QUIRK_CODE_BROKEN)
629 return false;
630
631 return true;
632 }
633
634 /**
635 * img_ir_allowed_protos() - Get allowed protocols from global decoder list.
636 * @priv: IR private data.
637 *
638 * Returns: Mask of protocols supported by the device @priv refers to.
639 */
img_ir_allowed_protos(struct img_ir_priv * priv)640 static u64 img_ir_allowed_protos(struct img_ir_priv *priv)
641 {
642 u64 protos = 0;
643 struct img_ir_decoder **decp;
644
645 for (decp = img_ir_decoders; *decp; ++decp) {
646 const struct img_ir_decoder *dec = *decp;
647 if (img_ir_decoder_compatible(priv, dec))
648 protos |= dec->type;
649 }
650 return protos;
651 }
652
653 /* Callback for changing protocol using sysfs */
img_ir_change_protocol(struct rc_dev * dev,u64 * ir_type)654 static int img_ir_change_protocol(struct rc_dev *dev, u64 *ir_type)
655 {
656 struct img_ir_priv *priv = dev->priv;
657 struct img_ir_priv_hw *hw = &priv->hw;
658 struct rc_dev *rdev = hw->rdev;
659 struct img_ir_decoder **decp;
660 u64 wakeup_protocols;
661
662 if (!*ir_type) {
663 /* disable all protocols */
664 img_ir_set_decoder(priv, NULL, 0);
665 goto success;
666 }
667 for (decp = img_ir_decoders; *decp; ++decp) {
668 const struct img_ir_decoder *dec = *decp;
669 if (!img_ir_decoder_compatible(priv, dec))
670 continue;
671 if (*ir_type & dec->type) {
672 *ir_type &= dec->type;
673 img_ir_set_decoder(priv, dec, *ir_type);
674 goto success;
675 }
676 }
677 return -EINVAL;
678
679 success:
680 /*
681 * Only allow matching wakeup protocols for now, and only if filtering
682 * is supported.
683 */
684 wakeup_protocols = *ir_type;
685 if (!hw->decoder || !hw->decoder->filter)
686 wakeup_protocols = 0;
687 rdev->allowed_wakeup_protocols = wakeup_protocols;
688 rdev->enabled_wakeup_protocols = wakeup_protocols;
689 return 0;
690 }
691
692 /* Changes ir-core protocol device attribute */
img_ir_set_protocol(struct img_ir_priv * priv,u64 proto)693 static void img_ir_set_protocol(struct img_ir_priv *priv, u64 proto)
694 {
695 struct rc_dev *rdev = priv->hw.rdev;
696
697 spin_lock_irq(&rdev->rc_map.lock);
698 rdev->rc_map.rc_type = __ffs64(proto);
699 spin_unlock_irq(&rdev->rc_map.lock);
700
701 mutex_lock(&rdev->lock);
702 rdev->enabled_protocols = proto;
703 rdev->allowed_wakeup_protocols = proto;
704 rdev->enabled_wakeup_protocols = proto;
705 mutex_unlock(&rdev->lock);
706 }
707
708 /* Set up IR decoders */
img_ir_init_decoders(void)709 static void img_ir_init_decoders(void)
710 {
711 struct img_ir_decoder **decp;
712
713 spin_lock(&img_ir_decoders_lock);
714 if (!img_ir_decoders_preprocessed) {
715 for (decp = img_ir_decoders; *decp; ++decp)
716 img_ir_decoder_preprocess(*decp);
717 img_ir_decoders_preprocessed = true;
718 }
719 spin_unlock(&img_ir_decoders_lock);
720 }
721
722 #ifdef CONFIG_PM_SLEEP
723 /**
724 * img_ir_enable_wake() - Switch to wake mode.
725 * @priv: IR private data.
726 *
727 * Returns: non-zero if the IR can wake the system.
728 */
img_ir_enable_wake(struct img_ir_priv * priv)729 static int img_ir_enable_wake(struct img_ir_priv *priv)
730 {
731 struct img_ir_priv_hw *hw = &priv->hw;
732 int ret = 0;
733
734 spin_lock_irq(&priv->lock);
735 if (hw->flags & IMG_IR_F_WAKE) {
736 /* interrupt only on a match */
737 hw->suspend_irqen = img_ir_read(priv, IMG_IR_IRQ_ENABLE);
738 img_ir_write(priv, IMG_IR_IRQ_ENABLE, IMG_IR_IRQ_DATA_MATCH);
739 img_ir_write_filter(priv, &hw->filters[RC_FILTER_WAKEUP]);
740 img_ir_write_timings(priv, &hw->reg_timings.timings,
741 RC_FILTER_WAKEUP);
742 hw->mode = IMG_IR_M_WAKE;
743 ret = 1;
744 }
745 spin_unlock_irq(&priv->lock);
746 return ret;
747 }
748
749 /**
750 * img_ir_disable_wake() - Switch out of wake mode.
