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1 /*
2 * Public API and common code for kernel->userspace relay file support.
3 *
4 * See Documentation/filesystems/relay.txt for an overview.
5 *
6 * Copyright (C) 2002-2005 - Tom Zanussi (zanussi@us.ibm.com), IBM Corp
7 * Copyright (C) 1999-2005 - Karim Yaghmour (karim@opersys.com)
8 *
9 * Moved to kernel/relay.c by Paul Mundt, 2006.
10 * November 2006 - CPU hotplug support by Mathieu Desnoyers
11 * (mathieu.desnoyers@polymtl.ca)
12 *
13 * This file is released under the GPL.
14 */
15 #include <linux/errno.h>
16 #include <linux/stddef.h>
17 #include <linux/slab.h>
18 #include <linux/export.h>
19 #include <linux/string.h>
20 #include <linux/relay.h>
21 #include <linux/vmalloc.h>
22 #include <linux/mm.h>
23 #include <linux/cpu.h>
24 #include <linux/splice.h>
25
26 /* list of open channels, for cpu hotplug */
27 static DEFINE_MUTEX(relay_channels_mutex);
28 static LIST_HEAD(relay_channels);
29
30 /*
31 * close() vm_op implementation for relay file mapping.
32 */
33 static void relay_file_mmap_close(struct vm_area_struct *vma)
34 {
35 struct rchan_buf *buf = vma->vm_private_data;
36 buf->chan->cb->buf_unmapped(buf, vma->vm_file);
37 }
38
39 /*
40 * fault() vm_op implementation for relay file mapping.
41 */
42 static int relay_buf_fault(struct vm_fault *vmf)
43 {
44 struct page *page;
45 struct rchan_buf *buf = vmf->vma->vm_private_data;
46 pgoff_t pgoff = vmf->pgoff;
47
48 if (!buf)
49 return VM_FAULT_OOM;
50
51 page = vmalloc_to_page(buf->start + (pgoff << PAGE_SHIFT));
52 if (!page)
53 return VM_FAULT_SIGBUS;
54 get_page(page);
55 vmf->page = page;
56
57 return 0;
58 }
59
60 /*
61 * vm_ops for relay file mappings.
62 */
63 static const struct vm_operations_struct relay_file_mmap_ops = {
64 .fault = relay_buf_fault,
65 .close = relay_file_mmap_close,
66 };
67
68 /*
69 * allocate an array of pointers of struct page
70 */
71 static struct page **relay_alloc_page_array(unsigned int n_pages)
72 {
73 const size_t pa_size = n_pages * sizeof(struct page *);
74 if (pa_size > PAGE_SIZE)
75 return vzalloc(pa_size);
76 return kzalloc(pa_size, GFP_KERNEL);
77 }
78
79 /*
80 * free an array of pointers of struct page
81 */
82 static void relay_free_page_array(struct page **array)
83 {
84 kvfree(array);
85 }
86
87 /**
88 * relay_mmap_buf: - mmap channel buffer to process address space
89 * @buf: relay channel buffer
90 * @vma: vm_area_struct describing memory to be mapped
91 *
92 * Returns 0 if ok, negative on error
93 *
94 * Caller should already have grabbed mmap_sem.
95 */
96 static int relay_mmap_buf(struct rchan_buf *buf, struct vm_area_struct *vma)
97 {
98 unsigned long length = vma->vm_end - vma->vm_start;
99 struct file *filp = vma->vm_file;
100
101 if (!buf)
102 return -EBADF;
103
104 if (length != (unsigned long)buf->chan->alloc_size)
105 return -EINVAL;
106
107 vma->vm_ops = &relay_file_mmap_ops;
108 vma->vm_flags |= VM_DONTEXPAND;
109 vma->vm_private_data = buf;
110 buf->chan->cb->buf_mapped(buf, filp);
111
112 return 0;
113 }
114
115 /**
116 * relay_alloc_buf - allocate a channel buffer
117 * @buf: the buffer struct
118 * @size: total size of the buffer
119 *
120 * Returns a pointer to the resulting buffer, %NULL if unsuccessful. The
121 * passed in size will get page aligned, if it isn't already.
122 */
123 static void *relay_alloc_buf(struct rchan_buf *buf, size_t *size)
124 {
125 void *mem;
126 unsigned int i, j, n_pages;
127
128 *size = PAGE_ALIGN(*size);
129 n_pages = *size >> PAGE_SHIFT;
130
131 buf->page_array = relay_alloc_page_array(n_pages);
132 if (!buf->page_array)
133 return NULL;
134
135 for (i = 0; i < n_pages; i++) {
136 buf->page_array[i] = alloc_page(GFP_KERNEL);
137 if (unlikely(!buf->page_array[i]))
138 goto depopulate;
139 set_page_private(buf->page_array[i], (unsigned long)buf);
140 }
141 mem = vmap(buf->page_array, n_pages, VM_MAP, PAGE_KERNEL);
142 if (!mem)
143 goto depopulate;
144
145 memset(mem, 0, *size);
146 buf->page_count = n_pages;
147 return mem;
148
149 depopulate:
150 for (j = 0; j < i; j++)
151 __free_page(buf->page_array[j]);
152 relay_free_page_array(buf->page_array);
153 return NULL;
154 }
155
156 /**
157 * relay_create_buf - allocate and initialize a channel buffer
158 * @chan: the relay channel
159 *
160 * Returns channel buffer if successful, %NULL otherwise.
