file.c source code [linux/fs/kernfs/file.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* fs/kernfs/file.c - kernfs file implementation
4	*
5	* Copyright (c) 2001-3 Patrick Mochel
6	* Copyright (c) 2007 SUSE Linux Products GmbH
7	* Copyright (c) 2007, 2013 Tejun Heo <tj@kernel.org>
8	*/
9
10	#include <linux/fs.h>
11	#include <linux/seq_file.h>
12	#include <linux/slab.h>
13	#include <linux/poll.h>
14	#include <linux/pagemap.h>
15	#include <linux/sched/mm.h>
16	#include <linux/fsnotify.h>
17	#include <linux/uio.h>
18
19	#include "kernfs-internal.h"
20
21	struct kernfs_open_node {
22	struct rcu_head rcu_head;
23	atomic_t event;
24	wait_queue_head_t poll;
25	struct list_head files; / goes through kernfs_open_file.list /
26	unsigned int nr_mmapped;
27	unsigned int nr_to_release;
28	};
29
30	/*
31	* kernfs_notify() may be called from any context and bounces notifications
32	* through a work item. To minimize space overhead in kernfs_node, the
33	* pending queue is implemented as a singly linked list of kernfs_nodes.
34	* The list is terminated with the self pointer so that whether a
35	* kernfs_node is on the list or not can be determined by testing the next
36	* pointer for %NULL.
37	*/
38	#define KERNFS_NOTIFY_EOL ((void *)&kernfs_notify_list)
39
40	static DEFINE_SPINLOCK(kernfs_notify_lock);
41	static struct kernfs_node *kernfs_notify_list = KERNFS_NOTIFY_EOL;
42
43	static inline struct mutex kernfs_open_file_mutex_ptr(struct* kernfs_node *kn)
44	{
45	int idx = hash_ptr(ptr: kn, NR_KERNFS_LOCK_BITS);
46
47	return &kernfs_locks->open_file_mutex[idx];
48	}
49
50	static inline struct mutex kernfs_open_file_mutex_lock(struct* kernfs_node *kn)
51	{
52	struct mutex *lock;
53
54	lock = kernfs_open_file_mutex_ptr(kn);
55
56	mutex_lock(lock);
57
58	return lock;
59	}
60
61	/**
62	* of_on - Get the kernfs_open_node of the specified kernfs_open_file
63	* @of: target kernfs_open_file
64	*
65	* Return: the kernfs_open_node of the kernfs_open_file
66	*/
67	static struct kernfs_open_node of_on(struct* kernfs_open_file *of)
68	{
69	return rcu_dereference_protected(of->kn->attr.open,
70	!list_empty(&of->list));
71	}
72
73	/**
74	* kernfs_deref_open_node_locked - Get kernfs_open_node corresponding to @kn
75	*
76	* @kn: target kernfs_node.
77	*
78	* Fetch and return ->attr.open of @kn when caller holds the
79	* kernfs_open_file_mutex_ptr(kn).
80	*
81	* Update of ->attr.open happens under kernfs_open_file_mutex_ptr(kn). So when
82	* the caller guarantees that this mutex is being held, other updaters can't
83	* change ->attr.open and this means that we can safely deref ->attr.open
84	* outside RCU read-side critical section.
85	*
86	* The caller needs to make sure that kernfs_open_file_mutex is held.
87	*
88	* Return: @kn->attr.open when kernfs_open_file_mutex is held.
89	*/
90	static struct kernfs_open_node *
91	kernfs_deref_open_node_locked(struct kernfs_node *kn)
92	{
93	return rcu_dereference_protected(kn->attr.open,
94	lockdep_is_held(kernfs_open_file_mutex_ptr(kn)));
95	}
96
97	static struct kernfs_open_file kernfs_of(struct* file *file)
98	{
99	return ((struct seq_file *)file->private_data)->private;
100	}
101
102	/*
103	* Determine the kernfs_ops for the given kernfs_node. This function must
104	* be called while holding an active reference.
105	*/
106	static const struct kernfs_ops kernfs_ops(struct* kernfs_node *kn)
107	{
108	if (kn->flags & KERNFS_LOCKDEP)
109	lockdep_assert_held(kn);
110	return kn->attr.ops;
111	}
112
113	/*
114	* As kernfs_seq_stop() is also called after kernfs_seq_start() or
115	* kernfs_seq_next() failure, it needs to distinguish whether it's stopping
116	* a seq_file iteration which is fully initialized with an active reference
117	* or an aborted kernfs_seq_start() due to get_active failure. The
118	* position pointer is the only context for each seq_file iteration and
119	* thus the stop condition should be encoded in it. As the return value is
120	* directly visible to userland, ERR_PTR(-ENODEV) is the only acceptable
121	* choice to indicate get_active failure.
