runtime.c source code [Linux/drivers/base/power/runtime.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/*
3	* drivers/base/power/runtime.c - Helper functions for device runtime PM
4	*
5	* Copyright (c) 2009 Rafael J. Wysocki <rjw@sisk.pl>, Novell Inc.
6	* Copyright (C) 2010 Alan Stern <stern@rowland.harvard.edu>
7	*/
8	#include <linux/sched/mm.h>
9	#include <linux/ktime.h>
10	#include <linux/hrtimer.h>
11	#include <linux/export.h>
12	#include <linux/pm_runtime.h>
13	#include <linux/pm_wakeirq.h>
14	#include <linux/rculist.h>
15	#include <trace/events/rpm.h>
16
17	#include "../base.h"
18	#include "power.h"
19
20	typedef int (pm_callback_t)(struct* device *);
21
22	static inline pm_callback_t get_callback_ptr(const void *start, size_t offset)
23	{
24	return (pm_callback_t )(start + offset);
25	}
26
27	static pm_callback_t __rpm_get_driver_callback(struct device *dev,
28	size_t cb_offset)
29	{
30	if (dev->driver && dev->driver->pm)
31	return get_callback_ptr(start: dev->driver->pm, offset: cb_offset);
32
33	return NULL;
34	}
35
36	static pm_callback_t __rpm_get_callback(struct device *dev, size_t cb_offset)
37	{
38	const struct dev_pm_ops *ops;
39	pm_callback_t cb = NULL;
40
41	if (dev->pm_domain)
42	ops = &dev->pm_domain->ops;
43	else if (dev->type && dev->type->pm)
44	ops = dev->type->pm;
45	else if (dev->class && dev->class->pm)
46	ops = dev->class->pm;
47	else if (dev->bus && dev->bus->pm)
48	ops = dev->bus->pm;
49	else
50	ops = NULL;
51
52	if (ops)
53	cb = get_callback_ptr(start: ops, offset: cb_offset);
54
55	if (!cb)
56	cb = __rpm_get_driver_callback(dev, cb_offset);
57
58	return cb;
59	}
60
61	#define RPM_GET_CALLBACK(dev, callback) \
62	__rpm_get_callback(dev, offsetof(struct dev_pm_ops, callback))
63
64	static int rpm_resume(struct device dev, int* rpmflags);
65	static int rpm_suspend(struct device dev, int* rpmflags);
66
67	/**
68	* update_pm_runtime_accounting - Update the time accounting of power states
69	* @dev: Device to update the accounting for
70	*
71	* In order to be able to have time accounting of the various power states
72	* (as used by programs such as PowerTOP to show the effectiveness of runtime
73	* PM), we need to track the time spent in each state.
74	* update_pm_runtime_accounting must be called each time before the
75	* runtime_status field is updated, to account the time in the old state
76	* correctly.
77	*/
78	static void update_pm_runtime_accounting(struct device *dev)
79	{
80	u64 now, last, delta;
81
82	if (dev->power.disable_depth > `0`)
83	return;
84
85	last = dev->power.accounting_timestamp;
86
87	now = ktime_get_mono_fast_ns();
88	dev->power.accounting_timestamp = now;
89
90	/*
91	* Because ktime_get_mono_fast_ns() is not monotonic during
92	* timekeeping updates, ensure that 'now' is after the last saved
93	* timesptamp.
94	*/
95	if (now < last)
96	return;
97
98	delta = now - last;
99
100	if (dev->power.runtime_status == RPM_SUSPENDED)
101	dev->power.suspended_time += delta;
102	else
103	dev->power.active_time += delta;
104	}
105
106	static void __update_runtime_status(struct device dev, enum* rpm_status status)
107	{
108	update_pm_runtime_accounting(dev);
109	trace_rpm_status(dev, status);
110	dev->power.runtime_status = status;
111	}
112
113	static u64 rpm_get_accounted_time(struct device *dev, bool suspended)
114	{
115	u64 time;
116	unsigned long flags;
117
118	spin_lock_irqsave(&dev->power.lock, flags);
119
120	update_pm_runtime_accounting(dev);
121	time = suspended ? dev->power.suspended_time : dev->power.active_time;
122
123	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
124
125	return time;
126	}
127
128	u64 pm_runtime_active_time(struct device *dev)
129	{
130	return rpm_get_accounted_time(dev, suspended: false);
131	}
132
133	u64 pm_runtime_suspended_time(struct device *dev)
134	{
135	return rpm_get_accounted_time(dev, suspended: true);
136	}
137	EXPORT_SYMBOL_GPL(pm_runtime_suspended_time);
138
139	/**
140	* pm_runtime_deactivate_timer - Deactivate given device's suspend timer.
141	* @dev: Device to handle.
142	*/
143	static void pm_runtime_deactivate_timer(struct device *dev)
144	{
145	if (dev->power.timer_expires > `0`) {
146	hrtimer_try_to_cancel(timer: &dev->power.suspend_timer);
147	dev->power.timer_expires = `0`;
148	}
149	}
150
151	/**
152	* pm_runtime_cancel_pending - Deactivate suspend timer and cancel requests.
153	* @dev: Device to handle.
154	*/
155	static void pm_runtime_cancel_pending(struct device *dev)
156	{
157	pm_runtime_deactivate_timer(dev);
158	/*
159	* In case there's a request pending, make sure its work function will
160	* return without doing anything.
161	*/
162	dev->power.request = RPM_REQ_NONE;
163	}
164
165	/*
166	* pm_runtime_autosuspend_expiration - Get a device's autosuspend-delay expiration time.
167	* @dev: Device to handle.
168	*
169	* Compute the autosuspend-delay expiration time based on the device's
170	* power.last_busy time. If the delay has already expired or is disabled
171	* (negative) or the power.use_autosuspend flag isn't set, return 0.
172	* Otherwise return the expiration time in nanoseconds (adjusted to be nonzero).
173	*
174	* This function may be called either with or without dev->power.lock held.
175	* Either way it can be racy, since power.last_busy may be updated at any time.
176	*/
177	u64 pm_runtime_autosuspend_expiration(struct device *dev)
178	{
179	int autosuspend_delay;
180	u64 expires;
181
182	if (!dev->power.use_autosuspend)
183	return `0`;
184
185	autosuspend_delay = READ_ONCE(dev->power.autosuspend_delay);
186	if (autosuspend_delay < `0`)
187	return `0`;
188
189	expires = READ_ONCE(dev->power.last_busy);
190	expires += (u64)autosuspend_delay * NSEC_PER_MSEC;
191	if (expires > ktime_get_mono_fast_ns())
192	return expires; / Expires in the future /
193
194	return `0`;
195	}
196	EXPORT_SYMBOL_GPL(pm_runtime_autosuspend_expiration);
197
198	static int dev_memalloc_noio(struct device dev, void* *data)
199	{
200	return dev->power.memalloc_noio;
201	}
202
203	/*
204	* pm_runtime_set_memalloc_noio - Set a device's memalloc_noio flag.
205	* @dev: Device to handle.
206	* @enable: True for setting the flag and False for clearing the flag.
207	*
208	* Set the flag for all devices in the path from the device to the
209	* root device in the device tree if @enable is true, otherwise clear
210	* the flag for devices in the path whose siblings don't set the flag.
211	*
212	* The function should only be called by block device, or network
213	* device driver for solving the deadlock problem during runtime
214	* resume/suspend:
215	*
216	* If memory allocation with GFP_KERNEL is called inside runtime
217	* resume/suspend callback of any one of its ancestors(or the
218	* block device itself), the deadlock may be triggered inside the
219	* memory allocation since it might not complete until the block
220	* device becomes active and the involed page I/O finishes. The
221	* situation is pointed out first by Alan Stern. Network device
222	* are involved in iSCSI kind of situation.
223	*
224	* The lock of dev_hotplug_mutex is held in the function for handling
225	* hotplug race because pm_runtime_set_memalloc_noio() may be called
226	* in async probe().
227	*
228	* The function should be called between device_add() and device_del()
229	* on the affected device(block/network device).
230	*/
231	void pm_runtime_set_memalloc_noio(struct device *dev, bool enable)
232	{
233	static DEFINE_MUTEX(dev_hotplug_mutex);
234
235	mutex_lock(lock: &dev_hotplug_mutex);
236	for (;;) {
237	bool enabled;
238
239	/ hold power lock since bitfield is not SMP-safe. /
240	spin_lock_irq(lock: &dev->power.lock);
241	enabled = dev->power.memalloc_noio;
242	dev->power.memalloc_noio = enable;
243	spin_unlock_irq(lock: &dev->power.lock);
244
245	/*
246	* not need to enable ancestors any more if the device
247	* has been enabled.
248	*/
249	if (enabled && enable)
250	break;
251
252	dev = dev->parent;
253
254	/*
255	* clear flag of the parent device only if all the
256	* children don't set the flag because ancestor's
257	* flag was set by any one of the descendants.
258	*/
259	if (!dev \|\| (!enable &&
260	device_for_each_child(parent: dev, NULL, fn: dev_memalloc_noio)))
261	break;
262	}
263	mutex_unlock(lock: &dev_hotplug_mutex);
264	}
265	EXPORT_SYMBOL_GPL(pm_runtime_set_memalloc_noio);
266
267	/**
268	* rpm_check_suspend_allowed - Test whether a device may be suspended.
269	* @dev: Device to test.