751 * @priv: IR private data
752 *
753 * Returns: 1 if the hardware should be allowed to wake from a sleep state.
754 * 0 otherwise.
755 */
img_ir_disable_wake(struct img_ir_priv * priv)756 static int img_ir_disable_wake(struct img_ir_priv *priv)
757 {
758 struct img_ir_priv_hw *hw = &priv->hw;
759 int ret = 0;
760
761 spin_lock_irq(&priv->lock);
762 if (hw->flags & IMG_IR_F_WAKE) {
763 /* restore normal filtering */
764 if (hw->flags & IMG_IR_F_FILTER) {
765 img_ir_write(priv, IMG_IR_IRQ_ENABLE,
766 (hw->suspend_irqen & IMG_IR_IRQ_EDGE) |
767 IMG_IR_IRQ_DATA_MATCH);
768 img_ir_write_filter(priv,
769 &hw->filters[RC_FILTER_NORMAL]);
770 } else {
771 img_ir_write(priv, IMG_IR_IRQ_ENABLE,
772 (hw->suspend_irqen & IMG_IR_IRQ_EDGE) |
773 IMG_IR_IRQ_DATA_VALID |
774 IMG_IR_IRQ_DATA2_VALID);
775 img_ir_write_filter(priv, NULL);
776 }
777 img_ir_write_timings(priv, &hw->reg_timings.timings,
778 RC_FILTER_NORMAL);
779 hw->mode = IMG_IR_M_NORMAL;
780 ret = 1;
781 }
782 spin_unlock_irq(&priv->lock);
783 return ret;
784 }
785 #endif /* CONFIG_PM_SLEEP */
786
787 /* lock must be held */
img_ir_begin_repeat(struct img_ir_priv * priv)788 static void img_ir_begin_repeat(struct img_ir_priv *priv)
789 {
790 struct img_ir_priv_hw *hw = &priv->hw;
791 if (hw->mode == IMG_IR_M_NORMAL) {
792 /* switch to repeat timings */
793 img_ir_write(priv, IMG_IR_CONTROL, 0);
794 hw->mode = IMG_IR_M_REPEATING;
795 img_ir_write_timings(priv, &hw->reg_timings.rtimings,
796 RC_FILTER_NORMAL);
797 img_ir_write(priv, IMG_IR_CONTROL, hw->reg_timings.ctrl);
798 }
799 }
800
801 /* lock must be held */
img_ir_end_repeat(struct img_ir_priv * priv)802 static void img_ir_end_repeat(struct img_ir_priv *priv)
803 {
804 struct img_ir_priv_hw *hw = &priv->hw;
805 if (hw->mode == IMG_IR_M_REPEATING) {
806 /* switch to normal timings */
807 img_ir_write(priv, IMG_IR_CONTROL, 0);
808 hw->mode = IMG_IR_M_NORMAL;
809 img_ir_write_timings(priv, &hw->reg_timings.timings,
810 RC_FILTER_NORMAL);
811 img_ir_write(priv, IMG_IR_CONTROL, hw->reg_timings.ctrl);
812 }
813 }
814
815 /* lock must be held */
img_ir_handle_data(struct img_ir_priv * priv,u32 len,u64 raw)816 static void img_ir_handle_data(struct img_ir_priv *priv, u32 len, u64 raw)
817 {
818 struct img_ir_priv_hw *hw = &priv->hw;
819 const struct img_ir_decoder *dec = hw->decoder;
820 int ret = IMG_IR_SCANCODE;
821 struct img_ir_scancode_req request;
822
823 request.protocol = RC_TYPE_UNKNOWN;
824 request.toggle = 0;
825
826 if (dec->scancode)
827 ret = dec->scancode(len, raw, hw->enabled_protocols, &request);
828 else if (len >= 32)
829 request.scancode = (u32)raw;
830 else if (len < 32)
831 request.scancode = (u32)raw & ((1 << len)-1);
832 dev_dbg(priv->dev, "data (%u bits) = %#llx\n",
833 len, (unsigned long long)raw);
834 if (ret == IMG_IR_SCANCODE) {
835 dev_dbg(priv->dev, "decoded scan code %#x, toggle %u\n",
836 request.scancode, request.toggle);
837 rc_keydown(hw->rdev, request.protocol, request.scancode,
838 request.toggle);
839 img_ir_end_repeat(priv);
840 } else if (ret == IMG_IR_REPEATCODE) {
841 if (hw->mode == IMG_IR_M_REPEATING) {
842 dev_dbg(priv->dev, "decoded repeat code\n");
843 rc_repeat(hw->rdev);
844 } else {
845 dev_dbg(priv->dev, "decoded unexpected repeat code, ignoring\n");
846 }
847 } else {
848 dev_dbg(priv->dev, "decode failed (%d)\n", ret);
849 return;
850 }
851
852
853 /* we mustn't update the end timer while trying to stop it */
854 if (dec->repeat && !hw->stopping) {
855 unsigned long interval;
856
857 img_ir_begin_repeat(priv);
858
859 /* update timer, but allowing for 1/8th tolerance */