161 */
162 static struct rchan_buf *relay_create_buf(struct rchan *chan)
163 {
164 struct rchan_buf *buf;
165
166 if (chan->n_subbufs > UINT_MAX / sizeof(size_t *))
167 return NULL;
168
169 buf = kzalloc(sizeof(struct rchan_buf), GFP_KERNEL);
170 if (!buf)
171 return NULL;
172 buf->padding = kmalloc(chan->n_subbufs * sizeof(size_t *), GFP_KERNEL);
173 if (!buf->padding)
174 goto free_buf;
175
176 buf->start = relay_alloc_buf(buf, &chan->alloc_size);
177 if (!buf->start)
178 goto free_buf;
179
180 buf->chan = chan;
181 kref_get(&buf->chan->kref);
182 return buf;
183
184 free_buf:
185 kfree(buf->padding);
186 kfree(buf);
187 return NULL;
188 }
189
190 /**
191 * relay_destroy_channel - free the channel struct
192 * @kref: target kernel reference that contains the relay channel
193 *
194 * Should only be called from kref_put().
195 */
196 static void relay_destroy_channel(struct kref *kref)
197 {
198 struct rchan *chan = container_of(kref, struct rchan, kref);
199 kfree(chan);
200 }
201
202 /**
203 * relay_destroy_buf - destroy an rchan_buf struct and associated buffer
204 * @buf: the buffer struct
205 */
206 static void relay_destroy_buf(struct rchan_buf *buf)
207 {
208 struct rchan *chan = buf->chan;
209 unsigned int i;
210
211 if (likely(buf->start)) {
212 vunmap(buf->start);
213 for (i = 0; i < buf->page_count; i++)
214 __free_page(buf->page_array[i]);
215 relay_free_page_array(buf->page_array);
216 }
217 *per_cpu_ptr(chan->buf, buf->cpu) = NULL;
218 kfree(buf->padding);
219 kfree(buf);
220 kref_put(&chan->kref, relay_destroy_channel);
221 }
222
223 /**
224 * relay_remove_buf - remove a channel buffer
225 * @kref: target kernel reference that contains the relay buffer
226 *
227 * Removes the file from the filesystem, which also frees the
228 * rchan_buf_struct and the channel buffer. Should only be called from
229 * kref_put().
230 */
231 static void relay_remove_buf(struct kref *kref)
232 {
233 struct rchan_buf *buf = container_of(kref, struct rchan_buf, kref);
234 relay_destroy_buf(buf);
235 }
236
237 /**
238 * relay_buf_empty - boolean, is the channel buffer empty?
239 * @buf: channel buffer
240 *
241 * Returns 1 if the buffer is empty, 0 otherwise.
242 */
243 static int relay_buf_empty(struct rchan_buf *buf)
244 {
245 return (buf->subbufs_produced - buf->subbufs_consumed) ? 0 : 1;
246 }
247
248 /**
249 * relay_buf_full - boolean, is the channel buffer full?
250 * @buf: channel buffer
251 *
252 * Returns 1 if the buffer is full, 0 otherwise.
253 */
254 int relay_buf_full(struct rchan_buf *buf)
255 {
256 size_t ready = buf->subbufs_produced - buf->subbufs_consumed;
257 return (ready >= buf->chan->n_subbufs) ? 1 : 0;
258 }
259 EXPORT_SYMBOL_GPL(relay_buf_full);
260
261 /*
262 * High-level relay kernel API and associated functions.
263 */
264
265 /*
266 * rchan_callback implementations defining default channel behavior. Used
267 * in place of corresponding NULL values in client callback struct.
268 */
269
270 /*
271 * subbuf_start() default callback. Does nothing.
272 */
273 static int subbuf_start_default_callback (struct rchan_buf *buf,
274 void *subbuf,
275 void *prev_subbuf,
276 size_t prev_padding)
277 {
278 if (relay_buf_full(buf))
279 return 0;
280
281 return 1;
282 }
283
284 /*
285 * buf_mapped() default callback. Does nothing.
286 */
287 static void buf_mapped_default_callback(struct rchan_buf *buf,
288 struct file *filp)
289 {
290 }
291
292 /*
293 * buf_unmapped() default callback. Does nothing.
294 */
295 static void buf_unmapped_default_callback(struct rchan_buf *buf,
296 struct file *filp)
297 {
298 }
299
300 /*
301 * create_buf_file_create() default callback. Does nothing.
302 */
303 static struct dentry *create_buf_file_default_callback(const char *filename,
304 struct dentry *parent,
305 umode_t mode,
306 struct rchan_buf *buf,
307 int *is_global)
308 {
309 return NULL;
310 }
311
312 /*
313 * remove_buf_file() default callback. Does nothing.
314 */
315 static int remove_buf_file_default_callback(struct dentry *dentry)
316 {
317 return -EINVAL;
318 }
319
320 /* relay channel default callbacks */
321 static struct rchan_callbacks default_channel_callbacks = {
322 .subbuf_start = subbuf_start_default_callback,
323 .buf_mapped = buf_mapped_default_callback,
324 .buf_unmapped = buf_unmapped_default_callback,
325 .create_buf_file = create_buf_file_default_callback,
326 .remove_buf_file = remove_buf_file_default_callback,
327 };
328
329 /**
330 * wakeup_readers - wake up readers waiting on a channel
331 * @work: contains the channel buffer
332 *
333 * This is the function used to defer reader waking
334 */
335 static void wakeup_readers(struct irq_work *work)
336 {
337 struct rchan_buf *buf;
338
339 buf = container_of(work, struct rchan_buf, wakeup_work);
340 wake_up_interruptible(&buf->read_wait);
341 }
342
343 /**
344 * __relay_reset - reset a channel buffer
345 * @buf: the channel buffer
346 * @init: 1 if this is a first-time initialization
347 *
348 * See relay_reset() for description of effect.