122	*
123	* Unfortunately, this is complicated due to the optional custom seq_file
124	* operations which may return ERR_PTR(-ENODEV) too. kernfs_seq_stop()
125	* can't distinguish whether ERR_PTR(-ENODEV) is from get_active failure or
126	* custom seq_file operations and thus can't decide whether put_active
127	* should be performed or not only on ERR_PTR(-ENODEV).
128	*
129	* This is worked around by factoring out the custom seq_stop() and
130	* put_active part into kernfs_seq_stop_active(), skipping it from
131	* kernfs_seq_stop() if ERR_PTR(-ENODEV) while invoking it directly after
132	* custom seq_file operations fail with ERR_PTR(-ENODEV) - this ensures
133	* that kernfs_seq_stop_active() is skipped only after get_active failure.
134	*/
135	static void kernfs_seq_stop_active(struct seq_file sf, void* *v)
136	{
137	struct kernfs_open_file *of = sf->private;
138	const struct kernfs_ops *ops = kernfs_ops(kn: of->kn);
139
140	if (ops->seq_stop)
141	ops->seq_stop(sf, v);
142	kernfs_put_active(kn: of->kn);
143	}
144
145	static void kernfs_seq_start(struct* seq_file sf, loff_t ppos)
146	{
147	struct kernfs_open_file *of = sf->private;
148	const struct kernfs_ops *ops;
149
150	/*
151	* @of->mutex nests outside active ref and is primarily to ensure that
152	* the ops aren't called concurrently for the same open file.
153	*/
154	mutex_lock(&of->mutex);
155	if (!kernfs_get_active(kn: of->kn))
156	return ERR_PTR(error: -ENODEV);
157
158	ops = kernfs_ops(kn: of->kn);
159	if (ops->seq_start) {
160	void *next = ops->seq_start(sf, ppos);
161	/ see the comment above kernfs_seq_stop_active() /
162	if (next == ERR_PTR(error: -ENODEV))
163	kernfs_seq_stop_active(sf, v: next);
164	return next;
165	}
166	return single_start(sf, ppos);
167	}
168
169	static void kernfs_seq_next(struct* seq_file sf, void* v, loff_t ppos)
170	{
171	struct kernfs_open_file *of = sf->private;
172	const struct kernfs_ops *ops = kernfs_ops(kn: of->kn);
173
174	if (ops->seq_next) {
175	void *next = ops->seq_next(sf, v, ppos);
176	/ see the comment above kernfs_seq_stop_active() /
177	if (next == ERR_PTR(error: -ENODEV))
178	kernfs_seq_stop_active(sf, v: next);
179	return next;
180	} else {
181	/*
182	* The same behavior and code as single_open(), always
183	* terminate after the initial read.
184	*/
185	++*ppos;
186	return NULL;
187	}
188	}
189
190	static void kernfs_seq_stop(struct seq_file sf, void* *v)
191	{
192	struct kernfs_open_file *of = sf->private;
193
194	if (v != ERR_PTR(error: -ENODEV))
195	kernfs_seq_stop_active(sf, v);
196	mutex_unlock(lock: &of->mutex);
197	}
198
199	static int kernfs_seq_show(struct seq_file sf, void* *v)
200	{
201	struct kernfs_open_file *of = sf->private;
202
203	of->event = atomic_read(v: &of_on(of)->event);
204
205	return of->kn->attr.ops->seq_show(sf, v);
206	}
207
208	static const struct seq_operations kernfs_seq_ops = {
209	.start = kernfs_seq_start,
210	.next = kernfs_seq_next,
211	.stop = kernfs_seq_stop,
212	.show = kernfs_seq_show,
213	};
214
215	/*
216	* As reading a bin file can have side-effects, the exact offset and bytes
217	* specified in read(2) call should be passed to the read callback making
218	* it difficult to use seq_file. Implement simplistic custom buffering for
219	* bin files.
220	*/
221	static ssize_t kernfs_file_read_iter(struct kiocb iocb, struct* iov_iter *iter)
222	{
223	struct kernfs_open_file *of = kernfs_of(file: iocb->ki_filp);
224	ssize_t len = min_t(size_t, iov_iter_count(iter), PAGE_SIZE);
225	const struct kernfs_ops *ops;
226	char *buf;
227
228	buf = of->prealloc_buf;
229	if (buf)
230	mutex_lock(&of->prealloc_mutex);
231	else
232	buf = kmalloc(size: len, GFP_KERNEL);
233	if (!buf)
234	return -ENOMEM;
235
236	/*
237	* @of->mutex nests outside active ref and is used both to ensure that
238	* the ops aren't called concurrently for the same open file.
