1 // SPDX-License-Identifier: GPL-2.0
2 // Copyright (C) 2019 Spreadtrum Communications Inc.
3
4 #include <linux/errno.h>
5 #include <linux/interrupt.h>
6 #include <linux/io.h>
7 #include <linux/kernel.h>
8 #include <linux/module.h>
9 #include <linux/mutex.h>
10 #include <linux/of.h>
11 #include <linux/platform_device.h>
12 #include <linux/spinlock.h>
13
14 #include "sprd-mcdt.h"
15
16 /* MCDT registers definition */
17 #define MCDT_CH0_TXD 0x0
18 #define MCDT_CH0_RXD 0x28
19 #define MCDT_DAC0_WTMK 0x60
20 #define MCDT_ADC0_WTMK 0x88
21 #define MCDT_DMA_EN 0xb0
22
23 #define MCDT_INT_EN0 0xb4
24 #define MCDT_INT_EN1 0xb8
25 #define MCDT_INT_EN2 0xbc
26
27 #define MCDT_INT_CLR0 0xc0
28 #define MCDT_INT_CLR1 0xc4
29 #define MCDT_INT_CLR2 0xc8
30
31 #define MCDT_INT_RAW1 0xcc
32 #define MCDT_INT_RAW2 0xd0
33 #define MCDT_INT_RAW3 0xd4
34
35 #define MCDT_INT_MSK1 0xd8
36 #define MCDT_INT_MSK2 0xdc
37 #define MCDT_INT_MSK3 0xe0
38
39 #define MCDT_DAC0_FIFO_ADDR_ST 0xe4
40 #define MCDT_ADC0_FIFO_ADDR_ST 0xe8
41
42 #define MCDT_CH_FIFO_ST0 0x134
43 #define MCDT_CH_FIFO_ST1 0x138
44 #define MCDT_CH_FIFO_ST2 0x13c
45
46 #define MCDT_INT_MSK_CFG0 0x140
47 #define MCDT_INT_MSK_CFG1 0x144
48
49 #define MCDT_DMA_CFG0 0x148
50 #define MCDT_FIFO_CLR 0x14c
51 #define MCDT_DMA_CFG1 0x150
52 #define MCDT_DMA_CFG2 0x154
53 #define MCDT_DMA_CFG3 0x158
54 #define MCDT_DMA_CFG4 0x15c
55 #define MCDT_DMA_CFG5 0x160
56
57 /* Channel water mark definition */
58 #define MCDT_CH_FIFO_AE_SHIFT 16
59 #define MCDT_CH_FIFO_AE_MASK GENMASK(24, 16)
60 #define MCDT_CH_FIFO_AF_MASK GENMASK(8, 0)
61
62 /* DMA channel select definition */
63 #define MCDT_DMA_CH0_SEL_MASK GENMASK(3, 0)
64 #define MCDT_DMA_CH0_SEL_SHIFT 0
65 #define MCDT_DMA_CH1_SEL_MASK GENMASK(7, 4)
66 #define MCDT_DMA_CH1_SEL_SHIFT 4
67 #define MCDT_DMA_CH2_SEL_MASK GENMASK(11, 8)
68 #define MCDT_DMA_CH2_SEL_SHIFT 8
69 #define MCDT_DMA_CH3_SEL_MASK GENMASK(15, 12)
70 #define MCDT_DMA_CH3_SEL_SHIFT 12
71 #define MCDT_DMA_CH4_SEL_MASK GENMASK(19, 16)
72 #define MCDT_DMA_CH4_SEL_SHIFT 16
73 #define MCDT_DAC_DMA_SHIFT 16
74
75 /* DMA channel ACK select definition */
76 #define MCDT_DMA_ACK_SEL_MASK GENMASK(3, 0)
77
78 /* Channel FIFO definition */
79 #define MCDT_CH_FIFO_ADDR_SHIFT 16
80 #define MCDT_CH_FIFO_ADDR_MASK GENMASK(9, 0)
81 #define MCDT_ADC_FIFO_SHIFT 16
82 #define MCDT_FIFO_LENGTH 512
83
84 #define MCDT_ADC_CHANNEL_NUM 10
85 #define MCDT_DAC_CHANNEL_NUM 10
86 #define MCDT_CHANNEL_NUM (MCDT_ADC_CHANNEL_NUM + MCDT_DAC_CHANNEL_NUM)
87
88 enum sprd_mcdt_fifo_int {
89 MCDT_ADC_FIFO_AE_INT,
90 MCDT_ADC_FIFO_AF_INT,
91 MCDT_DAC_FIFO_AE_INT,
92 MCDT_DAC_FIFO_AF_INT,
93 MCDT_ADC_FIFO_OV_INT,
94 MCDT_DAC_FIFO_OV_INT
95 };
96
97 enum sprd_mcdt_fifo_sts {
98 MCDT_ADC_FIFO_REAL_FULL,
99 MCDT_ADC_FIFO_REAL_EMPTY,
100 MCDT_ADC_FIFO_AF,
101 MCDT_ADC_FIFO_AE,
102 MCDT_DAC_FIFO_REAL_FULL,
103 MCDT_DAC_FIFO_REAL_EMPTY,
104 MCDT_DAC_FIFO_AF,
105 MCDT_DAC_FIFO_AE
106 };
107
108 struct sprd_mcdt_dev {
109 struct device *dev;
110 void __iomem *base;
111 spinlock_t lock;
112 struct sprd_mcdt_chan chan[MCDT_CHANNEL_NUM];
113 };
114
115 static LIST_HEAD(sprd_mcdt_chan_list);
116 static DEFINE_MUTEX(sprd_mcdt_list_mutex);
117
sprd_mcdt_update(struct sprd_mcdt_dev * mcdt,u32 reg,u32 val,u32 mask)118 static void sprd_mcdt_update(struct sprd_mcdt_dev *mcdt, u32 reg, u32 val,
119 u32 mask)
120 {
121 u32 orig = readl_relaxed(mcdt->base + reg);
122 u32 tmp;
123
124 tmp = (orig & ~mask) | val;
125 writel_relaxed(tmp, mcdt->base + reg);