270	*/
271	static int rpm_check_suspend_allowed(struct device *dev)
272	{
273	int retval = `0`;
274
275	if (dev->power.runtime_error)
276	retval = -EINVAL;
277	else if (dev->power.disable_depth > `0`)
278	retval = -EACCES;
279	else if (atomic_read(v: &dev->power.usage_count))
280	retval = -EAGAIN;
281	else if (!dev->power.ignore_children && atomic_read(v: &dev->power.child_count))
282	retval = -EBUSY;
283
284	/ Pending resume requests take precedence over suspends. /
285	else if ((dev->power.deferred_resume &&
286	dev->power.runtime_status == RPM_SUSPENDING) \|\|
287	(dev->power.request_pending && dev->power.request == RPM_REQ_RESUME))
288	retval = -EAGAIN;
289	else if (__dev_pm_qos_resume_latency(dev) == `0`)
290	retval = -EPERM;
291	else if (dev->power.runtime_status == RPM_SUSPENDED)
292	retval = `1`;
293
294	return retval;
295	}
296
297	static int rpm_get_suppliers(struct device *dev)
298	{
299	struct device_link *link;
300
301	list_for_each_entry_rcu(link, &dev->links.suppliers, c_node,
302	device_links_read_lock_held()) {
303	int retval;
304
305	if (!device_link_test(link, DL_FLAG_PM_RUNTIME))
306	continue;
307
308	retval = pm_runtime_get_sync(dev: link->supplier);
309	/ Ignore suppliers with disabled runtime PM. /
310	if (retval < `0` && retval != -EACCES) {
311	pm_runtime_put_noidle(dev: link->supplier);
312	return retval;
313	}
314	refcount_inc(r: &link->rpm_active);
315	}
316	return `0`;
317	}
318
319	/**
320	* pm_runtime_release_supplier - Drop references to device link's supplier.
321	* @link: Target device link.
322	*
323	* Drop all runtime PM references associated with @link to its supplier device.
324	*/
325	void pm_runtime_release_supplier(struct device_link *link)
326	{
327	struct device *supplier = link->supplier;
328
329	/*
330	* The additional power.usage_count check is a safety net in case
331	* the rpm_active refcount becomes saturated, in which case
332	* refcount_dec_not_one() would return true forever, but it is not
333	* strictly necessary.
334	*/
335	while (refcount_dec_not_one(r: &link->rpm_active) &&
336	atomic_read(v: &supplier->power.usage_count) > `0`)
337	pm_runtime_put_noidle(dev: supplier);
338	}
339
340	static void __rpm_put_suppliers(struct device *dev, bool try_to_suspend)
341	{
342	struct device_link *link;
343
344	list_for_each_entry_rcu(link, &dev->links.suppliers, c_node,
345	device_links_read_lock_held()) {
346	pm_runtime_release_supplier(link);
347	if (try_to_suspend)
348	pm_request_idle(dev: link->supplier);
349	}
350	}
351
352	static void rpm_put_suppliers(struct device *dev)
353	{
354	__rpm_put_suppliers(dev, try_to_suspend: true);
355	}
356
357	static void rpm_suspend_suppliers(struct device *dev)
358	{
359	struct device_link *link;
360	int idx = device_links_read_lock();
361
362	list_for_each_entry_rcu(link, &dev->links.suppliers, c_node,
363	device_links_read_lock_held())
364	pm_request_idle(dev: link->supplier);
365
366	device_links_read_unlock(idx);
367	}
368
369	/**
370	* __rpm_callback - Run a given runtime PM callback for a given device.
371	* @cb: Runtime PM callback to run.
372	* @dev: Device to run the callback for.
373	*/
374	static int __rpm_callback(int (cb)(struct* device ), struct* device *dev)
375	__releases(&dev->power.lock) __acquires(&dev->power.lock)
376	{
377	int retval = `0`, idx;
378	bool use_links = dev->power.links_count > `0`;
379
380	if (dev->power.irq_safe) {
381	spin_unlock(lock: &dev->power.lock);
382	} else {
383	spin_unlock_irq(lock: &dev->power.lock);
384
385	/*
386	* Resume suppliers if necessary.
387	*
388	* The device's runtime PM status cannot change until this
389	* routine returns, so it is safe to read the status outside of
390	* the lock.
391	*/
392	if (use_links && dev->power.runtime_status == RPM_RESUMING) {
393	idx = device_links_read_lock();
394
395	retval = rpm_get_suppliers(dev);
396	if (retval) {
397	rpm_put_suppliers(dev);
398	goto fail;
399	}
400
401	device_links_read_unlock(idx);
402	}
403	}
404
405	if (cb)
406	retval = cb(dev);
407
408	if (dev->power.irq_safe) {
409	spin_lock(lock: &dev->power.lock);
410	} else {
411	/*
412	* If the device is suspending and the callback has returned
413	* success, drop the usage counters of the suppliers that have
414	* been reference counted on its resume.
415	*
416	* Do that if resume fails too.
417	*/
418	if (use_links &&
419	((dev->power.runtime_status == RPM_SUSPENDING && !retval) \|\|
420	(dev->power.runtime_status == RPM_RESUMING && retval))) {
421	idx = device_links_read_lock();
422
423	__rpm_put_suppliers(dev, try_to_suspend: false);
424
425	fail:
426	device_links_read_unlock(idx);
427	}
428
429	spin_lock_irq(lock: &dev->power.lock);
430	}
431
432	return retval;
433	}
434
435	/**
436	* rpm_callback - Run a given runtime PM callback for a given device.
437	* @cb: Runtime PM callback to run.
438	* @dev: Device to run the callback for.
439	*/
440	static int rpm_callback(int (cb)(struct* device ), struct* device *dev)
441	{
442	int retval;
443
444	if (dev->power.memalloc_noio) {
445	unsigned int noio_flag;
446
447	/*
448	* Deadlock might be caused if memory allocation with
449	* GFP_KERNEL happens inside runtime_suspend and
450	* runtime_resume callbacks of one block device's
451	* ancestor or the block device itself. Network
452	* device might be thought as part of iSCSI block
453	* device, so network device and its ancestor should
454	* be marked as memalloc_noio too.
455	*/
456	noio_flag = memalloc_noio_save();
457	retval = __rpm_callback(cb, dev);
458	memalloc_noio_restore(flags: noio_flag);
459	} else {
460	retval = __rpm_callback(cb, dev);
461	}
462
463	/*
464	* Since -EACCES means that runtime PM is disabled for the given device,
465	* it should not be returned by runtime PM callbacks. If it is returned
466	* nevertheless, assume it to be a transient error and convert it to
467	* -EAGAIN.
468	*/
469	if (retval == -EACCES)
470	retval = -EAGAIN;
471
472	if (retval != -EAGAIN && retval != -EBUSY)
473	dev->power.runtime_error = retval;
474
475	return retval;
476	}
477
478	/**
479	* rpm_idle - Notify device bus type if the device can be suspended.
480	* @dev: Device to notify the bus type about.
481	* @rpmflags: Flag bits.
482	*
483	* Check if the device's runtime PM status allows it to be suspended. If
484	* another idle notification has been started earlier, return immediately. If
485	* the RPM_ASYNC flag is set then queue an idle-notification request; otherwise
486	* run the ->runtime_idle() callback directly. If the ->runtime_idle callback
487	* doesn't exist or if it returns 0, call rpm_suspend with the RPM_AUTO flag.
488	*
489	* This function must be called under dev->power.lock with interrupts disabled.
490	*/
491	static int rpm_idle(struct device dev, int* rpmflags)
492	{
493	int (callback)(struct* device *);
494	int retval;
495
496	trace_rpm_idle(dev, flags: rpmflags);
497	retval = rpm_check_suspend_allowed(dev);
498	if (retval < `0`)
499	; / Conditions are wrong. /
500
501	else if ((rpmflags & RPM_GET_PUT) && retval == `1`)
502	; / put() is allowed in RPM_SUSPENDED /
503
504	/ Idle notifications are allowed only in the RPM_ACTIVE state. /
505	else if (dev->power.runtime_status != RPM_ACTIVE)
506	retval = -EAGAIN;
507
508	/*
509	* Any pending request other than an idle notification takes
510	* precedence over us, except that the timer may be running.
511	*/
512	else if (dev->power.request_pending &&
513	dev->power.request > RPM_REQ_IDLE)
514	retval = -EAGAIN;
515
516	/ Act as though RPM_NOWAIT is always set. /
517	else if (dev->power.idle_notification)
518	retval = -EINPROGRESS;
519
520	if (retval)
521	goto out;
522
523	/ Pending requests need to be canceled. /
524	dev->power.request = RPM_REQ_NONE;
525
526	callback = RPM_GET_CALLBACK(dev, runtime_idle);
527
528	/ If no callback assume success. /
529	if (!callback \|\| dev->power.no_callbacks)
530	goto out;
531
532	/ Carry out an asynchronous or a synchronous idle notification. /
533	if (rpmflags & RPM_ASYNC) {
534	dev->power.request = RPM_REQ_IDLE;
535	if (!dev->power.request_pending) {
536	dev->power.request_pending = true;
537	queue_work(wq: pm_wq, work: &dev->power.work);
538	}
539	trace_rpm_return_int(dev, _THIS_IP_, ret: `0`);
540	return `0`;
541	}
542
543	dev->power.idle_notification = true;
544
545	if (dev->power.irq_safe)
546	spin_unlock(lock: &dev->power.lock);
547	else
548	spin_unlock_irq(lock: &dev->power.lock);
549
550	retval = callback(dev);
551
552	if (dev->power.irq_safe)
553	spin_lock(lock: &dev->power.lock);
554	else
555	spin_lock_irq(lock: &dev->power.lock);
556
557	dev->power.idle_notification = false;
558	wake_up_all(&dev->power.wait_queue);
559
560	out:
561	trace_rpm_return_int(dev, _THIS_IP_, ret: retval);
562	return retval ? retval : rpm_suspend(dev, rpmflags: rpmflags \| RPM_AUTO);
563	}
564
565	/**
566	* rpm_suspend - Carry out runtime suspend of given device.
567	* @dev: Device to suspend.
568	* @rpmflags: Flag bits.
569	*
570	* Check if the device's runtime PM status allows it to be suspended.
