1
// SPDX-License-Identifier: GPL-2.0
2
/*
3
 * Greybus operations
4
 *
5
 * Copyright 2014-2015 Google Inc.
6
 * Copyright 2014-2015 Linaro Ltd.
7
 */
8

9
#include <linux/kernel.h>
10
#include <linux/slab.h>
11
#include <linux/module.h>
12
#include <linux/sched.h>
13
#include <linux/wait.h>
14
#include <linux/workqueue.h>
15
#include <linux/greybus.h>
16

17
#include "greybus_trace.h"
18

19
static struct kmem_cache *gb_operation_cache;
20
static struct kmem_cache *gb_message_cache;
21

22
/* Workqueue to handle Greybus operation completions. */
23
static struct workqueue_struct *gb_operation_completion_wq;
24

25
/* Wait queue for synchronous cancellations. */
26
static DECLARE_WAIT_QUEUE_HEAD(gb_operation_cancellation_queue);
27

28
/*
29
 * Protects updates to operation->errno.
30
 */
31
static DEFINE_SPINLOCK(gb_operations_lock);
32

33
static int gb_operation_response_send(struct gb_operation *operation,
34
				      int errno);
35

36
/*
37
 * Increment operation active count and add to connection list unless the
38
 * connection is going away.
39
 *
40
 * Caller holds operation reference.
41
 */
42
static int gb_operation_get_active(struct gb_operation *operation)
43
{
44
	struct gb_connection *connection = operation->connection;
45
	unsigned long flags;
46

47
	spin_lock_irqsave(&connection->lock, flags);
48
	switch (connection->state) {
49
	case GB_CONNECTION_STATE_ENABLED:
50
		break;
51
	case GB_CONNECTION_STATE_ENABLED_TX:
52
		if (gb_operation_is_incoming(operation))
53
			goto err_unlock;
54
		break;
55
	case GB_CONNECTION_STATE_DISCONNECTING:
56
		if (!gb_operation_is_core(operation))
57
			goto err_unlock;
58
		break;
59
	default:
60
		goto err_unlock;
61
	}
62

63
	if (operation->active++ == 0)
64
		list_add_tail(&operation->links, &connection->operations);
65

66
	trace_gb_operation_get_active(operation);
67

68
	spin_unlock_irqrestore(&connection->lock, flags);
69

70
	return 0;
71

72
err_unlock:
73
	spin_unlock_irqrestore(&connection->lock, flags);
74

75
	return -ENOTCONN;
76
}
77

78
/* Caller holds operation reference. */
79
static void gb_operation_put_active(struct gb_operation *operation)
80
{
81
	struct gb_connection *connection = operation->connection;
82
	unsigned long flags;
83

84
	spin_lock_irqsave(&connection->lock, flags);
85

86
	trace_gb_operation_put_active(operation);
87

88
	if (--operation->active == 0) {
89
		list_del(&operation->links);
90
		if (atomic_read(&operation->waiters))
91
			wake_up(&gb_operation_cancellation_queue);
92
	}
93
	spin_unlock_irqrestore(&connection->lock, flags);
94
}
95

96
static bool gb_operation_is_active(struct gb_operation *operation)
97
{
98
	struct gb_connection *connection = operation->connection;
99
	unsigned long flags;
100
	bool ret;
101

102
	spin_lock_irqsave(&connection->lock, flags);
103
	ret = operation->active;
104
	spin_unlock_irqrestore(&connection->lock, flags);
105

106
	return ret;
107
}
108

109
/*
110
 * Set an operation's result.
111
 *
112
 * Initially an outgoing operation's errno value is -EBADR.
113
 * If no error occurs before sending the request message the only
114
 * valid value operation->errno can be set to is -EINPROGRESS,
115
 * indicating the request has been (or rather is about to be) sent.
116
 * At that point nobody should be looking at the result until the
117
 * response arrives.
118
 *
119
 * The first time the result gets set after the request has been
120
 * sent, that result "sticks."  That is, if two concurrent threads
121
 * race to set the result, the first one wins.  The return value
122
 * tells the caller whether its result was recorded; if not the
123
 * caller has nothing more to do.
124
 *
125
 * The result value -EILSEQ is reserved to signal an implementation
126
 * error; if it's ever observed, the code performing the request has
127
 * done something fundamentally wrong.  It is an error to try to set
128
 * the result to -EBADR, and attempts to do so result in a warning,
129
 * and -EILSEQ is used instead.  Similarly, the only valid result
130
 * value to set for an operation in initial state is -EINPROGRESS.
131
 * Attempts to do otherwise will also record a (successful) -EILSEQ
132
 * operation result.
133
 */
134
static bool gb_operation_result_set(struct gb_operation *operation, int result)
135
{
136
	unsigned long flags;
137
	int prev;
138

139
	if (result == -EINPROGRESS) {
140
		/*
141
		 * -EINPROGRESS is used to indicate the request is
142
		 * in flight.  It should be the first result value
143
		 * set after the initial -EBADR.  Issue a warning
144
		 * and record an implementation error if it's
145
		 * set at any other time.
146
		 */
147
		spin_lock_irqsave(&gb_operations_lock, flags);
148
		prev = operation->errno;
149
		if (prev == -EBADR)
150
			operation->errno = result;
151
		else
152
			operation->errno = -EILSEQ;
153
		spin_unlock_irqrestore(&gb_operations_lock, flags);
154
		WARN_ON(prev != -EBADR);
155