126 }
127
sprd_mcdt_dac_set_watermark(struct sprd_mcdt_dev * mcdt,u8 channel,u32 full,u32 empty)128 static void sprd_mcdt_dac_set_watermark(struct sprd_mcdt_dev *mcdt, u8 channel,
129 u32 full, u32 empty)
130 {
131 u32 reg = MCDT_DAC0_WTMK + channel * 4;
132 u32 water_mark =
133 (empty << MCDT_CH_FIFO_AE_SHIFT) & MCDT_CH_FIFO_AE_MASK;
134
135 water_mark |= full & MCDT_CH_FIFO_AF_MASK;
136 sprd_mcdt_update(mcdt, reg, water_mark,
137 MCDT_CH_FIFO_AE_MASK | MCDT_CH_FIFO_AF_MASK);
138 }
139
sprd_mcdt_adc_set_watermark(struct sprd_mcdt_dev * mcdt,u8 channel,u32 full,u32 empty)140 static void sprd_mcdt_adc_set_watermark(struct sprd_mcdt_dev *mcdt, u8 channel,
141 u32 full, u32 empty)
142 {
143 u32 reg = MCDT_ADC0_WTMK + channel * 4;
144 u32 water_mark =
145 (empty << MCDT_CH_FIFO_AE_SHIFT) & MCDT_CH_FIFO_AE_MASK;
146
147 water_mark |= full & MCDT_CH_FIFO_AF_MASK;
148 sprd_mcdt_update(mcdt, reg, water_mark,
149 MCDT_CH_FIFO_AE_MASK | MCDT_CH_FIFO_AF_MASK);
150 }
151
sprd_mcdt_dac_dma_enable(struct sprd_mcdt_dev * mcdt,u8 channel,bool enable)152 static void sprd_mcdt_dac_dma_enable(struct sprd_mcdt_dev *mcdt, u8 channel,
153 bool enable)
154 {
155 u32 shift = MCDT_DAC_DMA_SHIFT + channel;
156
157 if (enable)
158 sprd_mcdt_update(mcdt, MCDT_DMA_EN, BIT(shift), BIT(shift));
159 else
160 sprd_mcdt_update(mcdt, MCDT_DMA_EN, 0, BIT(shift));
161 }
162
sprd_mcdt_adc_dma_enable(struct sprd_mcdt_dev * mcdt,u8 channel,bool enable)163 static void sprd_mcdt_adc_dma_enable(struct sprd_mcdt_dev *mcdt, u8 channel,
164 bool enable)
165 {
166 if (enable)
167 sprd_mcdt_update(mcdt, MCDT_DMA_EN, BIT(channel), BIT(channel));
168 else
169 sprd_mcdt_update(mcdt, MCDT_DMA_EN, 0, BIT(channel));
170 }
171
sprd_mcdt_ap_int_enable(struct sprd_mcdt_dev * mcdt,u8 channel,bool enable)172 static void sprd_mcdt_ap_int_enable(struct sprd_mcdt_dev *mcdt, u8 channel,
173 bool enable)
174 {
175 if (enable)
176 sprd_mcdt_update(mcdt, MCDT_INT_MSK_CFG0, BIT(channel),
177 BIT(channel));
178 else
179 sprd_mcdt_update(mcdt, MCDT_INT_MSK_CFG0, 0, BIT(channel));
180 }
181
sprd_mcdt_dac_write_fifo(struct sprd_mcdt_dev * mcdt,u8 channel,u32 val)182 static void sprd_mcdt_dac_write_fifo(struct sprd_mcdt_dev *mcdt, u8 channel,
183 u32 val)
184 {
185 u32 reg = MCDT_CH0_TXD + channel * 4;
186
187 writel_relaxed(val, mcdt->base + reg);
188 }
189
sprd_mcdt_adc_read_fifo(struct sprd_mcdt_dev * mcdt,u8 channel,u32 * val)190 static void sprd_mcdt_adc_read_fifo(struct sprd_mcdt_dev *mcdt, u8 channel,
191 u32 *val)
192 {
193 u32 reg = MCDT_CH0_RXD + channel * 4;
194
195 *val = readl_relaxed(mcdt->base + reg);
196 }
197
sprd_mcdt_dac_dma_chn_select(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_dma_chan dma_chan)198 static void sprd_mcdt_dac_dma_chn_select(struct sprd_mcdt_dev *mcdt, u8 channel,
199 enum sprd_mcdt_dma_chan dma_chan)
200 {
201 switch (dma_chan) {
202 case SPRD_MCDT_DMA_CH0:
203 sprd_mcdt_update(mcdt, MCDT_DMA_CFG0,
204 channel << MCDT_DMA_CH0_SEL_SHIFT,
205 MCDT_DMA_CH0_SEL_MASK);
206 break;
207
208 case SPRD_MCDT_DMA_CH1:
209 sprd_mcdt_update(mcdt, MCDT_DMA_CFG0,
210 channel << MCDT_DMA_CH1_SEL_SHIFT,
211 MCDT_DMA_CH1_SEL_MASK);
212 break;
213
214 case SPRD_MCDT_DMA_CH2:
215 sprd_mcdt_update(mcdt, MCDT_DMA_CFG0,
216 channel << MCDT_DMA_CH2_SEL_SHIFT,
217 MCDT_DMA_CH2_SEL_MASK);
218 break;
219
220 case SPRD_MCDT_DMA_CH3:
221 sprd_mcdt_update(mcdt, MCDT_DMA_CFG0,
222 channel << MCDT_DMA_CH3_SEL_SHIFT,
223 MCDT_DMA_CH3_SEL_MASK);
224 break;
225
226 case SPRD_MCDT_DMA_CH4:
227 sprd_mcdt_update(mcdt, MCDT_DMA_CFG0,
228 channel << MCDT_DMA_CH4_SEL_SHIFT,
229 MCDT_DMA_CH4_SEL_MASK);
230 break;
231 }
232 }
233
sprd_mcdt_adc_dma_chn_select(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_dma_chan dma_chan)234 static void sprd_mcdt_adc_dma_chn_select(struct sprd_mcdt_dev *mcdt, u8 channel,
235 enum sprd_mcdt_dma_chan dma_chan)
236 {
237 switch (dma_chan) {
238 case SPRD_MCDT_DMA_CH0:
239 sprd_mcdt_update(mcdt, MCDT_DMA_CFG1,
240 channel << MCDT_DMA_CH0_SEL_SHIFT,
241 MCDT_DMA_CH0_SEL_MASK);
242 break;
243
244 case SPRD_MCDT_DMA_CH1:
245 sprd_mcdt_update(mcdt, MCDT_DMA_CFG1,
246 channel << MCDT_DMA_CH1_SEL_SHIFT,
247 MCDT_DMA_CH1_SEL_MASK);
248 break;
249
250 case SPRD_MCDT_DMA_CH2:
251 sprd_mcdt_update(mcdt, MCDT_DMA_CFG1,
252 channel << MCDT_DMA_CH2_SEL_SHIFT,
253 MCDT_DMA_CH2_SEL_MASK);
254 break;
255
256 case SPRD_MCDT_DMA_CH3:
257 sprd_mcdt_update(mcdt, MCDT_DMA_CFG1,
258 channel << MCDT_DMA_CH3_SEL_SHIFT,
259 MCDT_DMA_CH3_SEL_MASK);
260 break;
261
262 case SPRD_MCDT_DMA_CH4:
263 sprd_mcdt_update(mcdt, MCDT_DMA_CFG1,
264 channel << MCDT_DMA_CH4_SEL_SHIFT,
265 MCDT_DMA_CH4_SEL_MASK);
266 break;
267 }
268 }
269
sprd_mcdt_dma_ack_shift(u8 channel)270 static u32 sprd_mcdt_dma_ack_shift(u8 channel)
271 {
272 switch (channel) {
273 default:
274 case 0:
275 case 8:
276 return 0;
277 case 1:
278 case 9:
279 return 4;
280 case 2:
281 return 8;
282 case 3:
283 return 12;
284 case 4:
285 return 16;
286 case 5:
287 return 20;
288 case 6:
289 return 24;
290 case 7:
291 return 28;
292 }
293 }
294
sprd_mcdt_dac_dma_ack_select(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_dma_chan dma_chan)295 static void sprd_mcdt_dac_dma_ack_select(struct sprd_mcdt_dev *mcdt, u8 channel,
296 enum sprd_mcdt_dma_chan dma_chan)
297 {
298 u32 reg, shift = sprd_mcdt_dma_ack_shift(channel), ack = dma_chan;
299
300 switch (channel) {
301 case 0 ... 7:
302 reg = MCDT_DMA_CFG2;
303 break;
304
305 case 8 ... 9:
306 reg = MCDT_DMA_CFG3;
307 break;
308
309 default:
310 return;
311 }
312
313 sprd_mcdt_update(mcdt, reg, ack << shift,
314 MCDT_DMA_ACK_SEL_MASK << shift);
315 }
316
sprd_mcdt_adc_dma_ack_select(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_dma_chan dma_chan)317 static void sprd_mcdt_adc_dma_ack_select(struct sprd_mcdt_dev *mcdt, u8 channel,
318 enum sprd_mcdt_dma_chan dma_chan)
319 {
320 u32 reg, shift = sprd_mcdt_dma_ack_shift(channel), ack = dma_chan;
321
322 switch (channel) {
323 case 0 ... 7:
324 reg = MCDT_DMA_CFG4;
325 break;
326
327 case 8 ... 9:
328 reg = MCDT_DMA_CFG5;
329 break;
330
331 default:
332 return;
333 }
334
335 sprd_mcdt_update(mcdt, reg, ack << shift,
336 MCDT_DMA_ACK_SEL_MASK << shift);
337 }
338
sprd_mcdt_chan_fifo_sts(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_fifo_sts fifo_sts)339 static bool sprd_mcdt_chan_fifo_sts(struct sprd_mcdt_dev *mcdt, u8 channel,
340 enum sprd_mcdt_fifo_sts fifo_sts)
341 {
342 u32 reg, shift;
343
344 switch (channel) {
345 case 0 ... 3:
346 reg = MCDT_CH_FIFO_ST0;
347 break;
348 case 4 ... 7:
349 reg = MCDT_CH_FIFO_ST1;
350 break;
351 case 8 ... 9:
352 reg = MCDT_CH_FIFO_ST2;
353 break;
354 default:
355 return false;
356 }
357
358 switch (channel) {
359 case 0:
360 case 4:
361 case 8:
362 shift = fifo_sts;
363 break;
364
365 case 1:
366 case 5:
367 case 9:
368 shift = 8 + fifo_sts;
369 break;
370
371 case 2:
372 case 6:
373 shift = 16 + fifo_sts;
374 break;
375
376 case 3:
377 case 7:
378 shift = 24 + fifo_sts;
379 break;
380
381 default:
382 return false;
383 }
384
385 return !!(readl_relaxed(mcdt->base + reg) & BIT(shift));
386 }
387
sprd_mcdt_dac_fifo_clear(struct sprd_mcdt_dev * mcdt,u8 channel)388 static void sprd_mcdt_dac_fifo_clear(struct sprd_mcdt_dev *mcdt, u8 channel)
389 {
390 sprd_mcdt_update(mcdt, MCDT_FIFO_CLR, BIT(channel), BIT(channel));
391 }
392
sprd_mcdt_adc_fifo_clear(struct sprd_mcdt_dev * mcdt,u8 channel)393 static void sprd_mcdt_adc_fifo_clear(struct sprd_mcdt_dev *mcdt, u8 channel)
394 {
395 u32 shift = MCDT_ADC_FIFO_SHIFT + channel;
396
397 sprd_mcdt_update(mcdt, MCDT_FIFO_CLR, BIT(shift), BIT(shift));
398 }
399
sprd_mcdt_dac_fifo_avail(struct sprd_mcdt_dev * mcdt,u8 channel)400 static u32 sprd_mcdt_dac_fifo_avail(struct sprd_mcdt_dev *mcdt, u8 channel)
401 {
402 u32 reg = MCDT_DAC0_FIFO_ADDR_ST + channel * 8;
403 u32 r_addr = (readl_relaxed(mcdt->base + reg) >>
404 MCDT_CH_FIFO_ADDR_SHIFT) & MCDT_CH_FIFO_ADDR_MASK;
405 u32 w_addr = readl_relaxed(mcdt->base + reg) & MCDT_CH_FIFO_ADDR_MASK;
406
407 if (w_addr >= r_addr)
408 return 4 * (MCDT_FIFO_LENGTH - w_addr + r_addr);
409 else
410 return 4 * (r_addr - w_addr);
411 }
412
sprd_mcdt_adc_fifo_avail(struct sprd_mcdt_dev * mcdt,u8 channel)413 static u32 sprd_mcdt_adc_fifo_avail(struct sprd_mcdt_dev *mcdt, u8 channel)
414 {
415 u32 reg = MCDT_ADC0_FIFO_ADDR_ST + channel * 8;
416 u32 r_addr = (readl_relaxed(mcdt->base + reg) >>
417 MCDT_CH_FIFO_ADDR_SHIFT) & MCDT_CH_FIFO_ADDR_MASK;
418 u32 w_addr = readl_relaxed(mcdt->base + reg) & MCDT_CH_FIFO_ADDR_MASK;
419
420 if (w_addr >= r_addr)
421 return 4 * (w_addr - r_addr);
422 else
423 return 4 * (MCDT_FIFO_LENGTH - r_addr + w_addr);
424 }
425
sprd_mcdt_int_type_shift(u8 channel,enum sprd_mcdt_fifo_int int_type)426 static u32 sprd_mcdt_int_type_shift(u8 channel,
427 enum sprd_mcdt_fifo_int int_type)
428 {
429 switch (channel) {
430 case 0:
431 case 4:
432 case 8:
433 return int_type;
434
435 case 1:
436 case 5:
437 case 9:
438 return 8 + int_type;
439
440 case 2:
441 case 6:
442 return 16 + int_type;
443
444 case 3:
445 case 7:
446 return 24 + int_type;
447
448 default:
449 return 0;
450 }
451 }
452
sprd_mcdt_chan_int_en(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_fifo_int int_type,bool enable)453 static void sprd_mcdt_chan_int_en(struct sprd_mcdt_dev *mcdt, u8 channel,
454 enum sprd_mcdt_fifo_int int_type, bool enable)
455 {
456 u32 reg, shift = sprd_mcdt_int_type_shift(channel, int_type);
457
458 switch (channel) {
459 case 0 ... 3:
460 reg = MCDT_INT_EN0;
461 break;
462 case 4 ... 7:
463 reg = MCDT_INT_EN1;
464 break;
465 case 8 ... 9:
466 reg = MCDT_INT_EN2;
467 break;
468 default:
469 return;
470 }
471
472 if (enable)
473 sprd_mcdt_update(mcdt, reg, BIT(shift), BIT(shift));
474 else
475 sprd_mcdt_update(mcdt, reg, 0, BIT(shift));
476 }
477
sprd_mcdt_chan_int_clear(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_fifo_int int_type)478 static void sprd_mcdt_chan_int_clear(struct sprd_mcdt_dev *mcdt, u8 channel,
479 enum sprd_mcdt_fifo_int int_type)
480 {
481 u32 reg, shift = sprd_mcdt_int_type_shift(channel, int_type);
482
483 switch (channel) {
484 case 0 ... 3:
485 reg = MCDT_INT_CLR0;
486 break;
487 case 4 ... 7:
488 reg = MCDT_INT_CLR1;
489 break;
490 case 8 ... 9:
491 reg = MCDT_INT_CLR2;
492 break;
493 default:
494 return;
495 }
496
497 sprd_mcdt_update(mcdt, reg, BIT(shift), BIT(shift));
498 }
499
sprd_mcdt_chan_int_sts(struct sprd_mcdt_dev * mcdt,u8 channel,enum sprd_mcdt_fifo_int int_type)500 static bool sprd_mcdt_chan_int_sts(struct sprd_mcdt_dev *mcdt, u8 channel,