239	*/
240	mutex_lock(&of->mutex);
241	if (!kernfs_get_active(kn: of->kn)) {
242	len = -ENODEV;
243	mutex_unlock(lock: &of->mutex);
244	goto out_free;
245	}
246
247	of->event = atomic_read(v: &of_on(of)->event);
248
249	ops = kernfs_ops(kn: of->kn);
250	if (ops->read)
251	len = ops->read(of, buf, len, iocb->ki_pos);
252	else
253	len = -EINVAL;
254
255	kernfs_put_active(kn: of->kn);
256	mutex_unlock(lock: &of->mutex);
257
258	if (len < `0`)
259	goto out_free;
260
261	if (copy_to_iter(addr: buf, bytes: len, i: iter) != len) {
262	len = -EFAULT;
263	goto out_free;
264	}
265
266	iocb->ki_pos += len;
267
268	out_free:
269	if (buf == of->prealloc_buf)
270	mutex_unlock(lock: &of->prealloc_mutex);
271	else
272	kfree(objp: buf);
273	return len;
274	}
275
276	static ssize_t kernfs_fop_read_iter(struct kiocb iocb, struct* iov_iter *iter)
277	{
278	if (kernfs_of(file: iocb->ki_filp)->kn->flags & KERNFS_HAS_SEQ_SHOW)
279	return seq_read_iter(iocb, iter);
280	return kernfs_file_read_iter(iocb, iter);
281	}
282
283	/*
284	* Copy data in from userland and pass it to the matching kernfs write
285	* operation.
286	*
287	* There is no easy way for us to know if userspace is only doing a partial
288	* write, so we don't support them. We expect the entire buffer to come on
289	* the first write. Hint: if you're writing a value, first read the file,
290	* modify only the value you're changing, then write entire buffer
291	* back.
292	*/
293	static ssize_t kernfs_fop_write_iter(struct kiocb iocb, struct* iov_iter *iter)
294	{
295	struct kernfs_open_file *of = kernfs_of(file: iocb->ki_filp);
296	ssize_t len = iov_iter_count(i: iter);
297	const struct kernfs_ops *ops;
298	char *buf;
299
300	if (of->atomic_write_len) {
301	if (len > of->atomic_write_len)
302	return -E2BIG;
303	} else {
304	len = min_t(size_t, len, PAGE_SIZE);
305	}
306
307	buf = of->prealloc_buf;
308	if (buf)
309	mutex_lock(&of->prealloc_mutex);
310	else
311	buf = kmalloc(size: len + `1`, GFP_KERNEL);
312	if (!buf)
313	return -ENOMEM;
314
315	if (copy_from_iter(addr: buf, bytes: len, i: iter) != len) {
316	len = -EFAULT;
317	goto out_free;
318	}
319	buf[len] = `'\0'`; / guarantee string termination /
320
321	/*
322	* @of->mutex nests outside active ref and is used both to ensure that
323	* the ops aren't called concurrently for the same open file.
324	*/
325	mutex_lock(&of->mutex);
326	if (!kernfs_get_active(kn: of->kn)) {
327	mutex_unlock(lock: &of->mutex);
328	len = -ENODEV;
329	goto out_free;
330	}
331
332	ops = kernfs_ops(kn: of->kn);
333	if (ops->write)
334	len = ops->write(of, buf, len, iocb->ki_pos);
335	else
336	len = -EINVAL;
337
338	kernfs_put_active(kn: of->kn);
339	mutex_unlock(lock: &of->mutex);
340
341	if (len > `0`)
342	iocb->ki_pos += len;
343
344	out_free:
345	if (buf == of->prealloc_buf)
346	mutex_unlock(lock: &of->prealloc_mutex);
347	else
348	kfree(objp: buf);
349	return len;
350	}
351
352	static void kernfs_vma_open(struct vm_area_struct *vma)
353	{
354	struct file *file = vma->vm_file;
355	struct kernfs_open_file *of = kernfs_of(file);
356
357	if (!of->vm_ops)
358	return;
359
360	if (!kernfs_get_active(kn: of->kn))
361	return;
362
363	if (of->vm_ops->open)
364	of->vm_ops->open(vma);
365
366	kernfs_put_active(kn: of->kn);
367	}
368
369	static vm_fault_t kernfs_vma_fault(struct vm_fault *vmf)
370	{
371	struct file *file = vmf->vma->vm_file;
372	struct kernfs_open_file *of = kernfs_of(file);
373	vm_fault_t ret;
374
375	if (!of->vm_ops)
376	return VM_FAULT_SIGBUS;
377
378	if (!kernfs_get_active(kn: of->kn))
379	return VM_FAULT_SIGBUS;
380
381	ret = VM_FAULT_SIGBUS;
382	if (of->vm_ops->fault)
383	ret = of->vm_ops->fault(vmf);
384
385	kernfs_put_active(kn: of->kn);
386	return ret;
387	}
388
389	static vm_fault_t kernfs_vma_page_mkwrite(struct vm_fault *vmf)
390	{
391	struct file *file = vmf->vma->vm_file;
392	struct kernfs_open_file *of = kernfs_of(file);
393	vm_fault_t ret;
394
