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38 * @(#)kern_synch.c 8.9 (Berkeley) 5/19/95
39 * $FreeBSD: src/sys/kern/kern_synch.c,v 1.87.2.6 2002/10/13 07:29:53 kbyanc Exp $
40 * $DragonFly: src/sys/kern/kern_synch.c,v 1.91 2008/09/09 04:06:13 dillon Exp $
43 #include "opt_ktrace.h"
45 #include <sys/param.h>
46 #include <sys/systm.h>
48 #include <sys/kernel.h>
49 #include <sys/signalvar.h>
50 #include <sys/signal2.h>
51 #include <sys/resourcevar.h>
52 #include <sys/vmmeter.h>
53 #include <sys/sysctl.h>
57 #include <sys/ktrace.h>
59 #include <sys/xwait.h>
62 #include <sys/thread2.h>
63 #include <sys/spinlock2.h>
64 #include <sys/serialize.h>
66 #include <machine/cpu.h>
67 #include <machine/smp.h>
69 TAILQ_HEAD(tslpque
, thread
);
71 static void sched_setup (void *dummy
);
72 SYSINIT(sched_setup
, SI_SUB_KICK_SCHEDULER
, SI_ORDER_FIRST
, sched_setup
, NULL
)
77 int sched_quantum
; /* Roundrobin scheduling quantum in ticks. */
79 int ncpus2
, ncpus2_shift
, ncpus2_mask
;
80 int ncpus_fit
, ncpus_fit_mask
;
84 static struct callout loadav_callout
;
85 static struct callout schedcpu_callout
;
86 MALLOC_DEFINE(M_TSLEEP
, "tslpque", "tsleep queues");
88 #if !defined(KTR_TSLEEP)
89 #define KTR_TSLEEP KTR_ALL
91 KTR_INFO_MASTER(tsleep
);
92 KTR_INFO(KTR_TSLEEP
, tsleep
, tsleep_beg
, 0, "tsleep enter %p", sizeof(void *));
93 KTR_INFO(KTR_TSLEEP
, tsleep
, tsleep_end
, 1, "tsleep exit", 0);
94 KTR_INFO(KTR_TSLEEP
, tsleep
, wakeup_beg
, 2, "wakeup enter %p", sizeof(void *));
95 KTR_INFO(KTR_TSLEEP
, tsleep
, wakeup_end
, 3, "wakeup exit", 0);
97 #define logtsleep1(name) KTR_LOG(tsleep_ ## name)
98 #define logtsleep2(name, val) KTR_LOG(tsleep_ ## name, val)
100 struct loadavg averunnable
=
101 { {0, 0, 0}, FSCALE
}; /* load average, of runnable procs */
103 * Constants for averages over 1, 5, and 15 minutes
104 * when sampling at 5 second intervals.
106 static fixpt_t cexp
[3] = {
107 0.9200444146293232 * FSCALE
, /* exp(-1/12) */
108 0.9834714538216174 * FSCALE
, /* exp(-1/60) */
109 0.9944598480048967 * FSCALE
, /* exp(-1/180) */
112 static void endtsleep (void *);
113 static void unsleep_and_wakeup_thread(struct thread
*td
);
114 static void loadav (void *arg
);
115 static void schedcpu (void *arg
);
118 * Adjust the scheduler quantum. The quantum is specified in microseconds.
119 * Note that 'tick' is in microseconds per tick.
122 sysctl_kern_quantum(SYSCTL_HANDLER_ARGS
)
126 new_val
= sched_quantum
* tick
;
127 error
= sysctl_handle_int(oidp
, &new_val
, 0, req
);
128 if (error
!= 0 || req
->newptr
== NULL
)
132 sched_quantum
= new_val
/ tick
;
133 hogticks
= 2 * sched_quantum
;
137 SYSCTL_PROC(_kern
, OID_AUTO
, quantum
, CTLTYPE_INT
|CTLFLAG_RW
,
138 0, sizeof sched_quantum
, sysctl_kern_quantum
, "I", "");
141 * If `ccpu' is not equal to `exp(-1/20)' and you still want to use the
142 * faster/more-accurate formula, you'll have to estimate CCPU_SHIFT below
143 * and possibly adjust FSHIFT in "param.h" so that (FSHIFT >= CCPU_SHIFT).