571	* Cancel a pending idle notification, autosuspend or suspend. If
572	* another suspend has been started earlier, either return immediately
573	* or wait for it to finish, depending on the RPM_NOWAIT and RPM_ASYNC
574	* flags. If the RPM_ASYNC flag is set then queue a suspend request;
575	* otherwise run the ->runtime_suspend() callback directly. When
576	* ->runtime_suspend succeeded, if a deferred resume was requested while
577	* the callback was running then carry it out, otherwise send an idle
578	* notification for its parent (if the suspend succeeded and both
579	* ignore_children of parent->power and irq_safe of dev->power are not set).
580	* If ->runtime_suspend failed with -EAGAIN or -EBUSY, and if the RPM_AUTO
581	* flag is set and the next autosuspend-delay expiration time is in the
582	* future, schedule another autosuspend attempt.
583	*
584	* This function must be called under dev->power.lock with interrupts disabled.
585	*/
586	static int rpm_suspend(struct device dev, int* rpmflags)
587	__releases(&dev->power.lock) __acquires(&dev->power.lock)
588	{
589	int (callback)(struct* device *);
590	struct device *parent = NULL;
591	int retval;
592
593	trace_rpm_suspend(dev, flags: rpmflags);
594
595	repeat:
596	retval = rpm_check_suspend_allowed(dev);
597	if (retval < `0`)
598	goto out; / Conditions are wrong. /
599
600	/ Synchronous suspends are not allowed in the RPM_RESUMING state. /
601	if (dev->power.runtime_status == RPM_RESUMING && !(rpmflags & RPM_ASYNC))
602	retval = -EAGAIN;
603
604	if (retval)
605	goto out;
606
607	/ If the autosuspend_delay time hasn't expired yet, reschedule. /
608	if ((rpmflags & RPM_AUTO) && dev->power.runtime_status != RPM_SUSPENDING) {
609	u64 expires = pm_runtime_autosuspend_expiration(dev);
610
611	if (expires != `0`) {
612	/ Pending requests need to be canceled. /
613	dev->power.request = RPM_REQ_NONE;
614
615	/*
616	* Optimization: If the timer is already running and is
617	* set to expire at or before the autosuspend delay,
618	* avoid the overhead of resetting it. Just let it
619	* expire; pm_suspend_timer_fn() will take care of the
620	* rest.
621	*/
622	if (!(dev->power.timer_expires &&
623	dev->power.timer_expires <= expires)) {
624	/*
625	* We add a slack of 25% to gather wakeups
626	* without sacrificing the granularity.
627	*/
628	u64 slack = (u64)READ_ONCE(dev->power.autosuspend_delay) *
629	(NSEC_PER_MSEC >> `2`);
630
631	dev->power.timer_expires = expires;
632	hrtimer_start_range_ns(timer: &dev->power.suspend_timer,
633	tim: ns_to_ktime(ns: expires),
634	range_ns: slack,
635	mode: HRTIMER_MODE_ABS);
636	}
637	dev->power.timer_autosuspends = `1`;
638	goto out;
639	}
640	}
641
642	/ Other scheduled or pending requests need to be canceled. /
643	pm_runtime_cancel_pending(dev);
644
645	if (dev->power.runtime_status == RPM_SUSPENDING) {
646	DEFINE_WAIT(wait);
647
648	if (rpmflags & (RPM_ASYNC \| RPM_NOWAIT)) {
649	retval = -EINPROGRESS;
650	goto out;
651	}
652
653	if (dev->power.irq_safe) {
654	spin_unlock(lock: &dev->power.lock);
655
656	cpu_relax();
657
658	spin_lock(lock: &dev->power.lock);
659	goto repeat;
660	}
661
662	/ Wait for the other suspend running in parallel with us. /
663	for (;;) {
664	prepare_to_wait(wq_head: &dev->power.wait_queue, wq_entry: &wait,
665	TASK_UNINTERRUPTIBLE);
666	if (dev->power.runtime_status != RPM_SUSPENDING)
667	break;
668
669	spin_unlock_irq(lock: &dev->power.lock);
670
671	schedule();
672
673	spin_lock_irq(lock: &dev->power.lock);
674	}
675	finish_wait(wq_head: &dev->power.wait_queue, wq_entry: &wait);
676	goto repeat;
677	}
678
679	if (dev->power.no_callbacks)
680	goto no_callback; / Assume success. /
681
682	/ Carry out an asynchronous or a synchronous suspend. /
683	if (rpmflags & RPM_ASYNC) {
684	dev->power.request = (rpmflags & RPM_AUTO) ?
685	RPM_REQ_AUTOSUSPEND : RPM_REQ_SUSPEND;
686	if (!dev->power.request_pending) {
687	dev->power.request_pending = true;
688	queue_work(wq: pm_wq, work: &dev->power.work);
689	}
690	goto out;
691	}
692
693	__update_runtime_status(dev, status: RPM_SUSPENDING);
694
695	callback = RPM_GET_CALLBACK(dev, runtime_suspend);
696
697	dev_pm_enable_wake_irq_check(dev, can_change_status: true);
698	retval = rpm_callback(cb: callback, dev);
699	if (retval)
700	goto fail;
701
702	dev_pm_enable_wake_irq_complete(dev);
703
704	no_callback:
705	__update_runtime_status(dev, status: RPM_SUSPENDED);
706	pm_runtime_deactivate_timer(dev);
707
708	if (dev->parent) {
709	parent = dev->parent;
710	atomic_add_unless(v: &parent->power.child_count, a: -`1`, u: `0`);
711	}
712	wake_up_all(&dev->power.wait_queue);
713
714	if (dev->power.deferred_resume) {
715	dev->power.deferred_resume = false;
716	rpm_resume(dev, rpmflags: `0`);
717	retval = -EAGAIN;
718	goto out;
719	}
720
721	if (dev->power.irq_safe)
722	goto out;
723
724	/ Maybe the parent is now able to suspend. /
725	if (parent && !parent->power.ignore_children) {
726	spin_unlock(lock: &dev->power.lock);
727
728	spin_lock(lock: &parent->power.lock);
729	rpm_idle(dev: parent, RPM_ASYNC);
730	spin_unlock(lock: &parent->power.lock);
731
732	spin_lock(lock: &dev->power.lock);
733	}
734	/ Maybe the suppliers are now able to suspend. /
735	if (dev->power.links_count > `0`) {
736	spin_unlock_irq(lock: &dev->power.lock);
737
738	rpm_suspend_suppliers(dev);
739
740	spin_lock_irq(lock: &dev->power.lock);
741	}
742
743	out:
744	trace_rpm_return_int(dev, _THIS_IP_, ret: retval);
745
746	return retval;
747
748	fail:
749	dev_pm_disable_wake_irq_check(dev, cond_disable: true);
750	__update_runtime_status(dev, status: RPM_ACTIVE);
751	dev->power.deferred_resume = false;
752	wake_up_all(&dev->power.wait_queue);
753
754	/*
755	* On transient errors, if the callback routine failed an autosuspend,
756	* and if the last_busy time has been updated so that there is a new
757	* autosuspend expiration time, automatically reschedule another
758	* autosuspend.
759	*/
760	if (!dev->power.runtime_error && (rpmflags & RPM_AUTO) &&
761	pm_runtime_autosuspend_expiration(dev) != `0`)
762	goto repeat;
763
764	pm_runtime_cancel_pending(dev);
765
766	goto out;
767	}
768
769	/**
770	* rpm_resume - Carry out runtime resume of given device.
771	* @dev: Device to resume.
772	* @rpmflags: Flag bits.
773	*
774	* Check if the device's runtime PM status allows it to be resumed. Cancel
775	* any scheduled or pending requests. If another resume has been started
776	* earlier, either return immediately or wait for it to finish, depending on the
777	* RPM_NOWAIT and RPM_ASYNC flags. Similarly, if there's a suspend running in
778	* parallel with this function, either tell the other process to resume after
779	* suspending (deferred_resume) or wait for it to finish. If the RPM_ASYNC
780	* flag is set then queue a resume request; otherwise run the
781	* ->runtime_resume() callback directly. Queue an idle notification for the
782	* device if the resume succeeded.
783	*
784	* This function must be called under dev->power.lock with interrupts disabled.
785	*/
786	static int rpm_resume(struct device dev, int* rpmflags)
787	__releases(&dev->power.lock) __acquires(&dev->power.lock)
788	{
789	int (callback)(struct* device *);
790	struct device *parent = NULL;
791	int retval = `0`;
792
793	trace_rpm_resume(dev, flags: rpmflags);
794
795	repeat:
796	if (dev->power.runtime_error) {
797	retval = -EINVAL;
798	} else if (dev->power.disable_depth > `0`) {
799	if (dev->power.runtime_status == RPM_ACTIVE &&
800	dev->power.last_status == RPM_ACTIVE)
801	retval = `1`;
802	else if (rpmflags & RPM_TRANSPARENT)
803	goto out;
804	else
805	retval = -EACCES;
806	}
807	if (retval)
808	goto out;
809
810	/*
811	* Other scheduled or pending requests need to be canceled. Small
812	* optimization: If an autosuspend timer is running, leave it running
813	* rather than cancelling it now only to restart it again in the near
814	* future.