395	if (!of->vm_ops)
396	return VM_FAULT_SIGBUS;
397
398	if (!kernfs_get_active(kn: of->kn))
399	return VM_FAULT_SIGBUS;
400
401	ret = `0`;
402	if (of->vm_ops->page_mkwrite)
403	ret = of->vm_ops->page_mkwrite(vmf);
404	else
405	file_update_time(file);
406
407	kernfs_put_active(kn: of->kn);
408	return ret;
409	}
410
411	static int kernfs_vma_access(struct vm_area_struct vma, unsigned* long addr,
412	void buf, int* len, int write)
413	{
414	struct file *file = vma->vm_file;
415	struct kernfs_open_file *of = kernfs_of(file);
416	int ret;
417
418	if (!of->vm_ops)
419	return -EINVAL;
420
421	if (!kernfs_get_active(kn: of->kn))
422	return -EINVAL;
423
424	ret = -EINVAL;
425	if (of->vm_ops->access)
426	ret = of->vm_ops->access(vma, addr, buf, len, write);
427
428	kernfs_put_active(kn: of->kn);
429	return ret;
430	}
431
432	static const struct vm_operations_struct kernfs_vm_ops = {
433	.open = kernfs_vma_open,
434	.fault = kernfs_vma_fault,
435	.page_mkwrite = kernfs_vma_page_mkwrite,
436	.access = kernfs_vma_access,
437	};
438
439	static int kernfs_fop_mmap(struct file file, struct* vm_area_struct *vma)
440	{
441	struct kernfs_open_file *of = kernfs_of(file);
442	const struct kernfs_ops *ops;
443	int rc;
444
445	/*
446	* mmap path and of->mutex are prone to triggering spurious lockdep
447	* warnings and we don't want to add spurious locking dependency
448	* between the two. Check whether mmap is actually implemented
449	* without grabbing @of->mutex by testing HAS_MMAP flag. See the
450	* comment in kernfs_fop_open() for more details.
451	*/
452	if (!(of->kn->flags & KERNFS_HAS_MMAP))
453	return -ENODEV;
454
455	mutex_lock(&of->mutex);
456
457	rc = -ENODEV;
458	if (!kernfs_get_active(kn: of->kn))
459	goto out_unlock;
460
461	ops = kernfs_ops(kn: of->kn);
462	rc = ops->mmap(of, vma);
463	if (rc)
464	goto out_put;
465
466	/*
467	* PowerPC's pci_mmap of legacy_mem uses shmem_zero_setup()
468	* to satisfy versions of X which crash if the mmap fails: that
469	* substitutes a new vm_file, and we don't then want bin_vm_ops.
470	*/
471	if (vma->vm_file != file)
472	goto out_put;
473
474	rc = -EINVAL;
475	if (of->mmapped && of->vm_ops != vma->vm_ops)
476	goto out_put;
477
478	/*
479	* It is not possible to successfully wrap close.
480	* So error if someone is trying to use close.
481	*/
482	if (vma->vm_ops && vma->vm_ops->close)
483	goto out_put;
484
485	rc = `0`;
486	if (!of->mmapped) {
487	of->mmapped = true;
488	of_on(of)->nr_mmapped++;
489	of->vm_ops = vma->vm_ops;
490	}
491	vma->vm_ops = &kernfs_vm_ops;
492	out_put:
493	kernfs_put_active(kn: of->kn);
494	out_unlock:
495	mutex_unlock(lock: &of->mutex);
496
497	return rc;
498	}
499
500	/**
501	* kernfs_get_open_node - get or create kernfs_open_node
502	* @kn: target kernfs_node
503	* @of: kernfs_open_file for this instance of open
504	*
505	* If @kn->attr.open exists, increment its reference count; otherwise,
506	* create one. @of is chained to the files list.
507	*
508	* Locking:
509	* Kernel thread context (may sleep).
510	*
511	* Return:
512	* %0 on success, -errno on failure.
513	*/
514	static int kernfs_get_open_node(struct kernfs_node *kn,
515	struct kernfs_open_file *of)
516	{
517	struct kernfs_open_node *on;
518	struct mutex *mutex;
519
520	mutex = kernfs_open_file_mutex_lock(kn);
521	on = kernfs_deref_open_node_locked(kn);
522
523	if (!on) {
524	/ not there, initialize a new one /
525	on = kzalloc(size: sizeof(*on), GFP_KERNEL);
526	if (!on) {
527	mutex_unlock(lock: mutex);
528	return -ENOMEM;
529	}
530	atomic_set(v: &on->event, i: `1`);
531	init_waitqueue_head(&on->poll);
532	INIT_LIST_HEAD(list: &on->files);
533	rcu_assign_pointer(kn->attr.open, on);
534	}
535
536	list_add_tail(new: &of->list, head: &on->files);
537	if (kn->flags & KERNFS_HAS_RELEASE)
538	on->nr_to_release++;
539
540	mutex_unlock(lock: mutex);
541	return `0`;
542	}
543
544	/**
545	* kernfs_unlink_open_file - Unlink @of from @kn.