145 * To estimate CCPU_SHIFT for exp(-1/20), the following formula was used:
146 * 1 - exp(-1/20) ~= 0.0487 ~= 0.0488 == 1 (fixed pt, *11* bits).
148 * If you don't want to bother with the faster/more-accurate formula, you
149 * can set CCPU_SHIFT to (FSHIFT + 1) which will use a slower/less-accurate
150 * (more general) method of calculating the %age of CPU used by a process.
152 * decay 95% of `lwp_pctcpu' in 60 seconds; see CCPU_SHIFT before changing
154 #define CCPU_SHIFT 11
156 static fixpt_t ccpu
= 0.95122942450071400909 * FSCALE
; /* exp(-1/20) */
157 SYSCTL_INT(_kern
, OID_AUTO
, ccpu
, CTLFLAG_RD
, &ccpu
, 0, "");
160 * kernel uses `FSCALE', userland (SHOULD) use kern.fscale
162 int fscale __unused
= FSCALE
; /* exported to systat */
163 SYSCTL_INT(_kern
, OID_AUTO
, fscale
, CTLFLAG_RD
, 0, FSCALE
, "");
166 * Recompute process priorities, once a second.
168 * Since the userland schedulers are typically event oriented, if the
169 * estcpu calculation at wakeup() time is not sufficient to make a
170 * process runnable relative to other processes in the system we have
171 * a 1-second recalc to help out.
173 * This code also allows us to store sysclock_t data in the process structure
174 * without fear of an overrun, since sysclock_t are guarenteed to hold
175 * several seconds worth of count.
177 * WARNING! callouts can preempt normal threads. However, they will not
178 * preempt a thread holding a spinlock so we *can* safely use spinlocks.
180 static int schedcpu_stats(struct proc
*p
, void *data __unused
);
181 static int schedcpu_resource(struct proc
*p
, void *data __unused
);
186 allproc_scan(schedcpu_stats
, NULL
);
187 allproc_scan(schedcpu_resource
, NULL
);
188 wakeup((caddr_t
)&lbolt
);
189 wakeup((caddr_t
)&lbolt_syncer
);
190 callout_reset(&schedcpu_callout
, hz
, schedcpu
, NULL
);
194 * General process statistics once a second
197 schedcpu_stats(struct proc
*p
, void *data __unused
)
203 FOREACH_LWP_IN_PROC(lp
, p
) {
204 if (lp
->lwp_stat
== LSSLEEP
)
208 * Only recalculate processes that are active or have slept
209 * less then 2 seconds. The schedulers understand this.
211 if (lp
->lwp_slptime
<= 1) {
212 p
->p_usched
->recalculate(lp
);
214 lp
->lwp_pctcpu
= (lp
->lwp_pctcpu
* ccpu
) >> FSHIFT
;
222 * Resource checks. XXX break out since ksignal/killproc can block,
223 * limiting us to one process killed per second. There is probably
227 schedcpu_resource(struct proc
*p
, void *data __unused
)
233 if (p
->p_stat
== SIDL
||
234 p
->p_stat
== SZOMB
||
242 FOREACH_LWP_IN_PROC(lp
, p
) {
244 * We may have caught an lp in the middle of being
245 * created, lwp_thread can be NULL.
