1
// SPDX-License-Identifier: GPL-2.0-only
2
//
3
// Copyright(c) 2021-2022 Intel Corporation
4
//
5
// Authors: Cezary Rojewski <[email protected]>
6
//          Amadeusz Slawinski <[email protected]>
7
//
8

9
#include <linux/io-64-nonatomic-lo-hi.h>
10
#include <linux/slab.h>
11
#include <sound/hdaudio_ext.h>
12
#include "avs.h"
13
#include "messages.h"
14
#include "registers.h"
15
#include "trace.h"
16

17
#define AVS_IPC_TIMEOUT_MS	300
18
#define AVS_D0IX_DELAY_MS	300
19

20
static int
21
avs_dsp_set_d0ix(struct avs_dev *adev, bool enable)
22
{
23
	struct avs_ipc *ipc = adev->ipc;
24
	int ret;
25

26
	/* Is transition required? */
27
	if (ipc->in_d0ix == enable)
28
		return 0;
29

30
	ret = avs_dsp_op(adev, set_d0ix, enable);
31
	if (ret) {
32
		/* Prevent further d0ix attempts on conscious IPC failure. */
33
		if (ret == -AVS_EIPC)
34
			atomic_inc(&ipc->d0ix_disable_depth);
35

36
		ipc->in_d0ix = false;
37
		return ret;
38
	}
39

40
	ipc->in_d0ix = enable;
41
	return 0;
42
}
43

44
static void avs_dsp_schedule_d0ix(struct avs_dev *adev, struct avs_ipc_msg *tx)
45
{
46
	if (atomic_read(&adev->ipc->d0ix_disable_depth))
47
		return;
48

49
	mod_delayed_work(system_power_efficient_wq, &adev->ipc->d0ix_work,
50
			 msecs_to_jiffies(AVS_D0IX_DELAY_MS));
51
}
52

53
static void avs_dsp_d0ix_work(struct work_struct *work)
54
{
55
	struct avs_ipc *ipc = container_of(work, struct avs_ipc, d0ix_work.work);
56

57
	avs_dsp_set_d0ix(to_avs_dev(ipc->dev), true);
58
}
59

60
static int avs_dsp_wake_d0i0(struct avs_dev *adev, struct avs_ipc_msg *tx)
61
{
62
	struct avs_ipc *ipc = adev->ipc;
63

64
	if (!atomic_read(&ipc->d0ix_disable_depth)) {
65
		cancel_delayed_work_sync(&ipc->d0ix_work);
66
		return avs_dsp_set_d0ix(adev, false);
67
	}
68

69
	return 0;
70
}
71

72
int avs_dsp_disable_d0ix(struct avs_dev *adev)
73
{
74
	struct avs_ipc *ipc = adev->ipc;
75

76
	/* Prevent PG only on the first disable. */
77
	if (atomic_inc_return(&ipc->d0ix_disable_depth) == 1) {
78
		cancel_delayed_work_sync(&ipc->d0ix_work);
79
		return avs_dsp_set_d0ix(adev, false);
80
	}
81

82
	return 0;
83
}
84

85
int avs_dsp_enable_d0ix(struct avs_dev *adev)
86
{
87
	struct avs_ipc *ipc = adev->ipc;
88

89
	if (atomic_dec_and_test(&ipc->d0ix_disable_depth))
90
		queue_delayed_work(system_power_efficient_wq, &ipc->d0ix_work,
91
				   msecs_to_jiffies(AVS_D0IX_DELAY_MS));
92
	return 0;
93
}
94

95
static void avs_dsp_recovery(struct avs_dev *adev)
96
{
97
	struct avs_soc_component *acomp;
98
	unsigned int core_mask;
99
	int ret;
100

101
	mutex_lock(&adev->comp_list_mutex);
102
	/* disconnect all running streams */
103
	list_for_each_entry(acomp, &adev->comp_list, node) {
104
		struct snd_soc_pcm_runtime *rtd;
105
		struct snd_soc_card *card;
106