546	*
547	* @kn: target kernfs_node
548	* @of: associated kernfs_open_file
549	* @open_failed: ->open() failed, cancel ->release()
550	*
551	* Unlink @of from list of @kn's associated open files. If list of
552	* associated open files becomes empty, disassociate and free
553	* kernfs_open_node.
554	*
555	* LOCKING:
556	* None.
557	*/
558	static void kernfs_unlink_open_file(struct kernfs_node *kn,
559	struct kernfs_open_file *of,
560	bool open_failed)
561	{
562	struct kernfs_open_node *on;
563	struct mutex *mutex;
564
565	mutex = kernfs_open_file_mutex_lock(kn);
566
567	on = kernfs_deref_open_node_locked(kn);
568	if (!on) {
569	mutex_unlock(lock: mutex);
570	return;
571	}
572
573	if (of) {
574	if (kn->flags & KERNFS_HAS_RELEASE) {
575	WARN_ON_ONCE(of->released == open_failed);
576	if (open_failed)
577	on->nr_to_release--;
578	}
579	if (of->mmapped)
580	on->nr_mmapped--;
581	list_del(entry: &of->list);
582	}
583
584	if (list_empty(head: &on->files)) {
585	rcu_assign_pointer(kn->attr.open, NULL);
586	kfree_rcu(on, rcu_head);
587	}
588
589	mutex_unlock(lock: mutex);
590	}
591
592	static int kernfs_fop_open(struct inode inode, struct* file *file)
593	{
594	struct kernfs_node *kn = inode->i_private;
595	struct kernfs_root *root = kernfs_root(kn);
596	const struct kernfs_ops *ops;
597	struct kernfs_open_file *of;
598	bool has_read, has_write, has_mmap;
599	int error = -EACCES;
600
601	if (!kernfs_get_active(kn))
602	return -ENODEV;
603
604	ops = kernfs_ops(kn);
605
606	has_read = ops->seq_show \|\| ops->read \|\| ops->mmap;
607	has_write = ops->write \|\| ops->mmap;
608	has_mmap = ops->mmap;
609
610	/ see the flag definition for details /
611	if (root->flags & KERNFS_ROOT_EXTRA_OPEN_PERM_CHECK) {
612	if ((file->f_mode & FMODE_WRITE) &&
613	(!(inode->i_mode & S_IWUGO) \|\| !has_write))
614	goto err_out;
615
616	if ((file->f_mode & FMODE_READ) &&
617	(!(inode->i_mode & S_IRUGO) \|\| !has_read))
618	goto err_out;
619	}
620
621	/ allocate a kernfs_open_file for the file /
622	error = -ENOMEM;
623	of = kzalloc(size: sizeof(struct kernfs_open_file), GFP_KERNEL);
624	if (!of)
625	goto err_out;
626
627	/*
628	* The following is done to give a different lockdep key to
629	* @of->mutex for files which implement mmap. This is a rather
630	* crude way to avoid false positive lockdep warning around
631	* mm->mmap_lock - mmap nests @of->mutex under mm->mmap_lock and
632	* reading /sys/block/sda/trace/act_mask grabs sr_mutex, under
633	* which mm->mmap_lock nests, while holding @of->mutex. As each
634	* open file has a separate mutex, it's okay as long as those don't
635	* happen on the same file. At this point, we can't easily give
636	* each file a separate locking class. Let's differentiate on
637	* whether the file has mmap or not for now.
638	*
639	* For similar reasons, writable and readonly files are given different
640	* lockdep key, because the writable file /sys/power/resume may call vfs
641	* lookup helpers for arbitrary paths and readonly files can be read by
642	* overlayfs from vfs helpers when sysfs is a lower layer of overalyfs.
643	*
644	* All three cases look the same. They're supposed to
645	* look that way and give @of->mutex different static lockdep keys.
646	*/
647	if (has_mmap)
648	mutex_init(&of->mutex);
649	else if (file->f_mode & FMODE_WRITE)
650	mutex_init(&of->mutex);
651	else
652	mutex_init(&of->mutex);
653
654	of->kn = kn;
655	of->file = file;
656
657	/*
658	* Write path needs to atomic_write_len outside active reference.
659	* Cache it in open_file. See kernfs_fop_write_iter() for details.
660	*/
661	of->atomic_write_len = ops->atomic_write_len;
662
663	error = -EINVAL;
664	/*
665	* ->seq_show is incompatible with ->prealloc,
666	* as seq_read does its own allocation.
667	* ->read must be used instead.