860 interval = dec->repeat + (dec->repeat >> 3);
861 mod_timer(&hw->end_timer,
862 jiffies + msecs_to_jiffies(interval));
863 }
864 }
865
866 /* timer function to end waiting for repeat. */
img_ir_end_timer(unsigned long arg)867 static void img_ir_end_timer(unsigned long arg)
868 {
869 struct img_ir_priv *priv = (struct img_ir_priv *)arg;
870
871 spin_lock_irq(&priv->lock);
872 img_ir_end_repeat(priv);
873 spin_unlock_irq(&priv->lock);
874 }
875
876 /*
877 * Timer function to re-enable the current protocol after it had been
878 * cleared when invalid interrupts were generated due to a quirk in the
879 * img-ir decoder.
880 */
img_ir_suspend_timer(unsigned long arg)881 static void img_ir_suspend_timer(unsigned long arg)
882 {
883 struct img_ir_priv *priv = (struct img_ir_priv *)arg;
884
885 spin_lock_irq(&priv->lock);
886 /*
887 * Don't overwrite enabled valid/match IRQs if they have already been
888 * changed by e.g. a filter change.
889 */
890 if ((priv->hw.quirk_suspend_irq & IMG_IR_IRQ_EDGE) ==
891 img_ir_read(priv, IMG_IR_IRQ_ENABLE))
892 img_ir_write(priv, IMG_IR_IRQ_ENABLE,
893 priv->hw.quirk_suspend_irq);
894 /* enable */
895 img_ir_write(priv, IMG_IR_CONTROL, priv->hw.reg_timings.ctrl);
896 spin_unlock_irq(&priv->lock);
897 }
898
899 #ifdef CONFIG_COMMON_CLK
img_ir_change_frequency(struct img_ir_priv * priv,struct clk_notifier_data * change)900 static void img_ir_change_frequency(struct img_ir_priv *priv,
901 struct clk_notifier_data *change)
902 {
903 struct img_ir_priv_hw *hw = &priv->hw;
904
905 dev_dbg(priv->dev, "clk changed %lu HZ -> %lu HZ\n",
906 change->old_rate, change->new_rate);
907
908 spin_lock_irq(&priv->lock);
909 if (hw->clk_hz == change->new_rate)
910 goto unlock;
911 hw->clk_hz = change->new_rate;
912 /* refresh current timings */
913 if (hw->decoder) {
914 img_ir_decoder_convert(hw->decoder, &hw->reg_timings,
915 hw->clk_hz);
916 switch (hw->mode) {
917 case IMG_IR_M_NORMAL:
918 img_ir_write_timings(priv, &hw->reg_timings.timings,
919 RC_FILTER_NORMAL);
920 break;
921 case IMG_IR_M_REPEATING:
922 img_ir_write_timings(priv, &hw->reg_timings.rtimings,
923 RC_FILTER_NORMAL);
924 break;
925 #ifdef CONFIG_PM_SLEEP
926 case IMG_IR_M_WAKE:
927 img_ir_write_timings(priv, &hw->reg_timings.timings,
928 RC_FILTER_WAKEUP);
929 break;
930 #endif
931 }
932 }
933 unlock:
934 spin_unlock_irq(&priv->lock);
935 }
936
img_ir_clk_notify(struct notifier_block * self,unsigned long action,void * data)937 static int img_ir_clk_notify(struct notifier_block *self, unsigned long action,
938 void *data)
939 {
940 struct img_ir_priv *priv = container_of(self, struct img_ir_priv,
941 hw.clk_nb);
942 switch (action) {
943 case POST_RATE_CHANGE:
944 img_ir_change_frequency(priv, data);
945 break;
946 default:
947 break;
948 }
949 return NOTIFY_OK;
950 }
951 #endif /* CONFIG_COMMON_CLK */
952
953 /* called with priv->lock held */
img_ir_isr_hw(struct img_ir_priv * priv,u32 irq_status)954 void img_ir_isr_hw(struct img_ir_priv *priv, u32 irq_status)
955 {
956 struct img_ir_priv_hw *hw = &priv->hw;
957 u32 ir_status, len, lw, up;
958 unsigned int ct;
959
960 /* use the current decoder */
961 if (!hw->decoder)
962 return;
963
964 ct = hw->decoder->control.code_type;
965
966 ir_status = img_ir_read(priv, IMG_IR_STATUS);
967 if (!(ir_status & (IMG_IR_RXDVAL | IMG_IR_RXDVALD2))) {
968 if (!(priv->hw.ct_quirks[ct] & IMG_IR_QUIRK_CODE_IRQ) ||
969 hw->stopping)
970 return;
971 /*
972 * The below functionality is added as a work around to stop
973 * multiple Interrupts generated when an incomplete IR code is
974 * received by the decoder.
