xref: /linux/kernel/time/timer_migration.c (revision c532de5a67a70f8533d495f8f2aaa9a0491c3ad0)
1 // SPDX-License-Identifier: GPL-2.0-only
2 /*
3  * Infrastructure for migratable timers
4  *
5  * Copyright(C) 2022 linutronix GmbH
6  */
7 #include <linux/cpuhotplug.h>
8 #include <linux/slab.h>
9 #include <linux/smp.h>
10 #include <linux/spinlock.h>
11 #include <linux/timerqueue.h>
12 #include <trace/events/ipi.h>
13 
14 #include "timer_migration.h"
15 #include "tick-internal.h"
16 
17 #define CREATE_TRACE_POINTS
18 #include <trace/events/timer_migration.h>
19 
20 /*
21  * The timer migration mechanism is built on a hierarchy of groups. The
22  * lowest level group contains CPUs, the next level groups of CPU groups
23  * and so forth. The CPU groups are kept per node so for the normal case
24  * lock contention won't happen across nodes. Depending on the number of
25  * CPUs per node even the next level might be kept as groups of CPU groups
26  * per node and only the levels above cross the node topology.
27  *
28  * Example topology for a two node system with 24 CPUs each.
29  *
30  * LVL 2                           [GRP2:0]
31  *                              GRP1:0 = GRP1:M
32  *
33  * LVL 1            [GRP1:0]                      [GRP1:1]
34  *               GRP0:0 - GRP0:2               GRP0:3 - GRP0:5
35  *
36  * LVL 0  [GRP0:0]  [GRP0:1]  [GRP0:2]  [GRP0:3]  [GRP0:4]  [GRP0:5]
37  * CPUS     0-7       8-15      16-23     24-31     32-39     40-47
38  *
39  * The groups hold a timer queue of events sorted by expiry time. These
40  * queues are updated when CPUs go in idle. When they come out of idle
41  * ignore flag of events is set.
42  *
43  * Each group has a designated migrator CPU/group as long as a CPU/group is
44  * active in the group. This designated role is necessary to avoid that all
45  * active CPUs in a group try to migrate expired timers from other CPUs,
46  * which would result in massive lock bouncing.
47  *
48  * When a CPU is awake, it checks in it's own timer tick the group
49  * hierarchy up to the point where it is assigned the migrator role or if
50  * no CPU is active, it also checks the groups where no migrator is set
51  * (TMIGR_NONE).
52  *
53  * If it finds expired timers in one of the group queues it pulls them over
54  * from the idle CPU and runs the timer function. After that it updates the
55  * group and the parent groups if required.
56  *
57  * CPUs which go idle arm their CPU local timer hardware for the next local
58  * (pinned) timer event. If the next migratable timer expires after the
59  * next local timer or the CPU has no migratable timer pending then the
60  * CPU does not queue an event in the LVL0 group. If the next migratable
61  * timer expires before the next local timer then the CPU queues that timer
62  * in the LVL0 group. In both cases the CPU marks itself idle in the LVL0
63  * group.
64  *
65  * When CPU comes out of idle and when a group has at least a single active
66  * child, the ignore flag of the tmigr_event is set. This indicates, that
67  * the event is ignored even if it is still enqueued in the parent groups
68  * timer queue. It will be removed when touching the timer queue the next
69  * time. This spares locking in active path as the lock protects (after
70  * setup) only event information. For more information about locking,
71  * please read the section "Locking rules".
72  *
73  * If the CPU is the migrator of the group then it delegates that role to
74  * the next active CPU in the group or sets migrator to TMIGR_NONE when
75  * there is no active CPU in the group. This delegation needs to be
76  * propagated up the hierarchy so hand over from other leaves can happen at
77  * all hierarchy levels w/o doing a search.
78  *
79  * When the last CPU in the system goes idle, then it drops all migrator
80  * duties up to the top level of the hierarchy (LVL2 in the example). It
81  * then has to make sure, that it arms it's own local hardware timer for
82  * the earliest event in the system.
83  *
84  *
85  * Lifetime rules:
86  * ---------------
87  *
88  * The groups are built up at init time or when CPUs come online. They are
89  * not destroyed when a group becomes empty due to offlining. The group
90  * just won't participate in the hierarchy management anymore. Destroying
91  * groups would result in interesting race conditions which would just make
92  * the whole mechanism slow and complex.
93  *
94  *
95  * Locking rules:
96  * --------------
97  *
98  * For setting up new groups and handling events it's required to lock both
99  * child and parent group. The lock ordering is always bottom up. This also
100  * includes the per CPU locks in struct tmigr_cpu. For updating the migrator and
101  * active CPU/group information atomic_try_cmpxchg() is used instead and only
102  * the per CPU tmigr_cpu->lock is held.
103  *
104  * During the setup of groups tmigr_level_list is required. It is protected by
105  * @tmigr_mutex.
106  *
107  * When @timer_base->lock as well as tmigr related locks are required, the lock
108  * ordering is: first @timer_base->lock, afterwards tmigr related locks.
109  *
110  *
111  * Protection of the tmigr group state information:
112  * ------------------------------------------------
113  *
114  * The state information with the list of active children and migrator needs to
115  * be protected by a sequence counter. It prevents a race when updates in child
116  * groups are propagated in changed order. The state update is performed
117  * lockless and group wise. The following scenario describes what happens
118  * without updating the sequence counter:
119  *
120  * Therefore, let's take three groups and four CPUs (CPU2 and CPU3 as well
121  * as GRP0:1 will not change during the scenario):
122  *
123  *    LVL 1            [GRP1:0]
124  *                     migrator = GRP0:1
125  *                     active   = GRP0:0, GRP0:1
126  *                   /                \
127  *    LVL 0  [GRP0:0]                  [GRP0:1]
128  *           migrator = CPU0           migrator = CPU2
129  *           active   = CPU0           active   = CPU2
130  *              /         \                /         \
131  *    CPUs     0           1              2           3
132  *             active      idle           active      idle
133  *
134  *
135  * 1. CPU0 goes idle. As the update is performed group wise, in the first step
136  *    only GRP0:0 is updated. The update of GRP1:0 is pending as CPU0 has to
137  *    walk the hierarchy.
138  *
139  *    LVL 1            [GRP1:0]
140  *                     migrator = GRP0:1
141  *                     active   = GRP0:0, GRP0:1
142  *                   /                \
143  *    LVL 0  [GRP0:0]                  [GRP0:1]
144  *       --> migrator = TMIGR_NONE     migrator = CPU2
145  *       --> active   =                active   = CPU2
146  *              /         \                /         \
147  *    CPUs     0           1              2           3
148  *         --> idle        idle           active      idle
149  *
150  * 2. While CPU0 goes idle and continues to update the state, CPU1 comes out of
151  *    idle. CPU1 updates GRP0:0. The update for GRP1:0 is pending as CPU1 also
152  *    has to walk the hierarchy. Both CPUs (CPU0 and CPU1) now walk the
153  *    hierarchy to perform the needed update from their point of view. The
154  *    currently visible state looks the following:
155  *
156  *    LVL 1            [GRP1:0]
157  *                     migrator = GRP0:1
158  *                     active   = GRP0:0, GRP0:1
159  *                   /                \
160  *    LVL 0  [GRP0:0]                  [GRP0:1]
161  *       --> migrator = CPU1           migrator = CPU2
162  *       --> active   = CPU1           active   = CPU2
163  *              /         \                /         \
164  *    CPUs     0           1              2           3
165  *             idle    --> active         active      idle
166  *
167  * 3. Here is the race condition: CPU1 managed to propagate its changes (from
168  *    step 2) through the hierarchy to GRP1:0 before CPU0 (step 1) did. The
169  *    active members of GRP1:0 remain unchanged after the update since it is
170  *    still valid from CPU1 current point of view:
171  *
172  *    LVL 1            [GRP1:0]
173  *                 --> migrator = GRP0:1
174  *                 --> active   = GRP0:0, GRP0:1
175  *                   /                \
176  *    LVL 0  [GRP0:0]                  [GRP0:1]
177  *           migrator = CPU1           migrator = CPU2
178  *           active   = CPU1           active   = CPU2
179  *              /         \                /         \
180  *    CPUs     0           1              2           3
181  *             idle        active         active      idle
182  *
183  * 4. Now CPU0 finally propagates its changes (from step 1) to GRP1:0.
184  *
185  *    LVL 1            [GRP1:0]
186  *                 --> migrator = GRP0:1
187  *                 --> active   = GRP0:1
188  *                   /                \
189  *    LVL 0  [GRP0:0]                  [GRP0:1]
190  *           migrator = CPU1           migrator = CPU2
191  *           active   = CPU1           active   = CPU2
192  *              /         \                /         \
193  *    CPUs     0           1              2           3
194  *             idle        active         active      idle
195  *
196  *
197  * The race of CPU0 vs. CPU1 led to an inconsistent state in GRP1:0. CPU1 is
198  * active and is correctly listed as active in GRP0:0. However GRP1:0 does not
199  * have GRP0:0 listed as active, which is wrong. The sequence counter has been
200  * added to avoid inconsistent states during updates. The state is updated
201  * atomically only if all members, including the sequence counter, match the
202  * expected value (compare-and-exchange).