501 enum sprd_mcdt_fifo_int int_type)
502 {
503 u32 reg, shift = sprd_mcdt_int_type_shift(channel, int_type);
504
505 switch (channel) {
506 case 0 ... 3:
507 reg = MCDT_INT_MSK1;
508 break;
509 case 4 ... 7:
510 reg = MCDT_INT_MSK2;
511 break;
512 case 8 ... 9:
513 reg = MCDT_INT_MSK3;
514 break;
515 default:
516 return false;
517 }
518
519 return !!(readl_relaxed(mcdt->base + reg) & BIT(shift));
520 }
521
sprd_mcdt_irq_handler(int irq,void * dev_id)522 static irqreturn_t sprd_mcdt_irq_handler(int irq, void *dev_id)
523 {
524 struct sprd_mcdt_dev *mcdt = (struct sprd_mcdt_dev *)dev_id;
525 int i;
526
527 spin_lock(&mcdt->lock);
528
529 for (i = 0; i < MCDT_ADC_CHANNEL_NUM; i++) {
530 if (sprd_mcdt_chan_int_sts(mcdt, i, MCDT_ADC_FIFO_AF_INT)) {
531 struct sprd_mcdt_chan *chan = &mcdt->chan[i];
532
533 sprd_mcdt_chan_int_clear(mcdt, i, MCDT_ADC_FIFO_AF_INT);
534 if (chan->cb)
535 chan->cb->notify(chan->cb->data);
536 }
537 }
538
539 for (i = 0; i < MCDT_DAC_CHANNEL_NUM; i++) {
540 if (sprd_mcdt_chan_int_sts(mcdt, i, MCDT_DAC_FIFO_AE_INT)) {
541 struct sprd_mcdt_chan *chan =
542 &mcdt->chan[i + MCDT_ADC_CHANNEL_NUM];
543
544 sprd_mcdt_chan_int_clear(mcdt, i, MCDT_DAC_FIFO_AE_INT);
545 if (chan->cb)
546 chan->cb->notify(chan->cb->data);
547 }
548 }
549
550 spin_unlock(&mcdt->lock);
551
552 return IRQ_HANDLED;
553 }
554
555 /**
556 * sprd_mcdt_chan_write - write data to the MCDT channel's fifo
557 * @chan: the MCDT channel
558 * @tx_buf: send buffer
559 * @size: data size
560 *
561 * Note: We can not write data to the channel fifo when enabling the DMA mode,
562 * otherwise the channel fifo data will be invalid.
563 *
564 * If there are not enough space of the channel fifo, it will return errors
565 * to users.
566 *
567 * Returns 0 on success, or an appropriate error code on failure.
568 */
sprd_mcdt_chan_write(struct sprd_mcdt_chan * chan,char * tx_buf,u32 size)569 int sprd_mcdt_chan_write(struct sprd_mcdt_chan *chan, char *tx_buf, u32 size)
570 {
571 struct sprd_mcdt_dev *mcdt = chan->mcdt;
572 unsigned long flags;
573 int avail, i = 0, words = size / 4;
574 u32 *buf = (u32 *)tx_buf;
575
576 spin_lock_irqsave(&mcdt->lock, flags);
577
578 if (chan->dma_enable) {
579 dev_err(mcdt->dev,
580 "Can not write data when DMA mode enabled\n");
581 spin_unlock_irqrestore(&mcdt->lock, flags);
582 return -EINVAL;
583 }
584
585 if (sprd_mcdt_chan_fifo_sts(mcdt, chan->id, MCDT_DAC_FIFO_REAL_FULL)) {
586 dev_err(mcdt->dev, "Channel fifo is full now\n");
587 spin_unlock_irqrestore(&mcdt->lock, flags);
588 return -EBUSY;
589 }
590
591 avail = sprd_mcdt_dac_fifo_avail(mcdt, chan->id);
592 if (size > avail) {
593 dev_err(mcdt->dev,
594 "Data size is larger than the available fifo size\n");
595 spin_unlock_irqrestore(&mcdt->lock, flags);
596 return -EBUSY;
597 }
598
599 while (i++ < words)
600 sprd_mcdt_dac_write_fifo(mcdt, chan->id, *buf++);
601
602 spin_unlock_irqrestore(&mcdt->lock, flags);
603 return 0;
604 }
605 EXPORT_SYMBOL_GPL(sprd_mcdt_chan_write);
606
607 /**
608 * sprd_mcdt_chan_read - read data from the MCDT channel's fifo
609 * @chan: the MCDT channel
610 * @rx_buf: receive buffer
611 * @size: data size
612 *
613 * Note: We can not read data from the channel fifo when enabling the DMA mode,
614 * otherwise the reading data will be invalid.
615 *
616 * Usually user need start to read data once receiving the fifo full interrupt.
617 *
618 * Returns data size of reading successfully, or an error code on failure.