156
		return true;
157
	}
158

159
	/*
160
	 * The first result value set after a request has been sent
161
	 * will be the final result of the operation.  Subsequent
162
	 * attempts to set the result are ignored.
163
	 *
164
	 * Note that -EBADR is a reserved "initial state" result
165
	 * value.  Attempts to set this value result in a warning,
166
	 * and the result code is set to -EILSEQ instead.
167
	 */
168
	if (WARN_ON(result == -EBADR))
169
		result = -EILSEQ; /* Nobody should be setting -EBADR */
170

171
	spin_lock_irqsave(&gb_operations_lock, flags);
172
	prev = operation->errno;
173
	if (prev == -EINPROGRESS)
174
		operation->errno = result;	/* First and final result */
175
	spin_unlock_irqrestore(&gb_operations_lock, flags);
176

177
	return prev == -EINPROGRESS;
178
}
179

180
int gb_operation_result(struct gb_operation *operation)
181
{
182
	int result = operation->errno;
183

184
	WARN_ON(result == -EBADR);
185
	WARN_ON(result == -EINPROGRESS);
186

187
	return result;
188
}
189
EXPORT_SYMBOL_GPL(gb_operation_result);
190

191
/*
192
 * Looks up an outgoing operation on a connection and returns a refcounted
193
 * pointer if found, or NULL otherwise.
194
 */
195
static struct gb_operation *
196
gb_operation_find_outgoing(struct gb_connection *connection, u16 operation_id)
197
{
198
	struct gb_operation *operation;
199
	unsigned long flags;
200
	bool found = false;
201

202
	spin_lock_irqsave(&connection->lock, flags);
203
	list_for_each_entry(operation, &connection->operations, links)
204
		if (operation->id == operation_id &&
205
		    !gb_operation_is_incoming(operation)) {
206
			gb_operation_get(operation);
207
			found = true;
208
			break;
209
		}
210
	spin_unlock_irqrestore(&connection->lock, flags);
211

212
	return found ? operation : NULL;
213
}
214

215
static int gb_message_send(struct gb_message *message, gfp_t gfp)
216
{
217
	struct gb_connection *connection = message->operation->connection;
218

219
	trace_gb_message_send(message);
220
	return connection->hd->driver->message_send(connection->hd,
221
					connection->hd_cport_id,
222
					message,
223
					gfp);
224
}
225

226
/*
227
 * Cancel a message we have passed to the host device layer to be sent.
228
 */
229
static void gb_message_cancel(struct gb_message *message)
230
{
231
	struct gb_host_device *hd = message->operation->connection->hd;
232

233
	hd->driver->message_cancel(message);
234
}
235

236
static void gb_operation_request_handle(struct gb_operation *operation)
237
{
238
	struct gb_connection *connection = operation->connection;
239
	int status;
240
	int ret;
241

242
	if (connection->handler) {
243
		status = connection->handler(operation);
244
	} else {
245
		dev_err(&connection->hd->dev,
246
			"%s: unexpected incoming request of type 0x%02x\n",
247
			connection->name, operation->type);
248

249
		status = -EPROTONOSUPPORT;
250
	}
251

252
	ret = gb_operation_response_send(operation, status);
253
	if (ret) {
254
		dev_err(&connection->hd->dev,
255
			"%s: failed to send response %d for type 0x%02x: %d\n",
256
			connection->name, status, operation->type, ret);
257
		return;
258
	}
259
}
260

261
/*
262
 * Process operation work.
263
 *
264
 * For incoming requests, call the protocol request handler. The operation
265
 * result should be -EINPROGRESS at this point.
266
 *
267
 * For outgoing requests, the operation result value should have
268
 * been set before queueing this.  The operation callback function
269
 * allows the original requester to know the request has completed
270
 * and its result is available.
271
 */
272
static void gb_operation_work(struct work_struct *work)
273
{
274
	struct gb_operation *operation;
275
	int ret;
276

277
	operation = container_of(work, struct gb_operation, work);
278

279
	if (gb_operation_is_incoming(operation)) {
280
		gb_operation_request_handle(operation);
281
	} else {
282
		ret = timer_delete_sync(&operation->timer);
283
		if (!ret) {
284
			/* Cancel request message if scheduled by timeout. */
285
			if (gb_operation_result(operation) == -ETIMEDOUT)
286
				gb_message_cancel(operation->request);
287
		}
288

289
		operation->callback(operation);
290
	}
291

292
	gb_operation_put_active(operation);
293
	gb_operation_put(operation);
294
}
295

296
static void gb_operation_timeout(struct timer_list *t)
297
{
298
	struct gb_operation *operation = timer_container_of(operation, t,
299
							    timer);
300

301
	if (gb_operation_result_set(operation, -ETIMEDOUT)) {
302
		/*
303
		 * A stuck request message will be cancelled from the
304
		 * workqueue.
305
		 */
306
		queue_work(gb_operation_completion_wq, &operation->work);
307
	}
308
}
309

310
static void gb_operation_message_init(struct gb_host_device *hd,
311
				      struct gb_message *message,
312
				      u16 operation_id,
313
				      size_t payload_size, u8 type)
314
{
315
	struct gb_operation_msg_hdr *header;
316

317
	header = message->buffer;
318

319
	message->header = header;
320
	message->payload = payload_size ? header + 1 : NULL;
321
	message->payload_size = payload_size;
322

323
	/*
324
	 * The type supplied for incoming message buffers will be
325
	 * GB_REQUEST_TYPE_INVALID. Such buffers will be overwritten by
326
	 * arriving data so there's no need to initialize the message header.
327
	 */
328
	if (type != GB_REQUEST_TYPE_INVALID) {
329
		u16 message_size = (u16)(sizeof(*header) + payload_size);
330