815	*/
816	dev->power.request = RPM_REQ_NONE;
817	if (!dev->power.timer_autosuspends)
818	pm_runtime_deactivate_timer(dev);
819
820	if (dev->power.runtime_status == RPM_ACTIVE) {
821	retval = `1`;
822	goto out;
823	}
824
825	if (dev->power.runtime_status == RPM_RESUMING \|\|
826	dev->power.runtime_status == RPM_SUSPENDING) {
827	DEFINE_WAIT(wait);
828
829	if (rpmflags & (RPM_ASYNC \| RPM_NOWAIT)) {
830	if (dev->power.runtime_status == RPM_SUSPENDING) {
831	dev->power.deferred_resume = true;
832	if (rpmflags & RPM_NOWAIT)
833	retval = -EINPROGRESS;
834	} else {
835	retval = -EINPROGRESS;
836	}
837	goto out;
838	}
839
840	if (dev->power.irq_safe) {
841	spin_unlock(lock: &dev->power.lock);
842
843	cpu_relax();
844
845	spin_lock(lock: &dev->power.lock);
846	goto repeat;
847	}
848
849	/ Wait for the operation carried out in parallel with us. /
850	for (;;) {
851	prepare_to_wait(wq_head: &dev->power.wait_queue, wq_entry: &wait,
852	TASK_UNINTERRUPTIBLE);
853	if (dev->power.runtime_status != RPM_RESUMING &&
854	dev->power.runtime_status != RPM_SUSPENDING)
855	break;
856
857	spin_unlock_irq(lock: &dev->power.lock);
858
859	schedule();
860
861	spin_lock_irq(lock: &dev->power.lock);
862	}
863	finish_wait(wq_head: &dev->power.wait_queue, wq_entry: &wait);
864	goto repeat;
865	}
866
867	/*
868	* See if we can skip waking up the parent. This is safe only if
869	* power.no_callbacks is set, because otherwise we don't know whether
870	* the resume will actually succeed.
871	*/
872	if (dev->power.no_callbacks && !parent && dev->parent) {
873	spin_lock_nested(&dev->parent->power.lock, SINGLE_DEPTH_NESTING);
874	if (dev->parent->power.disable_depth > `0` \|\|
875	dev->parent->power.ignore_children \|\|
876	dev->parent->power.runtime_status == RPM_ACTIVE) {
877	atomic_inc(v: &dev->parent->power.child_count);
878	spin_unlock(lock: &dev->parent->power.lock);
879	retval = `1`;
880	goto no_callback; / Assume success. /
881	}
882	spin_unlock(lock: &dev->parent->power.lock);
883	}
884
885	/ Carry out an asynchronous or a synchronous resume. /
886	if (rpmflags & RPM_ASYNC) {
887	dev->power.request = RPM_REQ_RESUME;
888	if (!dev->power.request_pending) {
889	dev->power.request_pending = true;
890	queue_work(wq: pm_wq, work: &dev->power.work);
891	}
892	retval = `0`;
893	goto out;
894	}
895
896	if (!parent && dev->parent) {
897	/*
898	* Increment the parent's usage counter and resume it if
899	* necessary. Not needed if dev is irq-safe; then the
900	* parent is permanently resumed.
901	*/
902	parent = dev->parent;
903	if (dev->power.irq_safe)
904	goto skip_parent;
905
906	spin_unlock(lock: &dev->power.lock);
907
908	pm_runtime_get_noresume(dev: parent);
909
910	spin_lock(lock: &parent->power.lock);
911	/*
912	* Resume the parent if it has runtime PM enabled and not been
913	* set to ignore its children.
914	*/
915	if (!parent->power.disable_depth &&
916	!parent->power.ignore_children) {
917	rpm_resume(dev: parent, rpmflags: `0`);
918	if (parent->power.runtime_status != RPM_ACTIVE)
919	retval = -EBUSY;
920	}
921	spin_unlock(lock: &parent->power.lock);
922
923	spin_lock(lock: &dev->power.lock);
924	if (retval)
925	goto out;
926
927	goto repeat;
928	}
929	skip_parent:
930
931	if (dev->power.no_callbacks)
932	goto no_callback; / Assume success. /
933
934	__update_runtime_status(dev, status: RPM_RESUMING);
935
936	callback = RPM_GET_CALLBACK(dev, runtime_resume);
937
938	dev_pm_disable_wake_irq_check(dev, cond_disable: false);
939	retval = rpm_callback(cb: callback, dev);
940	if (retval) {
941	__update_runtime_status(dev, status: RPM_SUSPENDED);
942	pm_runtime_cancel_pending(dev);
943	dev_pm_enable_wake_irq_check(dev, can_change_status: false);
944	} else {
945	no_callback:
946	__update_runtime_status(dev, status: RPM_ACTIVE);
947	pm_runtime_mark_last_busy(dev);
948	if (parent)
949	atomic_inc(v: &parent->power.child_count);
950	}
951	wake_up_all(&dev->power.wait_queue);
952
953	if (retval >= `0`)
954	rpm_idle(dev, RPM_ASYNC);
955
956	out:
957	if (parent && !dev->power.irq_safe) {
958	spin_unlock_irq(lock: &dev->power.lock);
959
960	pm_runtime_put(dev: parent);
961
962	spin_lock_irq(lock: &dev->power.lock);
963	}
964
965	trace_rpm_return_int(dev, _THIS_IP_, ret: retval);
966
967	return retval;
968	}
969
970	/**
971	* pm_runtime_work - Universal runtime PM work function.
972	* @work: Work structure used for scheduling the execution of this function.
973	*
974	* Use @work to get the device object the work is to be done for, determine what
975	* is to be done and execute the appropriate runtime PM function.
976	*/
977	static void pm_runtime_work(struct work_struct *work)
978	{
979	struct device dev = container_of(work, struct* device, power.work);
980	enum rpm_request req;
981
982	spin_lock_irq(lock: &dev->power.lock);
983
984	if (!dev->power.request_pending)
985	goto out;
986
987	req = dev->power.request;
988	dev->power.request = RPM_REQ_NONE;
989	dev->power.request_pending = false;
990
991	switch (req) {
992	case RPM_REQ_NONE:
993	break;
994	case RPM_REQ_IDLE:
995	rpm_idle(dev, RPM_NOWAIT);
996	break;
997	case RPM_REQ_SUSPEND:
998	rpm_suspend(dev, RPM_NOWAIT);
999	break;
1000	case RPM_REQ_AUTOSUSPEND:
1001	rpm_suspend(dev, RPM_NOWAIT \| RPM_AUTO);
1002	break;
1003	case RPM_REQ_RESUME:
1004	rpm_resume(dev, RPM_NOWAIT);
1005	break;
1006	}
1007
1008	out:
1009	spin_unlock_irq(lock: &dev->power.lock);
1010	}
1011
1012	/**
1013	* pm_suspend_timer_fn - Timer function for pm_schedule_suspend().
1014	* @timer: hrtimer used by pm_schedule_suspend().
1015	*
1016	* Check if the time is right and queue a suspend request.
1017	*/
1018	static enum hrtimer_restart pm_suspend_timer_fn(struct hrtimer *timer)
1019	{
1020	struct device dev = container_of(timer, struct* device, power.suspend_timer);
1021	unsigned long flags;
1022	u64 expires;
1023
1024	spin_lock_irqsave(&dev->power.lock, flags);
1025
1026	expires = dev->power.timer_expires;
1027	/*
1028	* If 'expires' is after the current time, we've been called
1029	* too early.
1030	*/
1031	if (expires > `0` && expires <= ktime_get_mono_fast_ns()) {
1032	dev->power.timer_expires = `0`;
1033	rpm_suspend(dev, rpmflags: dev->power.timer_autosuspends ?
1034	(RPM_ASYNC \| RPM_AUTO) : RPM_ASYNC);
1035	}
1036
1037	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1038
1039	return HRTIMER_NORESTART;
1040	}
1041
1042	/**
1043	* pm_schedule_suspend - Set up a timer to submit a suspend request in future.
1044	* @dev: Device to suspend.
1045	* @delay: Time to wait before submitting a suspend request, in milliseconds.
1046	*/
1047	int pm_schedule_suspend(struct device dev, unsigned* int delay)
1048	{
1049	unsigned long flags;
1050	u64 expires;
1051	int retval;
1052
1053	spin_lock_irqsave(&dev->power.lock, flags);
1054
1055	if (!delay) {
1056	retval = rpm_suspend(dev, RPM_ASYNC);
1057	goto out;
1058	}
1059
1060	retval = rpm_check_suspend_allowed(dev);
1061	if (retval)
1062	goto out;
1063
1064	/ Other scheduled or pending requests need to be canceled. /
1065	pm_runtime_cancel_pending(dev);
1066
1067	expires = ktime_get_mono_fast_ns() + (u64)delay * NSEC_PER_MSEC;
1068	dev->power.timer_expires = expires;
1069	dev->power.timer_autosuspends = `0`;
1070	hrtimer_start(timer: &dev->power.suspend_timer, tim: expires, mode: HRTIMER_MODE_ABS);
1071
1072	out:
1073	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1074
1075	return retval;
1076	}
1077	EXPORT_SYMBOL_GPL(pm_schedule_suspend);
1078
1079	static int rpm_drop_usage_count(struct device *dev)
1080	{
1081	int ret;
1082
1083	ret = atomic_sub_return(i: `1`, v: &dev->power.usage_count);
1084	if (ret >= `0`)
1085	return ret;
1086
1087	/*
1088	* Because rpm_resume() does not check the usage counter, it will resume
1089	* the device even if the usage counter is 0 or negative, so it is
1090	* sufficient to increment the usage counter here to reverse the change
1091	* made above.
1092	*/
1093	atomic_inc(v: &dev->power.usage_count);
1094	dev_warn(dev, "Runtime PM usage count underflow!\n");
1095	return -EINVAL;
1096	}
1097
1098	/**
1099	* __pm_runtime_idle - Entry point for runtime idle operations.
1100	* @dev: Device to send idle notification for.
1101	* @rpmflags: Flag bits.
1102	*
1103	* If the RPM_GET_PUT flag is set, decrement the device's usage count and
1104	* return immediately if it is larger than zero (if it becomes negative, log a
1105	* warning, increment it, and return an error). Then carry out an idle
1106	* notification, either synchronous or asynchronous.
1107	*
1108	* This routine may be called in atomic context if the RPM_ASYNC flag is set,
1109	* or if pm_runtime_irq_safe() has been called.