247 if (lp
->lwp_thread
) {
248 ttime
+= lp
->lwp_thread
->td_sticks
;
249 ttime
+= lp
->lwp_thread
->td_uticks
;
253 switch(plimit_testcpulimit(p
->p_limit
, ttime
)) {
254 case PLIMIT_TESTCPU_KILL
:
255 killproc(p
, "exceeded maximum CPU limit");
257 case PLIMIT_TESTCPU_XCPU
:
258 if ((p
->p_flag
& P_XCPU
) == 0) {
271 * This is only used by ps. Generate a cpu percentage use over
272 * a period of one second.
277 updatepcpu(struct lwp
*lp
, int cpticks
, int ttlticks
)
282 acc
= (cpticks
<< FSHIFT
) / ttlticks
;
283 if (ttlticks
>= ESTCPUFREQ
) {
284 lp
->lwp_pctcpu
= acc
;
286 remticks
= ESTCPUFREQ
- ttlticks
;
287 lp
->lwp_pctcpu
= (acc
* ttlticks
+ lp
->lwp_pctcpu
* remticks
) /
293 * tsleep/wakeup hash table parameters. Try to find the sweet spot for
294 * like addresses being slept on.
296 #define TABLESIZE 1024
297 #define LOOKUP(x) (((intptr_t)(x) >> 6) & (TABLESIZE - 1))
299 static cpumask_t slpque_cpumasks
[TABLESIZE
];
302 * General scheduler initialization. We force a reschedule 25 times
303 * a second by default. Note that cpu0 is initialized in early boot and
304 * cannot make any high level calls.
306 * Each cpu has its own sleep queue.
309 sleep_gdinit(globaldata_t gd
)
311 static struct tslpque slpque_cpu0
[TABLESIZE
];
314 if (gd
->gd_cpuid
== 0) {
315 sched_quantum
= (hz
+ 24) / 25;
316 hogticks
= 2 * sched_quantum
;
318 gd
->gd_tsleep_hash
= slpque_cpu0
;
320 gd
->gd_tsleep_hash
= kmalloc(sizeof(slpque_cpu0
),
321 M_TSLEEP
, M_WAITOK
| M_ZERO
);
323 for (i
= 0; i
< TABLESIZE
; ++i
)
324 TAILQ_INIT(&gd
->gd_tsleep_hash
[i
]);
328 * General sleep call. Suspends the current process until a wakeup is
329 * performed on the specified identifier. The process will then be made
330 * runnable with the specified priority. Sleeps at most timo/hz seconds
331 * (0 means no timeout). If flags includes PCATCH flag, signals are checked
332 * before and after sleeping, else signals are not checked. Returns 0 if
333 * awakened, EWOULDBLOCK if the timeout expires. If PCATCH is set and a
334 * signal needs to be delivered, ERESTART is returned if the current system
335 * call should be restarted if possible, and EINTR is returned if the system
336 * call should be interrupted by the signal (return EINTR).
338 * Note that if we are a process, we release_curproc() before messing with
339 * the LWKT scheduler.
341 * During autoconfiguration or after a panic, a sleep will simply
342 * lower the priority briefly to allow interrupts, then return.
345 tsleep(void *ident
, int flags
, const char *wmesg
, int timo
)
347 struct thread
*td
= curthread
;
348 struct lwp
*lp
= td
->td_lwp
;
349 struct proc
*p
= td
->td_proc
; /* may be NULL */
356 struct callout thandle
;
359 * NOTE: removed KTRPOINT, it could cause races due to blocking
360 * even in stable. Just scrap it for now.
362 if (tsleep_now_works
== 0 || panicstr
) {
364 * After a panic, or before we actually have an operational
365 * softclock, just give interrupts a chance, then just return;
367 * don't run any other procs or panic below,
368 * in case this is the idle process and already asleep.
371 oldpri
= td
->td_pri
& TDPRI_MASK
;
372 lwkt_setpri_self(safepri
);
374 lwkt_setpri_self(oldpri
);
377 logtsleep2(tsleep_beg
, ident
);
379 KKASSERT(td
!= &gd
->gd_idlethread
); /* you must be kidding! */
382 * NOTE: all of this occurs on the current cpu, including any
383 * callout-based wakeups, so a critical section is a sufficient
386 * The entire sequence through to where we actually sleep must
387 * run without breaking the critical section.