349 */
350 static void __relay_reset(struct rchan_buf *buf, unsigned int init)
351 {
352 size_t i;
353
354 if (init) {
355 init_waitqueue_head(&buf->read_wait);
356 kref_init(&buf->kref);
357 init_irq_work(&buf->wakeup_work, wakeup_readers);
358 } else {
359 irq_work_sync(&buf->wakeup_work);
360 }
361
362 buf->subbufs_produced = 0;
363 buf->subbufs_consumed = 0;
364 buf->bytes_consumed = 0;
365 buf->finalized = 0;
366 buf->data = buf->start;
367 buf->offset = 0;
368
369 for (i = 0; i < buf->chan->n_subbufs; i++)
370 buf->padding[i] = 0;
371
372 buf->chan->cb->subbuf_start(buf, buf->data, NULL, 0);
373 }
374
375 /**
376 * relay_reset - reset the channel
377 * @chan: the channel
378 *
379 * This has the effect of erasing all data from all channel buffers
380 * and restarting the channel in its initial state. The buffers
381 * are not freed, so any mappings are still in effect.
382 *
383 * NOTE. Care should be taken that the channel isn't actually
384 * being used by anything when this call is made.
385 */
386 void relay_reset(struct rchan *chan)
387 {
388 struct rchan_buf *buf;
389 unsigned int i;
390
391 if (!chan)
392 return;
393
394 if (chan->is_global && (buf = *per_cpu_ptr(chan->buf, 0))) {
395 __relay_reset(buf, 0);
396 return;
397 }
398
399 mutex_lock(&relay_channels_mutex);
400 for_each_possible_cpu(i)
401 if ((buf = *per_cpu_ptr(chan->buf, i)))
402 __relay_reset(buf, 0);
403 mutex_unlock(&relay_channels_mutex);
404 }
405 EXPORT_SYMBOL_GPL(relay_reset);
406
407 static inline void relay_set_buf_dentry(struct rchan_buf *buf,
408 struct dentry *dentry)
409 {
410 buf->dentry = dentry;
411 d_inode(buf->dentry)->i_size = buf->early_bytes;
412 }
413
414 static struct dentry *relay_create_buf_file(struct rchan *chan,
415 struct rchan_buf *buf,
416 unsigned int cpu)
417 {
418 struct dentry *dentry;
419 char *tmpname;
420
421 tmpname = kzalloc(NAME_MAX + 1, GFP_KERNEL);
422 if (!tmpname)
423 return NULL;
424 snprintf(tmpname, NAME_MAX, "%s%d", chan->base_filename, cpu);
425
426 /* Create file in fs */
427 dentry = chan->cb->create_buf_file(tmpname, chan->parent,
428 S_IRUSR, buf,
429 &chan->is_global);
430
431 kfree(tmpname);
432
433 return dentry;
434 }
435
436 /*
437 * relay_open_buf - create a new relay channel buffer
438 *
439 * used by relay_open() and CPU hotplug.
440 */
441 static struct rchan_buf *relay_open_buf(struct rchan *chan, unsigned int cpu)
442 {
443 struct rchan_buf *buf = NULL;
444 struct dentry *dentry;
445
446 if (chan->is_global)
447 return *per_cpu_ptr(chan->buf, 0);
448
449 buf = relay_create_buf(chan);
450 if (!buf)
451 return NULL;
452
453 if (chan->has_base_filename) {
454 dentry = relay_create_buf_file(chan, buf, cpu);
455 if (!dentry)
456 goto free_buf;
457 relay_set_buf_dentry(buf, dentry);
458 } else {
459 /* Only retrieve global info, nothing more, nothing less */
460 dentry = chan->cb->create_buf_file(NULL, NULL,
461 S_IRUSR, buf,
462 &chan->is_global);
463 if (WARN_ON(dentry))
464 goto free_buf;
465 }
466
467 buf->cpu = cpu;
468 __relay_reset(buf, 1);
469
470 if(chan->is_global) {
471 *per_cpu_ptr(chan->buf, 0) = buf;
472 buf->cpu = 0;
473 }
474
475 return buf;
476
477 free_buf:
478 relay_destroy_buf(buf);
479 return NULL;
480 }
481
482 /**
483 * relay_close_buf - close a channel buffer
484 * @buf: channel buffer
485 *
486 * Marks the buffer finalized and restores the default callbacks.
487 * The channel buffer and channel buffer data structure are then freed
488 * automatically when the last reference is given up.
489 */
490 static void relay_close_buf(struct rchan_buf *buf)
491 {
492 buf->finalized = 1;
493 irq_work_sync(&buf->wakeup_work);
494 buf->chan->cb->remove_buf_file(buf->dentry);
495 kref_put(&buf->kref, relay_remove_buf);
496 }
497
498 static void setup_callbacks(struct rchan *chan,
499 struct rchan_callbacks *cb)
500 {
501 if (!cb) {
502 chan->cb = &default_channel_callbacks;
503 return;
504 }
505
506 if (!cb->subbuf_start)
507 cb->subbuf_start = subbuf_start_default_callback;
508 if (!cb->buf_mapped)
509 cb->buf_mapped = buf_mapped_default_callback;
510 if (!cb->buf_unmapped)
511 cb->buf_unmapped = buf_unmapped_default_callback;
512 if (!cb->create_buf_file)
513 cb->create_buf_file = create_buf_file_default_callback;
514 if (!cb->remove_buf_file)
515 cb->remove_buf_file = remove_buf_file_default_callback;
516 chan->cb = cb;
517 }
518
519 int relay_prepare_cpu(unsigned int cpu)
520 {
521 struct rchan *chan;
522 struct rchan_buf *buf;
523
524 mutex_lock(&relay_channels_mutex);
525 list_for_each_entry(chan, &relay_channels, list) {
526 if ((buf = *per_cpu_ptr(chan->buf, cpu)))
527 continue;
528 buf = relay_open_buf(chan, cpu);
529 if (!buf) {
530 pr_err("relay: cpu %d buffer creation failed\n", cpu);
531 mutex_unlock(&relay_channels_mutex);
532 return -ENOMEM;
533 }
534 *per_cpu_ptr(chan->buf, cpu) = buf;
535 }
536 mutex_unlock(&relay_channels_mutex);
537 return 0;
538 }
539
540 /**
541 * relay_open - create a new relay channel
542 * @base_filename: base name of files to create, %NULL for buffering only
543 * @parent: dentry of parent directory, %NULL for root directory or buffer
544 * @subbuf_size: size of sub-buffers
545 * @n_subbufs: number of sub-buffers
546 * @cb: client callback functions
547 * @private_data: user-defined data
548 *
549 * Returns channel pointer if successful, %NULL otherwise.