668	*/
669	if (ops->prealloc && ops->seq_show)
670	goto err_free;
671	if (ops->prealloc) {
672	int len = of->atomic_write_len ?: PAGE_SIZE;
673	of->prealloc_buf = kmalloc(size: len + `1`, GFP_KERNEL);
674	error = -ENOMEM;
675	if (!of->prealloc_buf)
676	goto err_free;
677	mutex_init(&of->prealloc_mutex);
678	}
679
680	/*
681	* Always instantiate seq_file even if read access doesn't use
682	* seq_file or is not requested. This unifies private data access
683	* and readable regular files are the vast majority anyway.
684	*/
685	if (ops->seq_show)
686	error = seq_open(file, &kernfs_seq_ops);
687	else
688	error = seq_open(file, NULL);
689	if (error)
690	goto err_free;
691
692	of->seq_file = file->private_data;
693	of->seq_file->private = of;
694
695	/ seq_file clears PWRITE unconditionally, restore it if WRITE /
696	if (file->f_mode & FMODE_WRITE)
697	file->f_mode \|= FMODE_PWRITE;
698
699	/ make sure we have open node struct /
700	error = kernfs_get_open_node(kn, of);
701	if (error)
702	goto err_seq_release;
703
704	if (ops->open) {
705	/ nobody has access to @of yet, skip @of->mutex /
706	error = ops->open(of);
707	if (error)
708	goto err_put_node;
709	}
710
711	/ open succeeded, put active references /
712	kernfs_put_active(kn);
713	return `0`;
714
715	err_put_node:
716	kernfs_unlink_open_file(kn, of, open_failed: true);
717	err_seq_release:
718	seq_release(inode, file);
719	err_free:
720	kfree(objp: of->prealloc_buf);
721	kfree(objp: of);
722	err_out:
723	kernfs_put_active(kn);
724	return error;
725	}
726
727	/ used from release/drain to ensure that ->release() is called exactly once /
728	static void kernfs_release_file(struct kernfs_node *kn,
729	struct kernfs_open_file *of)
730	{
731	/*
732	* @of is guaranteed to have no other file operations in flight and
733	* we just want to synchronize release and drain paths.
734	* @kernfs_open_file_mutex_ptr(kn) is enough. @of->mutex can't be used
735	* here because drain path may be called from places which can
736	* cause circular dependency.
737	*/
738	lockdep_assert_held(kernfs_open_file_mutex_ptr(kn));
739
740	if (!of->released) {
741	/*
742	* A file is never detached without being released and we
743	* need to be able to release files which are deactivated
744	* and being drained. Don't use kernfs_ops().
745	*/
746	kn->attr.ops->release(of);
747	of->released = true;
748	of_on(of)->nr_to_release--;
749	}
750	}
751
752	static int kernfs_fop_release(struct inode inode, struct* file *filp)
753	{
754	struct kernfs_node *kn = inode->i_private;
755	struct kernfs_open_file *of = kernfs_of(file: filp);
756
757	if (kn->flags & KERNFS_HAS_RELEASE) {
758	struct mutex *mutex;
759
760	mutex = kernfs_open_file_mutex_lock(kn);
761	kernfs_release_file(kn, of);
762	mutex_unlock(lock: mutex);
763	}
764
765	kernfs_unlink_open_file(kn, of, open_failed: false);
766	seq_release(inode, filp);
767	kfree(objp: of->prealloc_buf);
768	kfree(objp: of);
769
770	return `0`;
771	}
772
773	bool kernfs_should_drain_open_files(struct kernfs_node *kn)
774	{
775	struct kernfs_open_node *on;
776	bool ret;
777
778	/*
779	* @kn being deactivated guarantees that @kn->attr.open can't change
780	* beneath us making the lockless test below safe.
781	*/
782	WARN_ON_ONCE(atomic_read(&kn->active) != KN_DEACTIVATED_BIAS);
783
784	rcu_read_lock();
785	on = rcu_dereference(kn->attr.open);
786	ret = on && (on->nr_mmapped \|\| on->nr_to_release);
787	rcu_read_unlock();
788
789	return ret;
790	}
791
792	void kernfs_drain_open_files(struct kernfs_node *kn)
793	{
794	struct kernfs_open_node *on;
795	struct kernfs_open_file *of;
796	struct mutex *mutex;
797
798	mutex = kernfs_open_file_mutex_lock(kn);
799	on = kernfs_deref_open_node_locked(kn);
800	if (!on) {
801	mutex_unlock(lock: mutex);
802	return;
803	}
804
805	list_for_each_entry(of, &on->files, list) {
806	struct inode *inode = file_inode(f: of->file);
807
808	if (of->mmapped) {
809	unmap_mapping_range(mapping: inode->i_mapping, holebegin: `0`, holelen: `0`, even_cows: `1`);
810	of->mmapped = false;
811	on->nr_mmapped--;
812	}
813
814	if (kn->flags & KERNFS_HAS_RELEASE)
815	kernfs_release_file(kn, of);
816	}
817
818	WARN_ON_ONCE(on->nr_mmapped \|\| on->nr_to_release);
819	mutex_unlock(lock: mutex);
820	}
821
822	/*
823	* Kernfs attribute files are pollable. The idea is that you read
824	* the content and then you use 'poll' or 'select' to wait for
825	* the content to change. When the content changes (assuming the
826	* manager for the kobject supports notification), poll will
827	* return EPOLLERR\|EPOLLPRI, and select will return the fd whether
828	* it is waiting for read, write, or exceptions.