1110	*/
1111	int __pm_runtime_idle(struct device dev, int* rpmflags)
1112	{
1113	unsigned long flags;
1114	int retval;
1115
1116	if (rpmflags & RPM_GET_PUT) {
1117	retval = rpm_drop_usage_count(dev);
1118	if (retval < `0`) {
1119	return retval;
1120	} else if (retval > `0`) {
1121	trace_rpm_usage(dev, flags: rpmflags);
1122	return `0`;
1123	}
1124	}
1125
1126	might_sleep_if(!(rpmflags & RPM_ASYNC) && !dev->power.irq_safe);
1127
1128	spin_lock_irqsave(&dev->power.lock, flags);
1129	retval = rpm_idle(dev, rpmflags);
1130	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1131
1132	return retval;
1133	}
1134	EXPORT_SYMBOL_GPL(__pm_runtime_idle);
1135
1136	/**
1137	* __pm_runtime_suspend - Entry point for runtime put/suspend operations.
1138	* @dev: Device to suspend.
1139	* @rpmflags: Flag bits.
1140	*
1141	* If the RPM_GET_PUT flag is set, decrement the device's usage count and
1142	* return immediately if it is larger than zero (if it becomes negative, log a
1143	* warning, increment it, and return an error). Then carry out a suspend,
1144	* either synchronous or asynchronous.
1145	*
1146	* This routine may be called in atomic context if the RPM_ASYNC flag is set,
1147	* or if pm_runtime_irq_safe() has been called.
1148	*/
1149	int __pm_runtime_suspend(struct device dev, int* rpmflags)
1150	{
1151	unsigned long flags;
1152	int retval;
1153
1154	if (rpmflags & RPM_GET_PUT) {
1155	retval = rpm_drop_usage_count(dev);
1156	if (retval < `0`) {
1157	return retval;
1158	} else if (retval > `0`) {
1159	trace_rpm_usage(dev, flags: rpmflags);
1160	return `0`;
1161	}
1162	}
1163
1164	might_sleep_if(!(rpmflags & RPM_ASYNC) && !dev->power.irq_safe);
1165
1166	spin_lock_irqsave(&dev->power.lock, flags);
1167	retval = rpm_suspend(dev, rpmflags);
1168	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1169
1170	return retval;
1171	}
1172	EXPORT_SYMBOL_GPL(__pm_runtime_suspend);
1173
1174	/**
1175	* __pm_runtime_resume - Entry point for runtime resume operations.
1176	* @dev: Device to resume.
1177	* @rpmflags: Flag bits.
1178	*
1179	* If the RPM_GET_PUT flag is set, increment the device's usage count. Then
1180	* carry out a resume, either synchronous or asynchronous.
1181	*
1182	* This routine may be called in atomic context if the RPM_ASYNC flag is set,
1183	* or if pm_runtime_irq_safe() has been called.
1184	*/
1185	int __pm_runtime_resume(struct device dev, int* rpmflags)
1186	{
1187	unsigned long flags;
1188	int retval;
1189
1190	might_sleep_if(!(rpmflags & RPM_ASYNC) && !dev->power.irq_safe &&
1191	dev->power.runtime_status != RPM_ACTIVE);
1192
1193	if (rpmflags & RPM_GET_PUT)
1194	atomic_inc(v: &dev->power.usage_count);
1195
1196	spin_lock_irqsave(&dev->power.lock, flags);
1197	retval = rpm_resume(dev, rpmflags);
1198	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1199
1200	return retval;
1201	}
1202	EXPORT_SYMBOL_GPL(__pm_runtime_resume);
1203
1204	/**
1205	* pm_runtime_get_conditional - Conditionally bump up device usage counter.
1206	* @dev: Device to handle.
1207	* @ign_usage_count: Whether or not to look at the current usage counter value.
1208	*
1209	* Return -EINVAL if runtime PM is disabled for @dev.
1210	*
1211	* Otherwise, if its runtime PM status is %RPM_ACTIVE and (1) @ign_usage_count
1212	* is set, or (2) @dev is not ignoring children and its active child count is
1213	* nonero, or (3) the runtime PM usage counter of @dev is not zero, increment
1214	* the usage counter of @dev and return 1.
1215	*
1216	* Otherwise, return 0 without changing the usage counter.
1217	*
1218	* If @ign_usage_count is %true, this function can be used to prevent suspending
1219	* the device when its runtime PM status is %RPM_ACTIVE.
1220	*
1221	* If @ign_usage_count is %false, this function can be used to prevent
1222	* suspending the device when both its runtime PM status is %RPM_ACTIVE and its
1223	* runtime PM usage counter is not zero.
1224	*
1225	* The caller is responsible for decrementing the runtime PM usage counter of
1226	* @dev after this function has returned a positive value for it.
1227	*/
1228	static int pm_runtime_get_conditional(struct device *dev, bool ign_usage_count)
1229	{
1230	unsigned long flags;
1231	int retval;
1232
1233	spin_lock_irqsave(&dev->power.lock, flags);
1234	if (dev->power.disable_depth > `0`) {
1235	retval = -EINVAL;
1236	} else if (dev->power.runtime_status != RPM_ACTIVE) {
1237	retval = `0`;
1238	} else if (ign_usage_count \|\| (!dev->power.ignore_children &&
1239	atomic_read(v: &dev->power.child_count) > `0`)) {
1240	retval = `1`;
1241	atomic_inc(v: &dev->power.usage_count);
1242	} else {
1243	retval = atomic_inc_not_zero(v: &dev->power.usage_count);
1244	}
1245	trace_rpm_usage(dev, flags: `0`);
1246	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1247
1248	return retval;
1249	}
1250
1251	/**
1252	* pm_runtime_get_if_active - Bump up runtime PM usage counter if the device is
1253	* in active state
1254	* @dev: Target device.
1255	*
1256	* Increment the runtime PM usage counter of @dev if its runtime PM status is
1257	* %RPM_ACTIVE, in which case it returns 1. If the device is in a different
1258	* state, 0 is returned. -EINVAL is returned if runtime PM is disabled for the
1259	* device, in which case also the usage_count will remain unmodified.
1260	*/
1261	int pm_runtime_get_if_active(struct device *dev)
1262	{
1263	return pm_runtime_get_conditional(dev, ign_usage_count: true);
1264	}
1265	EXPORT_SYMBOL_GPL(pm_runtime_get_if_active);
1266
1267	/**
1268	* pm_runtime_get_if_in_use - Conditionally bump up runtime PM usage counter.
1269	* @dev: Target device.
1270	*
1271	* Increment the runtime PM usage counter of @dev if its runtime PM status is
1272	* %RPM_ACTIVE and its runtime PM usage counter is greater than 0 or it is not
1273	* ignoring children and its active child count is nonzero. 1 is returned in
1274	* this case.
1275	*
1276	* If @dev is in a different state or it is not in use (that is, its usage
1277	* counter is 0, or it is ignoring children, or its active child count is 0),
1278	* 0 is returned.
1279	*
1280	* -EINVAL is returned if runtime PM is disabled for the device, in which case
1281	* also the usage counter of @dev is not updated.
1282	*/
1283	int pm_runtime_get_if_in_use(struct device *dev)
1284	{
1285	return pm_runtime_get_conditional(dev, ign_usage_count: false);
1286	}
1287	EXPORT_SYMBOL_GPL(pm_runtime_get_if_in_use);
1288
1289	/**
1290	* __pm_runtime_set_status - Set runtime PM status of a device.
1291	* @dev: Device to handle.
1292	* @status: New runtime PM status of the device.
1293	*
1294	* If runtime PM of the device is disabled or its power.runtime_error field is
1295	* different from zero, the status may be changed either to RPM_ACTIVE, or to
1296	* RPM_SUSPENDED, as long as that reflects the actual state of the device.
1297	* However, if the device has a parent and the parent is not active, and the
1298	* parent's power.ignore_children flag is unset, the device's status cannot be
1299	* set to RPM_ACTIVE, so -EBUSY is returned in that case.
1300	*
1301	* If successful, __pm_runtime_set_status() clears the power.runtime_error field
1302	* and the device parent's counter of unsuspended children is modified to
1303	* reflect the new status. If the new status is RPM_SUSPENDED, an idle
1304	* notification request for the parent is submitted.
1305	*
1306	* If @dev has any suppliers (as reflected by device links to them), and @status
1307	* is RPM_ACTIVE, they will be activated upfront and if the activation of one
1308	* of them fails, the status of @dev will be changed to RPM_SUSPENDED (instead
1309	* of the @status value) and the suppliers will be deacticated on exit. The
1310	* error returned by the failing supplier activation will be returned in that
1311	* case.
1312	*/
1313	int __pm_runtime_set_status(struct device dev, unsigned* int status)
1314	{
1315	struct device *parent = dev->parent;
1316	bool notify_parent = false;
1317	unsigned long flags;
1318	int error = `0`;
1319
1320	if (status != RPM_ACTIVE && status != RPM_SUSPENDED)
1321	return -EINVAL;
1322
1323	spin_lock_irqsave(&dev->power.lock, flags);
1324
1325	/*
1326	* Prevent PM-runtime from being enabled for the device or return an
1327	* error if it is enabled already and working.
1328	*/
1329	if (dev->power.runtime_error \|\| dev->power.disable_depth)
1330	dev->power.disable_depth++;
1331	else
1332	error = -EAGAIN;
1333
1334	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1335
1336	if (error)
1337	return error;
1338
1339	/*
1340	* If the new status is RPM_ACTIVE, the suppliers can be activated
1341	* upfront regardless of the current status, because next time
1342	* rpm_put_suppliers() runs, the rpm_active refcounts of the links
1343	* involved will be dropped down to one anyway.