550 *
551 * Creates a channel buffer for each cpu using the sizes and
552 * attributes specified. The created channel buffer files
553 * will be named base_filename0...base_filenameN-1. File
554 * permissions will be %S_IRUSR.
555 *
556 * If opening a buffer (@parent = NULL) that you later wish to register
557 * in a filesystem, call relay_late_setup_files() once the @parent dentry
558 * is available.
559 */
560 struct rchan *relay_open(const char *base_filename,
561 struct dentry *parent,
562 size_t subbuf_size,
563 size_t n_subbufs,
564 struct rchan_callbacks *cb,
565 void *private_data)
566 {
567 unsigned int i;
568 struct rchan *chan;
569 struct rchan_buf *buf;
570
571 if (!(subbuf_size && n_subbufs))
572 return NULL;
573 if (subbuf_size > UINT_MAX / n_subbufs)
574 return NULL;
575
576 chan = kzalloc(sizeof(struct rchan), GFP_KERNEL);
577 if (!chan)
578 return NULL;
579
580 chan->buf = alloc_percpu(struct rchan_buf *);
581 chan->version = RELAYFS_CHANNEL_VERSION;
582 chan->n_subbufs = n_subbufs;
583 chan->subbuf_size = subbuf_size;
584 chan->alloc_size = PAGE_ALIGN(subbuf_size * n_subbufs);
585 chan->parent = parent;
586 chan->private_data = private_data;
587 if (base_filename) {
588 chan->has_base_filename = 1;
589 strlcpy(chan->base_filename, base_filename, NAME_MAX);
590 }
591 setup_callbacks(chan, cb);
592 kref_init(&chan->kref);
593
594 mutex_lock(&relay_channels_mutex);
595 for_each_online_cpu(i) {
596 buf = relay_open_buf(chan, i);
597 if (!buf)
598 goto free_bufs;
599 *per_cpu_ptr(chan->buf, i) = buf;
600 }
601 list_add(&chan->list, &relay_channels);
602 mutex_unlock(&relay_channels_mutex);
603
604 return chan;
605
606 free_bufs:
607 for_each_possible_cpu(i) {
608 if ((buf = *per_cpu_ptr(chan->buf, i)))
609 relay_close_buf(buf);
610 }
611
612 kref_put(&chan->kref, relay_destroy_channel);
613 mutex_unlock(&relay_channels_mutex);
614 kfree(chan);
615 return NULL;
616 }
617 EXPORT_SYMBOL_GPL(relay_open);
618
619 struct rchan_percpu_buf_dispatcher {
620 struct rchan_buf *buf;
621 struct dentry *dentry;
622 };
623
624 /* Called in atomic context. */
625 static void __relay_set_buf_dentry(void *info)
626 {
627 struct rchan_percpu_buf_dispatcher *p = info;
628
629 relay_set_buf_dentry(p->buf, p->dentry);
630 }
631
632 /**
633 * relay_late_setup_files - triggers file creation
634 * @chan: channel to operate on
635 * @base_filename: base name of files to create
636 * @parent: dentry of parent directory, %NULL for root directory
637 *
638 * Returns 0 if successful, non-zero otherwise.
639 *
640 * Use to setup files for a previously buffer-only channel created
641 * by relay_open() with a NULL parent dentry.
642 *
643 * For example, this is useful for perfomring early tracing in kernel,
644 * before VFS is up and then exposing the early results once the dentry
645 * is available.
646 */
647 int relay_late_setup_files(struct rchan *chan,
648 const char *base_filename,
649 struct dentry *parent)
650 {
651 int err = 0;
652 unsigned int i, curr_cpu;
653 unsigned long flags;
654 struct dentry *dentry;
655 struct rchan_buf *buf;
656 struct rchan_percpu_buf_dispatcher disp;
657
658 if (!chan || !base_filename)
659 return -EINVAL;
660
661 strlcpy(chan->base_filename, base_filename, NAME_MAX);
662
663 mutex_lock(&relay_channels_mutex);
664 /* Is chan already set up? */
665 if (unlikely(chan->has_base_filename)) {
666 mutex_unlock(&relay_channels_mutex);
667 return -EEXIST;
668 }
669 chan->has_base_filename = 1;
670 chan->parent = parent;
671
672 if (chan->is_global) {
673 err = -EINVAL;
674 buf = *per_cpu_ptr(chan->buf, 0);
675 if (!WARN_ON_ONCE(!buf)) {
676 dentry = relay_create_buf_file(chan, buf, 0);
677 if (dentry && !WARN_ON_ONCE(!chan->is_global)) {
678 relay_set_buf_dentry(buf, dentry);
679 err = 0;
680 }
681 }
682 mutex_unlock(&relay_channels_mutex);
683 return err;
684 }
685
686 curr_cpu = get_cpu();
687 /*
688 * The CPU hotplug notifier ran before us and created buffers with
689 * no files associated. So it's safe to call relay_setup_buf_file()
690 * on all currently online CPUs.