107
		card = acomp->base.card;
108
		if (!card)
109
			continue;
110

111
		for_each_card_rtds(card, rtd) {
112
			struct snd_pcm *pcm;
113
			int dir;
114

115
			pcm = rtd->pcm;
116
			if (!pcm || rtd->dai_link->no_pcm)
117
				continue;
118

119
			for_each_pcm_streams(dir) {
120
				struct snd_pcm_substream *substream;
121

122
				substream = pcm->streams[dir].substream;
123
				if (!substream || !substream->runtime)
124
					continue;
125

126
				/* No need for _irq() as we are in nonatomic context. */
127
				snd_pcm_stream_lock(substream);
128
				snd_pcm_stop(substream, SNDRV_PCM_STATE_DISCONNECTED);
129
				snd_pcm_stream_unlock(substream);
130
			}
131
		}
132
	}
133
	mutex_unlock(&adev->comp_list_mutex);
134

135
	/* forcibly shutdown all cores */
136
	core_mask = GENMASK(adev->hw_cfg.dsp_cores - 1, 0);
137
	avs_dsp_core_disable(adev, core_mask);
138

139
	/* attempt dsp reboot */
140
	ret = avs_dsp_boot_firmware(adev, true);
141
	if (ret < 0)
142
		dev_err(adev->dev, "dsp reboot failed: %d\n", ret);
143

144
	pm_runtime_enable(adev->dev);
145
	pm_request_autosuspend(adev->dev);
146

147
	atomic_set(&adev->ipc->recovering, 0);
148
}
149

150
static void avs_dsp_recovery_work(struct work_struct *work)
151
{
152
	struct avs_ipc *ipc = container_of(work, struct avs_ipc, recovery_work);
153

154
	avs_dsp_recovery(to_avs_dev(ipc->dev));
155
}
156

157
static void avs_dsp_exception_caught(struct avs_dev *adev, union avs_notify_msg *msg)
158
{
159
	struct avs_ipc *ipc = adev->ipc;
160

161
	/* Account for the double-exception case. */
162
	ipc->ready = false;
163

164
	if (!atomic_add_unless(&ipc->recovering, 1, 1)) {
165
		dev_err(adev->dev, "dsp recovery is already in progress\n");
166
		return;
167
	}
168

169
	dev_crit(adev->dev, "communication severed, rebooting dsp..\n");
170

171
	/* Avoid deadlock as the exception may be the response to SET_D0IX. */
172
	if (current_work() != &ipc->d0ix_work.work)
173
		cancel_delayed_work_sync(&ipc->d0ix_work);
174
	ipc->in_d0ix = false;
175
	/* Re-enabled on recovery completion. */
176
	pm_runtime_disable(adev->dev);
177

178
	/* Process received notification. */
179
	avs_dsp_op(adev, coredump, msg);
180

181
	schedule_work(&ipc->recovery_work);
182
}
183

184
static void avs_dsp_receive_rx(struct avs_dev *adev, u64 header)
185
{
186
	struct avs_ipc *ipc = adev->ipc;
187
	union avs_reply_msg msg = AVS_MSG(header);
188
	u32 sts, lec;
189

190
	sts = snd_hdac_adsp_readl(adev, AVS_FW_REG_STATUS(adev));
191
	lec = snd_hdac_adsp_readl(adev, AVS_FW_REG_ERROR(adev));
192
	trace_avs_ipc_reply_msg(header, sts, lec);
193

194
	ipc->rx.header = header;
195
	/* Abort copying payload if request processing was unsuccessful. */
196
	if (!msg.status) {
197
		/* update size in case of LARGE_CONFIG_GET */
198
		if (msg.msg_target == AVS_MOD_MSG &&
199
		    msg.global_msg_type == AVS_MOD_LARGE_CONFIG_GET)
200
			ipc->rx.size = min_t(u32, AVS_MAILBOX_SIZE,
201
					     msg.ext.large_config.data_off_size);
202