390 catch = flags
& PCATCH
;
394 crit_enter_quick(td
);
396 KASSERT(ident
!= NULL
, ("tsleep: no ident"));
397 KASSERT(lp
== NULL
||
398 lp
->lwp_stat
== LSRUN
|| /* Obvious */
399 lp
->lwp_stat
== LSSTOP
, /* Set in tstop */
401 ident
, wmesg
, lp
->lwp_stat
));
404 * Setup for the current process (if this is a process).
409 * Early termination if PCATCH was set and a
410 * signal is pending, interlocked with the
413 * Early termination only occurs when tsleep() is
414 * entered while in a normal LSRUN state.
416 if ((sig
= CURSIG(lp
)) != 0)
420 * Early termination if PCATCH was set and a
421 * mailbox signal was possibly delivered prior to
422 * the system call even being made, in order to
423 * allow the user to interlock without having to
424 * make additional system calls.
426 if (p
->p_flag
& P_MAILBOX
)
430 * Causes ksignal to wake us up when.
432 lp
->lwp_flag
|= LWP_SINTR
;
436 * Make sure the current process has been untangled from
437 * the userland scheduler and initialize slptime to start
440 p
->p_usched
->release_curproc(lp
);
445 * Move our thread to the correct queue and setup our wchan, etc.
447 lwkt_deschedule_self(td
);
448 td
->td_flags
|= TDF_TSLEEPQ
;
449 TAILQ_INSERT_TAIL(&gd
->gd_tsleep_hash
[id
], td
, td_threadq
);
450 atomic_set_int(&slpque_cpumasks
[id
], gd
->gd_cpumask
);
452 td
->td_wchan
= ident
;
453 td
->td_wmesg
= wmesg
;
454 td
->td_wdomain
= flags
& PDOMAIN_MASK
;
457 * Setup the timeout, if any
460 callout_init(&thandle
);
461 callout_reset(&thandle
, timo
, endtsleep
, td
);
469 * Ok, we are sleeping. Place us in the SSLEEP state.
471 KKASSERT((lp
->lwp_flag
& LWP_ONRUNQ
) == 0);
473 * tstop() sets LSSTOP, so don't fiddle with that.
475 if (lp
->lwp_stat
!= LSSTOP
)
476 lp
->lwp_stat
= LSSLEEP
;
477 lp
->lwp_ru
.ru_nvcsw
++;
481 * And when we are woken up, put us back in LSRUN. If we
482 * slept for over a second, recalculate our estcpu.
484 lp
->lwp_stat
= LSRUN
;
486 p
->p_usched
->recalculate(lp
);
493 * Make sure we haven't switched cpus while we were asleep. It's
494 * not supposed to happen. Cleanup our temporary flags.
496 KKASSERT(gd
== td
->td_gd
);
499 * Cleanup the timeout.
502 if (td
->td_flags
& TDF_TIMEOUT
) {
503 td
->td_flags
&= ~TDF_TIMEOUT
;
506 callout_stop(&thandle
);
511 * Since td_threadq is used both for our run queue AND for the
512 * tsleep hash queue, we can't still be on it at this point because
513 * we've gotten cpu back.
515 KASSERT((td
->td_flags
& TDF_TSLEEPQ
) == 0, ("tsleep: impossible thread flags %08x", td
->td_flags
));
521 * Figure out the correct error return. If interrupted by a
522 * signal we want to return EINTR or ERESTART.
524 * If P_MAILBOX is set no automatic system call restart occurs
525 * and we return EINTR. P_MAILBOX is meant to be used as an
526 * interlock, the user must poll it prior to any system call
527 * that it wishes to interlock a mailbox signal against since
528 * the flag is cleared on *any* system call that sleeps.
