| blob | f6aae7977824ab7595950e378c2dd0f0bbe0256d |
1 /*
2 * linux/kernel/time/tick-broadcast.c
3 *
4 * This file contains functions which emulate a local clock-event
5 * device via a broadcast event source.
6 *
7 * Copyright(C) 2005-2006, Thomas Gleixner <tglx@linutronix.de>
8 * Copyright(C) 2005-2007, Red Hat, Inc., Ingo Molnar
9 * Copyright(C) 2006-2007, Timesys Corp., Thomas Gleixner
10 *
11 * This code is licenced under the GPL version 2. For details see
12 * kernel-base/COPYING.
13 */
14 #include <linux/cpu.h>
15 #include <linux/err.h>
16 #include <linux/hrtimer.h>
17 #include <linux/interrupt.h>
18 #include <linux/percpu.h>
19 #include <linux/profile.h>
20 #include <linux/sched.h>
21 #include <linux/smp.h>
22 #include <linux/module.h>
26 /*
27 * Broadcast support for broken x86 hardware, where the local apic
28 * timer stops in C3 state.
29 */
38 #ifdef CONFIG_TICK_ONESHOT
41 #else
44 #endif
46 /*
47 * Debugging: see timer_list.c
48 */
50 {
52 }
55 {
57 }
59 /*
60 * Start the device in periodic mode
61 */
63 {
66 }
68 /*
69 * Check, if the device can be utilized as broadcast device:
70 */
73 {
84 }
86 /*
87 * Conditionally install/replace broadcast device
88 */
90 {
105 /*
106 * Inform all cpus about this. We might be in a situation
107 * where we did not switch to oneshot mode because the per cpu
108 * devices are affected by CLOCK_EVT_FEAT_C3STOP and the lack
109 * of a oneshot capable broadcast device. Without that
110 * notification the systems stays stuck in periodic mode
111 * forever.
112 */
115 }
117 /*
118 * Check, if the device is the broadcast device
119 */
121 {
123 }
126 {
133 }
135 }
139 {
141 }
144 {
151 }
152 }
154 /*
155 * Check, if the device is disfunctional and a place holder, which
156 * needs to be handled by the broadcast device.
157 */
159 {
166 /*
167 * Devices might be registered with both periodic and oneshot
168 * mode disabled. This signals, that the device needs to be
169 * operated from the broadcast device and is a placeholder for
170 * the cpu local device.
171 */
178 else
182 /*
183 * Clear the broadcast bit for this cpu if the
184 * device is not power state affected.
185 */
188 else
191 /*
192 * Clear the broadcast bit if the CPU is not in
193 * periodic broadcast on state.
194 */
200 /*
201 * If the system is in oneshot mode we can
202 * unconditionally clear the oneshot mask bit,
203 * because the CPU is running and therefore
204 * not in an idle state which causes the power
205 * state affected device to stop. Let the
206 * caller initialize the device.
207 */
213 /*
214 * If the system is in periodic mode, check
215 * whether the broadcast device can be
216 * switched off now.
217 */
220 /*
221 * If we kept the cpu in the broadcast mask,
222 * tell the caller to leave the per cpu device
223 * in shutdown state. The periodic interrupt
224 * is delivered by the broadcast device, if
225 * the broadcast device exists and is not
226 * hrtimer based.
227 */
233 }
234 }
237 }
239 #ifdef CONFIG_GENERIC_CLOCKEVENTS_BROADCAST
241 {
253 }
254 #endif
256 /*
257 * Broadcast the event to the cpus, which are set in the mask (mangled).
258 */
260 {
265 /*
266 * Check, if the current cpu is in the mask
267 */
272 /*
273 * We only run the local handler, if the broadcast
274 * device is not hrtimer based. Otherwise we run into
275 * a hrtimer recursion.
276 *
277 * local timer_interrupt()
278 * local_handler()
279 * expire_hrtimers()
280 * bc_handler()
281 * local_handler()
282 * expire_hrtimers()
283 */
285 }
288 /*
289 * It might be necessary to actually check whether the devices
290 * have different broadcast functions. For now, just use the
291 * one of the first device. This works as long as we have this
292 * misfeature only on x86 (lapic)
293 */
296 }
298 }
300 /*
301 * Periodic broadcast:
302 * - invoke the broadcast handlers
303 */
305 {
308 }
310 /*
311 * Event handler for periodic broadcast ticks
312 */
314 {
320 /* Handle spurious interrupts gracefully */
324 }
332 }
335 /*
336 * We run the handler of the local cpu after dropping
337 * tick_broadcast_lock because the handler might deadlock when
338 * trying to switch to oneshot mode.