203
		memcpy_fromio(ipc->rx.data, avs_uplink_addr(adev), ipc->rx.size);
204
		trace_avs_msg_payload(ipc->rx.data, ipc->rx.size);
205
	}
206
}
207

208
static void avs_dsp_process_notification(struct avs_dev *adev, u64 header)
209
{
210
	struct avs_notify_mod_data mod_data;
211
	union avs_notify_msg msg = AVS_MSG(header);
212
	size_t data_size = 0;
213
	void *data = NULL;
214
	u32 sts, lec;
215

216
	sts = snd_hdac_adsp_readl(adev, AVS_FW_REG_STATUS(adev));
217
	lec = snd_hdac_adsp_readl(adev, AVS_FW_REG_ERROR(adev));
218
	trace_avs_ipc_notify_msg(header, sts, lec);
219

220
	/* Ignore spurious notifications until handshake is established. */
221
	if (!adev->ipc->ready && msg.notify_msg_type != AVS_NOTIFY_FW_READY) {
222
		dev_dbg(adev->dev, "FW not ready, skip notification: 0x%08x\n", msg.primary);
223
		return;
224
	}
225

226
	/* Calculate notification payload size. */
227
	switch (msg.notify_msg_type) {
228
	case AVS_NOTIFY_FW_READY:
229
		break;
230

231
	case AVS_NOTIFY_PHRASE_DETECTED:
232
		data_size = sizeof(struct avs_notify_voice_data);
233
		break;
234

235
	case AVS_NOTIFY_RESOURCE_EVENT:
236
		data_size = sizeof(struct avs_notify_res_data);
237
		break;
238

239
	case AVS_NOTIFY_LOG_BUFFER_STATUS:
240
	case AVS_NOTIFY_EXCEPTION_CAUGHT:
241
		break;
242

243
	case AVS_NOTIFY_MODULE_EVENT:
244
		/* To know the total payload size, header needs to be read first. */
245
		memcpy_fromio(&mod_data, avs_uplink_addr(adev), sizeof(mod_data));
246
		data_size = sizeof(mod_data) + mod_data.data_size;
247
		break;
248

249
	default:
250
		dev_info(adev->dev, "unknown notification: 0x%08x\n", msg.primary);
251
		break;
252
	}
253

254
	if (data_size) {
255
		data = kmalloc(data_size, GFP_KERNEL);
256
		if (!data)
257
			return;
258

259
		memcpy_fromio(data, avs_uplink_addr(adev), data_size);
260
		trace_avs_msg_payload(data, data_size);
261
	}
262

263
	/* Perform notification-specific operations. */
264
	switch (msg.notify_msg_type) {
265
	case AVS_NOTIFY_FW_READY:
266
		dev_dbg(adev->dev, "FW READY 0x%08x\n", msg.primary);
267
		adev->ipc->ready = true;
268
		complete(&adev->fw_ready);
269
		break;
270

271
	case AVS_NOTIFY_LOG_BUFFER_STATUS:
272
		avs_log_buffer_status_locked(adev, &msg);
273
		break;
274

275
	case AVS_NOTIFY_EXCEPTION_CAUGHT:
276
		avs_dsp_exception_caught(adev, &msg);
277
		break;
278

279
	default:
280
		break;
281
	}
282

283
	kfree(data);
284
}
285

286
void avs_dsp_process_response(struct avs_dev *adev, u64 header)
287
{
288
	struct avs_ipc *ipc = adev->ipc;
289

290
	/*
291
	 * Response may either be solicited - a reply for a request that has
292
	 * been sent beforehand - or unsolicited (notification).
293
	 */
294
	if (avs_msg_is_reply(header)) {
295
		/* Response processing is invoked from IRQ thread. */
296
		spin_lock_irq(&ipc->rx_lock);
297
		avs_dsp_receive_rx(adev, header);
298
		ipc->rx_completed = true;
299
		spin_unlock_irq(&ipc->rx_lock);
300
	} else {
301
		avs_dsp_process_notification(adev, header);
302
	}
303