203  *
204  * Looking back at the previous example with the addition of the sequence
205  * counter: The update as performed by CPU0 in step 4 will fail. CPU1 changed
206  * the sequence number during the update in step 3 so the expected old value (as
207  * seen by CPU0 before starting the walk) does not match.
208  *
209  * Prevent race between new event and last CPU going inactive
210  * ----------------------------------------------------------
211  *
212  * When the last CPU is going idle and there is a concurrent update of a new
213  * first global timer of an idle CPU, the group and child states have to be read
214  * while holding the lock in tmigr_update_events(). The following scenario shows
215  * what happens, when this is not done.
216  *
217  * 1. Only CPU2 is active:
218  *
219  *    LVL 1            [GRP1:0]
220  *                     migrator = GRP0:1
221  *                     active   = GRP0:1
222  *                     next_expiry = KTIME_MAX
223  *                   /                \
224  *    LVL 0  [GRP0:0]                  [GRP0:1]
225  *           migrator = TMIGR_NONE     migrator = CPU2
226  *           active   =                active   = CPU2
227  *           next_expiry = KTIME_MAX   next_expiry = KTIME_MAX
228  *              /         \                /         \
229  *    CPUs     0           1              2           3
230  *             idle        idle           active      idle
231  *
232  * 2. Now CPU 2 goes idle (and has no global timer, that has to be handled) and
233  *    propagates that to GRP0:1:
234  *
235  *    LVL 1            [GRP1:0]
236  *                     migrator = GRP0:1
237  *                     active   = GRP0:1
238  *                     next_expiry = KTIME_MAX
239  *                   /                \
240  *    LVL 0  [GRP0:0]                  [GRP0:1]
241  *           migrator = TMIGR_NONE --> migrator = TMIGR_NONE
242  *           active   =            --> active   =
243  *           next_expiry = KTIME_MAX   next_expiry = KTIME_MAX
244  *              /         \                /         \
245  *    CPUs     0           1              2           3
246  *             idle        idle       --> idle        idle
247  *
248  * 3. Now the idle state is propagated up to GRP1:0. As this is now the last
249  *    child going idle in top level group, the expiry of the next group event
250  *    has to be handed back to make sure no event is lost. As there is no event
251  *    enqueued, KTIME_MAX is handed back to CPU2.
252  *
253  *    LVL 1            [GRP1:0]
254  *                 --> migrator = TMIGR_NONE
255  *                 --> active   =
256  *                     next_expiry = KTIME_MAX
257  *                   /                \
258  *    LVL 0  [GRP0:0]                  [GRP0:1]
259  *           migrator = TMIGR_NONE     migrator = TMIGR_NONE
260  *           active   =                active   =
261  *           next_expiry = KTIME_MAX   next_expiry = KTIME_MAX
262  *              /         \                /         \
263  *    CPUs     0           1              2           3
264  *             idle        idle       --> idle        idle
265  *
266  * 4. CPU 0 has a new timer queued from idle and it expires at TIMER0. CPU0
267  *    propagates that to GRP0:0:
268  *
269  *    LVL 1            [GRP1:0]
270  *                     migrator = TMIGR_NONE
271  *                     active   =
272  *                     next_expiry = KTIME_MAX
273  *                   /                \
274  *    LVL 0  [GRP0:0]                  [GRP0:1]
275  *           migrator = TMIGR_NONE     migrator = TMIGR_NONE
276  *           active   =                active   =
277  *       --> next_expiry = TIMER0      next_expiry  = KTIME_MAX
278  *              /         \                /         \
279  *    CPUs     0           1              2           3
280  *             idle        idle           idle        idle
281  *
282  * 5. GRP0:0 is not active, so the new timer has to be propagated to
283  *    GRP1:0. Therefore the GRP1:0 state has to be read. When the stalled value
284  *    (from step 2) is read, the timer is enqueued into GRP1:0, but nothing is
285  *    handed back to CPU0, as it seems that there is still an active child in
286  *    top level group.
287  *
288  *    LVL 1            [GRP1:0]
289  *                     migrator = TMIGR_NONE
290  *                     active   =
291  *                 --> next_expiry = TIMER0
292  *                   /                \
293  *    LVL 0  [GRP0:0]                  [GRP0:1]
294  *           migrator = TMIGR_NONE     migrator = TMIGR_NONE
295  *           active   =                active   =
296  *           next_expiry = TIMER0      next_expiry  = KTIME_MAX
297  *              /         \                /         \
298  *    CPUs     0           1              2           3
299  *             idle        idle           idle        idle
300  *
301  * This is prevented by reading the state when holding the lock (when a new
302  * timer has to be propagated from idle path)::
303  *
304  *   CPU2 (tmigr_inactive_up())          CPU0 (tmigr_new_timer_up())
305  *   --------------------------          ---------------------------
306  *   // step 3:
307  *   cmpxchg(&GRP1:0->state);
308  *   tmigr_update_events() {
309  *       spin_lock(&GRP1:0->lock);
310  *       // ... update events ...
311  *       // hand back first expiry when GRP1:0 is idle
312  *       spin_unlock(&GRP1:0->lock);
313  *       // ^^^ release state modification
314  *   }
315  *                                       tmigr_update_events() {
316  *                                           spin_lock(&GRP1:0->lock)
317  *                                           // ^^^ acquire state modification
318  *                                           group_state = atomic_read(&GRP1:0->state)
319  *                                           // .... update events ...
320  *                                           // hand back first expiry when GRP1:0 is idle
321  *                                           spin_unlock(&GRP1:0->lock) <3>
322  *                                           // ^^^ makes state visible for other
323  *                                           // callers of tmigr_new_timer_up()
324  *                                       }
325  *
326  * When CPU0 grabs the lock directly after cmpxchg, the first timer is reported
327  * back to CPU0 and also later on to CPU2. So no timer is missed. A concurrent
328  * update of the group state from active path is no problem, as the upcoming CPU
329  * will take care of the group events.
330  *
331  * Required event and timerqueue update after a remote expiry:
332  * -----------------------------------------------------------
333  *
334  * After expiring timers of a remote CPU, a walk through the hierarchy and
335  * update of events and timerqueues is required. It is obviously needed if there
336  * is a 'new' global timer but also if there is no new global timer but the
337  * remote CPU is still idle.
338  *
339  * 1. CPU0 and CPU1 are idle and have both a global timer expiring at the same
340  *    time. So both have an event enqueued in the timerqueue of GRP0:0. CPU3 is
341  *    also idle and has no global timer pending. CPU2 is the only active CPU and
342  *    thus also the migrator:
343  *
344  *    LVL 1            [GRP1:0]
345  *                     migrator = GRP0:1
346  *                     active   = GRP0:1
347  *                 --> timerqueue = evt-GRP0:0
348  *                   /                \
349  *    LVL 0  [GRP0:0]                  [GRP0:1]
350  *           migrator = TMIGR_NONE     migrator = CPU2
351  *           active   =                active   = CPU2
352  *           groupevt.ignore = false   groupevt.ignore = true
353  *           groupevt.cpu = CPU0       groupevt.cpu =
354  *           timerqueue = evt-CPU0,    timerqueue =
355  *                        evt-CPU1
356  *              /         \                /         \
357  *    CPUs     0           1              2           3
358  *             idle        idle           active      idle
359  *
360  * 2. CPU2 starts to expire remote timers. It starts with LVL0 group
361  *    GRP0:1. There is no event queued in the timerqueue, so CPU2 continues with
362  *    the parent of GRP0:1: GRP1:0. In GRP1:0 it dequeues the first event. It
363  *    looks at tmigr_event::cpu struct member and expires the pending timer(s)
364  *    of CPU0.
