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source: mainline/kernel/generic/src/proc/scheduler.c@ 935e28c

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Last change on this file since 935e28c was 935e28c, checked in by Adam Hraska <adam.hraska+hos@…>, 13 years ago
preemption_disable: Fixed bug that called scheduler() from interrupts. It disables calling scheduler() from preemption_enable() until in_exc_handler() is implemented properly.
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File size: 17.7 KB

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1	/*
2	* Copyright (c) 2010 Jakub Jermar
3	* All rights reserved.
4	*
5	* Redistribution and use in source and binary forms, with or without
6	* modification, are permitted provided that the following conditions
7	* are met:
8	*
9	* - Redistributions of source code must retain the above copyright
10	* notice, this list of conditions and the following disclaimer.
11	* - Redistributions in binary form must reproduce the above copyright
12	* notice, this list of conditions and the following disclaimer in the
13	* documentation and/or other materials provided with the distribution.
14	* - The name of the author may not be used to endorse or promote products
15	* derived from this software without specific prior written permission.
16	*
17	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
18	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
19	* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
20	* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
21	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
22	* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
23	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
24	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
25	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
26	* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
27	*/
28
29	/** @addtogroup genericproc
30	* @{
31	*/
32
33	/**
34	* @file
35	* @brief Scheduler and load balancing.
36	*
37	* This file contains the scheduler and kcpulb kernel thread which
38	* performs load-balancing of per-CPU run queues.
39	*/
40
41	#include <proc/scheduler.h>
42	#include <proc/thread.h>
43	#include <proc/task.h>
44	#include <mm/frame.h>
45	#include <mm/page.h>
46	#include <mm/as.h>
47	#include <time/timeout.h>
48	#include <time/delay.h>
49	#include <arch/asm.h>
50	#include <arch/faddr.h>
51	#include <arch/cycle.h>
52	#include <atomic.h>
53	#include <synch/spinlock.h>
54	#include <synch/workqueue.h>
55	#include <synch/rcu.h>
56	#include <config.h>
57	#include <context.h>
58	#include <fpu_context.h>
59	#include <func.h>
60	#include <arch.h>
61	#include <adt/list.h>
62	#include <panic.h>
63	#include <cpu.h>
64	#include <print.h>
65	#include <debug.h>
66	#include <stacktrace.h>
67	#include <cpu.h>
68
69	static void scheduler_separated_stack(void);
70
71	atomic_t nrdy; /*< Number of ready threads in the system. /
72
73	/** Carry out actions before new task runs. */
74	static void before_task_runs(void)
75	{
76	before_task_runs_arch();
77	}
78
79	/** Take actions before new thread runs.
80	*
81	* Perform actions that need to be
82	* taken before the newly selected
83	* thread is passed control.
84	*
85	* THREAD->lock is locked on entry
86	*
87	*/
88	static void before_thread_runs(void)
89	{
90	before_thread_runs_arch();
91	rcu_before_thread_runs();
92
93	#ifdef CONFIG_FPU_LAZY
94	if (THREAD == CPU->fpu_owner)
95	fpu_enable();
96	else
97	fpu_disable();
98	#else
99	fpu_enable();
100	if (THREAD->fpu_context_exists)
101	fpu_context_restore(THREAD->saved_fpu_context);
102	else {
103	fpu_init();
104	THREAD->fpu_context_exists = true;
105	}
106	#endif
107
108	#ifdef CONFIG_UDEBUG
109	if (THREAD->btrace) {
110	istate_t *istate = THREAD->udebug.uspace_state;
111	if (istate != NULL) {
112	printf("Thread %" PRIu64 " stack trace:\n", THREAD->tid);
113	stack_trace_istate(istate);
114	}
115
116	THREAD->btrace = false;
117	}
118	#endif
119	}
120
121	/** Take actions after THREAD had run.
122	*
123	* Perform actions that need to be
124	* taken after the running thread
125	* had been preempted by the scheduler.