829	* Once poll/select indicates that the value has changed, you
830	* need to close and re-open the file, or seek to 0 and read again.
831	* Reminder: this only works for attributes which actively support
832	* it, and it is not possible to test an attribute from userspace
833	* to see if it supports poll (Neither 'poll' nor 'select' return
834	* an appropriate error code). When in doubt, set a suitable timeout value.
835	*/
836	__poll_t kernfs_generic_poll(struct kernfs_open_file of, poll_table wait)
837	{
838	struct kernfs_open_node *on = of_on(of);
839
840	poll_wait(filp: of->file, wait_address: &on->poll, p: wait);
841
842	if (of->event != atomic_read(v: &on->event))
843	return DEFAULT_POLLMASK\|EPOLLERR\|EPOLLPRI;
844
845	return DEFAULT_POLLMASK;
846	}
847
848	static __poll_t kernfs_fop_poll(struct file filp, poll_table wait)
849	{
850	struct kernfs_open_file *of = kernfs_of(file: filp);
851	struct kernfs_node *kn = kernfs_dentry_node(dentry: filp->f_path.dentry);
852	__poll_t ret;
853
854	if (!kernfs_get_active(kn))
855	return DEFAULT_POLLMASK\|EPOLLERR\|EPOLLPRI;
856
857	if (kn->attr.ops->poll)
858	ret = kn->attr.ops->poll(of, wait);
859	else
860	ret = kernfs_generic_poll(of, wait);
861
862	kernfs_put_active(kn);
863	return ret;
864	}
865
866	static loff_t kernfs_fop_llseek(struct file file, loff_t offset, int* whence)
867	{
868	struct kernfs_open_file *of = kernfs_of(file);
869	const struct kernfs_ops *ops;
870	loff_t ret;
871
872	/*
873	* @of->mutex nests outside active ref and is primarily to ensure that
874	* the ops aren't called concurrently for the same open file.
875	*/
876	mutex_lock(&of->mutex);
877	if (!kernfs_get_active(kn: of->kn)) {
878	mutex_unlock(lock: &of->mutex);
879	return -ENODEV;
880	}
881
882	ops = kernfs_ops(kn: of->kn);
883	if (ops->llseek)
884	ret = ops->llseek(of, offset, whence);
885	else
886	ret = generic_file_llseek(file, offset, whence);
887
888	kernfs_put_active(kn: of->kn);
889	mutex_unlock(lock: &of->mutex);
890	return ret;
891	}
892
893	static void kernfs_notify_workfn(struct work_struct *work)
894	{
895	struct kernfs_node *kn;
896	struct kernfs_super_info *info;
897	struct kernfs_root *root;
898	repeat:
899	/ pop one off the notify_list /
900	spin_lock_irq(lock: &kernfs_notify_lock);
901	kn = kernfs_notify_list;
902	if (kn == KERNFS_NOTIFY_EOL) {
903	spin_unlock_irq(lock: &kernfs_notify_lock);
904	return;
905	}
906	kernfs_notify_list = kn->attr.notify_next;
907	kn->attr.notify_next = NULL;
908	spin_unlock_irq(lock: &kernfs_notify_lock);
909
910	root = kernfs_root(kn);
911	/ kick fsnotify /
912
913	down_read(sem: &root->kernfs_supers_rwsem);
914	list_for_each_entry(info, &kernfs_root(kn)->supers, node) {
915	struct kernfs_node *parent;
916	struct inode *p_inode = NULL;
917	struct inode *inode;
918	struct qstr name;
919
920	/*
921	* We want fsnotify_modify() on @kn but as the
922	* modifications aren't originating from userland don't
923	* have the matching @file available. Look up the inodes
924	* and generate the events manually.