1344	*/
1345	if (status == RPM_ACTIVE) {
1346	int idx = device_links_read_lock();
1347
1348	error = rpm_get_suppliers(dev);
1349	if (error)
1350	status = RPM_SUSPENDED;
1351
1352	device_links_read_unlock(idx);
1353	}
1354
1355	spin_lock_irqsave(&dev->power.lock, flags);
1356
1357	if (dev->power.runtime_status == status \|\| !parent)
1358	goto out_set;
1359
1360	if (status == RPM_SUSPENDED) {
1361	atomic_add_unless(v: &parent->power.child_count, a: -`1`, u: `0`);
1362	notify_parent = !parent->power.ignore_children;
1363	} else {
1364	spin_lock_nested(&parent->power.lock, SINGLE_DEPTH_NESTING);
1365
1366	/*
1367	* It is invalid to put an active child under a parent that is
1368	* not active, has runtime PM enabled and the
1369	* 'power.ignore_children' flag unset.
1370	*/
1371	if (!parent->power.disable_depth &&
1372	!parent->power.ignore_children &&
1373	parent->power.runtime_status != RPM_ACTIVE) {
1374	dev_err(dev, "runtime PM trying to activate child device %s but parent (%s) is not active\n",
1375	dev_name(dev),
1376	dev_name(parent));
1377	error = -EBUSY;
1378	} else if (dev->power.runtime_status == RPM_SUSPENDED) {
1379	atomic_inc(v: &parent->power.child_count);
1380	}
1381
1382	spin_unlock(lock: &parent->power.lock);
1383
1384	if (error) {
1385	status = RPM_SUSPENDED;
1386	goto out;
1387	}
1388	}
1389
1390	out_set:
1391	__update_runtime_status(dev, status);
1392	if (!error)
1393	dev->power.runtime_error = `0`;
1394
1395	out:
1396	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1397
1398	if (notify_parent)
1399	pm_request_idle(dev: parent);
1400
1401	if (status == RPM_SUSPENDED) {
1402	int idx = device_links_read_lock();
1403
1404	rpm_put_suppliers(dev);
1405
1406	device_links_read_unlock(idx);
1407	}
1408
1409	pm_runtime_enable(dev);
1410
1411	return error;
1412	}
1413	EXPORT_SYMBOL_GPL(__pm_runtime_set_status);
1414
1415	/**
1416	* __pm_runtime_barrier - Cancel pending requests and wait for completions.
1417	* @dev: Device to handle.
1418	*
1419	* Flush all pending requests for the device from pm_wq and wait for all
1420	* runtime PM operations involving the device in progress to complete.
1421	*
1422	* Should be called under dev->power.lock with interrupts disabled.
1423	*/
1424	static void __pm_runtime_barrier(struct device *dev)
1425	{
1426	pm_runtime_deactivate_timer(dev);
1427
1428	if (dev->power.request_pending) {
1429	dev->power.request = RPM_REQ_NONE;
1430	spin_unlock_irq(lock: &dev->power.lock);
1431
1432	cancel_work_sync(work: &dev->power.work);
1433
1434	spin_lock_irq(lock: &dev->power.lock);
1435	dev->power.request_pending = false;
1436	}
1437
1438	if (dev->power.runtime_status == RPM_SUSPENDING \|\|
1439	dev->power.runtime_status == RPM_RESUMING \|\|
1440	dev->power.idle_notification) {
1441	DEFINE_WAIT(wait);
1442
1443	/ Suspend, wake-up or idle notification in progress. /
1444	for (;;) {
1445	prepare_to_wait(wq_head: &dev->power.wait_queue, wq_entry: &wait,
1446	TASK_UNINTERRUPTIBLE);
1447	if (dev->power.runtime_status != RPM_SUSPENDING
1448	&& dev->power.runtime_status != RPM_RESUMING
1449	&& !dev->power.idle_notification)
1450	break;
1451	spin_unlock_irq(lock: &dev->power.lock);
1452
1453	schedule();
1454
1455	spin_lock_irq(lock: &dev->power.lock);
1456	}
1457	finish_wait(wq_head: &dev->power.wait_queue, wq_entry: &wait);
1458	}
1459	}
1460
1461	/**
1462	* pm_runtime_barrier - Flush pending requests and wait for completions.
1463	* @dev: Device to handle.
1464	*
1465	* Prevent the device from being suspended by incrementing its usage counter and
1466	* if there's a pending resume request for the device, wake the device up.
1467	* Next, make sure that all pending requests for the device have been flushed
1468	* from pm_wq and wait for all runtime PM operations involving the device in
1469	* progress to complete.
1470	*
1471	* Return value:
1472	* 1, if there was a resume request pending and the device had to be woken up,
1473	* 0, otherwise
1474	*/
1475	int pm_runtime_barrier(struct device *dev)
1476	{
1477	int retval = `0`;
1478
1479	pm_runtime_get_noresume(dev);
1480	spin_lock_irq(lock: &dev->power.lock);
1481
1482	if (dev->power.request_pending
1483	&& dev->power.request == RPM_REQ_RESUME) {
1484	rpm_resume(dev, rpmflags: `0`);
1485	retval = `1`;
1486	}
1487
1488	__pm_runtime_barrier(dev);
1489
1490	spin_unlock_irq(lock: &dev->power.lock);
1491	pm_runtime_put_noidle(dev);
1492
1493	return retval;
1494	}
1495	EXPORT_SYMBOL_GPL(pm_runtime_barrier);
1496
1497	bool pm_runtime_block_if_disabled(struct device *dev)
1498	{
1499	bool ret;
1500
1501	spin_lock_irq(lock: &dev->power.lock);
1502
1503	ret = !pm_runtime_enabled(dev);
1504	if (ret && dev->power.last_status == RPM_INVALID)
1505	dev->power.last_status = RPM_BLOCKED;
1506
1507	spin_unlock_irq(lock: &dev->power.lock);
1508
1509	return ret;
1510	}
1511
1512	void pm_runtime_unblock(struct device *dev)
1513	{
1514	spin_lock_irq(lock: &dev->power.lock);
1515
1516	if (dev->power.last_status == RPM_BLOCKED)
1517	dev->power.last_status = RPM_INVALID;
1518
1519	spin_unlock_irq(lock: &dev->power.lock);
1520	}
1521
1522	void __pm_runtime_disable(struct device *dev, bool check_resume)
1523	{
1524	spin_lock_irq(lock: &dev->power.lock);
1525
1526	if (dev->power.disable_depth > `0`) {
1527	dev->power.disable_depth++;
1528	goto out;
1529	}
1530
1531	/*
1532	* Wake up the device if there's a resume request pending, because that
1533	* means there probably is some I/O to process and disabling runtime PM
1534	* shouldn't prevent the device from processing the I/O.
1535	*/
1536	if (check_resume && dev->power.request_pending &&
1537	dev->power.request == RPM_REQ_RESUME) {
1538	/*
1539	* Prevent suspends and idle notifications from being carried
1540	* out after we have woken up the device.
1541	*/
1542	pm_runtime_get_noresume(dev);
1543
1544	rpm_resume(dev, rpmflags: `0`);
1545
1546	pm_runtime_put_noidle(dev);
1547	}
1548
1549	/ Update time accounting before disabling PM-runtime. /
1550	update_pm_runtime_accounting(dev);
1551
1552	if (!dev->power.disable_depth++) {
1553	__pm_runtime_barrier(dev);
1554	dev->power.last_status = dev->power.runtime_status;
1555	}
1556
1557	out:
1558	spin_unlock_irq(lock: &dev->power.lock);
1559	}
1560	EXPORT_SYMBOL_GPL(__pm_runtime_disable);
1561
1562	/**
1563	* pm_runtime_enable - Enable runtime PM of a device.
1564	* @dev: Device to handle.
1565	*/
1566	void pm_runtime_enable(struct device *dev)
1567	{
1568	unsigned long flags;
1569
1570	spin_lock_irqsave(&dev->power.lock, flags);
1571
1572	if (!dev->power.disable_depth) {
1573	dev_warn(dev, "Unbalanced %s!\n", __func__);
1574	goto out;
1575	}
1576
1577	if (--dev->power.disable_depth > `0`)
1578	goto out;
1579
1580	if (dev->power.last_status == RPM_BLOCKED) {
1581	dev_warn(dev, "Attempt to enable runtime PM when it is blocked\n");
1582	dump_stack();
1583	}
1584	dev->power.last_status = RPM_INVALID;
1585	dev->power.accounting_timestamp = ktime_get_mono_fast_ns();
1586
1587	if (dev->power.runtime_status == RPM_SUSPENDED &&
1588	!dev->power.ignore_children &&
1589	atomic_read(v: &dev->power.child_count) > `0`)
1590	dev_warn(dev, "Enabling runtime PM for inactive device with active children\n");
1591
1592	out:
1593	spin_unlock_irqrestore(lock: &dev->power.lock, flags);
1594	}
1595	EXPORT_SYMBOL_GPL(pm_runtime_enable);
1596
1597	static void pm_runtime_set_suspended_action(void *data)
1598	{
1599	pm_runtime_set_suspended(dev: data);
1600	}
1601
1602	/**
1603	* devm_pm_runtime_set_active_enabled - set_active version of devm_pm_runtime_enable.
1604	*
1605	* @dev: Device to handle.
1606	*/
1607	int devm_pm_runtime_set_active_enabled(struct device *dev)
1608	{
1609	int err;
1610
1611	err = pm_runtime_set_active(dev);
1612	if (err)
1613	return err;
1614
1615	err = devm_add_action_or_reset(dev, pm_runtime_set_suspended_action, dev);
1616	if (err)
1617	return err;
1618
1619	return devm_pm_runtime_enable(dev);
1620	}
1621	EXPORT_SYMBOL_GPL(devm_pm_runtime_set_active_enabled);
1622
1623	static void pm_runtime_disable_action(void *data)
1624	{
1625	pm_runtime_dont_use_autosuspend(dev: data);
1626	pm_runtime_disable(dev: data);
1627	}
1628
1629	/**
1630	* devm_pm_runtime_enable - devres-enabled version of pm_runtime_enable.