691 */
692 for_each_online_cpu(i) {
693 buf = *per_cpu_ptr(chan->buf, i);
694 if (unlikely(!buf)) {
695 WARN_ONCE(1, KERN_ERR "CPU has no buffer!\n");
696 err = -EINVAL;
697 break;
698 }
699
700 dentry = relay_create_buf_file(chan, buf, i);
701 if (unlikely(!dentry)) {
702 err = -EINVAL;
703 break;
704 }
705
706 if (curr_cpu == i) {
707 local_irq_save(flags);
708 relay_set_buf_dentry(buf, dentry);
709 local_irq_restore(flags);
710 } else {
711 disp.buf = buf;
712 disp.dentry = dentry;
713 smp_mb();
714 /* relay_channels_mutex must be held, so wait. */
715 err = smp_call_function_single(i,
716 __relay_set_buf_dentry,
717 &disp, 1);
718 }
719 if (unlikely(err))
720 break;
721 }
722 put_cpu();
723 mutex_unlock(&relay_channels_mutex);
724
725 return err;
726 }
727 EXPORT_SYMBOL_GPL(relay_late_setup_files);
728
729 /**
730 * relay_switch_subbuf - switch to a new sub-buffer
731 * @buf: channel buffer
732 * @length: size of current event
733 *
734 * Returns either the length passed in or 0 if full.
735 *
736 * Performs sub-buffer-switch tasks such as invoking callbacks,
737 * updating padding counts, waking up readers, etc.
738 */
739 size_t relay_switch_subbuf(struct rchan_buf *buf, size_t length)
740 {
741 void *old, *new;
742 size_t old_subbuf, new_subbuf;
743
744 if (unlikely(length > buf->chan->subbuf_size))
745 goto toobig;
746
747 if (buf->offset != buf->chan->subbuf_size + 1) {
748 buf->prev_padding = buf->chan->subbuf_size - buf->offset;
749 old_subbuf = buf->subbufs_produced % buf->chan->n_subbufs;
750 buf->padding[old_subbuf] = buf->prev_padding;
751 buf->subbufs_produced++;
752 if (buf->dentry)
753 d_inode(buf->dentry)->i_size +=
754 buf->chan->subbuf_size -
755 buf->padding[old_subbuf];
756 else
757 buf->early_bytes += buf->chan->subbuf_size -
758 buf->padding[old_subbuf];
759 smp_mb();
760 if (waitqueue_active(&buf->read_wait)) {
761 /*
762 * Calling wake_up_interruptible() from here
763 * will deadlock if we happen to be logging
764 * from the scheduler (trying to re-grab
765 * rq->lock), so defer it.
766 */
767 irq_work_queue(&buf->wakeup_work);
768 }
769 }
770
771 old = buf->data;
772 new_subbuf = buf->subbufs_produced % buf->chan->n_subbufs;
773 new = buf->start + new_subbuf * buf->chan->subbuf_size;
774 buf->offset = 0;
775 if (!buf->chan->cb->subbuf_start(buf, new, old, buf->prev_padding)) {
776 buf->offset = buf->chan->subbuf_size + 1;
777 return 0;
778 }
779 buf->data = new;
780 buf->padding[new_subbuf] = 0;
781
782 if (unlikely(length + buf->offset > buf->chan->subbuf_size))
783 goto toobig;
784
785 return length;
786
787 toobig:
788 buf->chan->last_toobig = length;
789 return 0;
790 }
791 EXPORT_SYMBOL_GPL(relay_switch_subbuf);
792
793 /**
794 * relay_subbufs_consumed - update the buffer's sub-buffers-consumed count
795 * @chan: the channel
796 * @cpu: the cpu associated with the channel buffer to update
797 * @subbufs_consumed: number of sub-buffers to add to current buf's count
798 *
799 * Adds to the channel buffer's consumed sub-buffer count.
800 * subbufs_consumed should be the number of sub-buffers newly consumed,
801 * not the total consumed.
802 *
803 * NOTE. Kernel clients don't need to call this function if the channel
804 * mode is 'overwrite'.
805 */
806 void relay_subbufs_consumed(struct rchan *chan,
807 unsigned int cpu,
808 size_t subbufs_consumed)
809 {
810 struct rchan_buf *buf;
811
812 if (!chan || cpu >= NR_CPUS)
813 return;
814
815 buf = *per_cpu_ptr(chan->buf, cpu);
816 if (!buf || subbufs_consumed > chan->n_subbufs)
817 return;
818
819 if (subbufs_consumed > buf->subbufs_produced - buf->subbufs_consumed)
820 buf->subbufs_consumed = buf->subbufs_produced;
821 else
822 buf->subbufs_consumed += subbufs_consumed;
823 }
824 EXPORT_SYMBOL_GPL(relay_subbufs_consumed);
825
826 /**
827 * relay_close - close the channel
828 * @chan: the channel
829 *
830 * Closes all channel buffers and frees the channel.
831 */
832 void relay_close(struct rchan *chan)
833 {
834 struct rchan_buf *buf;
835 unsigned int i;
836
837 if (!chan)
838 return;
839
840 mutex_lock(&relay_channels_mutex);
841 if (chan->is_global && (buf = *per_cpu_ptr(chan->buf, 0)))
842 relay_close_buf(buf);
843 else
844 for_each_possible_cpu(i)
845 if ((buf = *per_cpu_ptr(chan->buf, i)))
846 relay_close_buf(buf);
847
848 if (chan->last_toobig)
849 printk(KERN_WARNING "relay: one or more items not logged "
850 "[item size (%zd) > sub-buffer size (%zd)]\n",
851 chan->last_toobig, chan->subbuf_size);
852
853 list_del(&chan->list);
854 kref_put(&chan->kref, relay_destroy_channel);
855 mutex_unlock(&relay_channels_mutex);
856 }
857 EXPORT_SYMBOL_GPL(relay_close);
858
859 /**
860 * relay_flush - close the channel
861 * @chan: the channel
862 *
863 * Flushes all channel buffers, i.e. forces buffer switch.