365  *
366  *    LVL 1            [GRP1:0]
367  *                     migrator = GRP0:1
368  *                     active   = GRP0:1
369  *                 --> timerqueue =
370  *                   /                \
371  *    LVL 0  [GRP0:0]                  [GRP0:1]
372  *           migrator = TMIGR_NONE     migrator = CPU2
373  *           active   =                active   = CPU2
374  *           groupevt.ignore = false   groupevt.ignore = true
375  *       --> groupevt.cpu = CPU0       groupevt.cpu =
376  *           timerqueue = evt-CPU0,    timerqueue =
377  *                        evt-CPU1
378  *              /         \                /         \
379  *    CPUs     0           1              2           3
380  *             idle        idle           active      idle
381  *
382  * 3. Some work has to be done after expiring the timers of CPU0. If we stop
383  *    here, then CPU1's pending global timer(s) will not expire in time and the
384  *    timerqueue of GRP0:0 has still an event for CPU0 enqueued which has just
385  *    been processed. So it is required to walk the hierarchy from CPU0's point
386  *    of view and update it accordingly. CPU0's event will be removed from the
387  *    timerqueue because it has no pending timer. If CPU0 would have a timer
388  *    pending then it has to expire after CPU1's first timer because all timers
389  *    from this period were just expired. Either way CPU1's event will be first
390  *    in GRP0:0's timerqueue and therefore set in the CPU field of the group
391  *    event which is then enqueued in GRP1:0's timerqueue as GRP0:0 is still not
392  *    active:
393  *
394  *    LVL 1            [GRP1:0]
395  *                     migrator = GRP0:1
396  *                     active   = GRP0:1
397  *                 --> timerqueue = evt-GRP0:0
398  *                   /                \
399  *    LVL 0  [GRP0:0]                  [GRP0:1]
400  *           migrator = TMIGR_NONE     migrator = CPU2
401  *           active   =                active   = CPU2
402  *           groupevt.ignore = false   groupevt.ignore = true
403  *       --> groupevt.cpu = CPU1       groupevt.cpu =
404  *       --> timerqueue = evt-CPU1     timerqueue =
405  *              /         \                /         \
406  *    CPUs     0           1              2           3
407  *             idle        idle           active      idle
408  *
409  * Now CPU2 (migrator) will continue step 2 at GRP1:0 and will expire the
410  * timer(s) of CPU1.
411  *
412  * The hierarchy walk in step 3 can be skipped if the migrator notices that a
413  * CPU of GRP0:0 is active again. The CPU will mark GRP0:0 active and take care
414  * of the group as migrator and any needed updates within the hierarchy.
415  */
416 
417 static DEFINE_MUTEX(tmigr_mutex);
418 static struct list_head *tmigr_level_list __read_mostly;
419 
420 static unsigned int tmigr_hierarchy_levels __read_mostly;
421 static unsigned int tmigr_crossnode_level __read_mostly;
422 
423 static DEFINE_PER_CPU(struct tmigr_cpu, tmigr_cpu);
424 
425 #define TMIGR_NONE	0xFF
426 #define BIT_CNT		8
427 
428 static inline bool tmigr_is_not_available(struct tmigr_cpu *tmc)
429 {
430 	return !(tmc->tmgroup && tmc->online);
431 }
432 
433 /*
434  * Returns true, when @childmask corresponds to the group migrator or when the
435  * group is not active - so no migrator is set.
436  */
437 static bool tmigr_check_migrator(struct tmigr_group *group, u8 childmask)
438 {
439 	union tmigr_state s;
440 
441 	s.state = atomic_read(&group->migr_state);
442 
443 	if ((s.migrator == childmask) || (s.migrator == TMIGR_NONE))
444 		return true;
445 
446 	return false;
447 }
448 
449 static bool tmigr_check_migrator_and_lonely(struct tmigr_group *group, u8 childmask)
450 {
451 	bool lonely, migrator = false;
452 	unsigned long active;
453 	union tmigr_state s;
454 
455 	s.state = atomic_read(&group->migr_state);
456 
457 	if ((s.migrator == childmask) || (s.migrator == TMIGR_NONE))
458 		migrator = true;
459 
460 	active = s.active;
461 	lonely = bitmap_weight(&active, BIT_CNT) <= 1;
462 
463 	return (migrator && lonely);
464 }
465 
466 static bool tmigr_check_lonely(struct tmigr_group *group)
467 {
468 	unsigned long active;
469 	union tmigr_state s;
470 
471 	s.state = atomic_read(&group->migr_state);
472 
473 	active = s.active;
474 
475 	return bitmap_weight(&active, BIT_CNT) <= 1;
476 }
477 
478 /**
479  * struct tmigr_walk - data required for walking the hierarchy
480  * @nextexp:		Next CPU event expiry information which is handed into
481  *			the timer migration code by the timer code
482  *			(get_next_timer_interrupt())
483  * @firstexp:		Contains the first event expiry information when
484  *			hierarchy is completely idle.  When CPU itself was the
485  *			last going idle, information makes sure, that CPU will
486  *			be back in time. When using this value in the remote
487  *			expiry case, firstexp is stored in the per CPU tmigr_cpu
488  *			struct of CPU which expires remote timers. It is updated
489  *			in top level group only. Be aware, there could occur a
490  *			new top level of the hierarchy between the 'top level
491  *			call' in tmigr_update_events() and the check for the
492  *			parent group in walk_groups(). Then @firstexp might
493  *			contain a value != KTIME_MAX even if it was not the
494  *			final top level. This is not a problem, as the worst
495  *			outcome is a CPU which might wake up a little early.
496  * @evt:		Pointer to tmigr_event which needs to be queued (of idle
497  *			child group)
498  * @childmask:		groupmask of child group
499  * @remote:		Is set, when the new timer path is executed in
500  *			tmigr_handle_remote_cpu()
501  * @basej:		timer base in jiffies
502  * @now:		timer base monotonic
503  * @check:		is set if there is the need to handle remote timers;
504  *			required in tmigr_requires_handle_remote() only
505  * @tmc_active:		this flag indicates, whether the CPU which triggers
506  *			the hierarchy walk is !idle in the timer migration
507  *			hierarchy. When the CPU is idle and the whole hierarchy is
508  *			idle, only the first event of the top level has to be
509  *			considered.
510  */
511 struct tmigr_walk {
512 	u64			nextexp;
513 	u64			firstexp;
514 	struct tmigr_event	*evt;
515 	u8			childmask;
516 	bool			remote;
517 	unsigned long		basej;
518 	u64			now;
519 	bool			check;
520 	bool			tmc_active;
521 };
522 
523 typedef bool (*up_f)(struct tmigr_group *, struct tmigr_group *, struct tmigr_walk *);
524 
525 static void __walk_groups(up_f up, struct tmigr_walk *data,
526 			  struct tmigr_cpu *tmc)
527 {
528 	struct tmigr_group *child = NULL, *group = tmc->tmgroup;
529 
530 	do {
531 		WARN_ON_ONCE(group->level >= tmigr_hierarchy_levels);
532 
533 		if (up(group, child, data))
534 			break;
535 
536 		child = group;
537 		group = group->parent;
538 		data->childmask = child->groupmask;
539 	} while (group);
540 }
541 
542 static void walk_groups(up_f up, struct tmigr_walk *data, struct tmigr_cpu *tmc)
543 {
544 	lockdep_assert_held(&tmc->lock);
545 
546 	__walk_groups(up, data, tmc);
547 }
548 
549 /*
550  * Returns the next event of the timerqueue @group->events
551  *
552  * Removes timers with ignore flag and update next_expiry of the group. Values
553  * of the group event are updated in tmigr_update_events() only.
554  */
555 static struct tmigr_event *tmigr_next_groupevt(struct tmigr_group *group)
556 {
557 	struct timerqueue_node *node = NULL;
558 	struct tmigr_event *evt = NULL;
559 
560 	lockdep_assert_held(&group->lock);
561 
562 	WRITE_ONCE(group->next_expiry, KTIME_MAX);
563 
564 	while ((node = timerqueue_getnext(&group->events))) {
565 		evt = container_of(node, struct tmigr_event, nextevt);
566 
567 		if (!evt->ignore) {
568 			WRITE_ONCE(group->next_expiry, evt->nextevt.expires);
569 			return evt;
570 		}
571 
572 		/*
573 		 * Remove next timers with ignore flag, because the group lock
574 		 * is held anyway
575 		 */
576 		if (!timerqueue_del(&group->events, node))
577 			break;
578 	}
579 
580 	return NULL;
581 }
582 
583 /*
584  * Return the next event (with the expiry equal or before @now)
585  *
586  * Event, which is returned, is also removed from the queue.
587  */
588 static struct tmigr_event *tmigr_next_expired_groupevt(struct tmigr_group *group,
589 						       u64 now)
590 {
591 	struct tmigr_event *evt = tmigr_next_groupevt(group);
592 
593 	if (!evt || now < evt->nextevt.expires)
594 		return NULL;
595 
596 	/*
597 	 * The event is ready to expire. Remove it and update next group event.
598 	 */
599 	timerqueue_del(&group->events, &evt->nextevt);
600 	tmigr_next_groupevt(group);
601 
602 	return evt;
603 }
604 
605 static u64 tmigr_next_groupevt_expires(struct tmigr_group *group)
606 {
607 	struct tmigr_event *evt;
608 
609 	evt = tmigr_next_groupevt(group);
610 
611 	if (!evt)
612 		return KTIME_MAX;
613 	else
614 		return evt->nextevt.expires;
615 }
616 
617 static bool tmigr_active_up(struct tmigr_group *group,
618 			    struct tmigr_group *child,
619 			    struct tmigr_walk *data)
620 {
621 	union tmigr_state curstate, newstate;
622 	bool walk_done;
623 	u8 childmask;
624 
625 	childmask = data->childmask;
626 	/*
627 	 * No memory barrier is required here in contrast to
628 	 * tmigr_inactive_up(), as the group state change does not depend on the
629 	 * child state.