1631	*
1632	* NOTE: this will also handle calling pm_runtime_dont_use_autosuspend() for
1633	* you at driver exit time if needed.
1634	*
1635	* @dev: Device to handle.
1636	*/
1637	int devm_pm_runtime_enable(struct device *dev)
1638	{
1639	pm_runtime_enable(dev);
1640
1641	return devm_add_action_or_reset(dev, pm_runtime_disable_action, dev);
1642	}
1643	EXPORT_SYMBOL_GPL(devm_pm_runtime_enable);
1644
1645	static void pm_runtime_put_noidle_action(void *data)
1646	{
1647	pm_runtime_put_noidle(dev: data);
1648	}
1649
1650	/**
1651	* devm_pm_runtime_get_noresume - devres-enabled version of pm_runtime_get_noresume.
1652	*
1653	* @dev: Device to handle.
1654	*/
1655	int devm_pm_runtime_get_noresume(struct device *dev)
1656	{
1657	pm_runtime_get_noresume(dev);
1658
1659	return devm_add_action_or_reset(dev, pm_runtime_put_noidle_action, dev);
1660	}
1661	EXPORT_SYMBOL_GPL(devm_pm_runtime_get_noresume);
1662
1663	/**
1664	* pm_runtime_forbid - Block runtime PM of a device.
1665	* @dev: Device to handle.
1666	*
1667	* Increase the device's usage count and clear its power.runtime_auto flag,
1668	* so that it cannot be suspended at run time until pm_runtime_allow() is called
1669	* for it.
1670	*/
1671	void pm_runtime_forbid(struct device *dev)
1672	{
1673	spin_lock_irq(lock: &dev->power.lock);
1674	if (!dev->power.runtime_auto)
1675	goto out;
1676
1677	dev->power.runtime_auto = false;
1678	atomic_inc(v: &dev->power.usage_count);
1679	rpm_resume(dev, rpmflags: `0`);
1680
1681	out:
1682	spin_unlock_irq(lock: &dev->power.lock);
1683	}
1684	EXPORT_SYMBOL_GPL(pm_runtime_forbid);
1685
1686	/**
1687	* pm_runtime_allow - Unblock runtime PM of a device.
1688	* @dev: Device to handle.
1689	*
1690	* Decrease the device's usage count and set its power.runtime_auto flag.
1691	*/
1692	void pm_runtime_allow(struct device *dev)
1693	{
1694	int ret;
1695
1696	spin_lock_irq(lock: &dev->power.lock);
1697	if (dev->power.runtime_auto)
1698	goto out;
1699
1700	dev->power.runtime_auto = true;
1701	ret = rpm_drop_usage_count(dev);
1702	if (ret == `0`)
1703	rpm_idle(dev, RPM_AUTO \| RPM_ASYNC);
1704	else if (ret > `0`)
1705	trace_rpm_usage(dev, RPM_AUTO \| RPM_ASYNC);
1706
1707	out:
1708	spin_unlock_irq(lock: &dev->power.lock);
1709	}
1710	EXPORT_SYMBOL_GPL(pm_runtime_allow);
1711
1712	/**
1713	* pm_runtime_no_callbacks - Ignore runtime PM callbacks for a device.
1714	* @dev: Device to handle.
1715	*
1716	* Set the power.no_callbacks flag, which tells the PM core that this
1717	* device is power-managed through its parent and has no runtime PM
1718	* callbacks of its own. The runtime sysfs attributes will be removed.
1719	*/
1720	void pm_runtime_no_callbacks(struct device *dev)
1721	{
1722	spin_lock_irq(lock: &dev->power.lock);
1723	dev->power.no_callbacks = `1`;
1724	spin_unlock_irq(lock: &dev->power.lock);
1725	if (device_is_registered(dev))
1726	rpm_sysfs_remove(dev);
1727	}
1728	EXPORT_SYMBOL_GPL(pm_runtime_no_callbacks);
1729
1730	/**
1731	* pm_runtime_irq_safe - Leave interrupts disabled during callbacks.
1732	* @dev: Device to handle
1733	*
1734	* Set the power.irq_safe flag, which tells the PM core that the
1735	* ->runtime_suspend() and ->runtime_resume() callbacks for this device should
1736	* always be invoked with the spinlock held and interrupts disabled. It also
1737	* causes the parent's usage counter to be permanently incremented, preventing
1738	* the parent from runtime suspending -- otherwise an irq-safe child might have
1739	* to wait for a non-irq-safe parent.
1740	*/
1741	void pm_runtime_irq_safe(struct device *dev)
1742	{
1743	if (dev->parent)
1744	pm_runtime_get_sync(dev: dev->parent);
1745
1746	spin_lock_irq(lock: &dev->power.lock);
1747	dev->power.irq_safe = `1`;
1748	spin_unlock_irq(lock: &dev->power.lock);
1749	}
1750	EXPORT_SYMBOL_GPL(pm_runtime_irq_safe);
1751
1752	/**
1753	* update_autosuspend - Handle a change to a device's autosuspend settings.
1754	* @dev: Device to handle.
1755	* @old_delay: The former autosuspend_delay value.
1756	* @old_use: The former use_autosuspend value.
1757	*
1758	* Prevent runtime suspend if the new delay is negative and use_autosuspend is
1759	* set; otherwise allow it. Send an idle notification if suspends are allowed.
1760	*
1761	* This function must be called under dev->power.lock with interrupts disabled.
1762	*/
1763	static void update_autosuspend(struct device dev, int* old_delay, int old_use)
1764	{
1765	int delay = dev->power.autosuspend_delay;
1766
1767	/ Should runtime suspend be prevented now? /
1768	if (dev->power.use_autosuspend && delay < `0`) {
1769
1770	/ If it used to be allowed then prevent it. /
1771	if (!old_use \|\| old_delay >= `0`) {
1772	atomic_inc(v: &dev->power.usage_count);
1773	rpm_resume(dev, rpmflags: `0`);
1774	} else {
1775	trace_rpm_usage(dev, flags: `0`);
1776	}
1777	}
1778
1779	/ Runtime suspend should be allowed now. /
1780	else {
1781
1782	/ If it used to be prevented then allow it. /
1783	if (old_use && old_delay < `0`)
1784	atomic_dec(v: &dev->power.usage_count);
1785
1786	/ Maybe we can autosuspend now. /
1787	rpm_idle(dev, RPM_AUTO);
1788	}
1789	}
1790
1791	/**
1792	* pm_runtime_set_autosuspend_delay - Set a device's autosuspend_delay value.
1793	* @dev: Device to handle.
1794	* @delay: Value of the new delay in milliseconds.
1795	*
1796	* Set the device's power.autosuspend_delay value. If it changes to negative
1797	* and the power.use_autosuspend flag is set, prevent runtime suspends. If it
1798	* changes the other way, allow runtime suspends.
1799	*/
1800	void pm_runtime_set_autosuspend_delay(struct device dev, int* delay)
1801	{
1802	int old_delay, old_use;
1803
1804	spin_lock_irq(lock: &dev->power.lock);
1805	old_delay = dev->power.autosuspend_delay;
1806	old_use = dev->power.use_autosuspend;
1807	dev->power.autosuspend_delay = delay;
1808	update_autosuspend(dev, old_delay, old_use);
1809	spin_unlock_irq(lock: &dev->power.lock);
1810	}
1811	EXPORT_SYMBOL_GPL(pm_runtime_set_autosuspend_delay);
1812
1813	/**
1814	* __pm_runtime_use_autosuspend - Set a device's use_autosuspend flag.
1815	* @dev: Device to handle.
1816	* @use: New value for use_autosuspend.
1817	*
1818	* Set the device's power.use_autosuspend flag, and allow or prevent runtime
1819	* suspends as needed.
1820	*/
1821	void __pm_runtime_use_autosuspend(struct device *dev, bool use)
1822	{
1823	int old_delay, old_use;
1824
1825	spin_lock_irq(lock: &dev->power.lock);
1826	old_delay = dev->power.autosuspend_delay;
1827	old_use = dev->power.use_autosuspend;
1828	dev->power.use_autosuspend = use;
1829	update_autosuspend(dev, old_delay, old_use);
1830	spin_unlock_irq(lock: &dev->power.lock);
1831	}
1832	EXPORT_SYMBOL_GPL(__pm_runtime_use_autosuspend);
1833
1834	/**
1835	* pm_runtime_init - Initialize runtime PM fields in given device object.
1836	* @dev: Device object to initialize.
1837	*/
1838	void pm_runtime_init(struct device *dev)
1839	{
1840	dev->power.runtime_status = RPM_SUSPENDED;
1841	dev->power.last_status = RPM_INVALID;
1842	dev->power.idle_notification = false;
1843
1844	dev->power.disable_depth = `1`;
1845	atomic_set(v: &dev->power.usage_count, i: `0`);
1846
1847	dev->power.runtime_error = `0`;
1848
1849	atomic_set(v: &dev->power.child_count, i: `0`);
1850	pm_suspend_ignore_children(dev, enable: false);
1851	dev->power.runtime_auto = true;
1852
1853	dev->power.request_pending = false;
1854	dev->power.request = RPM_REQ_NONE;
1855	dev->power.deferred_resume = false;
1856	dev->power.needs_force_resume = false;
1857	INIT_WORK(&dev->power.work, pm_runtime_work);
1858
1859	dev->power.timer_expires = `0`;
1860	hrtimer_setup(timer: &dev->power.suspend_timer, function: pm_suspend_timer_fn, CLOCK_MONOTONIC,
1861	mode: HRTIMER_MODE_ABS);
1862
1863	init_waitqueue_head(&dev->power.wait_queue);
1864	}
1865
1866	/**
1867	* pm_runtime_reinit - Re-initialize runtime PM fields in given device object.