331
		/*
332
		 * For a request, the operation id gets filled in
333
		 * when the message is sent.  For a response, it
334
		 * will be copied from the request by the caller.
335
		 *
336
		 * The result field in a request message must be
337
		 * zero.  It will be set just prior to sending for
338
		 * a response.
339
		 */
340
		header->size = cpu_to_le16(message_size);
341
		header->operation_id = 0;
342
		header->type = type;
343
		header->result = 0;
344
	}
345
}
346

347
/*
348
 * Allocate a message to be used for an operation request or response.
349
 * Both types of message contain a common header.  The request message
350
 * for an outgoing operation is outbound, as is the response message
351
 * for an incoming operation.  The message header for an outbound
352
 * message is partially initialized here.
353
 *
354
 * The headers for inbound messages don't need to be initialized;
355
 * they'll be filled in by arriving data.
356
 *
357
 * Our message buffers have the following layout:
358
 *	message header  \_ these combined are
359
 *	message payload /  the message size
360
 */
361
static struct gb_message *
362
gb_operation_message_alloc(struct gb_host_device *hd, u8 type,
363
			   size_t payload_size, gfp_t gfp_flags)
364
{
365
	struct gb_message *message;
366
	struct gb_operation_msg_hdr *header;
367
	size_t message_size = payload_size + sizeof(*header);
368

369
	if (message_size > hd->buffer_size_max) {
370
		dev_warn(&hd->dev, "requested message size too big (%zu > %zu)\n",
371
			 message_size, hd->buffer_size_max);
372
		return NULL;
373
	}
374

375
	/* Allocate the message structure and buffer. */
376
	message = kmem_cache_zalloc(gb_message_cache, gfp_flags);
377
	if (!message)
378
		return NULL;
379

380
	message->buffer = kzalloc(message_size, gfp_flags);
381
	if (!message->buffer)
382
		goto err_free_message;
383

384
	/* Initialize the message.  Operation id is filled in later. */
385
	gb_operation_message_init(hd, message, 0, payload_size, type);
386

387
	return message;
388

389
err_free_message:
390
	kmem_cache_free(gb_message_cache, message);
391

392
	return NULL;
393
}
394

395
static void gb_operation_message_free(struct gb_message *message)
396
{
397
	kfree(message->buffer);
398
	kmem_cache_free(gb_message_cache, message);
399
}
400

401
/*
402
 * Map an enum gb_operation_status value (which is represented in a
403
 * message as a single byte) to an appropriate Linux negative errno.
404
 */
405
static int gb_operation_status_map(u8 status)
406
{
407
	switch (status) {
408
	case GB_OP_SUCCESS:
409
		return 0;
410
	case GB_OP_INTERRUPTED:
411
		return -EINTR;
412
	case GB_OP_TIMEOUT:
413
		return -ETIMEDOUT;
414
	case GB_OP_NO_MEMORY:
415
		return -ENOMEM;
416
	case GB_OP_PROTOCOL_BAD:
417
		return -EPROTONOSUPPORT;
418
	case GB_OP_OVERFLOW:
419
		return -EMSGSIZE;
420
	case GB_OP_INVALID:
421
		return -EINVAL;
422
	case GB_OP_RETRY:
423
		return -EAGAIN;
424
	case GB_OP_NONEXISTENT:
425
		return -ENODEV;
426
	case GB_OP_MALFUNCTION:
427
		return -EILSEQ;
428
	case GB_OP_UNKNOWN_ERROR:
429
	default:
430
		return -EIO;
431
	}
432
}
433

434
/*
435
 * Map a Linux errno value (from operation->errno) into the value
436
 * that should represent it in a response message status sent
437
 * over the wire.  Returns an enum gb_operation_status value (which
438
 * is represented in a message as a single byte).
439
 */
440
static u8 gb_operation_errno_map(int errno)
441
{
442
	switch (errno) {
443
	case 0:
444
		return GB_OP_SUCCESS;
445
	case -EINTR:
446
		return GB_OP_INTERRUPTED;
447
	case -ETIMEDOUT:
448
		return GB_OP_TIMEOUT;
449
	case -ENOMEM:
450
		return GB_OP_NO_MEMORY;
451
	case -EPROTONOSUPPORT:
452
		return GB_OP_PROTOCOL_BAD;
453
	case -EMSGSIZE:
454
		return GB_OP_OVERFLOW;	/* Could be underflow too */
455
	case -EINVAL:
456
		return GB_OP_INVALID;
457
	case -EAGAIN:
458
		return GB_OP_RETRY;
459
	case -EILSEQ:
460
		return GB_OP_MALFUNCTION;
461
	case -ENODEV:
462
		return GB_OP_NONEXISTENT;
463
	case -EIO:
464
	default:
465
		return GB_OP_UNKNOWN_ERROR;
466
	}
467
}
468

469
bool gb_operation_response_alloc(struct gb_operation *operation,
470
				 size_t response_size, gfp_t gfp)
471
{
472
	struct gb_host_device *hd = operation->connection->hd;
473
	struct gb_operation_msg_hdr *request_header;
474
	struct gb_message *response;
475
	u8 type;
476

477
	type = operation->type | GB_MESSAGE_TYPE_RESPONSE;
478
	response = gb_operation_message_alloc(hd, type, response_size, gfp);
479
	if (!response)
480
		return false;
481
	response->operation = operation;
482