630 	 */
631 	curstate.state = atomic_read(&group->migr_state);
632 
633 	do {
634 		newstate = curstate;
635 		walk_done = true;
636 
637 		if (newstate.migrator == TMIGR_NONE) {
638 			newstate.migrator = childmask;
639 
640 			/* Changes need to be propagated */
641 			walk_done = false;
642 		}
643 
644 		newstate.active |= childmask;
645 		newstate.seq++;
646 
647 	} while (!atomic_try_cmpxchg(&group->migr_state, &curstate.state, newstate.state));
648 
649 	trace_tmigr_group_set_cpu_active(group, newstate, childmask);
650 
651 	/*
652 	 * The group is active (again). The group event might be still queued
653 	 * into the parent group's timerqueue but can now be handled by the
654 	 * migrator of this group. Therefore the ignore flag for the group event
655 	 * is updated to reflect this.
656 	 *
657 	 * The update of the ignore flag in the active path is done lockless. In
658 	 * worst case the migrator of the parent group observes the change too
659 	 * late and expires remotely all events belonging to this group. The
660 	 * lock is held while updating the ignore flag in idle path. So this
661 	 * state change will not be lost.
662 	 */
663 	group->groupevt.ignore = true;
664 
665 	return walk_done;
666 }
667 
668 static void __tmigr_cpu_activate(struct tmigr_cpu *tmc)
669 {
670 	struct tmigr_walk data;
671 
672 	data.childmask = tmc->groupmask;
673 
674 	trace_tmigr_cpu_active(tmc);
675 
676 	tmc->cpuevt.ignore = true;
677 	WRITE_ONCE(tmc->wakeup, KTIME_MAX);
678 
679 	walk_groups(&tmigr_active_up, &data, tmc);
680 }
681 
682 /**
683  * tmigr_cpu_activate() - set this CPU active in timer migration hierarchy
684  *
685  * Call site timer_clear_idle() is called with interrupts disabled.
686  */
687 void tmigr_cpu_activate(void)
688 {
689 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
690 
691 	if (tmigr_is_not_available(tmc))
692 		return;
693 
694 	if (WARN_ON_ONCE(!tmc->idle))
695 		return;
696 
697 	raw_spin_lock(&tmc->lock);
698 	tmc->idle = false;
699 	__tmigr_cpu_activate(tmc);
700 	raw_spin_unlock(&tmc->lock);
701 }
702 
703 /*
704  * Returns true, if there is nothing to be propagated to the next level
705  *
706  * @data->firstexp is set to expiry of first gobal event of the (top level of
707  * the) hierarchy, but only when hierarchy is completely idle.
708  *
709  * The child and group states need to be read under the lock, to prevent a race
710  * against a concurrent tmigr_inactive_up() run when the last CPU goes idle. See
711  * also section "Prevent race between new event and last CPU going inactive" in
712  * the documentation at the top.
713  *
714  * This is the only place where the group event expiry value is set.
715  */
716 static
717 bool tmigr_update_events(struct tmigr_group *group, struct tmigr_group *child,
718 			 struct tmigr_walk *data)
719 {
720 	struct tmigr_event *evt, *first_childevt;
721 	union tmigr_state childstate, groupstate;
722 	bool remote = data->remote;
723 	bool walk_done = false;
724 	u64 nextexp;
725 
726 	if (child) {
727 		raw_spin_lock(&child->lock);
728 		raw_spin_lock_nested(&group->lock, SINGLE_DEPTH_NESTING);
729 
730 		childstate.state = atomic_read(&child->migr_state);
731 		groupstate.state = atomic_read(&group->migr_state);
732 
733 		if (childstate.active) {
734 			walk_done = true;
735 			goto unlock;
736 		}
737 
738 		first_childevt = tmigr_next_groupevt(child);
739 		nextexp = child->next_expiry;
740 		evt = &child->groupevt;
741 
742 		evt->ignore = (nextexp == KTIME_MAX) ? true : false;
743 	} else {
744 		nextexp = data->nextexp;
745 
746 		first_childevt = evt = data->evt;
747 
748 		/*
749 		 * Walking the hierarchy is required in any case when a
750 		 * remote expiry was done before. This ensures to not lose
751 		 * already queued events in non active groups (see section
752 		 * "Required event and timerqueue update after a remote
753 		 * expiry" in the documentation at the top).
754 		 *
755 		 * The two call sites which are executed without a remote expiry
756 		 * before, are not prevented from propagating changes through
757 		 * the hierarchy by the return:
758 		 *  - When entering this path by tmigr_new_timer(), @evt->ignore
759 		 *    is never set.
760 		 *  - tmigr_inactive_up() takes care of the propagation by
761 		 *    itself and ignores the return value. But an immediate
762 		 *    return is possible if there is a parent, sparing group
763 		 *    locking at this level, because the upper walking call to
764 		 *    the parent will take care about removing this event from
765 		 *    within the group and update next_expiry accordingly.
766 		 *
767 		 * However if there is no parent, ie: the hierarchy has only a
768 		 * single level so @group is the top level group, make sure the
769 		 * first event information of the group is updated properly and
770 		 * also handled properly, so skip this fast return path.
771 		 */
772 		if (evt->ignore && !remote && group->parent)
773 			return true;
774 
775 		raw_spin_lock(&group->lock);
776 
777 		childstate.state = 0;
778 		groupstate.state = atomic_read(&group->migr_state);
779 	}
780 
781 	/*
782 	 * If the child event is already queued in the group, remove it from the
783 	 * queue when the expiry time changed only or when it could be ignored.
784 	 */
785 	if (timerqueue_node_queued(&evt->nextevt)) {
786 		if ((evt->nextevt.expires == nextexp) && !evt->ignore) {
787 			/* Make sure not to miss a new CPU event with the same expiry */
788 			evt->cpu = first_childevt->cpu;
789 			goto check_toplvl;
790 		}
791 
792 		if (!timerqueue_del(&group->events, &evt->nextevt))
793 			WRITE_ONCE(group->next_expiry, KTIME_MAX);
794 	}
795 
796 	if (evt->ignore) {
797 		/*
798 		 * When the next child event could be ignored (nextexp is
799 		 * KTIME_MAX) and there was no remote timer handling before or
800 		 * the group is already active, there is no need to walk the
801 		 * hierarchy even if there is a parent group.
802 		 *
803 		 * The other way round: even if the event could be ignored, but
804 		 * if a remote timer handling was executed before and the group
805 		 * is not active, walking the hierarchy is required to not miss
806 		 * an enqueued timer in the non active group. The enqueued timer
807 		 * of the group needs to be propagated to a higher level to
808 		 * ensure it is handled.
809 		 */
810 		if (!remote || groupstate.active)
811 			walk_done = true;
812 	} else {
813 		evt->nextevt.expires = nextexp;
814 		evt->cpu = first_childevt->cpu;
815 
816 		if (timerqueue_add(&group->events, &evt->nextevt))
817 			WRITE_ONCE(group->next_expiry, nextexp);
818 	}
819 
820 check_toplvl:
821 	if (!group->parent && (groupstate.migrator == TMIGR_NONE)) {
822 		walk_done = true;
823 
824 		/*
825 		 * Nothing to do when update was done during remote timer
826 		 * handling. First timer in top level group which needs to be
827 		 * handled when top level group is not active, is calculated
828 		 * directly in tmigr_handle_remote_up().
829 		 */
830 		if (remote)
831 			goto unlock;
832 
833 		/*
834 		 * The top level group is idle and it has to be ensured the
835 		 * global timers are handled in time. (This could be optimized
836 		 * by keeping track of the last global scheduled event and only
837 		 * arming it on the CPU if the new event is earlier. Not sure if
838 		 * its worth the complexity.)
839 		 */
840 		data->firstexp = tmigr_next_groupevt_expires(group);
841 	}
842 
843 	trace_tmigr_update_events(child, group, childstate, groupstate,
844 				  nextexp);
845 
846 unlock:
847 	raw_spin_unlock(&group->lock);
848 
849 	if (child)
850 		raw_spin_unlock(&child->lock);
851 
852 	return walk_done;
853 }
854 
855 static bool tmigr_new_timer_up(struct tmigr_group *group,
856 			       struct tmigr_group *child,
857 			       struct tmigr_walk *data)
858 {
859 	return tmigr_update_events(group, child, data);
860 }
861 
862 /*
863  * Returns the expiry of the next timer that needs to be handled. KTIME_MAX is
864  * returned, if an active CPU will handle all the timer migration hierarchy
865  * timers.