1868	* @dev: Device object to re-initialize.
1869	*/
1870	void pm_runtime_reinit(struct device *dev)
1871	{
1872	if (!pm_runtime_enabled(dev)) {
1873	if (dev->power.runtime_status == RPM_ACTIVE)
1874	pm_runtime_set_suspended(dev);
1875	if (dev->power.irq_safe) {
1876	spin_lock_irq(lock: &dev->power.lock);
1877	dev->power.irq_safe = `0`;
1878	spin_unlock_irq(lock: &dev->power.lock);
1879	if (dev->parent)
1880	pm_runtime_put(dev: dev->parent);
1881	}
1882	}
1883	/*
1884	* Clear power.needs_force_resume in case it has been set by
1885	* pm_runtime_force_suspend() invoked from a driver remove callback.
1886	*/
1887	dev->power.needs_force_resume = false;
1888	}
1889
1890	/**
1891	* pm_runtime_remove - Prepare for removing a device from device hierarchy.
1892	* @dev: Device object being removed from device hierarchy.
1893	*/
1894	void pm_runtime_remove(struct device *dev)
1895	{
1896	__pm_runtime_disable(dev, false);
1897	pm_runtime_reinit(dev);
1898	}
1899
1900	/**
1901	* pm_runtime_get_suppliers - Resume and reference-count supplier devices.
1902	* @dev: Consumer device.
1903	*/
1904	void pm_runtime_get_suppliers(struct device *dev)
1905	{
1906	struct device_link *link;
1907	int idx;
1908
1909	idx = device_links_read_lock();
1910
1911	dev_for_each_link_to_supplier(link, dev)
1912	if (device_link_test(link, DL_FLAG_PM_RUNTIME)) {
1913	link->supplier_preactivated = true;
1914	pm_runtime_get_sync(dev: link->supplier);
1915	}
1916
1917	device_links_read_unlock(idx);
1918	}
1919
1920	/**
1921	* pm_runtime_put_suppliers - Drop references to supplier devices.
1922	* @dev: Consumer device.
1923	*/
1924	void pm_runtime_put_suppliers(struct device *dev)
1925	{
1926	struct device_link *link;
1927	int idx;
1928
1929	idx = device_links_read_lock();
1930
1931	list_for_each_entry_rcu(link, &dev->links.suppliers, c_node,
1932	device_links_read_lock_held())
1933	if (link->supplier_preactivated) {
1934	link->supplier_preactivated = false;
1935	pm_runtime_put(dev: link->supplier);
1936	}
1937
1938	device_links_read_unlock(idx);
1939	}
1940
1941	void pm_runtime_new_link(struct device *dev)
1942	{
1943	spin_lock_irq(lock: &dev->power.lock);
1944	dev->power.links_count++;
1945	spin_unlock_irq(lock: &dev->power.lock);
1946	}
1947
1948	static void pm_runtime_drop_link_count(struct device *dev)
1949	{
1950	spin_lock_irq(lock: &dev->power.lock);
1951	WARN_ON(dev->power.links_count == `0`);
1952	dev->power.links_count--;
1953	spin_unlock_irq(lock: &dev->power.lock);
1954	}
1955
1956	/**
1957	* pm_runtime_drop_link - Prepare for device link removal.
1958	* @link: Device link going away.
1959	*
1960	* Drop the link count of the consumer end of @link and decrement the supplier
1961	* device's runtime PM usage counter as many times as needed to drop all of the
1962	* PM runtime reference to it from the consumer.
1963	*/
1964	void pm_runtime_drop_link(struct device_link *link)
1965	{
1966	if (!device_link_test(link, DL_FLAG_PM_RUNTIME))
1967	return;
1968
1969	pm_runtime_drop_link_count(dev: link->consumer);
1970	pm_runtime_release_supplier(link);
1971	pm_request_idle(dev: link->supplier);
1972	}
1973
1974	static pm_callback_t get_callback(struct device *dev, size_t cb_offset)
1975	{
1976	/*
1977	* Setting power.strict_midlayer means that the middle layer
1978	* code does not want its runtime PM callbacks to be invoked via
1979	* pm_runtime_force_suspend() and pm_runtime_force_resume(), so
1980	* return a direct pointer to the driver callback in that case.
1981	*/
1982	if (dev_pm_strict_midlayer_is_set(dev))
1983	return __rpm_get_driver_callback(dev, cb_offset);
1984
1985	return __rpm_get_callback(dev, cb_offset);
1986	}
1987
1988	#define GET_CALLBACK(dev, callback) \
1989	get_callback(dev, offsetof(struct dev_pm_ops, callback))
1990
1991	/**
1992	* pm_runtime_force_suspend - Force a device into suspend state if needed.
1993	* @dev: Device to suspend.
1994	*
1995	* Disable runtime PM so we safely can check the device's runtime PM status and
1996	* if it is active, invoke its ->runtime_suspend callback to suspend it and
1997	* change its runtime PM status field to RPM_SUSPENDED. Also, if the device's
1998	* usage and children counters don't indicate that the device was in use before
1999	* the system-wide transition under way, decrement its parent's children counter
2000	* (if there is a parent). Keep runtime PM disabled to preserve the state
2001	* unless we encounter errors.
2002	*
2003	* Typically this function may be invoked from a system suspend callback to make
2004	* sure the device is put into low power state and it should only be used during
2005	* system-wide PM transitions to sleep states. It assumes that the analogous
2006	* pm_runtime_force_resume() will be used to resume the device.
2007	*/
2008	int pm_runtime_force_suspend(struct device *dev)
2009	{
2010	int (callback)(struct* device *);
2011	int ret;
2012
2013	pm_runtime_disable(dev);
2014	if (pm_runtime_status_suspended(dev) \|\| dev->power.needs_force_resume)
2015	return `0`;
2016
2017	callback = GET_CALLBACK(dev, runtime_suspend);
2018
2019	dev_pm_enable_wake_irq_check(dev, can_change_status: true);
2020	ret = callback ? callback(dev) : `0`;
2021	if (ret)
2022	goto err;
2023
2024	dev_pm_enable_wake_irq_complete(dev);
2025
2026	/*
2027	* If the device can stay in suspend after the system-wide transition
2028	* to the working state that will follow, drop the children counter of
2029	* its parent and the usage counters of its suppliers. Otherwise, set
2030	* power.needs_force_resume to let pm_runtime_force_resume() know that
2031	* the device needs to be taken care of and to prevent this function
2032	* from handling the device again in case the device is passed to it
2033	* once more subsequently.
2034	*/
2035	if (pm_runtime_need_not_resume(dev))
2036	pm_runtime_set_suspended(dev);
2037	else
2038	dev->power.needs_force_resume = true;
2039
2040	return `0`;
2041
2042	err:
2043	dev_pm_disable_wake_irq_check(dev, cond_disable: true);
2044	pm_runtime_enable(dev);
2045	return ret;
2046	}
2047	EXPORT_SYMBOL_GPL(pm_runtime_force_suspend);
2048
2049	#ifdef CONFIG_PM_SLEEP
2050
2051	/**
2052	* pm_runtime_force_resume - Force a device into resume state if needed.
2053	* @dev: Device to resume.
2054	*
2055	* This function expects that either pm_runtime_force_suspend() has put the
2056	* device into a low-power state prior to calling it, or the device had been
2057	* runtime-suspended before the preceding system-wide suspend transition and it
2058	* was left in suspend during that transition.
2059	*
2060	* The actions carried out by pm_runtime_force_suspend(), or by a runtime
2061	* suspend in general, are reversed and the device is brought back into full
2062	* power if it is expected to be used on system resume, which is the case when
2063	* its needs_force_resume flag is set or when its smart_suspend flag is set and
2064	* its runtime PM status is "active".
2065	*
2066	* In other cases, the resume is deferred to be managed via runtime PM.
2067	*
2068	* Typically, this function may be invoked from a system resume callback.
2069	*/
2070	int pm_runtime_force_resume(struct device *dev)
2071	{
2072	int (callback)(struct* device *);
2073	int ret = `0`;
2074
2075	if (!dev->power.needs_force_resume && (!dev_pm_smart_suspend(dev) \|\|
2076	pm_runtime_status_suspended(dev)))
2077	goto out;
2078
2079	callback = GET_CALLBACK(dev, runtime_resume);
2080
2081	dev_pm_disable_wake_irq_check(dev, cond_disable: false);
2082	ret = callback ? callback(dev) : `0`;
2083	if (ret) {
2084	pm_runtime_set_suspended(dev);
2085	dev_pm_enable_wake_irq_check(dev, can_change_status: false);
2086	goto out;
2087	}
2088
2089	pm_runtime_mark_last_busy(dev);
2090
2091	out:
2092	/*
2093	* The smart_suspend flag can be cleared here because it is not going
2094	* to be necessary until the next system-wide suspend transition that
2095	* will update it again.
2096	*/
2097	dev->power.smart_suspend = false;
2098	/*
2099	* Also clear needs_force_resume to make this function skip devices that
2100	* have been seen by it once.
2101	*/
2102	dev->power.needs_force_resume = false;
2103
2104	pm_runtime_enable(dev);
2105	return ret;
2106	}
2107	EXPORT_SYMBOL_GPL(pm_runtime_force_resume);
2108
2109	bool pm_runtime_need_not_resume(struct device *dev)
2110	{
2111	return atomic_read(v: &dev->power.usage_count) <= `1` &&
2112	(atomic_read(v: &dev->power.child_count) == `0` \|\|
2113	dev->power.ignore_children);
2114	}
2115
2116	#endif /* CONFIG_PM_SLEEP */
2117

Browse the source code of Linux/drivers/base/power/runtime.c