532 if (catch && error
== 0) {
533 if ((p
->p_flag
& P_MAILBOX
) && sig
== 0) {
535 } else if (sig
!= 0 || (sig
= CURSIG(lp
))) {
536 if (SIGISMEMBER(p
->p_sigacts
->ps_sigintr
, sig
))
542 lp
->lwp_flag
&= ~(LWP_BREAKTSLEEP
| LWP_SINTR
);
543 p
->p_flag
&= ~P_MAILBOX
;
545 logtsleep1(tsleep_end
);
551 * This is a dandy function that allows us to interlock tsleep/wakeup
552 * operations with unspecified upper level locks, such as lockmgr locks,
553 * simply by holding a critical section. The sequence is:
555 * (enter critical section)
556 * (acquire upper level lock)
557 * tsleep_interlock(blah)
558 * (release upper level lock)
560 * (exit critical section)
562 * Basically this function sets our cpumask for the ident which informs
563 * other cpus that our cpu 'might' be waiting (or about to wait on) the
564 * hash index related to the ident. The critical section prevents another
565 * cpu's wakeup() from being processed on our cpu until we are actually
566 * able to enter the tsleep(). Thus, no race occurs between our attempt
567 * to release a resource and sleep, and another cpu's attempt to acquire
568 * a resource and call wakeup.
570 * There isn't much of a point to this function unless you call it while
571 * holding a critical section.
574 _tsleep_interlock(globaldata_t gd
, void *ident
)
576 int id
= LOOKUP(ident
);
578 atomic_set_int(&slpque_cpumasks
[id
], gd
->gd_cpumask
);
582 tsleep_interlock(void *ident
)
584 _tsleep_interlock(mycpu
, ident
);
588 * Interlocked spinlock sleep. An exclusively held spinlock must
589 * be passed to msleep(). The function will atomically release the
590 * spinlock and tsleep on the ident, then reacquire the spinlock and
593 * This routine is fairly important along the critical path, so optimize it
597 msleep(void *ident
, struct spinlock
*spin
, int flags
,
598 const char *wmesg
, int timo
)
600 globaldata_t gd
= mycpu
;
604 _tsleep_interlock(gd
, ident
);
605 spin_unlock_wr_quick(gd
, spin
);
606 error
= tsleep(ident
, flags
, wmesg
, timo
);
607 spin_lock_wr_quick(gd
, spin
);
614 * Interlocked serializer sleep. An exclusively held serializer must
615 * be passed to serialize_sleep(). The function will atomically release
616 * the serializer and tsleep on the ident, then reacquire the serializer
620 serialize_sleep(void *ident
, struct lwkt_serialize
*slz
, int flags
,
621 const char *wmesg
, int timo
)
625 ASSERT_SERIALIZED(slz
);
628 tsleep_interlock(ident
);
629 lwkt_serialize_exit(slz
);
630 ret
= tsleep(ident
, flags
, wmesg
, timo
);
631 lwkt_serialize_enter(slz
);
638 * Directly block on the LWKT thread by descheduling it. This
639 * is much faster then tsleep(), but the only legal way to wake
640 * us up is to directly schedule the thread.
642 * Setting TDF_SINTR will cause new signals to directly schedule us.
644 * This routine is typically called while in a critical section.
647 lwkt_sleep(const char *wmesg
, int flags
)
649 thread_t td
= curthread
;
652 if ((flags
& PCATCH
) == 0 || td
->td_lwp
== NULL
) {
653 td
->td_flags
|= TDF_BLOCKED
;
654 td
->td_wmesg
= wmesg
;
655 lwkt_deschedule_self(td
);
658 td
->td_flags
&= ~TDF_BLOCKED
;
661 if ((sig
= CURSIG(td
->td_lwp
)) != 0) {
662 if (SIGISMEMBER(td
->td_proc
->p_sigacts
->ps_sigintr
, sig
))
668 td
->td_flags
|= TDF_BLOCKED
| TDF_SINTR
;
669 td
->td_wmesg
= wmesg
;
670 lwkt_deschedule_self(td
);
672 td
->td_flags
&= ~(TDF_BLOCKED
| TDF_SINTR
);
678 * Implement the timeout for tsleep.