126	*
127	* THREAD->lock is locked on entry
128	*
129	*/
130	static void after_thread_ran(void)
131	{
132	workq_after_thread_ran();
133	rcu_after_thread_ran();
134	after_thread_ran_arch();
135	}
136
137	#ifdef CONFIG_FPU_LAZY
138	void scheduler_fpu_lazy_request(void)
139	{
140	restart:
141	fpu_enable();
142	irq_spinlock_lock(&CPU->lock, false);
143
144	/* Save old context */
145	if (CPU->fpu_owner != NULL) {
146	irq_spinlock_lock(&CPU->fpu_owner->lock, false);
147	fpu_context_save(CPU->fpu_owner->saved_fpu_context);
148
149	/* Don't prevent migration */
150	CPU->fpu_owner->fpu_context_engaged = false;
151	irq_spinlock_unlock(&CPU->fpu_owner->lock, false);
152	CPU->fpu_owner = NULL;
153	}
154
155	irq_spinlock_lock(&THREAD->lock, false);
156	if (THREAD->fpu_context_exists) {
157	fpu_context_restore(THREAD->saved_fpu_context);
158	} else {
159	/* Allocate FPU context */
160	if (!THREAD->saved_fpu_context) {
161	/* Might sleep */
162	irq_spinlock_unlock(&THREAD->lock, false);
163	irq_spinlock_unlock(&CPU->lock, false);
164	THREAD->saved_fpu_context =
165	(fpu_context_t *) slab_alloc(fpu_context_slab, 0);
166
167	/* We may have switched CPUs during slab_alloc */
168	goto restart;
169	}
170	fpu_init();
171	THREAD->fpu_context_exists = true;
172	}
173
174	CPU->fpu_owner = THREAD;
175	THREAD->fpu_context_engaged = true;
176	irq_spinlock_unlock(&THREAD->lock, false);
177
178	irq_spinlock_unlock(&CPU->lock, false);
179	}
180	#endif /* CONFIG_FPU_LAZY */
181
182	/** Initialize scheduler
183	*
184	* Initialize kernel scheduler.
185	*
186	*/
187	void scheduler_init(void)
188	{
189	}
190
191	/** Get thread to be scheduled
192	*
193	* Get the optimal thread to be scheduled
194	* according to thread accounting and scheduler
195	* policy.
196	*
197	* @return Thread to be scheduled.
198	*
199	*/
200	static thread_t *find_best_thread(void)
201	{
202	ASSERT(CPU != NULL);
203
204	loop:
205
206	if (atomic_get(&CPU->nrdy) == 0) {
207	/*
208	* For there was nothing to run, the CPU goes to sleep
209	* until a hardware interrupt or an IPI comes.
210	* This improves energy saving and hyperthreading.
211	*/
212	irq_spinlock_lock(&CPU->lock, false);
213	CPU->idle = true;
214	irq_spinlock_unlock(&CPU->lock, false);
215	interrupts_enable();
216
217	/*
218	* An interrupt might occur right now and wake up a thread.
219	* In such case, the CPU will continue to go to sleep
220	* even though there is a runnable thread.
221	*/
222	cpu_sleep();
223	interrupts_disable();
224	goto loop;
225	}
226
227	ASSERT(!CPU->idle);
228
229	unsigned int i;
230	for (i = 0; i < RQ_COUNT; i++) {
231	irq_spinlock_lock(&(CPU->rq[i].lock), false);
232	if (CPU->rq[i].n == 0) {
233	/*
234	* If this queue is empty, try a lower-priority queue.
235	*/
236	irq_spinlock_unlock(&(CPU->rq[i].lock), false);
237	continue;
238	}
239
240	atomic_dec(&CPU->nrdy);
241	atomic_dec(&nrdy);
242	CPU->rq[i].n--;
243
244	/*
245	* Take the first thread from the queue.