925	*/
926	inode = ilookup(sb: info->sb, ino: kernfs_ino(kn));
927	if (!inode)
928	continue;
929
930	name = (struct qstr)QSTR_INIT(kn->name, strlen(kn->name));
931	parent = kernfs_get_parent(kn);
932	if (parent) {
933	p_inode = ilookup(sb: info->sb, ino: kernfs_ino(kn: parent));
934	if (p_inode) {
935	fsnotify(FS_MODIFY \| FS_EVENT_ON_CHILD,
936	data: inode, data_type: FSNOTIFY_EVENT_INODE,
937	dir: p_inode, name: &name, inode, cookie: `0`);
938	iput(p_inode);
939	}
940
941	kernfs_put(kn: parent);
942	}
943
944	if (!p_inode)
945	fsnotify_inode(inode, FS_MODIFY);
946
947	iput(inode);
948	}
949
950	up_read(sem: &root->kernfs_supers_rwsem);
951	kernfs_put(kn);
952	goto repeat;
953	}
954
955	/**
956	* kernfs_notify - notify a kernfs file
957	* @kn: file to notify
958	*
959	* Notify @kn such that poll(2) on @kn wakes up. Maybe be called from any
960	* context.
961	*/
962	void kernfs_notify(struct kernfs_node *kn)
963	{
964	static DECLARE_WORK(kernfs_notify_work, kernfs_notify_workfn);
965	unsigned long flags;
966	struct kernfs_open_node *on;
967
968	if (WARN_ON(kernfs_type(kn) != KERNFS_FILE))
969	return;
970
971	/ kick poll immediately /
972	rcu_read_lock();
973	on = rcu_dereference(kn->attr.open);
974	if (on) {
975	atomic_inc(v: &on->event);
976	wake_up_interruptible(&on->poll);
977	}
978	rcu_read_unlock();
979
980	/ schedule work to kick fsnotify /
981	spin_lock_irqsave(&kernfs_notify_lock, flags);
982	if (!kn->attr.notify_next) {
983	kernfs_get(kn);
984	kn->attr.notify_next = kernfs_notify_list;
985	kernfs_notify_list = kn;
986	schedule_work(work: &kernfs_notify_work);
987	}
988	spin_unlock_irqrestore(lock: &kernfs_notify_lock, flags);
989	}
990	EXPORT_SYMBOL_GPL(kernfs_notify);
991
992	const struct file_operations kernfs_file_fops = {
993	.read_iter = kernfs_fop_read_iter,
994	.write_iter = kernfs_fop_write_iter,
995	.llseek = kernfs_fop_llseek,
996	.mmap = kernfs_fop_mmap,
997	.open = kernfs_fop_open,
998	.release = kernfs_fop_release,
999	.poll = kernfs_fop_poll,
1000	.fsync = noop_fsync,
1001	.splice_read = copy_splice_read,
1002	.splice_write = iter_file_splice_write,
1003	};
1004
1005	/**
1006	* __kernfs_create_file - kernfs internal function to create a file
1007	* @parent: directory to create the file in
1008	* @name: name of the file
1009	* @mode: mode of the file
1010	* @uid: uid of the file
1011	* @gid: gid of the file
1012	* @size: size of the file
1013	* @ops: kernfs operations for the file
1014	* @priv: private data for the file
1015	* @ns: optional namespace tag of the file
1016	* @key: lockdep key for the file's active_ref, %NULL to disable lockdep
1017	*
1018	* Return: the created node on success, ERR_PTR() value on error.
1019	*/
1020	struct kernfs_node __kernfs_create_file(struct* kernfs_node *parent,
1021	const char *name,
1022	umode_t mode, kuid_t uid, kgid_t gid,
1023	loff_t size,
1024	const struct kernfs_ops *ops,
1025	void priv, const* void *ns,
1026	struct lock_class_key *key)
1027	{
1028	struct kernfs_node *kn;
1029	unsigned flags;
1030	int rc;
1031
1032	flags = KERNFS_FILE;
1033
1034	kn = kernfs_new_node(parent, name, mode: (mode & S_IALLUGO) \| S_IFREG,
1035	uid, gid, flags);
1036	if (!kn)
1037	return ERR_PTR(error: -ENOMEM);
1038
1039	kn->attr.ops = ops;
1040	kn->attr.size = size;
1041	kn->ns = ns;
1042	kn->priv = priv;
1043
1044	#ifdef CONFIG_DEBUG_LOCK_ALLOC
1045	if (key) {
1046	lockdep_init_map(lock: &kn->dep_map, name: "kn->active", key, subclass: `0`);
1047	kn->flags \|= KERNFS_LOCKDEP;
1048	}
1049	#endif
1050
1051	/*
1052	* kn->attr.ops is accessible only while holding active ref. We
1053	* need to know whether some ops are implemented outside active
1054	* ref. Cache their existence in flags.
1055	*/
1056	if (ops->seq_show)
1057	kn->flags \|= KERNFS_HAS_SEQ_SHOW;
1058	if (ops->mmap)
1059	kn->flags \|= KERNFS_HAS_MMAP;
1060	if (ops->release)
1061	kn->flags \|= KERNFS_HAS_RELEASE;
1062
1063	rc = kernfs_add_one(kn);
1064	if (rc) {
1065	kernfs_put(kn);
1066	return ERR_PTR(error: rc);
1067	}
1068	return kn;
1069	}
1070

source code of linux/fs/kernfs/file.c