866  */
867 static u64 tmigr_new_timer(struct tmigr_cpu *tmc, u64 nextexp)
868 {
869 	struct tmigr_walk data = { .nextexp = nextexp,
870 				   .firstexp = KTIME_MAX,
871 				   .evt = &tmc->cpuevt };
872 
873 	lockdep_assert_held(&tmc->lock);
874 
875 	if (tmc->remote)
876 		return KTIME_MAX;
877 
878 	trace_tmigr_cpu_new_timer(tmc);
879 
880 	tmc->cpuevt.ignore = false;
881 	data.remote = false;
882 
883 	walk_groups(&tmigr_new_timer_up, &data, tmc);
884 
885 	/* If there is a new first global event, make sure it is handled */
886 	return data.firstexp;
887 }
888 
889 static void tmigr_handle_remote_cpu(unsigned int cpu, u64 now,
890 				    unsigned long jif)
891 {
892 	struct timer_events tevt;
893 	struct tmigr_walk data;
894 	struct tmigr_cpu *tmc;
895 
896 	tmc = per_cpu_ptr(&tmigr_cpu, cpu);
897 
898 	raw_spin_lock_irq(&tmc->lock);
899 
900 	/*
901 	 * If the remote CPU is offline then the timers have been migrated to
902 	 * another CPU.
903 	 *
904 	 * If tmigr_cpu::remote is set, at the moment another CPU already
905 	 * expires the timers of the remote CPU.
906 	 *
907 	 * If tmigr_event::ignore is set, then the CPU returns from idle and
908 	 * takes care of its timers.
909 	 *
910 	 * If the next event expires in the future, then the event has been
911 	 * updated and there are no timers to expire right now. The CPU which
912 	 * updated the event takes care when hierarchy is completely
913 	 * idle. Otherwise the migrator does it as the event is enqueued.
914 	 */
915 	if (!tmc->online || tmc->remote || tmc->cpuevt.ignore ||
916 	    now < tmc->cpuevt.nextevt.expires) {
917 		raw_spin_unlock_irq(&tmc->lock);
918 		return;
919 	}
920 
921 	trace_tmigr_handle_remote_cpu(tmc);
922 
923 	tmc->remote = true;
924 	WRITE_ONCE(tmc->wakeup, KTIME_MAX);
925 
926 	/* Drop the lock to allow the remote CPU to exit idle */
927 	raw_spin_unlock_irq(&tmc->lock);
928 
929 	if (cpu != smp_processor_id())
930 		timer_expire_remote(cpu);
931 
932 	/*
933 	 * Lock ordering needs to be preserved - timer_base locks before tmigr
934 	 * related locks (see section "Locking rules" in the documentation at
935 	 * the top). During fetching the next timer interrupt, also tmc->lock
936 	 * needs to be held. Otherwise there is a possible race window against
937 	 * the CPU itself when it comes out of idle, updates the first timer in
938 	 * the hierarchy and goes back to idle.
939 	 *
940 	 * timer base locks are dropped as fast as possible: After checking
941 	 * whether the remote CPU went offline in the meantime and after
942 	 * fetching the next remote timer interrupt. Dropping the locks as fast
943 	 * as possible keeps the locking region small and prevents holding
944 	 * several (unnecessary) locks during walking the hierarchy for updating
945 	 * the timerqueue and group events.
946 	 */
947 	local_irq_disable();
948 	timer_lock_remote_bases(cpu);
949 	raw_spin_lock(&tmc->lock);
950 
951 	/*
952 	 * When the CPU went offline in the meantime, no hierarchy walk has to
953 	 * be done for updating the queued events, because the walk was
954 	 * already done during marking the CPU offline in the hierarchy.
955 	 *
956 	 * When the CPU is no longer idle, the CPU takes care of the timers and
957 	 * also of the timers in the hierarchy.
958 	 *
959 	 * (See also section "Required event and timerqueue update after a
960 	 * remote expiry" in the documentation at the top)
961 	 */
962 	if (!tmc->online || !tmc->idle) {
963 		timer_unlock_remote_bases(cpu);
964 		goto unlock;
965 	}
966 
967 	/* next	event of CPU */
968 	fetch_next_timer_interrupt_remote(jif, now, &tevt, cpu);
969 	timer_unlock_remote_bases(cpu);
970 
971 	data.nextexp = tevt.global;
972 	data.firstexp = KTIME_MAX;
973 	data.evt = &tmc->cpuevt;
974 	data.remote = true;
975 
976 	/*
977 	 * The update is done even when there is no 'new' global timer pending
978 	 * on the remote CPU (see section "Required event and timerqueue update
979 	 * after a remote expiry" in the documentation at the top)
980 	 */
981 	walk_groups(&tmigr_new_timer_up, &data, tmc);
982 
983 unlock:
984 	tmc->remote = false;
985 	raw_spin_unlock_irq(&tmc->lock);
986 }
987 
988 static bool tmigr_handle_remote_up(struct tmigr_group *group,
989 				   struct tmigr_group *child,
990 				   struct tmigr_walk *data)
991 {
992 	struct tmigr_event *evt;
993 	unsigned long jif;
994 	u8 childmask;
995 	u64 now;
996 
997 	jif = data->basej;
998 	now = data->now;
999 
1000 	childmask = data->childmask;
1001 
1002 	trace_tmigr_handle_remote(group);
1003 again:
1004 	/*
1005 	 * Handle the group only if @childmask is the migrator or if the
1006 	 * group has no migrator. Otherwise the group is active and is
1007 	 * handled by its own migrator.
1008 	 */
1009 	if (!tmigr_check_migrator(group, childmask))
1010 		return true;
1011 
1012 	raw_spin_lock_irq(&group->lock);
1013 
1014 	evt = tmigr_next_expired_groupevt(group, now);
1015 
1016 	if (evt) {
1017 		unsigned int remote_cpu = evt->cpu;
1018 
1019 		raw_spin_unlock_irq(&group->lock);
1020 
1021 		tmigr_handle_remote_cpu(remote_cpu, now, jif);
1022 
1023 		/* check if there is another event, that needs to be handled */
1024 		goto again;
1025 	}
1026 
1027 	/*
1028 	 * Keep track of the expiry of the first event that needs to be handled
1029 	 * (group->next_expiry was updated by tmigr_next_expired_groupevt(),
1030 	 * next was set by tmigr_handle_remote_cpu()).
1031 	 */
1032 	data->firstexp = group->next_expiry;
1033 
1034 	raw_spin_unlock_irq(&group->lock);
1035 
1036 	return false;
1037 }
1038 
1039 /**
1040  * tmigr_handle_remote() - Handle global timers of remote idle CPUs
1041  *
1042  * Called from the timer soft interrupt with interrupts enabled.
1043  */
1044 void tmigr_handle_remote(void)
1045 {
1046 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1047 	struct tmigr_walk data;
1048 
1049 	if (tmigr_is_not_available(tmc))
1050 		return;
1051 
1052 	data.childmask = tmc->groupmask;
1053 	data.firstexp = KTIME_MAX;
1054 
1055 	/*
1056 	 * NOTE: This is a doubled check because the migrator test will be done
1057 	 * in tmigr_handle_remote_up() anyway. Keep this check to speed up the
1058 	 * return when nothing has to be done.
1059 	 */
1060 	if (!tmigr_check_migrator(tmc->tmgroup, tmc->groupmask)) {
1061 		/*
1062 		 * If this CPU was an idle migrator, make sure to clear its wakeup
1063 		 * value so it won't chase timers that have already expired elsewhere.
1064 		 * This avoids endless requeue from tmigr_new_timer().
1065 		 */
1066 		if (READ_ONCE(tmc->wakeup) == KTIME_MAX)
1067 			return;
1068 	}
1069 
1070 	data.now = get_jiffies_update(&data.basej);
1071 
1072 	/*
1073 	 * Update @tmc->wakeup only at the end and do not reset @tmc->wakeup to
1074 	 * KTIME_MAX. Even if tmc->lock is not held during the whole remote
1075 	 * handling, tmc->wakeup is fine to be stale as it is called in
1076 	 * interrupt context and tick_nohz_next_event() is executed in interrupt
1077 	 * exit path only after processing the last pending interrupt.
1078 	 */
1079 
1080 	__walk_groups(&tmigr_handle_remote_up, &data, tmc);
1081 
1082 	raw_spin_lock_irq(&tmc->lock);
1083 	WRITE_ONCE(tmc->wakeup, data.firstexp);
1084 	raw_spin_unlock_irq(&tmc->lock);
1085 }
1086 
1087 static bool tmigr_requires_handle_remote_up(struct tmigr_group *group,
1088 					    struct tmigr_group *child,
1089 					    struct tmigr_walk *data)
1090 {
1091 	u8 childmask;
1092 
1093 	childmask = data->childmask;
1094 
1095 	/*
1096 	 * Handle the group only if the child is the migrator or if the group
1097 	 * has no migrator. Otherwise the group is active and is handled by its
1098 	 * own migrator.
1099 	 */
1100 	if (!tmigr_check_migrator(group, childmask))
1101 		return true;
1102 
1103 	/*
1104 	 * When there is a parent group and the CPU which triggered the
1105 	 * hierarchy walk is not active, proceed the walk to reach the top level
1106 	 * group before reading the next_expiry value.
1107 	 */
1108 	if (group->parent && !data->tmc_active)
1109 		return false;
1110 
1111 	/*
1112 	 * The lock is required on 32bit architectures to read the variable
1113 	 * consistently with a concurrent writer. On 64bit the lock is not
1114 	 * required because the read operation is not split and so it is always
1115 	 * consistent.