246	*/
247	thread_t *thread = list_get_instance(
248	list_first(&CPU->rq[i].rq), thread_t, rq_link);
249	list_remove(&thread->rq_link);
250
251	irq_spinlock_pass(&(CPU->rq[i].lock), &thread->lock);
252
253	thread->cpu = CPU;
254	thread->ticks = us2ticks((i + 1) * 10000);
255	thread->priority = i; /* Correct rq index */
256
257	/*
258	* Clear the stolen flag so that it can be migrated
259	* when load balancing needs emerge.
260	*/
261	thread->stolen = false;
262	irq_spinlock_unlock(&thread->lock, false);
263
264	return thread;
265	}
266
267	goto loop;
268	}
269
270	/** Prevent rq starvation
271	*
272	* Prevent low priority threads from starving in rq's.
273	*
274	* When the function decides to relink rq's, it reconnects
275	* respective pointers so that in result threads with 'pri'
276	* greater or equal start are moved to a higher-priority queue.
277	*
278	* @param start Threshold priority.
279	*
280	*/
281	static void relink_rq(int start)
282	{
283	list_t list;
284
285	list_initialize(&list);
286	irq_spinlock_lock(&CPU->lock, false);
287
288	if (CPU->needs_relink > NEEDS_RELINK_MAX) {
289	int i;
290	for (i = start; i < RQ_COUNT - 1; i++) {
291	/* Remember and empty rq[i + 1] */
292
293	irq_spinlock_lock(&CPU->rq[i + 1].lock, false);
294	list_concat(&list, &CPU->rq[i + 1].rq);
295	size_t n = CPU->rq[i + 1].n;
296	CPU->rq[i + 1].n = 0;
297	irq_spinlock_unlock(&CPU->rq[i + 1].lock, false);
298
299	/* Append rq[i + 1] to rq[i] */
300
301	irq_spinlock_lock(&CPU->rq[i].lock, false);
302	list_concat(&CPU->rq[i].rq, &list);
303	CPU->rq[i].n += n;
304	irq_spinlock_unlock(&CPU->rq[i].lock, false);
305	}
306
307	CPU->needs_relink = 0;
308	}
309
310	irq_spinlock_unlock(&CPU->lock, false);
311	}
312
313	/** The scheduler
314	*
315	* The thread scheduling procedure.
316	* Passes control directly to
317	* scheduler_separated_stack().
318	*
319	*/
320	void scheduler(void)
321	{
322	volatile ipl_t ipl;
323
324	ASSERT(CPU != NULL);
325
326	ipl = interrupts_disable();
327
328	if (atomic_get(&haltstate))
329	halt();
330
331	if (THREAD) {
332	irq_spinlock_lock(&THREAD->lock, false);
333
334	/* Update thread kernel accounting */
335	THREAD->kcycles += get_cycle() - THREAD->last_cycle;
336
337	#ifndef CONFIG_FPU_LAZY
338	fpu_context_save(THREAD->saved_fpu_context);
339	#endif
340	if (!context_save(&THREAD->saved_context)) {
341	/*
342	* This is the place where threads leave scheduler();
343	*/
344
345	/* Save current CPU cycle */
346	THREAD->last_cycle = get_cycle();
347
348	irq_spinlock_unlock(&THREAD->lock, false);
349	interrupts_restore(THREAD->saved_context.ipl);
350
351	return;
352	}
353
354	/*
355	* Interrupt priority level of preempted thread is recorded
356	* here to facilitate scheduler() invocations from
357	* interrupts_disable()'d code (e.g. waitq_sleep_timeout()).
358	*
359	*/
360	THREAD->saved_context.ipl = ipl;
361	}
362
363	/*
364	* Through the 'THE' structure, we keep track of THREAD, TASK, CPU, AS
365	* and preemption counter. At this point THE could be coming either
366	* from THREAD's or CPU's stack.
367	*
368	*/
369	the_copy(THE, (the_t *) CPU->stack);
370
371	/*
372	* We may not keep the old stack.
373	* Reason: If we kept the old stack and got blocked, for instance, in
374	* find_best_thread(), the old thread could get rescheduled by another
375	* CPU and overwrite the part of its own stack that was also used by
376	* the scheduler on this CPU.