619 */
sprd_mcdt_chan_read(struct sprd_mcdt_chan * chan,char * rx_buf,u32 size)620 int sprd_mcdt_chan_read(struct sprd_mcdt_chan *chan, char *rx_buf, u32 size)
621 {
622 struct sprd_mcdt_dev *mcdt = chan->mcdt;
623 unsigned long flags;
624 int i = 0, avail, words = size / 4;
625 u32 *buf = (u32 *)rx_buf;
626
627 spin_lock_irqsave(&mcdt->lock, flags);
628
629 if (chan->dma_enable) {
630 dev_err(mcdt->dev, "Can not read data when DMA mode enabled\n");
631 spin_unlock_irqrestore(&mcdt->lock, flags);
632 return -EINVAL;
633 }
634
635 if (sprd_mcdt_chan_fifo_sts(mcdt, chan->id, MCDT_ADC_FIFO_REAL_EMPTY)) {
636 dev_err(mcdt->dev, "Channel fifo is empty\n");
637 spin_unlock_irqrestore(&mcdt->lock, flags);
638 return -EBUSY;
639 }
640
641 avail = sprd_mcdt_adc_fifo_avail(mcdt, chan->id);
642 if (size > avail)
643 words = avail / 4;
644
645 while (i++ < words)
646 sprd_mcdt_adc_read_fifo(mcdt, chan->id, buf++);
647
648 spin_unlock_irqrestore(&mcdt->lock, flags);
649 return words * 4;
650 }
651 EXPORT_SYMBOL_GPL(sprd_mcdt_chan_read);
652
653 /**
654 * sprd_mcdt_chan_int_enable - enable the interrupt mode for the MCDT channel
655 * @chan: the MCDT channel
656 * @water_mark: water mark to trigger a interrupt
657 * @cb: callback when a interrupt happened
658 *
659 * Now it only can enable fifo almost full interrupt for ADC channel and fifo
660 * almost empty interrupt for DAC channel. Morevoer for interrupt mode, user
661 * should use sprd_mcdt_chan_read() or sprd_mcdt_chan_write() to read or write
662 * data manually.
663 *
664 * For ADC channel, user can start to read data once receiving one fifo full
665 * interrupt. For DAC channel, user can start to write data once receiving one
666 * fifo empty interrupt or just call sprd_mcdt_chan_write() to write data
667 * directly.
668 *
669 * Returns 0 on success, or an error code on failure.
670 */
sprd_mcdt_chan_int_enable(struct sprd_mcdt_chan * chan,u32 water_mark,struct sprd_mcdt_chan_callback * cb)671 int sprd_mcdt_chan_int_enable(struct sprd_mcdt_chan *chan, u32 water_mark,
672 struct sprd_mcdt_chan_callback *cb)
673 {
674 struct sprd_mcdt_dev *mcdt = chan->mcdt;
675 unsigned long flags;
676 int ret = 0;
677
678 spin_lock_irqsave(&mcdt->lock, flags);
679
680 if (chan->dma_enable || chan->int_enable) {
681 dev_err(mcdt->dev, "Failed to set interrupt mode.\n");
682 spin_unlock_irqrestore(&mcdt->lock, flags);
683 return -EINVAL;
684 }
685
686 switch (chan->type) {
687 case SPRD_MCDT_ADC_CHAN:
688 sprd_mcdt_adc_fifo_clear(mcdt, chan->id);
689 sprd_mcdt_adc_set_watermark(mcdt, chan->id, water_mark,
690 MCDT_FIFO_LENGTH - 1);
691 sprd_mcdt_chan_int_en(mcdt, chan->id,
692 MCDT_ADC_FIFO_AF_INT, true);
693 sprd_mcdt_ap_int_enable(mcdt, chan->id, true);
694 break;
695
696 case SPRD_MCDT_DAC_CHAN:
697 sprd_mcdt_dac_fifo_clear(mcdt, chan->id);
698 sprd_mcdt_dac_set_watermark(mcdt, chan->id,
699 MCDT_FIFO_LENGTH - 1, water_mark);
700 sprd_mcdt_chan_int_en(mcdt, chan->id,
701 MCDT_DAC_FIFO_AE_INT, true);
702 sprd_mcdt_ap_int_enable(mcdt, chan->id, true);
703 break;
704
705 default:
706 dev_err(mcdt->dev, "Unsupported channel type\n");
707 ret = -EINVAL;
708 }
709
710 if (!ret) {
711 chan->cb = cb;
712 chan->int_enable = true;
713 }
714
715 spin_unlock_irqrestore(&mcdt->lock, flags);
716
717 return ret;
718 }
719 EXPORT_SYMBOL_GPL(sprd_mcdt_chan_int_enable);
720
721 /**
722 * sprd_mcdt_chan_int_disable - disable the interrupt mode for the MCDT channel
723 * @chan: the MCDT channel
724 */
sprd_mcdt_chan_int_disable(struct sprd_mcdt_chan * chan)725 void sprd_mcdt_chan_int_disable(struct sprd_mcdt_chan *chan)
726 {
727 struct sprd_mcdt_dev *mcdt = chan->mcdt;
728 unsigned long flags;
729
730 spin_lock_irqsave(&mcdt->lock, flags);
731
732 if (!chan->int_enable) {
733 spin_unlock_irqrestore(&mcdt->lock, flags);
734 return;
735 }
736
737 switch (chan->type) {
738 case SPRD_MCDT_ADC_CHAN:
739 sprd_mcdt_chan_int_en(mcdt, chan->id,
740 MCDT_ADC_FIFO_AF_INT, false);
741 sprd_mcdt_chan_int_clear(mcdt, chan->id, MCDT_ADC_FIFO_AF_INT);
742 sprd_mcdt_ap_int_enable(mcdt, chan->id, false);
743 break;
744
745 case SPRD_MCDT_DAC_CHAN:
746 sprd_mcdt_chan_int_en(mcdt, chan->id,
747 MCDT_DAC_FIFO_AE_INT, false);
748 sprd_mcdt_chan_int_clear(mcdt, chan->id, MCDT_DAC_FIFO_AE_INT);
749 sprd_mcdt_ap_int_enable(mcdt, chan->id, false);
750 break;
751
752 default:
753 break;
754 }
755
756 chan->int_enable = false;
757 spin_unlock_irqrestore(&mcdt->lock, flags);
758 }
759 EXPORT_SYMBOL_GPL(sprd_mcdt_chan_int_disable);
760
761 /**
762 * sprd_mcdt_chan_dma_enable - enable the DMA mode for the MCDT channel
763 * @chan: the MCDT channel
764 * @dma_chan: specify which DMA channel will be used for this MCDT channel
765 * @water_mark: water mark to trigger a DMA request
766 *
767 * Enable the DMA mode for the MCDT channel, that means we can use DMA to
768 * transfer data to the channel fifo and do not need reading/writing data
769 * manually.