1116 	 */
1117 	if (IS_ENABLED(CONFIG_64BIT)) {
1118 		data->firstexp = READ_ONCE(group->next_expiry);
1119 		if (data->now >= data->firstexp) {
1120 			data->check = true;
1121 			return true;
1122 		}
1123 	} else {
1124 		raw_spin_lock(&group->lock);
1125 		data->firstexp = group->next_expiry;
1126 		if (data->now >= group->next_expiry) {
1127 			data->check = true;
1128 			raw_spin_unlock(&group->lock);
1129 			return true;
1130 		}
1131 		raw_spin_unlock(&group->lock);
1132 	}
1133 
1134 	return false;
1135 }
1136 
1137 /**
1138  * tmigr_requires_handle_remote() - Check the need of remote timer handling
1139  *
1140  * Must be called with interrupts disabled.
1141  */
1142 bool tmigr_requires_handle_remote(void)
1143 {
1144 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1145 	struct tmigr_walk data;
1146 	unsigned long jif;
1147 	bool ret = false;
1148 
1149 	if (tmigr_is_not_available(tmc))
1150 		return ret;
1151 
1152 	data.now = get_jiffies_update(&jif);
1153 	data.childmask = tmc->groupmask;
1154 	data.firstexp = KTIME_MAX;
1155 	data.tmc_active = !tmc->idle;
1156 	data.check = false;
1157 
1158 	/*
1159 	 * If the CPU is active, walk the hierarchy to check whether a remote
1160 	 * expiry is required.
1161 	 *
1162 	 * Check is done lockless as interrupts are disabled and @tmc->idle is
1163 	 * set only by the local CPU.
1164 	 */
1165 	if (!tmc->idle) {
1166 		__walk_groups(&tmigr_requires_handle_remote_up, &data, tmc);
1167 
1168 		return data.check;
1169 	}
1170 
1171 	/*
1172 	 * When the CPU is idle, compare @tmc->wakeup with @data.now. The lock
1173 	 * is required on 32bit architectures to read the variable consistently
1174 	 * with a concurrent writer. On 64bit the lock is not required because
1175 	 * the read operation is not split and so it is always consistent.
1176 	 */
1177 	if (IS_ENABLED(CONFIG_64BIT)) {
1178 		if (data.now >= READ_ONCE(tmc->wakeup))
1179 			return true;
1180 	} else {
1181 		raw_spin_lock(&tmc->lock);
1182 		if (data.now >= tmc->wakeup)
1183 			ret = true;
1184 		raw_spin_unlock(&tmc->lock);
1185 	}
1186 
1187 	return ret;
1188 }
1189 
1190 /**
1191  * tmigr_cpu_new_timer() - enqueue next global timer into hierarchy (idle tmc)
1192  * @nextexp:	Next expiry of global timer (or KTIME_MAX if not)
1193  *
1194  * The CPU is already deactivated in the timer migration
1195  * hierarchy. tick_nohz_get_sleep_length() calls tick_nohz_next_event()
1196  * and thereby the timer idle path is executed once more. @tmc->wakeup
1197  * holds the first timer, when the timer migration hierarchy is
1198  * completely idle.
1199  *
1200  * Returns the first timer that needs to be handled by this CPU or KTIME_MAX if
1201  * nothing needs to be done.
1202  */
1203 u64 tmigr_cpu_new_timer(u64 nextexp)
1204 {
1205 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1206 	u64 ret;
1207 
1208 	if (tmigr_is_not_available(tmc))
1209 		return nextexp;
1210 
1211 	raw_spin_lock(&tmc->lock);
1212 
1213 	ret = READ_ONCE(tmc->wakeup);
1214 	if (nextexp != KTIME_MAX) {
1215 		if (nextexp != tmc->cpuevt.nextevt.expires ||
1216 		    tmc->cpuevt.ignore) {
1217 			ret = tmigr_new_timer(tmc, nextexp);
1218 			/*
1219 			 * Make sure the reevaluation of timers in idle path
1220 			 * will not miss an event.
1221 			 */
1222 			WRITE_ONCE(tmc->wakeup, ret);
1223 		}
1224 	}
1225 	trace_tmigr_cpu_new_timer_idle(tmc, nextexp);
1226 	raw_spin_unlock(&tmc->lock);
1227 	return ret;
1228 }
1229 
1230 static bool tmigr_inactive_up(struct tmigr_group *group,
1231 			      struct tmigr_group *child,
1232 			      struct tmigr_walk *data)
1233 {
1234 	union tmigr_state curstate, newstate, childstate;
1235 	bool walk_done;
1236 	u8 childmask;
1237 
1238 	childmask = data->childmask;
1239 	childstate.state = 0;
1240 
1241 	/*
1242 	 * The memory barrier is paired with the cmpxchg() in tmigr_active_up()
1243 	 * to make sure the updates of child and group states are ordered. The
1244 	 * ordering is mandatory, as the group state change depends on the child
1245 	 * state.
1246 	 */
1247 	curstate.state = atomic_read_acquire(&group->migr_state);
1248 
1249 	for (;;) {
1250 		if (child)
1251 			childstate.state = atomic_read(&child->migr_state);
1252 
1253 		newstate = curstate;
1254 		walk_done = true;
1255 
1256 		/* Reset active bit when the child is no longer active */
1257 		if (!childstate.active)
1258 			newstate.active &= ~childmask;
1259 
1260 		if (newstate.migrator == childmask) {
1261 			/*
1262 			 * Find a new migrator for the group, because the child
1263 			 * group is idle!
1264 			 */
1265 			if (!childstate.active) {
1266 				unsigned long new_migr_bit, active = newstate.active;
1267 
1268 				new_migr_bit = find_first_bit(&active, BIT_CNT);
1269 
1270 				if (new_migr_bit != BIT_CNT) {
1271 					newstate.migrator = BIT(new_migr_bit);
1272 				} else {
1273 					newstate.migrator = TMIGR_NONE;
1274 
1275 					/* Changes need to be propagated */
1276 					walk_done = false;
1277 				}
1278 			}
1279 		}
1280 
1281 		newstate.seq++;
1282 
1283 		WARN_ON_ONCE((newstate.migrator != TMIGR_NONE) && !(newstate.active));
1284 
1285 		if (atomic_try_cmpxchg(&group->migr_state, &curstate.state, newstate.state)) {
1286 			trace_tmigr_group_set_cpu_inactive(group, newstate, childmask);
1287 			break;
1288 		}
1289 
1290 		/*
1291 		 * The memory barrier is paired with the cmpxchg() in
1292 		 * tmigr_active_up() to make sure the updates of child and group
1293 		 * states are ordered. It is required only when the above
1294 		 * try_cmpxchg() fails.
1295 		 */
1296 		smp_mb__after_atomic();
1297 	}
1298 
1299 	data->remote = false;
1300 
1301 	/* Event Handling */
1302 	tmigr_update_events(group, child, data);
1303 
1304 	return walk_done;
1305 }
1306 
1307 static u64 __tmigr_cpu_deactivate(struct tmigr_cpu *tmc, u64 nextexp)
1308 {
1309 	struct tmigr_walk data = { .nextexp = nextexp,
1310 				   .firstexp = KTIME_MAX,
1311 				   .evt = &tmc->cpuevt,
1312 				   .childmask = tmc->groupmask };
1313 
1314 	/*
1315 	 * If nextexp is KTIME_MAX, the CPU event will be ignored because the
1316 	 * local timer expires before the global timer, no global timer is set
1317 	 * or CPU goes offline.
1318 	 */
1319 	if (nextexp != KTIME_MAX)
1320 		tmc->cpuevt.ignore = false;
1321 
1322 	walk_groups(&tmigr_inactive_up, &data, tmc);
1323 	return data.firstexp;
1324 }
1325 
1326 /**
1327  * tmigr_cpu_deactivate() - Put current CPU into inactive state
1328  * @nextexp:	The next global timer expiry of the current CPU
1329  *
1330  * Must be called with interrupts disabled.
1331  *
1332  * Return: the next event expiry of the current CPU or the next event expiry
1333  * from the hierarchy if this CPU is the top level migrator or the hierarchy is
1334  * completely idle.
1335  */
1336 u64 tmigr_cpu_deactivate(u64 nextexp)
1337 {
1338 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1339 	u64 ret;
1340 
1341 	if (tmigr_is_not_available(tmc))
1342 		return nextexp;
1343 
1344 	raw_spin_lock(&tmc->lock);
1345 
1346 	ret = __tmigr_cpu_deactivate(tmc, nextexp);
1347 
1348 	tmc->idle = true;
1349 
1350 	/*
1351 	 * Make sure the reevaluation of timers in idle path will not miss an
1352 	 * event.