377	*
378	* Moreover, we have to bypass the compiler-generated POP sequence
379	* which is fooled by SP being set to the very top of the stack.
380	* Therefore the scheduler() function continues in
381	* scheduler_separated_stack().
382	*
383	*/
384	context_save(&CPU->saved_context);
385	context_set(&CPU->saved_context, FADDR(scheduler_separated_stack),
386	(uintptr_t) CPU->stack, STACK_SIZE);
387	context_restore(&CPU->saved_context);
388
389	/* Not reached */
390	}
391
392	/** Scheduler stack switch wrapper
393	*
394	* Second part of the scheduler() function
395	* using new stack. Handling the actual context
396	* switch to a new thread.
397	*
398	*/
399	void scheduler_separated_stack(void)
400	{
401	DEADLOCK_PROBE_INIT(p_joinwq);
402	task_t *old_task = TASK;
403	as_t *old_as = AS;
404
405	ASSERT((!THREAD) \|\| (irq_spinlock_locked(&THREAD->lock)));
406	ASSERT(CPU != NULL);
407	ASSERT(interrupts_disabled());
408
409	/*
410	* Hold the current task and the address space to prevent their
411	* possible destruction should thread_destroy() be called on this or any
412	* other processor while the scheduler is still using them.
413	*/
414	if (old_task)
415	task_hold(old_task);
416
417	if (old_as)
418	as_hold(old_as);
419
420	if (THREAD) {
421	/* Must be run after the switch to scheduler stack */
422	after_thread_ran();
423
424	switch (THREAD->state) {
425	case Running:
426	irq_spinlock_unlock(&THREAD->lock, false);
427	thread_ready(THREAD);
428	break;
429
430	case Exiting:
431	rcu_thread_exiting();
432	repeat:
433	if (THREAD->detached) {
434	thread_destroy(THREAD, false);
435	} else {
436	/*
437	* The thread structure is kept allocated until
438	* somebody calls thread_detach() on it.
439	*/
440	if (!irq_spinlock_trylock(&THREAD->join_wq.lock)) {
441	/*
442	* Avoid deadlock.
443	*/
444	irq_spinlock_unlock(&THREAD->lock, false);
445	delay(HZ);
446	irq_spinlock_lock(&THREAD->lock, false);
447	DEADLOCK_PROBE(p_joinwq,
448	DEADLOCK_THRESHOLD);
449	goto repeat;
450	}
451	_waitq_wakeup_unsafe(&THREAD->join_wq,
452	WAKEUP_FIRST);
453	irq_spinlock_unlock(&THREAD->join_wq.lock, false);
454
455	THREAD->state = Lingering;
456	irq_spinlock_unlock(&THREAD->lock, false);
457	}
458	break;
459
460	case Sleeping:
461	/*
462	* Prefer the thread after it's woken up.
463	*/
464	THREAD->priority = -1;
465
466	/*
467	* We need to release wq->lock which we locked in
468	* waitq_sleep(). Address of wq->lock is kept in
469	* THREAD->sleep_queue.
470	*/
471	irq_spinlock_unlock(&THREAD->sleep_queue->lock, false);
472
473	irq_spinlock_unlock(&THREAD->lock, false);
474	break;
475
476	default:
477	/*
478	* Entering state is unexpected.
479	*/
480	panic("tid%" PRIu64 ": unexpected state %s.",
481	THREAD->tid, thread_states[THREAD->state]);
482	break;
483	}
484
485	THREAD = NULL;
486	}
487
488	THREAD = find_best_thread();
489
490	irq_spinlock_lock(&THREAD->lock, false);
491	int priority = THREAD->priority;
492	irq_spinlock_unlock(&THREAD->lock, false);
493
494	relink_rq(priority);
495
496	/*
497	* If both the old and the new task are the same,
498	* lots of work is avoided.
499	*/
500	if (TASK != THREAD->task) {
501	as_t *new_as = THREAD->task->as;
502
503	/*
504	* Note that it is possible for two tasks
505	* to share one address space.