680 * We set LWP_BREAKTSLEEP to indicate that an event has occured, but
681 * we only call setrunnable if the process is not stopped.
683 * This type of callout timeout is scheduled on the same cpu the process
684 * is sleeping on. Also, at the moment, the MP lock is held.
692 ASSERT_MP_LOCK_HELD(curthread
);
696 * cpu interlock. Thread flags are only manipulated on
697 * the cpu owning the thread. proc flags are only manipulated
698 * by the older of the MP lock. We have both.
700 if (td
->td_flags
& TDF_TSLEEPQ
) {
701 td
->td_flags
|= TDF_TIMEOUT
;
703 if ((lp
= td
->td_lwp
) != NULL
) {
704 lp
->lwp_flag
|= LWP_BREAKTSLEEP
;
705 if (lp
->lwp_proc
->p_stat
!= SSTOP
)
708 unsleep_and_wakeup_thread(td
);
715 * Unsleep and wakeup a thread. This function runs without the MP lock
716 * which means that it can only manipulate thread state on the owning cpu,
717 * and cannot touch the process state at all.
721 unsleep_and_wakeup_thread(struct thread
*td
)
723 globaldata_t gd
= mycpu
;
727 if (td
->td_gd
!= gd
) {
728 lwkt_send_ipiq(td
->td_gd
, (ipifunc1_t
)unsleep_and_wakeup_thread
, td
);
733 if (td
->td_flags
& TDF_TSLEEPQ
) {
734 td
->td_flags
&= ~TDF_TSLEEPQ
;
735 id
= LOOKUP(td
->td_wchan
);
736 TAILQ_REMOVE(&gd
->gd_tsleep_hash
[id
], td
, td_threadq
);
737 if (TAILQ_FIRST(&gd
->gd_tsleep_hash
[id
]) == NULL
)
738 atomic_clear_int(&slpque_cpumasks
[id
], gd
->gd_cpumask
);
745 * Make all processes sleeping on the specified identifier runnable.
746 * count may be zero or one only.
748 * The domain encodes the sleep/wakeup domain AND the first cpu to check
749 * (which is always the current cpu). As we iterate across cpus
751 * This call may run without the MP lock held. We can only manipulate thread
752 * state on the cpu owning the thread. We CANNOT manipulate process state
756 _wakeup(void *ident
, int domain
)
768 logtsleep2(wakeup_beg
, ident
);
771 qp
= &gd
->gd_tsleep_hash
[id
];
773 for (td
= TAILQ_FIRST(qp
); td
!= NULL
; td
= ntd
) {
774 ntd
= TAILQ_NEXT(td
, td_threadq
);
775 if (td
->td_wchan
== ident
&&
776 td
->td_wdomain
== (domain
& PDOMAIN_MASK
)
778 KKASSERT(td
->td_flags
& TDF_TSLEEPQ
);
779 td
->td_flags
&= ~TDF_TSLEEPQ
;
780 TAILQ_REMOVE(qp
, td
, td_threadq
);
781 if (TAILQ_FIRST(qp
) == NULL
) {
782 atomic_clear_int(&slpque_cpumasks
[id
],
786 if (domain
& PWAKEUP_ONE
)
794 * We finished checking the current cpu but there still may be
795 * more work to do. Either wakeup_one was requested and no matching
796 * thread was found, or a normal wakeup was requested and we have
797 * to continue checking cpus.