770 *
771 * Returns 0 on success, or an error code on failure.
772 */
sprd_mcdt_chan_dma_enable(struct sprd_mcdt_chan * chan,enum sprd_mcdt_dma_chan dma_chan,u32 water_mark)773 int sprd_mcdt_chan_dma_enable(struct sprd_mcdt_chan *chan,
774 enum sprd_mcdt_dma_chan dma_chan,
775 u32 water_mark)
776 {
777 struct sprd_mcdt_dev *mcdt = chan->mcdt;
778 unsigned long flags;
779 int ret = 0;
780
781 spin_lock_irqsave(&mcdt->lock, flags);
782
783 if (chan->dma_enable || chan->int_enable ||
784 dma_chan > SPRD_MCDT_DMA_CH4) {
785 dev_err(mcdt->dev, "Failed to set DMA mode\n");
786 spin_unlock_irqrestore(&mcdt->lock, flags);
787 return -EINVAL;
788 }
789
790 switch (chan->type) {
791 case SPRD_MCDT_ADC_CHAN:
792 sprd_mcdt_adc_fifo_clear(mcdt, chan->id);
793 sprd_mcdt_adc_set_watermark(mcdt, chan->id,
794 water_mark, MCDT_FIFO_LENGTH - 1);
795 sprd_mcdt_adc_dma_enable(mcdt, chan->id, true);
796 sprd_mcdt_adc_dma_chn_select(mcdt, chan->id, dma_chan);
797 sprd_mcdt_adc_dma_ack_select(mcdt, chan->id, dma_chan);
798 break;
799
800 case SPRD_MCDT_DAC_CHAN:
801 sprd_mcdt_dac_fifo_clear(mcdt, chan->id);
802 sprd_mcdt_dac_set_watermark(mcdt, chan->id,
803 MCDT_FIFO_LENGTH - 1, water_mark);
804 sprd_mcdt_dac_dma_enable(mcdt, chan->id, true);
805 sprd_mcdt_dac_dma_chn_select(mcdt, chan->id, dma_chan);
806 sprd_mcdt_dac_dma_ack_select(mcdt, chan->id, dma_chan);
807 break;
808
809 default:
810 dev_err(mcdt->dev, "Unsupported channel type\n");
811 ret = -EINVAL;
812 }
813
814 if (!ret)
815 chan->dma_enable = true;
816
817 spin_unlock_irqrestore(&mcdt->lock, flags);
818
819 return ret;
820 }
821 EXPORT_SYMBOL_GPL(sprd_mcdt_chan_dma_enable);
822
823 /**
824 * sprd_mcdt_chan_dma_disable - disable the DMA mode for the MCDT channel
825 * @chan: the MCDT channel
826 */
sprd_mcdt_chan_dma_disable(struct sprd_mcdt_chan * chan)827 void sprd_mcdt_chan_dma_disable(struct sprd_mcdt_chan *chan)
828 {
829 struct sprd_mcdt_dev *mcdt = chan->mcdt;
830 unsigned long flags;
831
832 spin_lock_irqsave(&mcdt->lock, flags);
833
834 if (!chan->dma_enable) {
835 spin_unlock_irqrestore(&mcdt->lock, flags);
836 return;
837 }
838
839 switch (chan->type) {
840 case SPRD_MCDT_ADC_CHAN:
841 sprd_mcdt_adc_dma_enable(mcdt, chan->id, false);
842 sprd_mcdt_adc_fifo_clear(mcdt, chan->id);
843 break;
844
845 case SPRD_MCDT_DAC_CHAN:
846 sprd_mcdt_dac_dma_enable(mcdt, chan->id, false);
847 sprd_mcdt_dac_fifo_clear(mcdt, chan->id);
848 break;
849
850 default:
851 break;
852 }
853
854 chan->dma_enable = false;
855 spin_unlock_irqrestore(&mcdt->lock, flags);
856 }
857 EXPORT_SYMBOL_GPL(sprd_mcdt_chan_dma_disable);
858
859 /**
860 * sprd_mcdt_request_chan - request one MCDT channel
861 * @channel: channel id
862 * @type: channel type, it can be one ADC channel or DAC channel
863 *
864 * Rreturn NULL if no available channel.