506	*/
507	if (old_as != new_as) {
508	/*
509	* Both tasks and address spaces are different.
510	* Replace the old one with the new one.
511	*/
512	as_switch(old_as, new_as);
513	}
514
515	TASK = THREAD->task;
516	before_task_runs();
517	}
518
519	if (old_task)
520	task_release(old_task);
521
522	if (old_as)
523	as_release(old_as);
524
525	irq_spinlock_lock(&THREAD->lock, false);
526	THREAD->state = Running;
527
528	#ifdef SCHEDULER_VERBOSE
529	printf("cpu%u: tid %" PRIu64 " (priority=%d, ticks=%" PRIu64
530	", nrdy=%ld)\n", CPU->id, THREAD->tid, THREAD->priority,
531	THREAD->ticks, atomic_get(&CPU->nrdy));
532	#endif
533
534	/*
535	* Some architectures provide late kernel PA2KA(identity)
536	* mapping in a page fault handler. However, the page fault
537	* handler uses the kernel stack of the running thread and
538	* therefore cannot be used to map it. The kernel stack, if
539	* necessary, is to be mapped in before_thread_runs(). This
540	* function must be executed before the switch to the new stack.
541	*/
542	before_thread_runs();
543
544	/*
545	* Copy the knowledge of CPU, TASK, THREAD and preemption counter to
546	* thread's stack.
547	*/
548	the_copy(THE, (the_t *) THREAD->kstack);
549
550	context_restore(&THREAD->saved_context);
551
552	/* Not reached */
553	}
554
555	#ifdef CONFIG_SMP
556	/** Load balancing thread
557	*
558	* SMP load balancing thread, supervising thread supplies
559	* for the CPU it's wired to.
560	*
561	* @param arg Generic thread argument (unused).
562	*
563	*/
564	void kcpulb(void *arg)
565	{
566	atomic_count_t average;
567	atomic_count_t rdy;
568
569	/*
570	* Detach kcpulb as nobody will call thread_join_timeout() on it.
571	*/
572	thread_detach(THREAD);
573
574	loop:
575	/*
576	* Work in 1s intervals.
577	*/
578	thread_sleep(1);
579
580	not_satisfied:
581	/*
582	* Calculate the number of threads that will be migrated/stolen from
583	* other CPU's. Note that situation can have changed between two
584	* passes. Each time get the most up to date counts.
585	*
586	*/
587	average = atomic_get(&nrdy) / config.cpu_active + 1;
588	rdy = atomic_get(&CPU->nrdy);
589
590	if (average <= rdy)
591	goto satisfied;
592
593	atomic_count_t count = average - rdy;
594
595	/*
596	* Searching least priority queues on all CPU's first and most priority
597	* queues on all CPU's last.
598	*/
599	size_t acpu;
600	size_t acpu_bias = 0;
601	int rq;
602
603	for (rq = RQ_COUNT - 1; rq >= 0; rq--) {
604	for (acpu = 0; acpu < config.cpu_active; acpu++) {
605	cpu_t *cpu = &cpus[(acpu + acpu_bias) % config.cpu_active];
606
607	/*
608	* Not interested in ourselves.
609	* Doesn't require interrupt disabling for kcpulb has
610	* THREAD_FLAG_WIRED.
611	*
612	*/
613	if (CPU == cpu)
614	continue;
615
616	if (atomic_get(&cpu->nrdy) <= average)
617	continue;
618
619	irq_spinlock_lock(&(cpu->rq[rq].lock), true);
620	if (cpu->rq[rq].n == 0) {
621	irq_spinlock_unlock(&(cpu->rq[rq].lock), true);
622	continue;
623	}
624
625	thread_t *thread = NULL;
626
627	/* Search rq from the back */
628	link_t *link = cpu->rq[rq].rq.head.prev;
629
630	while (link != &(cpu->rq[rq].rq.head)) {
631	thread = (thread_t *) list_get_instance(link,
632	thread_t, rq_link);
633
634	/*
635	* Do not steal CPU-wired threads, threads
636	* already stolen, threads for which migration
637	* was temporarily disabled or threads whose
638	* FPU context is still in the CPU.