1353 	 */
1354 	WRITE_ONCE(tmc->wakeup, ret);
1355 
1356 	trace_tmigr_cpu_idle(tmc, nextexp);
1357 	raw_spin_unlock(&tmc->lock);
1358 	return ret;
1359 }
1360 
1361 /**
1362  * tmigr_quick_check() - Quick forecast of next tmigr event when CPU wants to
1363  *			 go idle
1364  * @nextevt:	The next global timer expiry of the current CPU
1365  *
1366  * Return:
1367  * * KTIME_MAX		- when it is probable that nothing has to be done (not
1368  *			  the only one in the level 0 group; and if it is the
1369  *			  only one in level 0 group, but there are more than a
1370  *			  single group active on the way to top level)
1371  * * nextevt		- when CPU is offline and has to handle timer on its own
1372  *			  or when on the way to top in every group only a single
1373  *			  child is active but @nextevt is before the lowest
1374  *			  next_expiry encountered while walking up to top level.
1375  * * next_expiry	- value of lowest expiry encountered while walking groups
1376  *			  if only a single child is active on each and @nextevt
1377  *			  is after this lowest expiry.
1378  */
1379 u64 tmigr_quick_check(u64 nextevt)
1380 {
1381 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1382 	struct tmigr_group *group = tmc->tmgroup;
1383 
1384 	if (tmigr_is_not_available(tmc))
1385 		return nextevt;
1386 
1387 	if (WARN_ON_ONCE(tmc->idle))
1388 		return nextevt;
1389 
1390 	if (!tmigr_check_migrator_and_lonely(tmc->tmgroup, tmc->groupmask))
1391 		return KTIME_MAX;
1392 
1393 	do {
1394 		if (!tmigr_check_lonely(group)) {
1395 			return KTIME_MAX;
1396 		} else {
1397 			/*
1398 			 * Since current CPU is active, events may not be sorted
1399 			 * from bottom to the top because the CPU's event is ignored
1400 			 * up to the top and its sibling's events not propagated upwards.
1401 			 * Thus keep track of the lowest observed expiry.
1402 			 */
1403 			nextevt = min_t(u64, nextevt, READ_ONCE(group->next_expiry));
1404 			if (!group->parent)
1405 				return nextevt;
1406 		}
1407 		group = group->parent;
1408 	} while (group);
1409 
1410 	return KTIME_MAX;
1411 }
1412 
1413 /*
1414  * tmigr_trigger_active() - trigger a CPU to become active again
1415  *
1416  * This function is executed on a CPU which is part of cpu_online_mask, when the
1417  * last active CPU in the hierarchy is offlining. With this, it is ensured that
1418  * the other CPU is active and takes over the migrator duty.
1419  */
1420 static long tmigr_trigger_active(void *unused)
1421 {
1422 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1423 
1424 	WARN_ON_ONCE(!tmc->online || tmc->idle);
1425 
1426 	return 0;
1427 }
1428 
1429 static int tmigr_cpu_offline(unsigned int cpu)
1430 {
1431 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1432 	int migrator;
1433 	u64 firstexp;
1434 
1435 	raw_spin_lock_irq(&tmc->lock);
1436 	tmc->online = false;
1437 	WRITE_ONCE(tmc->wakeup, KTIME_MAX);
1438 
1439 	/*
1440 	 * CPU has to handle the local events on his own, when on the way to
1441 	 * offline; Therefore nextevt value is set to KTIME_MAX
1442 	 */
1443 	firstexp = __tmigr_cpu_deactivate(tmc, KTIME_MAX);
1444 	trace_tmigr_cpu_offline(tmc);
1445 	raw_spin_unlock_irq(&tmc->lock);
1446 
1447 	if (firstexp != KTIME_MAX) {
1448 		migrator = cpumask_any_but(cpu_online_mask, cpu);
1449 		work_on_cpu(migrator, tmigr_trigger_active, NULL);
1450 	}
1451 
1452 	return 0;
1453 }
1454 
1455 static int tmigr_cpu_online(unsigned int cpu)
1456 {
1457 	struct tmigr_cpu *tmc = this_cpu_ptr(&tmigr_cpu);
1458 
1459 	/* Check whether CPU data was successfully initialized */
1460 	if (WARN_ON_ONCE(!tmc->tmgroup))
1461 		return -EINVAL;
1462 
1463 	raw_spin_lock_irq(&tmc->lock);
1464 	trace_tmigr_cpu_online(tmc);
1465 	tmc->idle = timer_base_is_idle();
1466 	if (!tmc->idle)
1467 		__tmigr_cpu_activate(tmc);
1468 	tmc->online = true;
1469 	raw_spin_unlock_irq(&tmc->lock);
1470 	return 0;
1471 }
1472 
1473 static void tmigr_init_group(struct tmigr_group *group, unsigned int lvl,
1474 			     int node)
1475 {
1476 	union tmigr_state s;
1477 
1478 	raw_spin_lock_init(&group->lock);
1479 
1480 	group->level = lvl;
1481 	group->numa_node = lvl < tmigr_crossnode_level ? node : NUMA_NO_NODE;
1482 
1483 	group->num_children = 0;
1484 
1485 	s.migrator = TMIGR_NONE;
1486 	s.active = 0;
1487 	s.seq = 0;
1488 	atomic_set(&group->migr_state, s.state);
1489 
1490 	timerqueue_init_head(&group->events);
1491 	timerqueue_init(&group->groupevt.nextevt);
1492 	group->groupevt.nextevt.expires = KTIME_MAX;
1493 	WRITE_ONCE(group->next_expiry, KTIME_MAX);
1494 	group->groupevt.ignore = true;
1495 }
1496 
1497 static struct tmigr_group *tmigr_get_group(unsigned int cpu, int node,
1498 					   unsigned int lvl)
1499 {
1500 	struct tmigr_group *tmp, *group = NULL;
1501 
1502 	lockdep_assert_held(&tmigr_mutex);
1503 
1504 	/* Try to attach to an existing group first */
1505 	list_for_each_entry(tmp, &tmigr_level_list[lvl], list) {
1506 		/*
1507 		 * If @lvl is below the cross NUMA node level, check whether
1508 		 * this group belongs to the same NUMA node.
1509 		 */
1510 		if (lvl < tmigr_crossnode_level && tmp->numa_node != node)
1511 			continue;
1512 
1513 		/* Capacity left? */
1514 		if (tmp->num_children >= TMIGR_CHILDREN_PER_GROUP)
1515 			continue;
1516 
1517 		/*
1518 		 * TODO: A possible further improvement: Make sure that all CPU
1519 		 * siblings end up in the same group of the lowest level of the
1520 		 * hierarchy. Rely on the topology sibling mask would be a
1521 		 * reasonable solution.
1522 		 */
1523 
1524 		group = tmp;
1525 		break;
1526 	}
1527 
1528 	if (group)
1529 		return group;
1530 
1531 	/* Allocate and	set up a new group */
1532 	group = kzalloc_node(sizeof(*group), GFP_KERNEL, node);
1533 	if (!group)
1534 		return ERR_PTR(-ENOMEM);
1535 
1536 	tmigr_init_group(group, lvl, node);
1537 
1538 	/* Setup successful. Add it to the hierarchy */
1539 	list_add(&group->list, &tmigr_level_list[lvl]);
1540 	trace_tmigr_group_set(group);
1541 	return group;
1542 }
1543 
1544 static void tmigr_connect_child_parent(struct tmigr_group *child,
1545 				       struct tmigr_group *parent,
1546 				       bool activate)
1547 {
1548 	struct tmigr_walk data;
1549 
1550 	raw_spin_lock_irq(&child->lock);
1551 	raw_spin_lock_nested(&parent->lock, SINGLE_DEPTH_NESTING);
1552 
1553 	child->parent = parent;
1554 	child->groupmask = BIT(parent->num_children++);
1555 
1556 	raw_spin_unlock(&parent->lock);
1557 	raw_spin_unlock_irq(&child->lock);
1558 
1559 	trace_tmigr_connect_child_parent(child);
1560 
1561 	if (!activate)
1562 		return;
1563 
1564 	/*
1565 	 * To prevent inconsistent states, active children need to be active in
1566 	 * the new parent as well. Inactive children are already marked inactive
1567 	 * in the parent group:
1568 	 *
1569 	 * * When new groups were created by tmigr_setup_groups() starting from
1570 	 *   the lowest level (and not higher then one level below the current
1571 	 *   top level), then they are not active. They will be set active when
1572 	 *   the new online CPU comes active.
1573 	 *
1574 	 * * But if a new group above the current top level is required, it is
1575 	 *   mandatory to propagate the active state of the already existing
1576 	 *   child to the new parent. So tmigr_connect_child_parent() is
1577 	 *   executed with the formerly top level group (child) and the newly
1578 	 *   created group (parent).
1579 	 *
1580 	 * * It is ensured that the child is active, as this setup path is
1581 	 *   executed in hotplug prepare callback. This is exectued by an
1582 	 *   already connected and !idle CPU. Even if all other CPUs go idle,
1583 	 *   the CPU executing the setup will be responsible up to current top
1584 	 *   level group. And the next time it goes inactive, it will release
1585 	 *   the new childmask and parent to subsequent walkers through this
1586 	 *   @child. Therefore propagate active state unconditionally.