339 */
342 }
344 /**
345 * tick_broadcast_control - Enable/disable or force broadcast mode
346 * @mode: The selected broadcast mode
347 *
348 * Called when the system enters a state where affected tick devices
349 * might stop. Note: TICK_BROADCAST_FORCE cannot be undone.
350 *
351 * Called with interrupts disabled, so clockevents_lock is not
352 * required here because the local clock event device cannot go away
353 * under us.
354 */
356 {
364 /*
365 * Is the device not affected by the powerstate ?
366 */
384 /*
385 * Only shutdown the cpu local device, if:
386 *
387 * - the broadcast device exists
388 * - the broadcast device is not a hrtimer based one
389 * - the broadcast device is in periodic mode to
390 * avoid a hickup during switch to oneshot mode
391 */
395 }
406 TICKDEV_MODE_PERIODIC)
408 }
410 }
419 else
421 }
422 }
424 }
427 /*
428 * Set the periodic handler depending on broadcast on/off
429 */
431 {
434 else
436 }
438 #ifdef CONFIG_HOTPLUG_CPU
439 /*
440 * Remove a CPU from broadcasting
441 */
443 {
456 }
459 }
460 #endif
463 {
474 }
476 /*
477 * This is called from tick_resume_local() on a resuming CPU. That's
478 * called from the core resume function, tick_unfreeze() and the magic XEN
479 * resume hackery.
480 *
481 * In none of these cases the broadcast device mode can change and the
482 * bit of the resuming CPU in the broadcast mask is safe as well.
483 */
485 {
488 else
490 }
493 {
513 }
514 }
516 }
518 #ifdef CONFIG_TICK_ONESHOT
524 /*
525 * Exposed for debugging: see timer_list.c
526 */
528 {
530 }
532 /*
533 * Called before going idle with interrupts disabled. Checks whether a
534 * broadcast event from the other core is about to happen. We detected
535 * that in tick_broadcast_oneshot_control(). The callsite can use this
536 * to avoid a deep idle transition as we are about to get the
537 * broadcast IPI right away.
538 */
540 {
542 }
544 /*
545 * Set broadcast interrupt affinity
546 */
549 {
558 }
561 ktime_t expires)
562 {
568 }
571 {
573 }
575 /*
576 * Called from irq_enter() when idle was interrupted to reenable the
577 * per cpu device.
578 */
580 {
584 /*
585 * We might be in the middle of switching over from
586 * periodic to oneshot. If the CPU has not yet
587 * switched over, leave the device alone.
588 */
591 CLOCK_EVT_STATE_ONESHOT);
592 }
593 }
594 }
596 /*
597 * Handle oneshot mode broadcasting
598 */
600 {
611 /* Find all expired events */
616 /*
617 * Mark the remote cpu in the pending mask, so
618 * it can avoid reprogramming the cpu local
619 * timer in tick_broadcast_oneshot_control().
620 */
625 }
626 }
628 /*
629 * Remove the current cpu from the pending mask. The event is
630 * delivered immediately in tick_do_broadcast() !
631 */
634 /* Take care of enforced broadcast requests */
638 /*
639 * Sanity check. Catch the case where we try to broadcast to
640 * offline cpus.
641 */
645 /*
646 * Wakeup the cpus which have an expired event.
647 */
650 /*
651 * Two reasons for reprogram:
652 *
653 * - The global event did not expire any CPU local
654 * events. This happens in dyntick mode, as the maximum PIT
655 * delta is quite small.
656 *
657 * - There are pending events on sleeping CPUs which were not
658 * in the event mask
659 */
668 }
669 }
672 {
678 }
682 {
683 /*
684 * For hrtimer based broadcasting we cannot shutdown the cpu
685 * local device if our own event is the first one to expire or
686 * if we own the broadcast timer.
687 */
693 }
695 }
698 {
701 ktime_t now;
703 /*
704 * If there is no broadcast device, tell the caller not to go
705 * into deep idle.