864 */
865 void relay_flush(struct rchan *chan)
866 {
867 struct rchan_buf *buf;
868 unsigned int i;
869
870 if (!chan)
871 return;
872
873 if (chan->is_global && (buf = *per_cpu_ptr(chan->buf, 0))) {
874 relay_switch_subbuf(buf, 0);
875 return;
876 }
877
878 mutex_lock(&relay_channels_mutex);
879 for_each_possible_cpu(i)
880 if ((buf = *per_cpu_ptr(chan->buf, i)))
881 relay_switch_subbuf(buf, 0);
882 mutex_unlock(&relay_channels_mutex);
883 }
884 EXPORT_SYMBOL_GPL(relay_flush);
885
886 /**
887 * relay_file_open - open file op for relay files
888 * @inode: the inode
889 * @filp: the file
890 *
891 * Increments the channel buffer refcount.
892 */
893 static int relay_file_open(struct inode *inode, struct file *filp)
894 {
895 struct rchan_buf *buf = inode->i_private;
896 kref_get(&buf->kref);
897 filp->private_data = buf;
898
899 return nonseekable_open(inode, filp);
900 }
901
902 /**
903 * relay_file_mmap - mmap file op for relay files
904 * @filp: the file
905 * @vma: the vma describing what to map
906 *
907 * Calls upon relay_mmap_buf() to map the file into user space.
908 */
909 static int relay_file_mmap(struct file *filp, struct vm_area_struct *vma)
910 {
911 struct rchan_buf *buf = filp->private_data;
912 return relay_mmap_buf(buf, vma);
913 }
914
915 /**
916 * relay_file_poll - poll file op for relay files
917 * @filp: the file
918 * @wait: poll table
919 *
920 * Poll implemention.
921 */
922 static unsigned int relay_file_poll(struct file *filp, poll_table *wait)
923 {
924 unsigned int mask = 0;
925 struct rchan_buf *buf = filp->private_data;
926
927 if (buf->finalized)
928 return POLLERR;
929
930 if (filp->f_mode & FMODE_READ) {
931 poll_wait(filp, &buf->read_wait, wait);
932 if (!relay_buf_empty(buf))
933 mask |= POLLIN | POLLRDNORM;
934 }
935
936 return mask;
937 }
938
939 /**
940 * relay_file_release - release file op for relay files
941 * @inode: the inode
942 * @filp: the file
943 *
944 * Decrements the channel refcount, as the filesystem is
945 * no longer using it.
946 */
947 static int relay_file_release(struct inode *inode, struct file *filp)
948 {
949 struct rchan_buf *buf = filp->private_data;
950 kref_put(&buf->kref, relay_remove_buf);
951
952 return 0;
953 }
954
955 /*
956 * relay_file_read_consume - update the consumed count for the buffer
957 */
958 static void relay_file_read_consume(struct rchan_buf *buf,
959 size_t read_pos,
960 size_t bytes_consumed)
961 {
962 size_t subbuf_size = buf->chan->subbuf_size;
963 size_t n_subbufs = buf->chan->n_subbufs;
964 size_t read_subbuf;
965
966 if (buf->subbufs_produced == buf->subbufs_consumed &&
967 buf->offset == buf->bytes_consumed)
968 return;
969
970 if (buf->bytes_consumed + bytes_consumed > subbuf_size) {
971 relay_subbufs_consumed(buf->chan, buf->cpu, 1);
972 buf->bytes_consumed = 0;
973 }
974
975 buf->bytes_consumed += bytes_consumed;
976 if (!read_pos)
977 read_subbuf = buf->subbufs_consumed % n_subbufs;
978 else
979 read_subbuf = read_pos / buf->chan->subbuf_size;
980 if (buf->bytes_consumed + buf->padding[read_subbuf] == subbuf_size) {
981 if ((read_subbuf == buf->subbufs_produced % n_subbufs) &&
982 (buf->offset == subbuf_size))
983 return;
984 relay_subbufs_consumed(buf->chan, buf->cpu, 1);
985 buf->bytes_consumed = 0;
986 }
987 }
988
989 /*
990 * relay_file_read_avail - boolean, are there unconsumed bytes available?