975 * The decoder generates rapid interrupts without actually
976 * having received any new data. After a single interrupt it's
977 * expected to clear up, but instead multiple interrupts are
978 * rapidly generated. only way to get out of this loop is to
979 * reset the control register after a short delay.
980 */
981 img_ir_write(priv, IMG_IR_CONTROL, 0);
982 hw->quirk_suspend_irq = img_ir_read(priv, IMG_IR_IRQ_ENABLE);
983 img_ir_write(priv, IMG_IR_IRQ_ENABLE,
984 hw->quirk_suspend_irq & IMG_IR_IRQ_EDGE);
985
986 /* Timer activated to re-enable the protocol. */
987 mod_timer(&hw->suspend_timer,
988 jiffies + msecs_to_jiffies(5));
989 return;
990 }
991 ir_status &= ~(IMG_IR_RXDVAL | IMG_IR_RXDVALD2);
992 img_ir_write(priv, IMG_IR_STATUS, ir_status);
993
994 len = (ir_status & IMG_IR_RXDLEN) >> IMG_IR_RXDLEN_SHIFT;
995 /* some versions report wrong length for certain code types */
996 if (hw->ct_quirks[ct] & IMG_IR_QUIRK_CODE_LEN_INCR)
997 ++len;
998
999 lw = img_ir_read(priv, IMG_IR_DATA_LW);
1000 up = img_ir_read(priv, IMG_IR_DATA_UP);
1001 img_ir_handle_data(priv, len, (u64)up << 32 | lw);
1002 }
1003
img_ir_setup_hw(struct img_ir_priv * priv)1004 void img_ir_setup_hw(struct img_ir_priv *priv)
1005 {
1006 struct img_ir_decoder **decp;
1007
1008 if (!priv->hw.rdev)
1009 return;
1010
1011 /* Use the first available decoder (or disable stuff if NULL) */
1012 for (decp = img_ir_decoders; *decp; ++decp) {
1013 const struct img_ir_decoder *dec = *decp;
1014 if (img_ir_decoder_compatible(priv, dec)) {
1015 img_ir_set_protocol(priv, dec->type);
1016 img_ir_set_decoder(priv, dec, 0);
1017 return;
1018 }
1019 }
1020 img_ir_set_decoder(priv, NULL, 0);
1021 }
1022
1023 /**
1024 * img_ir_probe_hw_caps() - Probe capabilities of the hardware.
1025 * @priv: IR private data.
1026 */
img_ir_probe_hw_caps(struct img_ir_priv * priv)1027 static void img_ir_probe_hw_caps(struct img_ir_priv *priv)
1028 {
1029 struct img_ir_priv_hw *hw = &priv->hw;
1030 /*
1031 * When a version of the block becomes available without these quirks,
1032 * they'll have to depend on the core revision.