304
	complete(&ipc->busy_completion);
305
}
306

307
static bool avs_ipc_is_busy(struct avs_ipc *ipc)
308
{
309
	struct avs_dev *adev = to_avs_dev(ipc->dev);
310
	const struct avs_spec *const spec = adev->spec;
311
	u32 hipc_rsp;
312

313
	hipc_rsp = snd_hdac_adsp_readl(adev, spec->hipc->rsp_offset);
314
	return hipc_rsp & spec->hipc->rsp_busy_mask;
315
}
316

317
static int avs_ipc_wait_busy_completion(struct avs_ipc *ipc, int timeout)
318
{
319
	u32 repeats_left = 128; /* to avoid infinite looping */
320
	int ret;
321

322
again:
323
	ret = wait_for_completion_timeout(&ipc->busy_completion, msecs_to_jiffies(timeout));
324

325
	/* DSP could be unresponsive at this point. */
326
	if (!ipc->ready)
327
		return -EPERM;
328

329
	if (!ret) {
330
		if (!avs_ipc_is_busy(ipc))
331
			return -ETIMEDOUT;
332
		/*
333
		 * Firmware did its job, either notification or reply
334
		 * has been received - now wait until it's processed.
335
		 */
336
		wait_for_completion_killable(&ipc->busy_completion);
337
	}
338

339
	/* Ongoing notification's bottom-half may cause early wakeup */
340
	spin_lock(&ipc->rx_lock);
341
	if (!ipc->rx_completed) {
342
		if (repeats_left) {
343
			/* Reply delayed due to notification. */
344
			repeats_left--;
345
			reinit_completion(&ipc->busy_completion);
346
			spin_unlock(&ipc->rx_lock);
347
			goto again;
348
		}
349

350
		spin_unlock(&ipc->rx_lock);
351
		return -ETIMEDOUT;
352
	}
353

354
	spin_unlock(&ipc->rx_lock);
355
	return 0;
356
}
357

358
static void avs_ipc_msg_init(struct avs_ipc *ipc, struct avs_ipc_msg *reply)
359
{
360
	lockdep_assert_held(&ipc->rx_lock);
361

362
	ipc->rx.header = 0;
363
	ipc->rx.size = reply ? reply->size : 0;
364
	ipc->rx_completed = false;
365

366
	reinit_completion(&ipc->done_completion);
367
	reinit_completion(&ipc->busy_completion);
368
}
369

370
static void avs_dsp_send_tx(struct avs_dev *adev, struct avs_ipc_msg *tx, bool read_fwregs)
371
{
372
	const struct avs_spec *const spec = adev->spec;
373
	u32 sts = UINT_MAX;
374
	u32 lec = UINT_MAX;
375

376
	tx->header |= spec->hipc->req_busy_mask;
377
	if (read_fwregs) {
378
		sts = snd_hdac_adsp_readl(adev, AVS_FW_REG_STATUS(adev));
379
		lec = snd_hdac_adsp_readl(adev, AVS_FW_REG_ERROR(adev));
380
	}
381

382
	trace_avs_request(tx, sts, lec);
383

384
	if (tx->size)
385
		memcpy_toio(avs_downlink_addr(adev), tx->data, tx->size);
386
	snd_hdac_adsp_writel(adev, spec->hipc->req_ext_offset, tx->header >> 32);
387
	snd_hdac_adsp_writel(adev, spec->hipc->req_offset, tx->header & UINT_MAX);
388
}
389

390
static int avs_dsp_do_send_msg(struct avs_dev *adev, struct avs_ipc_msg *request,
391
			       struct avs_ipc_msg *reply, int timeout, const char *name)
392
{
393
	struct avs_ipc *ipc = adev->ipc;
394
	int ret;
395

396
	if (!ipc->ready)
397
		return -EPERM;
398

399
	mutex_lock(&ipc->msg_mutex);
400

401
	spin_lock(&ipc->rx_lock);
402
	avs_ipc_msg_init(ipc, reply);
403
	avs_dsp_send_tx(adev, request, true);
404
	spin_unlock(&ipc->rx_lock);
405