483
	/*
484
	 * Size and type get initialized when the message is
485
	 * allocated.  The errno will be set before sending.  All
486
	 * that's left is the operation id, which we copy from the
487
	 * request message header (as-is, in little-endian order).
488
	 */
489
	request_header = operation->request->header;
490
	response->header->operation_id = request_header->operation_id;
491
	operation->response = response;
492

493
	return true;
494
}
495
EXPORT_SYMBOL_GPL(gb_operation_response_alloc);
496

497
/*
498
 * Create a Greybus operation to be sent over the given connection.
499
 * The request buffer will be big enough for a payload of the given
500
 * size.
501
 *
502
 * For outgoing requests, the request message's header will be
503
 * initialized with the type of the request and the message size.
504
 * Outgoing operations must also specify the response buffer size,
505
 * which must be sufficient to hold all expected response data.  The
506
 * response message header will eventually be overwritten, so there's
507
 * no need to initialize it here.
508
 *
509
 * Request messages for incoming operations can arrive in interrupt
510
 * context, so they must be allocated with GFP_ATOMIC.  In this case
511
 * the request buffer will be immediately overwritten, so there is
512
 * no need to initialize the message header.  Responsibility for
513
 * allocating a response buffer lies with the incoming request
514
 * handler for a protocol.  So we don't allocate that here.
515
 *
516
 * Returns a pointer to the new operation or a null pointer if an
517
 * error occurs.
518
 */
519
static struct gb_operation *
520
gb_operation_create_common(struct gb_connection *connection, u8 type,
521
			   size_t request_size, size_t response_size,
522
			   unsigned long op_flags, gfp_t gfp_flags)
523
{
524
	struct gb_host_device *hd = connection->hd;
525
	struct gb_operation *operation;
526

527
	operation = kmem_cache_zalloc(gb_operation_cache, gfp_flags);
528
	if (!operation)
529
		return NULL;
530
	operation->connection = connection;
531

532
	operation->request = gb_operation_message_alloc(hd, type, request_size,
533
							gfp_flags);
534
	if (!operation->request)
535
		goto err_cache;
536
	operation->request->operation = operation;
537

538
	/* Allocate the response buffer for outgoing operations */
539
	if (!(op_flags & GB_OPERATION_FLAG_INCOMING)) {
540
		if (!gb_operation_response_alloc(operation, response_size,
541
						 gfp_flags)) {
542
			goto err_request;
543
		}
544

545
		timer_setup(&operation->timer, gb_operation_timeout, 0);
546
	}
547

548
	operation->flags = op_flags;
549
	operation->type = type;
550
	operation->errno = -EBADR;  /* Initial value--means "never set" */
551

552
	INIT_WORK(&operation->work, gb_operation_work);
553
	init_completion(&operation->completion);
554
	kref_init(&operation->kref);
555
	atomic_set(&operation->waiters, 0);
556

557
	return operation;
558

559
err_request:
560
	gb_operation_message_free(operation->request);
561
err_cache:
562
	kmem_cache_free(gb_operation_cache, operation);
563

564
	return NULL;
565
}
566

567
/*
568
 * Create a new operation associated with the given connection.  The
569
 * request and response sizes provided are the number of bytes
570
 * required to hold the request/response payload only.  Both of
571
 * these are allowed to be 0.  Note that 0x00 is reserved as an
572
 * invalid operation type for all protocols, and this is enforced
573
 * here.
574
 */
575
struct gb_operation *
576
gb_operation_create_flags(struct gb_connection *connection,
577
			  u8 type, size_t request_size,
578
			  size_t response_size, unsigned long flags,
579
			  gfp_t gfp)
580
{
581
	struct gb_operation *operation;
582

583
	if (WARN_ON_ONCE(type == GB_REQUEST_TYPE_INVALID))
584
		return NULL;
585
	if (WARN_ON_ONCE(type & GB_MESSAGE_TYPE_RESPONSE))
586
		type &= ~GB_MESSAGE_TYPE_RESPONSE;
587

588
	if (WARN_ON_ONCE(flags & ~GB_OPERATION_FLAG_USER_MASK))
589
		flags &= GB_OPERATION_FLAG_USER_MASK;
590

591
	operation = gb_operation_create_common(connection, type,
592
					       request_size, response_size,
593
					       flags, gfp);
594
	if (operation)
595
		trace_gb_operation_create(operation);
596

597
	return operation;
598
}
599
EXPORT_SYMBOL_GPL(gb_operation_create_flags);
600

601
struct gb_operation *
602
gb_operation_create_core(struct gb_connection *connection,
603
			 u8 type, size_t request_size,
604
			 size_t response_size, unsigned long flags,
605
			 gfp_t gfp)
606
{
607
	struct gb_operation *operation;
608

609
	flags |= GB_OPERATION_FLAG_CORE;
610

611
	operation = gb_operation_create_common(connection, type,
612
					       request_size, response_size,
613
					       flags, gfp);
614
	if (operation)
615
		trace_gb_operation_create_core(operation);
616

617
	return operation;
618
}
619

620
/* Do not export this function. */
621

622
size_t gb_operation_get_payload_size_max(struct gb_connection *connection)
623
{
624
	struct gb_host_device *hd = connection->hd;
625

626
	return hd->buffer_size_max - sizeof(struct gb_operation_msg_hdr);
627
}
628
EXPORT_SYMBOL_GPL(gb_operation_get_payload_size_max);
629

630
static struct gb_operation *
631
gb_operation_create_incoming(struct gb_connection *connection, u16 id,
632
			     u8 type, void *data, size_t size)
633
{
634
	struct gb_operation *operation;
635
	size_t request_size;
636
	unsigned long flags = GB_OPERATION_FLAG_INCOMING;
637