991 */
992 static int relay_file_read_avail(struct rchan_buf *buf, size_t read_pos)
993 {
994 size_t subbuf_size = buf->chan->subbuf_size;
995 size_t n_subbufs = buf->chan->n_subbufs;
996 size_t produced = buf->subbufs_produced;
997 size_t consumed = buf->subbufs_consumed;
998
999 relay_file_read_consume(buf, read_pos, 0);
1000
1001 consumed = buf->subbufs_consumed;
1002
1003 if (unlikely(buf->offset > subbuf_size)) {
1004 if (produced == consumed)
1005 return 0;
1006 return 1;
1007 }
1008
1009 if (unlikely(produced - consumed >= n_subbufs)) {
1010 consumed = produced - n_subbufs + 1;
1011 buf->subbufs_consumed = consumed;
1012 buf->bytes_consumed = 0;
1013 }
1014
1015 produced = (produced % n_subbufs) * subbuf_size + buf->offset;
1016 consumed = (consumed % n_subbufs) * subbuf_size + buf->bytes_consumed;
1017
1018 if (consumed > produced)
1019 produced += n_subbufs * subbuf_size;
1020
1021 if (consumed == produced) {
1022 if (buf->offset == subbuf_size &&
1023 buf->subbufs_produced > buf->subbufs_consumed)
1024 return 1;
1025 return 0;
1026 }
1027
1028 return 1;
1029 }
1030
1031 /**
1032 * relay_file_read_subbuf_avail - return bytes available in sub-buffer
1033 * @read_pos: file read position
1034 * @buf: relay channel buffer
1035 */
1036 static size_t relay_file_read_subbuf_avail(size_t read_pos,
1037 struct rchan_buf *buf)
1038 {
1039 size_t padding, avail = 0;
1040 size_t read_subbuf, read_offset, write_subbuf, write_offset;
1041 size_t subbuf_size = buf->chan->subbuf_size;
1042
1043 write_subbuf = (buf->data - buf->start) / subbuf_size;
1044 write_offset = buf->offset > subbuf_size ? subbuf_size : buf->offset;
1045 read_subbuf = read_pos / subbuf_size;
1046 read_offset = read_pos % subbuf_size;
1047 padding = buf->padding[read_subbuf];
1048
1049 if (read_subbuf == write_subbuf) {
1050 if (read_offset + padding < write_offset)
1051 avail = write_offset - (read_offset + padding);
1052 } else
1053 avail = (subbuf_size - padding) - read_offset;
1054
1055 return avail;
1056 }
1057
1058 /**
1059 * relay_file_read_start_pos - find the first available byte to read
1060 * @read_pos: file read position
1061 * @buf: relay channel buffer
1062 *
1063 * If the @read_pos is in the middle of padding, return the
1064 * position of the first actually available byte, otherwise
1065 * return the original value.
1066 */
1067 static size_t relay_file_read_start_pos(size_t read_pos,
1068 struct rchan_buf *buf)
1069 {
1070 size_t read_subbuf, padding, padding_start, padding_end;
1071 size_t subbuf_size = buf->chan->subbuf_size;
1072 size_t n_subbufs = buf->chan->n_subbufs;
1073 size_t consumed = buf->subbufs_consumed % n_subbufs;
1074
1075 if (!read_pos)
1076 read_pos = consumed * subbuf_size + buf->bytes_consumed;
1077 read_subbuf = read_pos / subbuf_size;
1078 padding = buf->padding[read_subbuf];
1079 padding_start = (read_subbuf + 1) * subbuf_size - padding;
1080 padding_end = (read_subbuf + 1) * subbuf_size;
1081 if (read_pos >= padding_start && read_pos < padding_end) {
1082 read_subbuf = (read_subbuf + 1) % n_subbufs;
1083 read_pos = read_subbuf * subbuf_size;
1084 }
1085
1086 return read_pos;
1087 }
1088
1089 /**
1090 * relay_file_read_end_pos - return the new read position
1091 * @read_pos: file read position
1092 * @buf: relay channel buffer
1093 * @count: number of bytes to be read
1094 */
1095 static size_t relay_file_read_end_pos(struct rchan_buf *buf,
1096 size_t read_pos,
1097 size_t count)
1098 {
1099 size_t read_subbuf, padding, end_pos;
1100 size_t subbuf_size = buf->chan->subbuf_size;
1101 size_t n_subbufs = buf->chan->n_subbufs;
1102
1103 read_subbuf = read_pos / subbuf_size;
1104 padding = buf->padding[read_subbuf];
1105 if (read_pos % subbuf_size + count + padding == subbuf_size)
1106 end_pos = (read_subbuf + 1) * subbuf_size;
1107 else
1108 end_pos = read_pos + count;
1109 if (end_pos >= subbuf_size * n_subbufs)
1110 end_pos = 0;
1111
1112 return end_pos;
1113 }
1114
1115 static ssize_t relay_file_read(struct file *filp,
1116 char __user *buffer,
1117 size_t count,
1118 loff_t *ppos)
1119 {
1120 struct rchan_buf *buf = filp->private_data;
1121 size_t read_start, avail;
1122 size_t written = 0;
1123 int ret;
1124
1125 if (!count)
1126 return 0;
1127
1128 inode_lock(file_inode(filp));
1129 do {
1130 void *from;
1131
1132 if (!relay_file_read_avail(buf, *ppos))
1133 break;
1134
1135 read_start = relay_file_read_start_pos(*ppos, buf);
1136 avail = relay_file_read_subbuf_avail(read_start, buf);
1137 if (!avail)
1138 break;
1139
1140 avail = min(count, avail);
1141 from = buf->start + read_start;
1142 ret = avail;
1143 if (copy_to_user(buffer, from, avail))
1144 break;
1145
1146 buffer += ret;
1147 written += ret;
1148 count -= ret;
1149
1150 relay_file_read_consume(buf, read_start, ret);
1151 *ppos = relay_file_read_end_pos(buf, read_start, ret);
1152 } while (count);