406
	ret = avs_ipc_wait_busy_completion(ipc, timeout);
407
	if (ret) {
408
		if (ret == -ETIMEDOUT) {
409
			union avs_notify_msg msg = AVS_NOTIFICATION(EXCEPTION_CAUGHT);
410

411
			/* Same treatment as on exception, just stack_dump=0. */
412
			avs_dsp_exception_caught(adev, &msg);
413
		}
414
		goto exit;
415
	}
416

417
	ret = ipc->rx.rsp.status;
418
	/*
419
	 * If IPC channel is blocked e.g.: due to ongoing recovery,
420
	 * -EPERM error code is expected and thus it's not an actual error.
421
	 *
422
	 * Unsupported IPCs are of no harm either.
423
	 */
424
	if (ret == -EPERM || ret == AVS_IPC_NOT_SUPPORTED)
425
		dev_dbg(adev->dev, "%s (0x%08x 0x%08x) failed: %d\n",
426
			name, request->glb.primary, request->glb.ext.val, ret);
427
	else if (ret)
428
		dev_err(adev->dev, "%s (0x%08x 0x%08x) failed: %d\n",
429
			name, request->glb.primary, request->glb.ext.val, ret);
430

431
	if (reply) {
432
		reply->header = ipc->rx.header;
433
		reply->size = ipc->rx.size;
434
		if (reply->data && ipc->rx.size)
435
			memcpy(reply->data, ipc->rx.data, reply->size);
436
	}
437

438
exit:
439
	mutex_unlock(&ipc->msg_mutex);
440
	return ret;
441
}
442

443
static int avs_dsp_send_msg_sequence(struct avs_dev *adev, struct avs_ipc_msg *request,
444
				     struct avs_ipc_msg *reply, int timeout, bool wake_d0i0,
445
				     bool schedule_d0ix, const char *name)
446
{
447
	int ret;
448

449
	trace_avs_d0ix("wake", wake_d0i0, request->header);
450
	if (wake_d0i0) {
451
		ret = avs_dsp_wake_d0i0(adev, request);
452
		if (ret)
453
			return ret;
454
	}
455

456
	ret = avs_dsp_do_send_msg(adev, request, reply, timeout, name);
457
	if (ret)
458
		return ret;
459

460
	trace_avs_d0ix("schedule", schedule_d0ix, request->header);
461
	if (schedule_d0ix)
462
		avs_dsp_schedule_d0ix(adev, request);
463

464
	return 0;
465
}
466

467
int avs_dsp_send_msg_timeout(struct avs_dev *adev, struct avs_ipc_msg *request,
468
			     struct avs_ipc_msg *reply, int timeout, const char *name)
469
{
470
	bool wake_d0i0 = avs_dsp_op(adev, d0ix_toggle, request, true);
471
	bool schedule_d0ix = avs_dsp_op(adev, d0ix_toggle, request, false);
472

473
	return avs_dsp_send_msg_sequence(adev, request, reply, timeout, wake_d0i0, schedule_d0ix,
474
					 name);
475
}
476

477
int avs_dsp_send_msg(struct avs_dev *adev, struct avs_ipc_msg *request,
478
		     struct avs_ipc_msg *reply, const char *name)
479
{
480
	return avs_dsp_send_msg_timeout(adev, request, reply, adev->ipc->default_timeout_ms, name);
481
}
482

483
int avs_dsp_send_pm_msg_timeout(struct avs_dev *adev, struct avs_ipc_msg *request,
484
				struct avs_ipc_msg *reply, int timeout, bool wake_d0i0,
485
				const char *name)
486
{
487
	return avs_dsp_send_msg_sequence(adev, request, reply, timeout, wake_d0i0, false, name);
488
}
489

490
int avs_dsp_send_pm_msg(struct avs_dev *adev, struct avs_ipc_msg *request,
491
			struct avs_ipc_msg *reply, bool wake_d0i0, const char *name)
492
{
493
	return avs_dsp_send_pm_msg_timeout(adev, request, reply, adev->ipc->default_timeout_ms,
494
					   wake_d0i0, name);
495
}
496