638
	/* Caller has made sure we at least have a message header. */
639
	request_size = size - sizeof(struct gb_operation_msg_hdr);
640

641
	if (!id)
642
		flags |= GB_OPERATION_FLAG_UNIDIRECTIONAL;
643

644
	operation = gb_operation_create_common(connection, type,
645
					       request_size,
646
					       GB_REQUEST_TYPE_INVALID,
647
					       flags, GFP_ATOMIC);
648
	if (!operation)
649
		return NULL;
650

651
	operation->id = id;
652
	memcpy(operation->request->header, data, size);
653
	trace_gb_operation_create_incoming(operation);
654

655
	return operation;
656
}
657

658
/*
659
 * Get an additional reference on an operation.
660
 */
661
void gb_operation_get(struct gb_operation *operation)
662
{
663
	kref_get(&operation->kref);
664
}
665
EXPORT_SYMBOL_GPL(gb_operation_get);
666

667
/*
668
 * Destroy a previously created operation.
669
 */
670
static void _gb_operation_destroy(struct kref *kref)
671
{
672
	struct gb_operation *operation;
673

674
	operation = container_of(kref, struct gb_operation, kref);
675

676
	trace_gb_operation_destroy(operation);
677

678
	if (operation->response)
679
		gb_operation_message_free(operation->response);
680
	gb_operation_message_free(operation->request);
681

682
	kmem_cache_free(gb_operation_cache, operation);
683
}
684

685
/*
686
 * Drop a reference on an operation, and destroy it when the last
687
 * one is gone.
688
 */
689
void gb_operation_put(struct gb_operation *operation)
690
{
691
	if (WARN_ON(!operation))
692
		return;
693

694
	kref_put(&operation->kref, _gb_operation_destroy);
695
}
696
EXPORT_SYMBOL_GPL(gb_operation_put);
697

698
/* Tell the requester we're done */
699
static void gb_operation_sync_callback(struct gb_operation *operation)
700
{
701
	complete(&operation->completion);
702
}
703

704
/**
705
 * gb_operation_request_send() - send an operation request message
706
 * @operation:	the operation to initiate
707
 * @callback:	the operation completion callback
708
 * @timeout:	operation timeout in milliseconds, or zero for no timeout
709
 * @gfp:	the memory flags to use for any allocations
710
 *
711
 * The caller has filled in any payload so the request message is ready to go.
712
 * The callback function supplied will be called when the response message has
713
 * arrived, a unidirectional request has been sent, or the operation is
714
 * cancelled, indicating that the operation is complete. The callback function
715
 * can fetch the result of the operation using gb_operation_result() if
716
 * desired.
717
 *
718
 * Return: 0 if the request was successfully queued in the host-driver queues,
719
 * or a negative errno.
720
 */
721
int gb_operation_request_send(struct gb_operation *operation,
722
			      gb_operation_callback callback,
723
			      unsigned int timeout,
724
			      gfp_t gfp)
725
{
726
	struct gb_connection *connection = operation->connection;
727
	struct gb_operation_msg_hdr *header;
728
	unsigned int cycle;
729
	int ret;
730

731
	if (gb_connection_is_offloaded(connection))
732
		return -EBUSY;
733

734
	if (!callback)
735
		return -EINVAL;
736

737
	/*
738
	 * Record the callback function, which is executed in
739
	 * non-atomic (workqueue) context when the final result
740
	 * of an operation has been set.
741
	 */
742
	operation->callback = callback;
743

744
	/*
745
	 * Assign the operation's id, and store it in the request header.
746
	 * Zero is a reserved operation id for unidirectional operations.
747
	 */
748
	if (gb_operation_is_unidirectional(operation)) {
749
		operation->id = 0;
750
	} else {
751
		cycle = (unsigned int)atomic_inc_return(&connection->op_cycle);
752
		operation->id = (u16)(cycle % U16_MAX + 1);
753
	}
754

755
	header = operation->request->header;
756
	header->operation_id = cpu_to_le16(operation->id);
757

758
	gb_operation_result_set(operation, -EINPROGRESS);
759

760
	/*
761
	 * Get an extra reference on the operation. It'll be dropped when the
762
	 * operation completes.
763
	 */
764
	gb_operation_get(operation);
765
	ret = gb_operation_get_active(operation);
766
	if (ret)
767
		goto err_put;
768

769
	ret = gb_message_send(operation->request, gfp);
770
	if (ret)
771
		goto err_put_active;
772

773
	if (timeout) {
774
		operation->timer.expires = jiffies + msecs_to_jiffies(timeout);
775
		add_timer(&operation->timer);
776
	}
777

778
	return 0;
779

780
err_put_active:
781
	gb_operation_put_active(operation);
782
err_put:
783
	gb_operation_put(operation);
784

785
	return ret;
786
}
787
EXPORT_SYMBOL_GPL(gb_operation_request_send);
788

789
/*
790
 * Send a synchronous operation.  This function is expected to
791
 * block, returning only when the response has arrived, (or when an
792
 * error is detected.  The return value is the result of the
793
 * operation.
794
 */
795
int gb_operation_request_send_sync_timeout(struct gb_operation *operation,
796
					   unsigned int timeout)
797
{
798
	int ret;
799

800
	ret = gb_operation_request_send(operation, gb_operation_sync_callback,
801
					timeout, GFP_KERNEL);
802
	if (ret)
803
		return ret;
804

805
	ret = wait_for_completion_interruptible(&operation->completion);
806
	if (ret < 0) {
807
		/* Cancel the operation if interrupted */
808
		gb_operation_cancel(operation, -ECANCELED);
809
	}
810