1153 inode_unlock(file_inode(filp));
1154
1155 return written;
1156 }
1157
1158 static void relay_consume_bytes(struct rchan_buf *rbuf, int bytes_consumed)
1159 {
1160 rbuf->bytes_consumed += bytes_consumed;
1161
1162 if (rbuf->bytes_consumed >= rbuf->chan->subbuf_size) {
1163 relay_subbufs_consumed(rbuf->chan, rbuf->cpu, 1);
1164 rbuf->bytes_consumed %= rbuf->chan->subbuf_size;
1165 }
1166 }
1167
1168 static void relay_pipe_buf_release(struct pipe_inode_info *pipe,
1169 struct pipe_buffer *buf)
1170 {
1171 struct rchan_buf *rbuf;
1172
1173 rbuf = (struct rchan_buf *)page_private(buf->page);
1174 relay_consume_bytes(rbuf, buf->private);
1175 }
1176
1177 static const struct pipe_buf_operations relay_pipe_buf_ops = {
1178 .can_merge = 0,
1179 .confirm = generic_pipe_buf_confirm,
1180 .release = relay_pipe_buf_release,
1181 .steal = generic_pipe_buf_steal,
1182 .get = generic_pipe_buf_get,
1183 };
1184
1185 static void relay_page_release(struct splice_pipe_desc *spd, unsigned int i)
1186 {
1187 }
1188
1189 /*
1190 * subbuf_splice_actor - splice up to one subbuf's worth of data
1191 */
1192 static ssize_t subbuf_splice_actor(struct file *in,
1193 loff_t *ppos,
1194 struct pipe_inode_info *pipe,
1195 size_t len,
1196 unsigned int flags,
1197 int *nonpad_ret)
1198 {
1199 unsigned int pidx, poff, total_len, subbuf_pages, nr_pages;
1200 struct rchan_buf *rbuf = in->private_data;
1201 unsigned int subbuf_size = rbuf->chan->subbuf_size;
1202 uint64_t pos = (uint64_t) *ppos;
1203 uint32_t alloc_size = (uint32_t) rbuf->chan->alloc_size;
1204 size_t read_start = (size_t) do_div(pos, alloc_size);
1205 size_t read_subbuf = read_start / subbuf_size;
1206 size_t padding = rbuf->padding[read_subbuf];
1207 size_t nonpad_end = read_subbuf * subbuf_size + subbuf_size - padding;
1208 struct page *pages[PIPE_DEF_BUFFERS];
1209 struct partial_page partial[PIPE_DEF_BUFFERS];
1210 struct splice_pipe_desc spd = {
1211 .pages = pages,
1212 .nr_pages = 0,
1213 .nr_pages_max = PIPE_DEF_BUFFERS,
1214 .partial = partial,
1215 .ops = &relay_pipe_buf_ops,
1216 .spd_release = relay_page_release,
1217 };
1218 ssize_t ret;
1219
1220 if (rbuf->subbufs_produced == rbuf->subbufs_consumed)
1221 return 0;
1222 if (splice_grow_spd(pipe, &spd))
1223 return -ENOMEM;
1224
1225 /*
1226 * Adjust read len, if longer than what is available
1227 */
1228 if (len > (subbuf_size - read_start % subbuf_size))
1229 len = subbuf_size - read_start % subbuf_size;
1230
1231 subbuf_pages = rbuf->chan->alloc_size >> PAGE_SHIFT;
1232 pidx = (read_start / PAGE_SIZE) % subbuf_pages;
1233 poff = read_start & ~PAGE_MASK;
1234 nr_pages = min_t(unsigned int, subbuf_pages, spd.nr_pages_max);
1235
1236 for (total_len = 0; spd.nr_pages < nr_pages; spd.nr_pages++) {
1237 unsigned int this_len, this_end, private;
1238 unsigned int cur_pos = read_start + total_len;
1239
1240 if (!len)
1241 break;
1242
1243 this_len = min_t(unsigned long, len, PAGE_SIZE - poff);
1244 private = this_len;
1245
1246 spd.pages[spd.nr_pages] = rbuf->page_array[pidx];
1247 spd.partial[spd.nr_pages].offset = poff;
1248
1249 this_end = cur_pos + this_len;
1250 if (this_end >= nonpad_end) {
1251 this_len = nonpad_end - cur_pos;
1252 private = this_len + padding;
1253 }
1254 spd.partial[spd.nr_pages].len = this_len;
1255 spd.partial[spd.nr_pages].private = private;
1256
1257 len -= this_len;
1258 total_len += this_len;
1259 poff = 0;
1260 pidx = (pidx + 1) % subbuf_pages;
1261
1262 if (this_end >= nonpad_end) {
1263 spd.nr_pages++;
1264 break;
1265 }
1266 }
1267
1268 ret = 0;
1269 if (!spd.nr_pages)
1270 goto out;
1271
1272 ret = *nonpad_ret = splice_to_pipe(pipe, &spd);
1273 if (ret < 0 || ret < total_len)
1274 goto out;
1275
1276 if (read_start + ret == nonpad_end)
1277 ret += padding;
1278
1279 out:
1280 splice_shrink_spd(&spd);
1281 return ret;
1282 }
1283
1284 static ssize_t relay_file_splice_read(struct file *in,
1285 loff_t *ppos,
1286 struct pipe_inode_info *pipe,
1287 size_t len,
1288 unsigned int flags)
1289 {
1290 ssize_t spliced;
1291 int ret;
1292 int nonpad_ret = 0;
1293
1294 ret = 0;
1295 spliced = 0;
1296
1297 while (len && !spliced) {
1298 ret = subbuf_splice_actor(in, ppos, pipe, len, flags, &nonpad_ret);
1299 if (ret < 0)
1300 break;
1301 else if (!ret) {
1302 if (flags & SPLICE_F_NONBLOCK)
1303 ret = -EAGAIN;
1304 break;
1305 }
1306
1307 *ppos += ret;
1308 if (ret > len)
1309 len = 0;
1310 else
1311 len -= ret;
1312 spliced += nonpad_ret;
1313 nonpad_ret = 0;
1314 }
1315
1316 if (spliced)
1317 return spliced;
1318
1319 return ret;
1320 }
1321
1322 const struct file_operations relay_file_operations = {
1323 .open = relay_file_open,
1324 .poll = relay_file_poll,
1325 .mmap = relay_file_mmap,
1326 .read = relay_file_read,
1327 .llseek = no_llseek,
1328 .release = relay_file_release,
1329 .splice_read = relay_file_splice_read,
1330 };
1331 EXPORT_SYMBOL_GPL(relay_file_operations);