1033 */
1034 hw->ct_quirks[IMG_IR_CODETYPE_PULSELEN]
1035 |= IMG_IR_QUIRK_CODE_LEN_INCR;
1036 hw->ct_quirks[IMG_IR_CODETYPE_BIPHASE]
1037 |= IMG_IR_QUIRK_CODE_IRQ;
1038 hw->ct_quirks[IMG_IR_CODETYPE_2BITPULSEPOS]
1039 |= IMG_IR_QUIRK_CODE_BROKEN;
1040 }
1041
img_ir_probe_hw(struct img_ir_priv * priv)1042 int img_ir_probe_hw(struct img_ir_priv *priv)
1043 {
1044 struct img_ir_priv_hw *hw = &priv->hw;
1045 struct rc_dev *rdev;
1046 int error;
1047
1048 /* Ensure hardware decoders have been preprocessed */
1049 img_ir_init_decoders();
1050
1051 /* Probe hardware capabilities */
1052 img_ir_probe_hw_caps(priv);
1053
1054 /* Set up the end timer */
1055 setup_timer(&hw->end_timer, img_ir_end_timer, (unsigned long)priv);
1056 setup_timer(&hw->suspend_timer, img_ir_suspend_timer,
1057 (unsigned long)priv);
1058
1059 /* Register a clock notifier */
1060 if (!IS_ERR(priv->clk)) {
1061 hw->clk_hz = clk_get_rate(priv->clk);
1062 #ifdef CONFIG_COMMON_CLK
1063 hw->clk_nb.notifier_call = img_ir_clk_notify;
1064 error = clk_notifier_register(priv->clk, &hw->clk_nb);
1065 if (error)
1066 dev_warn(priv->dev,
1067 "failed to register clock notifier\n");
1068 #endif
1069 } else {
1070 hw->clk_hz = 32768;
1071 }
1072
1073 /* Allocate hardware decoder */
1074 hw->rdev = rdev = rc_allocate_device();
1075 if (!rdev) {
1076 dev_err(priv->dev, "cannot allocate input device\n");
1077 error = -ENOMEM;
1078 goto err_alloc_rc;
1079 }
1080 rdev->priv = priv;
1081 rdev->map_name = RC_MAP_EMPTY;
1082 rdev->allowed_protocols = img_ir_allowed_protos(priv);
1083 rdev->input_name = "IMG Infrared Decoder";
1084 rdev->s_filter = img_ir_set_normal_filter;
1085 rdev->s_wakeup_filter = img_ir_set_wakeup_filter;
1086
1087 /* Register hardware decoder */
1088 error = rc_register_device(rdev);
1089 if (error) {
1090 dev_err(priv->dev, "failed to register IR input device\n");
1091 goto err_register_rc;
1092 }
1093
1094 /*
1095 * Set this after rc_register_device as no protocols have been
1096 * registered yet.
1097 */
1098 rdev->change_protocol = img_ir_change_protocol;
1099
1100 device_init_wakeup(priv->dev, 1);
1101
1102 return 0;
1103
1104 err_register_rc:
1105 img_ir_set_decoder(priv, NULL, 0);
1106 hw->rdev = NULL;
1107 rc_free_device(rdev);
1108 err_alloc_rc:
1109 #ifdef CONFIG_COMMON_CLK
1110 if (!IS_ERR(priv->clk))
1111 clk_notifier_unregister(priv->clk, &hw->clk_nb);
1112 #endif
1113 return error;
1114 }
1115
img_ir_remove_hw(struct img_ir_priv * priv)1116 void img_ir_remove_hw(struct img_ir_priv *priv)
1117 {
1118 struct img_ir_priv_hw *hw = &priv->hw;
1119 struct rc_dev *rdev = hw->rdev;
1120 if (!rdev)
1121 return;
1122 img_ir_set_decoder(priv, NULL, 0);
1123 hw->rdev = NULL;
1124 rc_unregister_device(rdev);
1125 #ifdef CONFIG_COMMON_CLK
1126 if (!IS_ERR(priv->clk))
1127 clk_notifier_unregister(priv->clk, &hw->clk_nb);
1128 #endif
1129 }
1130
1131 #ifdef CONFIG_PM_SLEEP
img_ir_suspend(struct device * dev)1132 int img_ir_suspend(struct device *dev)
1133 {
1134 struct img_ir_priv *priv = dev_get_drvdata(dev);
1135
1136 if (device_may_wakeup(dev) && img_ir_enable_wake(priv))
1137 enable_irq_wake(priv->irq);
1138 return 0;
1139 }
1140
img_ir_resume(struct device * dev)1141 int img_ir_resume(struct device *dev)
1142 {
1143 struct img_ir_priv *priv = dev_get_drvdata(dev);
1144
1145 if (device_may_wakeup(dev) && img_ir_disable_wake(priv))
1146 disable_irq_wake(priv->irq);
1147 return 0;
1148 }
1149 #endif /* CONFIG_PM_SLEEP */
1150