811
	return gb_operation_result(operation);
812
}
813
EXPORT_SYMBOL_GPL(gb_operation_request_send_sync_timeout);
814

815
/*
816
 * Send a response for an incoming operation request.  A non-zero
817
 * errno indicates a failed operation.
818
 *
819
 * If there is any response payload, the incoming request handler is
820
 * responsible for allocating the response message.  Otherwise the
821
 * it can simply supply the result errno; this function will
822
 * allocate the response message if necessary.
823
 */
824
static int gb_operation_response_send(struct gb_operation *operation,
825
				      int errno)
826
{
827
	struct gb_connection *connection = operation->connection;
828
	int ret;
829

830
	if (!operation->response &&
831
	    !gb_operation_is_unidirectional(operation)) {
832
		if (!gb_operation_response_alloc(operation, 0, GFP_KERNEL))
833
			return -ENOMEM;
834
	}
835

836
	/* Record the result */
837
	if (!gb_operation_result_set(operation, errno)) {
838
		dev_err(&connection->hd->dev, "request result already set\n");
839
		return -EIO;	/* Shouldn't happen */
840
	}
841

842
	/* Sender of request does not care about response. */
843
	if (gb_operation_is_unidirectional(operation))
844
		return 0;
845

846
	/* Reference will be dropped when message has been sent. */
847
	gb_operation_get(operation);
848
	ret = gb_operation_get_active(operation);
849
	if (ret)
850
		goto err_put;
851

852
	/* Fill in the response header and send it */
853
	operation->response->header->result = gb_operation_errno_map(errno);
854

855
	ret = gb_message_send(operation->response, GFP_KERNEL);
856
	if (ret)
857
		goto err_put_active;
858

859
	return 0;
860

861
err_put_active:
862
	gb_operation_put_active(operation);
863
err_put:
864
	gb_operation_put(operation);
865

866
	return ret;
867
}
868

869
/*
870
 * This function is called when a message send request has completed.
871
 */
872
void greybus_message_sent(struct gb_host_device *hd,
873
			  struct gb_message *message, int status)
874
{
875
	struct gb_operation *operation = message->operation;
876
	struct gb_connection *connection = operation->connection;
877

878
	/*
879
	 * If the message was a response, we just need to drop our
880
	 * reference to the operation.  If an error occurred, report
881
	 * it.
882
	 *
883
	 * For requests, if there's no error and the operation in not
884
	 * unidirectional, there's nothing more to do until the response
885
	 * arrives. If an error occurred attempting to send it, or if the
886
	 * operation is unidrectional, record the result of the operation and
887
	 * schedule its completion.
888
	 */
889
	if (message == operation->response) {
890
		if (status) {
891
			dev_err(&connection->hd->dev,
892
				"%s: error sending response 0x%02x: %d\n",
893
				connection->name, operation->type, status);
894
		}
895

896
		gb_operation_put_active(operation);
897
		gb_operation_put(operation);
898
	} else if (status || gb_operation_is_unidirectional(operation)) {
899
		if (gb_operation_result_set(operation, status)) {
900
			queue_work(gb_operation_completion_wq,
901
				   &operation->work);
902
		}
903
	}
904
}
905
EXPORT_SYMBOL_GPL(greybus_message_sent);
906

907
/*
908
 * We've received data on a connection, and it doesn't look like a
909
 * response, so we assume it's a request.
910
 *
911
 * This is called in interrupt context, so just copy the incoming
912
 * data into the request buffer and handle the rest via workqueue.
913
 */
914
static void gb_connection_recv_request(struct gb_connection *connection,
915
				const struct gb_operation_msg_hdr *header,
916
				void *data, size_t size)
917
{
918
	struct gb_operation *operation;
919
	u16 operation_id;
920
	u8 type;
921
	int ret;
922

923
	operation_id = le16_to_cpu(header->operation_id);
924
	type = header->type;
925

926
	operation = gb_operation_create_incoming(connection, operation_id,
927
						 type, data, size);
928
	if (!operation) {
929
		dev_err(&connection->hd->dev,
930
			"%s: can't create incoming operation\n",
931
			connection->name);
932
		return;
933
	}
934

935
	ret = gb_operation_get_active(operation);
936
	if (ret) {
937
		gb_operation_put(operation);
938
		return;
939
	}
940
	trace_gb_message_recv_request(operation->request);
941

942
	/*
943
	 * The initial reference to the operation will be dropped when the
944
	 * request handler returns.
945
	 */
946
	if (gb_operation_result_set(operation, -EINPROGRESS))
947
		queue_work(connection->wq, &operation->work);
948
}
949

950
/*
951
 * We've received data that appears to be an operation response
952
 * message.  Look up the operation, and record that we've received
953
 * its response.
954
 *
955
 * This is called in interrupt context, so just copy the incoming
956
 * data into the response buffer and handle the rest via workqueue.
957
 */
958
static void gb_connection_recv_response(struct gb_connection *connection,
959
				const struct gb_operation_msg_hdr *header,
960
				void *data, size_t size)
961
{
962
	struct gb_operation *operation;
963
	struct gb_message *message;
964
	size_t message_size;
965
	u16 operation_id;
966
	int errno;
967

968
	operation_id = le16_to_cpu(header->operation_id);
969

970
	if (!operation_id) {
971
		dev_err_ratelimited(&connection->hd->dev,
972
				    "%s: invalid response id 0 received\n",
973
				    connection->name);
974
		return;
975
	}
976