865 */
sprd_mcdt_request_chan(u8 channel,enum sprd_mcdt_channel_type type)866 struct sprd_mcdt_chan *sprd_mcdt_request_chan(u8 channel,
867 enum sprd_mcdt_channel_type type)
868 {
869 struct sprd_mcdt_chan *temp, *chan = NULL;
870
871 mutex_lock(&sprd_mcdt_list_mutex);
872
873 list_for_each_entry(temp, &sprd_mcdt_chan_list, list) {
874 if (temp->type == type && temp->id == channel) {
875 chan = temp;
876 break;
877 }
878 }
879
880 if (chan)
881 list_del(&chan->list);
882
883 mutex_unlock(&sprd_mcdt_list_mutex);
884
885 return chan;
886 }
887 EXPORT_SYMBOL_GPL(sprd_mcdt_request_chan);
888
889 /**
890 * sprd_mcdt_free_chan - free one MCDT channel
891 * @chan: the channel to be freed
892 */
sprd_mcdt_free_chan(struct sprd_mcdt_chan * chan)893 void sprd_mcdt_free_chan(struct sprd_mcdt_chan *chan)
894 {
895 struct sprd_mcdt_chan *temp;
896
897 sprd_mcdt_chan_dma_disable(chan);
898 sprd_mcdt_chan_int_disable(chan);
899
900 mutex_lock(&sprd_mcdt_list_mutex);
901
902 list_for_each_entry(temp, &sprd_mcdt_chan_list, list) {
903 if (temp == chan) {
904 mutex_unlock(&sprd_mcdt_list_mutex);
905 return;
906 }
907 }
908
909 list_add_tail(&chan->list, &sprd_mcdt_chan_list);
910 mutex_unlock(&sprd_mcdt_list_mutex);
911 }
912 EXPORT_SYMBOL_GPL(sprd_mcdt_free_chan);
913
sprd_mcdt_init_chans(struct sprd_mcdt_dev * mcdt,struct resource * res)914 static void sprd_mcdt_init_chans(struct sprd_mcdt_dev *mcdt,
915 struct resource *res)
916 {
917 int i;
918
919 for (i = 0; i < MCDT_CHANNEL_NUM; i++) {
920 struct sprd_mcdt_chan *chan = &mcdt->chan[i];
921
922 if (i < MCDT_ADC_CHANNEL_NUM) {
923 chan->id = i;
924 chan->type = SPRD_MCDT_ADC_CHAN;
925 chan->fifo_phys = res->start + MCDT_CH0_RXD + i * 4;
926 } else {
927 chan->id = i - MCDT_ADC_CHANNEL_NUM;
928 chan->type = SPRD_MCDT_DAC_CHAN;
929 chan->fifo_phys = res->start + MCDT_CH0_TXD +
930 (i - MCDT_ADC_CHANNEL_NUM) * 4;
931 }
932
933 chan->mcdt = mcdt;
934 INIT_LIST_HEAD(&chan->list);
935
936 mutex_lock(&sprd_mcdt_list_mutex);
937 list_add_tail(&chan->list, &sprd_mcdt_chan_list);
938 mutex_unlock(&sprd_mcdt_list_mutex);
939 }
940 }
941
sprd_mcdt_probe(struct platform_device * pdev)942 static int sprd_mcdt_probe(struct platform_device *pdev)
943 {
944 struct sprd_mcdt_dev *mcdt;
945 struct resource *res;
946 int ret, irq;
947
948 mcdt = devm_kzalloc(&pdev->dev, sizeof(*mcdt), GFP_KERNEL);
949 if (!mcdt)
950 return -ENOMEM;
951
952 res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
953 mcdt->base = devm_ioremap_resource(&pdev->dev, res);
954 if (IS_ERR(mcdt->base))
955 return PTR_ERR(mcdt->base);
956
957 mcdt->dev = &pdev->dev;
958 spin_lock_init(&mcdt->lock);
959 platform_set_drvdata(pdev, mcdt);
960
961 irq = platform_get_irq(pdev, 0);
962 if (irq < 0)
963 return irq;
964
965 ret = devm_request_irq(&pdev->dev, irq, sprd_mcdt_irq_handler,
966 0, "sprd-mcdt", mcdt);
967 if (ret) {
968 dev_err(&pdev->dev, "Failed to request MCDT IRQ\n");
969 return ret;
970 }
971
972 sprd_mcdt_init_chans(mcdt, res);
973
974 return 0;
975 }
976
sprd_mcdt_remove(struct platform_device * pdev)977 static int sprd_mcdt_remove(struct platform_device *pdev)
978 {
979 struct sprd_mcdt_chan *chan, *temp;
980
981 mutex_lock(&sprd_mcdt_list_mutex);
982
983 list_for_each_entry_safe(chan, temp, &sprd_mcdt_chan_list, list)
984 list_del(&chan->list);
985
986 mutex_unlock(&sprd_mcdt_list_mutex);
987
988 return 0;
989 }
990
991 static const struct of_device_id sprd_mcdt_of_match[] = {
992 { .compatible = "sprd,sc9860-mcdt", },
993 { }
994 };
995 MODULE_DEVICE_TABLE(of, sprd_mcdt_of_match);
996
997 static struct platform_driver sprd_mcdt_driver = {
998 .probe = sprd_mcdt_probe,
999 .remove = sprd_mcdt_remove,
1000 .driver = {
1001 .name = "sprd-mcdt",
1002 .of_match_table = sprd_mcdt_of_match,
1003 },
1004 };
1005
1006 module_platform_driver(sprd_mcdt_driver);
1007
1008 MODULE_DESCRIPTION("Spreadtrum Multi-Channel Data Transfer Driver");
1009 MODULE_LICENSE("GPL v2");
1010