497
static int avs_dsp_do_send_rom_msg(struct avs_dev *adev, struct avs_ipc_msg *request, int timeout,
498
				   const char *name)
499
{
500
	struct avs_ipc *ipc = adev->ipc;
501
	int ret;
502

503
	mutex_lock(&ipc->msg_mutex);
504

505
	spin_lock(&ipc->rx_lock);
506
	avs_ipc_msg_init(ipc, NULL);
507
	/*
508
	 * with hw still stalled, memory windows may not be
509
	 * configured properly so avoid accessing SRAM
510
	 */
511
	avs_dsp_send_tx(adev, request, false);
512
	spin_unlock(&ipc->rx_lock);
513

514
	/* ROM messages must be sent before main core is unstalled */
515
	ret = avs_dsp_op(adev, stall, AVS_MAIN_CORE_MASK, false);
516
	if (!ret) {
517
		ret = wait_for_completion_timeout(&ipc->done_completion, msecs_to_jiffies(timeout));
518
		ret = ret ? 0 : -ETIMEDOUT;
519
	}
520
	if (ret)
521
		dev_err(adev->dev, "%s (0x%08x 0x%08x) failed: %d\n",
522
			name, request->glb.primary, request->glb.ext.val, ret);
523

524
	mutex_unlock(&ipc->msg_mutex);
525

526
	return ret;
527
}
528

529
int avs_dsp_send_rom_msg_timeout(struct avs_dev *adev, struct avs_ipc_msg *request, int timeout,
530
				 const char *name)
531
{
532
	return avs_dsp_do_send_rom_msg(adev, request, timeout, name);
533
}
534

535
int avs_dsp_send_rom_msg(struct avs_dev *adev, struct avs_ipc_msg *request, const char *name)
536
{
537
	return avs_dsp_send_rom_msg_timeout(adev, request, adev->ipc->default_timeout_ms, name);
538
}
539

540
void avs_dsp_interrupt_control(struct avs_dev *adev, bool enable)
541
{
542
	const struct avs_spec *const spec = adev->spec;
543
	u32 value, mask;
544

545
	/*
546
	 * No particular bit setting order. All of these are required
547
	 * to have a functional SW <-> FW communication.
548
	 */
549
	value = enable ? AVS_ADSP_ADSPIC_IPC : 0;
550
	snd_hdac_adsp_updatel(adev, AVS_ADSP_REG_ADSPIC, AVS_ADSP_ADSPIC_IPC, value);
551

552
	mask = AVS_ADSP_HIPCCTL_DONE | AVS_ADSP_HIPCCTL_BUSY;
553
	value = enable ? mask : 0;
554
	snd_hdac_adsp_updatel(adev, spec->hipc->ctl_offset, mask, value);
555
}
556

557
int avs_ipc_init(struct avs_ipc *ipc, struct device *dev)
558
{
559
	ipc->rx.data = devm_kzalloc(dev, AVS_MAILBOX_SIZE, GFP_KERNEL);
560
	if (!ipc->rx.data)
561
		return -ENOMEM;
562

563
	ipc->dev = dev;
564
	ipc->ready = false;
565
	ipc->default_timeout_ms = AVS_IPC_TIMEOUT_MS;
566
	INIT_WORK(&ipc->recovery_work, avs_dsp_recovery_work);
567
	INIT_DELAYED_WORK(&ipc->d0ix_work, avs_dsp_d0ix_work);
568
	init_completion(&ipc->done_completion);
569
	init_completion(&ipc->busy_completion);
570
	spin_lock_init(&ipc->rx_lock);
571
	mutex_init(&ipc->msg_mutex);
572

573
	return 0;
574
}
575

576
void avs_ipc_block(struct avs_ipc *ipc)
577
{
578
	ipc->ready = false;
579
	cancel_work_sync(&ipc->recovery_work);
580
	cancel_delayed_work_sync(&ipc->d0ix_work);
581
	ipc->in_d0ix = false;
582
}
583

584