1587 	 */
1588 	data.childmask = child->groupmask;
1589 
1590 	/*
1591 	 * There is only one new level per time (which is protected by
1592 	 * tmigr_mutex). When connecting the child and the parent and set the
1593 	 * child active when the parent is inactive, the parent needs to be the
1594 	 * uppermost level. Otherwise there went something wrong!
1595 	 */
1596 	WARN_ON(!tmigr_active_up(parent, child, &data) && parent->parent);
1597 }
1598 
1599 static int tmigr_setup_groups(unsigned int cpu, unsigned int node)
1600 {
1601 	struct tmigr_group *group, *child, **stack;
1602 	int top = 0, err = 0, i = 0;
1603 	struct list_head *lvllist;
1604 
1605 	stack = kcalloc(tmigr_hierarchy_levels, sizeof(*stack), GFP_KERNEL);
1606 	if (!stack)
1607 		return -ENOMEM;
1608 
1609 	do {
1610 		group = tmigr_get_group(cpu, node, i);
1611 		if (IS_ERR(group)) {
1612 			err = PTR_ERR(group);
1613 			break;
1614 		}
1615 
1616 		top = i;
1617 		stack[i++] = group;
1618 
1619 		/*
1620 		 * When booting only less CPUs of a system than CPUs are
1621 		 * available, not all calculated hierarchy levels are required.
1622 		 *
1623 		 * The loop is aborted as soon as the highest level, which might
1624 		 * be different from tmigr_hierarchy_levels, contains only a
1625 		 * single group.
1626 		 */
1627 		if (group->parent || i == tmigr_hierarchy_levels ||
1628 		    (list_empty(&tmigr_level_list[i]) &&
1629 		     list_is_singular(&tmigr_level_list[i - 1])))
1630 			break;
1631 
1632 	} while (i < tmigr_hierarchy_levels);
1633 
1634 	while (i > 0) {
1635 		group = stack[--i];
1636 
1637 		if (err < 0) {
1638 			list_del(&group->list);
1639 			kfree(group);
1640 			continue;
1641 		}
1642 
1643 		WARN_ON_ONCE(i != group->level);
1644 
1645 		/*
1646 		 * Update tmc -> group / child -> group connection
1647 		 */
1648 		if (i == 0) {
1649 			struct tmigr_cpu *tmc = per_cpu_ptr(&tmigr_cpu, cpu);
1650 
1651 			raw_spin_lock_irq(&group->lock);
1652 
1653 			tmc->tmgroup = group;
1654 			tmc->groupmask = BIT(group->num_children++);
1655 
1656 			raw_spin_unlock_irq(&group->lock);
1657 
1658 			trace_tmigr_connect_cpu_parent(tmc);
1659 
1660 			/* There are no children that need to be connected */
1661 			continue;
1662 		} else {
1663 			child = stack[i - 1];
1664 			/* Will be activated at online time */
1665 			tmigr_connect_child_parent(child, group, false);
1666 		}
1667 
1668 		/* check if uppermost level was newly created */
1669 		if (top != i)
1670 			continue;
1671 
1672 		WARN_ON_ONCE(top == 0);
1673 
1674 		lvllist = &tmigr_level_list[top];
1675 		if (group->num_children == 1 && list_is_singular(lvllist)) {
1676 			/*
1677 			 * The target CPU must never do the prepare work, except
1678 			 * on early boot when the boot CPU is the target. Otherwise
1679 			 * it may spuriously activate the old top level group inside
1680 			 * the new one (nevertheless whether old top level group is
1681 			 * active or not) and/or release an uninitialized childmask.
1682 			 */
1683 			WARN_ON_ONCE(cpu == raw_smp_processor_id());
1684 
1685 			lvllist = &tmigr_level_list[top - 1];
1686 			list_for_each_entry(child, lvllist, list) {
1687 				if (child->parent)
1688 					continue;
1689 
1690 				tmigr_connect_child_parent(child, group, true);
1691 			}
1692 		}
1693 	}
1694 
1695 	kfree(stack);
1696 
1697 	return err;
1698 }
1699 
1700 static int tmigr_add_cpu(unsigned int cpu)
1701 {
1702 	int node = cpu_to_node(cpu);
1703 	int ret;
1704 
1705 	mutex_lock(&tmigr_mutex);
1706 	ret = tmigr_setup_groups(cpu, node);
1707 	mutex_unlock(&tmigr_mutex);
1708 
1709 	return ret;
1710 }
1711 
1712 static int tmigr_cpu_prepare(unsigned int cpu)
1713 {
1714 	struct tmigr_cpu *tmc = per_cpu_ptr(&tmigr_cpu, cpu);
1715 	int ret = 0;
1716 
1717 	/* Not first online attempt? */
1718 	if (tmc->tmgroup)
1719 		return ret;
1720 
1721 	raw_spin_lock_init(&tmc->lock);
1722 	timerqueue_init(&tmc->cpuevt.nextevt);
1723 	tmc->cpuevt.nextevt.expires = KTIME_MAX;
1724 	tmc->cpuevt.ignore = true;
1725 	tmc->cpuevt.cpu = cpu;
1726 	tmc->remote = false;
1727 	WRITE_ONCE(tmc->wakeup, KTIME_MAX);
1728 
1729 	ret = tmigr_add_cpu(cpu);
1730 	if (ret < 0)
1731 		return ret;
1732 
1733 	if (tmc->groupmask == 0)
1734 		return -EINVAL;
1735 
1736 	return ret;
1737 }
1738 
1739 static int __init tmigr_init(void)
1740 {
1741 	unsigned int cpulvl, nodelvl, cpus_per_node, i;
1742 	unsigned int nnodes = num_possible_nodes();
1743 	unsigned int ncpus = num_possible_cpus();
1744 	int ret = -ENOMEM;
1745 
1746 	BUILD_BUG_ON_NOT_POWER_OF_2(TMIGR_CHILDREN_PER_GROUP);
1747 
1748 	/* Nothing to do if running on UP */
1749 	if (ncpus == 1)
1750 		return 0;
1751 
1752 	/*
1753 	 * Calculate the required hierarchy levels. Unfortunately there is no
1754 	 * reliable information available, unless all possible CPUs have been
1755 	 * brought up and all NUMA nodes are populated.
1756 	 *
1757 	 * Estimate the number of levels with the number of possible nodes and
1758 	 * the number of possible CPUs. Assume CPUs are spread evenly across
1759 	 * nodes. We cannot rely on cpumask_of_node() because it only works for
1760 	 * online CPUs.
1761 	 */
1762 	cpus_per_node = DIV_ROUND_UP(ncpus, nnodes);
1763 
1764 	/* Calc the hierarchy levels required to hold the CPUs of a node */
1765 	cpulvl = DIV_ROUND_UP(order_base_2(cpus_per_node),
1766 			      ilog2(TMIGR_CHILDREN_PER_GROUP));
1767 
1768 	/* Calculate the extra levels to connect all nodes */
1769 	nodelvl = DIV_ROUND_UP(order_base_2(nnodes),
1770 			       ilog2(TMIGR_CHILDREN_PER_GROUP));
1771 
1772 	tmigr_hierarchy_levels = cpulvl + nodelvl;
1773 
1774 	/*
1775 	 * If a NUMA node spawns more than one CPU level group then the next
1776 	 * level(s) of the hierarchy contains groups which handle all CPU groups
1777 	 * of the same NUMA node. The level above goes across NUMA nodes. Store
1778 	 * this information for the setup code to decide in which level node
1779 	 * matching is no longer required.
1780 	 */
1781 	tmigr_crossnode_level = cpulvl;
1782 
1783 	tmigr_level_list = kcalloc(tmigr_hierarchy_levels, sizeof(struct list_head), GFP_KERNEL);
1784 	if (!tmigr_level_list)
1785 		goto err;
1786 
1787 	for (i = 0; i < tmigr_hierarchy_levels; i++)
1788 		INIT_LIST_HEAD(&tmigr_level_list[i]);
1789 
1790 	pr_info("Timer migration: %d hierarchy levels; %d children per group;"
1791 		" %d crossnode level\n",
1792 		tmigr_hierarchy_levels, TMIGR_CHILDREN_PER_GROUP,
1793 		tmigr_crossnode_level);
1794 
1795 	ret = cpuhp_setup_state(CPUHP_TMIGR_PREPARE, "tmigr:prepare",
1796 				tmigr_cpu_prepare, NULL);
1797 	if (ret)
1798 		goto err;
1799 
1800 	ret = cpuhp_setup_state(CPUHP_AP_TMIGR_ONLINE, "tmigr:online",
1801 				tmigr_cpu_online, tmigr_cpu_offline);
1802 	if (ret)
1803 		goto err;
1804 
1805 	return 0;
1806 
1807 err:
1808 	pr_err("Timer migration setup failed\n");
1809 	return ret;
1810 }
1811 early_initcall(tmigr_init);
1812