977
	operation = gb_operation_find_outgoing(connection, operation_id);
978
	if (!operation) {
979
		dev_err_ratelimited(&connection->hd->dev,
980
				    "%s: unexpected response id 0x%04x received\n",
981
				    connection->name, operation_id);
982
		return;
983
	}
984

985
	errno = gb_operation_status_map(header->result);
986
	message = operation->response;
987
	message_size = sizeof(*header) + message->payload_size;
988
	if (!errno && size > message_size) {
989
		dev_err_ratelimited(&connection->hd->dev,
990
				    "%s: malformed response 0x%02x received (%zu > %zu)\n",
991
				    connection->name, header->type,
992
				    size, message_size);
993
		errno = -EMSGSIZE;
994
	} else if (!errno && size < message_size) {
995
		if (gb_operation_short_response_allowed(operation)) {
996
			message->payload_size = size - sizeof(*header);
997
		} else {
998
			dev_err_ratelimited(&connection->hd->dev,
999
					    "%s: short response 0x%02x received (%zu < %zu)\n",
1000
					    connection->name, header->type,
1001
					    size, message_size);
1002
			errno = -EMSGSIZE;
1003
		}
1004
	}
1005

1006
	/* We must ignore the payload if a bad status is returned */
1007
	if (errno)
1008
		size = sizeof(*header);
1009

1010
	/* The rest will be handled in work queue context */
1011
	if (gb_operation_result_set(operation, errno)) {
1012
		memcpy(message->buffer, data, size);
1013

1014
		trace_gb_message_recv_response(message);
1015

1016
		queue_work(gb_operation_completion_wq, &operation->work);
1017
	}
1018

1019
	gb_operation_put(operation);
1020
}
1021

1022
/*
1023
 * Handle data arriving on a connection.  As soon as we return the
1024
 * supplied data buffer will be reused (so unless we do something
1025
 * with, it's effectively dropped).
1026
 */
1027
void gb_connection_recv(struct gb_connection *connection,
1028
			void *data, size_t size)
1029
{
1030
	struct gb_operation_msg_hdr header;
1031
	struct device *dev = &connection->hd->dev;
1032
	size_t msg_size;
1033

1034
	if (connection->state == GB_CONNECTION_STATE_DISABLED ||
1035
	    gb_connection_is_offloaded(connection)) {
1036
		dev_warn_ratelimited(dev, "%s: dropping %zu received bytes\n",
1037
				     connection->name, size);
1038
		return;
1039
	}
1040

1041
	if (size < sizeof(header)) {
1042
		dev_err_ratelimited(dev, "%s: short message received\n",
1043
				    connection->name);
1044
		return;
1045
	}
1046

1047
	/* Use memcpy as data may be unaligned */
1048
	memcpy(&header, data, sizeof(header));
1049
	msg_size = le16_to_cpu(header.size);
1050
	if (size < msg_size) {
1051
		dev_err_ratelimited(dev,
1052
				    "%s: incomplete message 0x%04x of type 0x%02x received (%zu < %zu)\n",
1053
				    connection->name,
1054
				    le16_to_cpu(header.operation_id),
1055
				    header.type, size, msg_size);
1056
		return;		/* XXX Should still complete operation */
1057
	}
1058

1059
	if (header.type & GB_MESSAGE_TYPE_RESPONSE) {
1060
		gb_connection_recv_response(connection,	&header, data,
1061
					    msg_size);
1062
	} else {
1063
		gb_connection_recv_request(connection, &header, data,
1064
					   msg_size);
1065
	}
1066
}
1067

1068
/*
1069
 * Cancel an outgoing operation synchronously, and record the given error to
1070
 * indicate why.
1071
 */
1072
void gb_operation_cancel(struct gb_operation *operation, int errno)
1073
{
1074
	if (WARN_ON(gb_operation_is_incoming(operation)))
1075
		return;
1076

1077
	if (gb_operation_result_set(operation, errno)) {
1078
		gb_message_cancel(operation->request);
1079
		queue_work(gb_operation_completion_wq, &operation->work);
1080
	}
1081
	trace_gb_message_cancel_outgoing(operation->request);
1082

1083
	atomic_inc(&operation->waiters);
1084
	wait_event(gb_operation_cancellation_queue,
1085
		   !gb_operation_is_active(operation));
1086
	atomic_dec(&operation->waiters);
1087
}
1088
EXPORT_SYMBOL_GPL(gb_operation_cancel);
1089

1090
/*
1091
 * Cancel an incoming operation synchronously. Called during connection tear
1092
 * down.
1093
 */
1094
void gb_operation_cancel_incoming(struct gb_operation *operation, int errno)
1095
{
1096
	if (WARN_ON(!gb_operation_is_incoming(operation)))
1097
		return;
1098

1099
	if (!gb_operation_is_unidirectional(operation)) {
1100
		/*
1101
		 * Make sure the request handler has submitted the response
1102
		 * before cancelling it.
1103
		 */
1104
		flush_work(&operation->work);
1105
		if (!gb_operation_result_set(operation, errno))
1106
			gb_message_cancel(operation->response);
1107
	}
1108
	trace_gb_message_cancel_incoming(operation->response);
1109

1110
	atomic_inc(&operation->waiters);
1111
	wait_event(gb_operation_cancellation_queue,
1112
		   !gb_operation_is_active(operation));
1113
	atomic_dec(&operation->waiters);
1114
}
1115