639	*/
640	irq_spinlock_lock(&thread->lock, false);
641
642	if ((!thread->wired) && (!thread->stolen) &&
643	(!thread->nomigrate) &&
644	(!thread->fpu_context_engaged)) {
645	/*
646	* Remove thread from ready queue.
647	*/
648	irq_spinlock_unlock(&thread->lock,
649	false);
650
651	atomic_dec(&cpu->nrdy);
652	atomic_dec(&nrdy);
653
654	cpu->rq[rq].n--;
655	list_remove(&thread->rq_link);
656
657	break;
658	}
659
660	irq_spinlock_unlock(&thread->lock, false);
661
662	link = link->prev;
663	thread = NULL;
664	}
665
666	if (thread) {
667	/*
668	* Ready thread on local CPU
669	*/
670
671	irq_spinlock_pass(&(cpu->rq[rq].lock),
672	&thread->lock);
673
674	#ifdef KCPULB_VERBOSE
675	printf("kcpulb%u: TID %" PRIu64 " -> cpu%u, "
676	"nrdy=%ld, avg=%ld\n", CPU->id, t->tid,
677	CPU->id, atomic_get(&CPU->nrdy),
678	atomic_get(&nrdy) / config.cpu_active);
679	#endif
680
681	thread->stolen = true;
682	thread->state = Entering;
683
684	irq_spinlock_unlock(&thread->lock, true);
685	thread_ready(thread);
686
687	if (--count == 0)
688	goto satisfied;
689
690	/*
691	* We are not satisfied yet, focus on another
692	* CPU next time.
693	*
694	*/
695	acpu_bias++;
696
697	continue;
698	} else
699	irq_spinlock_unlock(&(cpu->rq[rq].lock), true);
700
701	}
702	}
703
704	if (atomic_get(&CPU->nrdy)) {
705	/*
706	* Be a little bit light-weight and let migrated threads run.
707	*
708	*/
709	scheduler();
710	} else {
711	/*
712	* We failed to migrate a single thread.
713	* Give up this turn.
714	*
715	*/
716	goto loop;
717	}
718
719	goto not_satisfied;
720
721	satisfied:
722	goto loop;
723	}
724	#endif /* CONFIG_SMP */
725
726	/** Print information about threads & scheduler queues
727	*
728	*/
729	void sched_print_list(void)
730	{
731	size_t cpu;
732	for (cpu = 0; cpu < config.cpu_count; cpu++) {
733	if (!cpus[cpu].active)
734	continue;
735
736	irq_spinlock_lock(&cpus[cpu].lock, true);
737
738	printf("cpu%u: address=%p, nrdy=%" PRIua ", needs_relink=%zu\n",
739	cpus[cpu].id, &cpus[cpu], atomic_get(&cpus[cpu].nrdy),
740	cpus[cpu].needs_relink);
741
742	unsigned int i;
743	for (i = 0; i < RQ_COUNT; i++) {
744	irq_spinlock_lock(&(cpus[cpu].rq[i].lock), false);
745	if (cpus[cpu].rq[i].n == 0) {
746	irq_spinlock_unlock(&(cpus[cpu].rq[i].lock), false);
747	continue;
748	}
749
750	printf("\trq[%u]: ", i);
751	list_foreach(cpus[cpu].rq[i].rq, cur) {
752	thread_t *thread = list_get_instance(cur,
753	thread_t, rq_link);
754	printf("%" PRIu64 "(%s) ", thread->tid,
755	thread_states[thread->state]);
756	}
757	printf("\n");
758
759	irq_spinlock_unlock(&(cpus[cpu].rq[i].lock), false);
760	}
761
762	irq_spinlock_unlock(&cpus[cpu].lock, true);
763	}
764	}
765
766	/** @}
767	*/

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