706 */
717 /*
718 * If the current CPU owns the hrtimer broadcast
719 * mechanism, it cannot go deep idle and we do not add
720 * the CPU to the broadcast mask. We don't have to go
721 * through the EXIT path as the local timer is not
722 * shutdown.
723 */
728 /*
729 * If the broadcast device is in periodic mode, we
730 * return.
731 */
733 /* If it is a hrtimer based broadcast, return busy */
737 }
742 /* Conditionally shut down the local timer. */
745 /*
746 * We only reprogram the broadcast timer if we
747 * did not mark ourself in the force mask and
748 * if the cpu local event is earlier than the
749 * broadcast event. If the current CPU is in
750 * the force mask, then we are going to be
751 * woken by the IPI right away; we return
752 * busy, so the CPU does not try to go deep
753 * idle.
754 */
759 /*
760 * In case of hrtimer broadcasts the
761 * programming might have moved the
762 * timer to this cpu. If yes, remove
763 * us from the broadcast mask and
764 * return busy.
765 */
769 tick_broadcast_oneshot_mask);
770 }
771 }
772 }
776 /*
777 * The cpu which was handling the broadcast
778 * timer marked this cpu in the broadcast
779 * pending mask and fired the broadcast
780 * IPI. So we are going to handle the expired
781 * event anyway via the broadcast IPI
782 * handler. No need to reprogram the timer
783 * with an already expired event.
784 */
786 tick_broadcast_pending_mask))
789 /*
790 * Bail out if there is no next event.
791 */
794 /*
795 * If the pending bit is not set, then we are
796 * either the CPU handling the broadcast
797 * interrupt or we got woken by something else.
798 *
799 * We are not longer in the broadcast mask, so
800 * if the cpu local expiry time is already
801 * reached, we would reprogram the cpu local
802 * timer with an already expired event.
803 *
804 * This can lead to a ping-pong when we return
805 * to idle and therefor rearm the broadcast
806 * timer before the cpu local timer was able
807 * to fire. This happens because the forced
808 * reprogramming makes sure that the event
809 * will happen in the future and depending on
810 * the min_delta setting this might be far
811 * enough out that the ping-pong starts.
812 *
813 * If the cpu local next_event has expired
814 * then we know that the broadcast timer
815 * next_event has expired as well and
816 * broadcast is about to be handled. So we
817 * avoid reprogramming and enforce that the
818 * broadcast handler, which did not run yet,
819 * will invoke the cpu local handler.
820 *
821 * We cannot call the handler directly from
822 * here, because we might be in a NOHZ phase
823 * and we did not go through the irq_enter()
824 * nohz fixups.
825 */
830 }
831 /*
832 * We got woken by something else. Reprogram
833 * the cpu local timer device.
834 */
836 }
837 }
838 out:
841 }
843 /*
844 * Reset the one shot broadcast for a cpu
845 *
846 * Called with tick_broadcast_lock held
847 */
849 {
852 }
855 ktime_t expires)
856 {
864 }
865 }
867 /**
868 * tick_broadcast_setup_oneshot - setup the broadcast device
869 */
871 {
874 /* Set it up only once ! */
880 /*
881 * We must be careful here. There might be other CPUs
882 * waiting for periodic broadcast. We need to set the
883 * oneshot_mask bits for those and program the
884 * broadcast device to fire.
885 */
894 tick_next_period);
899 /*
900 * The first cpu which switches to oneshot mode sets
901 * the bit for all other cpus which are in the general
902 * (periodic) broadcast mask. So the bit is set and
903 * would prevent the first broadcast enter after this
904 * to program the bc device.
905 */
907 }
908 }
910 /*
911 * Select oneshot operating mode for the broadcast device
912 */
914 {
926 }
928 #ifdef CONFIG_HOTPLUG_CPU
930 {
938 /* This moves the broadcast assignment to this CPU: */
940 }
942 }
944 /*
945 * Remove a dead CPU from broadcasting
946 */
948 {
953 /*
954 * Clear the broadcast masks for the dead cpu, but do not stop
955 * the broadcast device!
956 */
962 }
963 #endif
965 /*
966 * Check, whether the broadcast device is in one shot mode
967 */
969 {
971 }
973 /*
974 * Check whether the broadcast device supports oneshot.
975 */
977 {
981 }
983 #else
985 {
992 }
993 #endif
996 {
1000 #ifdef CONFIG_TICK_ONESHOT
1004 #endif
1005 }