1116
/**
1117
 * gb_operation_sync_timeout() - implement a "simple" synchronous operation
1118
 * @connection: the Greybus connection to send this to
1119
 * @type: the type of operation to send
1120
 * @request: pointer to a memory buffer to copy the request from
1121
 * @request_size: size of @request
1122
 * @response: pointer to a memory buffer to copy the response to
1123
 * @response_size: the size of @response.
1124
 * @timeout: operation timeout in milliseconds
1125
 *
1126
 * This function implements a simple synchronous Greybus operation.  It sends
1127
 * the provided operation request and waits (sleeps) until the corresponding
1128
 * operation response message has been successfully received, or an error
1129
 * occurs.  @request and @response are buffers to hold the request and response
1130
 * data respectively, and if they are not NULL, their size must be specified in
1131
 * @request_size and @response_size.
1132
 *
1133
 * If a response payload is to come back, and @response is not NULL,
1134
 * @response_size number of bytes will be copied into @response if the operation
1135
 * is successful.
1136
 *
1137
 * If there is an error, the response buffer is left alone.
1138
 */
1139
int gb_operation_sync_timeout(struct gb_connection *connection, int type,
1140
			      void *request, int request_size,
1141
			      void *response, int response_size,
1142
			      unsigned int timeout)
1143
{
1144
	struct gb_operation *operation;
1145
	int ret;
1146

1147
	if ((response_size && !response) ||
1148
	    (request_size && !request))
1149
		return -EINVAL;
1150

1151
	operation = gb_operation_create(connection, type,
1152
					request_size, response_size,
1153
					GFP_KERNEL);
1154
	if (!operation)
1155
		return -ENOMEM;
1156

1157
	if (request_size)
1158
		memcpy(operation->request->payload, request, request_size);
1159

1160
	ret = gb_operation_request_send_sync_timeout(operation, timeout);
1161
	if (ret) {
1162
		dev_err(&connection->hd->dev,
1163
			"%s: synchronous operation id 0x%04x of type 0x%02x failed: %d\n",
1164
			connection->name, operation->id, type, ret);
1165
	} else {
1166
		if (response_size) {
1167
			memcpy(response, operation->response->payload,
1168
			       response_size);
1169
		}
1170
	}
1171

1172
	gb_operation_put(operation);
1173

1174
	return ret;
1175
}
1176
EXPORT_SYMBOL_GPL(gb_operation_sync_timeout);
1177

1178
/**
1179
 * gb_operation_unidirectional_timeout() - initiate a unidirectional operation
1180
 * @connection:		connection to use
1181
 * @type:		type of operation to send
1182
 * @request:		memory buffer to copy the request from
1183
 * @request_size:	size of @request
1184
 * @timeout:		send timeout in milliseconds
1185
 *
1186
 * Initiate a unidirectional operation by sending a request message and
1187
 * waiting for it to be acknowledged as sent by the host device.
1188
 *
1189
 * Note that successful send of a unidirectional operation does not imply that
1190
 * the request as actually reached the remote end of the connection.
1191
 */
1192
int gb_operation_unidirectional_timeout(struct gb_connection *connection,
1193
					int type, void *request,
1194
					int request_size,
1195
					unsigned int timeout)
1196
{
1197
	struct gb_operation *operation;
1198
	int ret;
1199

1200
	if (request_size && !request)
1201
		return -EINVAL;
1202

1203
	operation = gb_operation_create_flags(connection, type,
1204
					      request_size, 0,
1205
					      GB_OPERATION_FLAG_UNIDIRECTIONAL,
1206
					      GFP_KERNEL);
1207
	if (!operation)
1208
		return -ENOMEM;
1209

1210
	if (request_size)
1211
		memcpy(operation->request->payload, request, request_size);
1212

1213
	ret = gb_operation_request_send_sync_timeout(operation, timeout);
1214
	if (ret) {
1215
		dev_err(&connection->hd->dev,
1216
			"%s: unidirectional operation of type 0x%02x failed: %d\n",
1217
			connection->name, type, ret);
1218
	}
1219

1220
	gb_operation_put(operation);
1221

1222
	return ret;
1223
}
1224
EXPORT_SYMBOL_GPL(gb_operation_unidirectional_timeout);
1225

1226
int __init gb_operation_init(void)
1227
{
1228
	gb_message_cache = kmem_cache_create("gb_message_cache",
1229
					     sizeof(struct gb_message), 0, 0,
1230
					     NULL);
1231
	if (!gb_message_cache)
1232
		return -ENOMEM;
1233

1234
	gb_operation_cache = kmem_cache_create("gb_operation_cache",
1235
					       sizeof(struct gb_operation), 0,
1236
					       0, NULL);
1237
	if (!gb_operation_cache)
1238
		goto err_destroy_message_cache;
1239

1240
	gb_operation_completion_wq = alloc_workqueue("greybus_completion",
1241
						     0, 0);
1242
	if (!gb_operation_completion_wq)
1243
		goto err_destroy_operation_cache;
1244

1245
	return 0;
1246

1247
err_destroy_operation_cache:
1248
	kmem_cache_destroy(gb_operation_cache);
1249
	gb_operation_cache = NULL;
1250
err_destroy_message_cache:
1251
	kmem_cache_destroy(gb_message_cache);
1252
	gb_message_cache = NULL;
1253

1254
	return -ENOMEM;
1255
}
1256

1257
void gb_operation_exit(void)
1258
{
1259
	destroy_workqueue(gb_operation_completion_wq);
1260
	gb_operation_completion_wq = NULL;
1261
	kmem_cache_destroy(gb_operation_cache);
1262
	gb_operation_cache = NULL;
1263
	kmem_cache_destroy(gb_message_cache);
1264
	gb_message_cache = NULL;
1265
}
1266

1267