799 * It should be noted that this scheme is actually less expensive then
800 * the old scheme when waking up multiple threads, since we send
801 * only one IPI message per target candidate which may then schedule
802 * multiple threads. Before we could have wound up sending an IPI
803 * message for each thread on the target cpu (!= current cpu) that
804 * needed to be woken up.
806 * NOTE: Wakeups occuring on remote cpus are asynchronous. This
807 * should be ok since we are passing idents in the IPI rather then
810 if ((domain
& PWAKEUP_MYCPU
) == 0 &&
811 (mask
= slpque_cpumasks
[id
] & gd
->gd_other_cpus
) != 0) {
812 lwkt_send_ipiq2_mask(mask
, _wakeup
, ident
,
813 domain
| PWAKEUP_MYCPU
);
817 logtsleep1(wakeup_end
);
822 * Wakeup all threads tsleep()ing on the specified ident, on all cpus
827 _wakeup(ident
, PWAKEUP_ENCODE(0, mycpu
->gd_cpuid
));
831 * Wakeup one thread tsleep()ing on the specified ident, on any cpu.
834 wakeup_one(void *ident
)
836 /* XXX potentially round-robin the first responding cpu */
837 _wakeup(ident
, PWAKEUP_ENCODE(0, mycpu
->gd_cpuid
) | PWAKEUP_ONE
);
841 * Wakeup threads tsleep()ing on the specified ident on the current cpu
845 wakeup_mycpu(void *ident
)
847 _wakeup(ident
, PWAKEUP_MYCPU
);
851 * Wakeup one thread tsleep()ing on the specified ident on the current cpu
855 wakeup_mycpu_one(void *ident
)
857 /* XXX potentially round-robin the first responding cpu */
858 _wakeup(ident
, PWAKEUP_MYCPU
|PWAKEUP_ONE
);
862 * Wakeup all thread tsleep()ing on the specified ident on the specified cpu
866 wakeup_oncpu(globaldata_t gd
, void *ident
)
870 _wakeup(ident
, PWAKEUP_MYCPU
);
872 lwkt_send_ipiq2(gd
, _wakeup
, ident
, PWAKEUP_MYCPU
);
875 _wakeup(ident
, PWAKEUP_MYCPU
);
880 * Wakeup one thread tsleep()ing on the specified ident on the specified cpu
884 wakeup_oncpu_one(globaldata_t gd
, void *ident
)
888 _wakeup(ident
, PWAKEUP_MYCPU
| PWAKEUP_ONE
);
890 lwkt_send_ipiq2(gd
, _wakeup
, ident
, PWAKEUP_MYCPU
| PWAKEUP_ONE
);
893 _wakeup(ident
, PWAKEUP_MYCPU
| PWAKEUP_ONE
);
898 * Wakeup all threads waiting on the specified ident that slept using
899 * the specified domain, on all cpus.
902 wakeup_domain(void *ident
, int domain
)
904 _wakeup(ident
, PWAKEUP_ENCODE(domain
, mycpu
->gd_cpuid
));
908 * Wakeup one thread waiting on the specified ident that slept using
909 * the specified domain, on any cpu.
912 wakeup_domain_one(void *ident
, int domain
)
914 /* XXX potentially round-robin the first responding cpu */
915 _wakeup(ident
, PWAKEUP_ENCODE(domain
, mycpu
->gd_cpuid
) | PWAKEUP_ONE
);
921 * Make a process runnable. The MP lock must be held on call. This only
922 * has an effect if we are in SSLEEP. We only break out of the
923 * tsleep if LWP_BREAKTSLEEP is set, otherwise we just fix-up the state.
925 * NOTE: With the MP lock held we can only safely manipulate the process
926 * structure. We cannot safely manipulate the thread structure.
929 setrunnable(struct lwp
*lp
)
932 ASSERT_MP_LOCK_HELD(curthread
);
933 if (lp
->lwp_stat
== LSSTOP
)
934 lp
->lwp_stat
= LSSLEEP
;
935 if (lp
->lwp_stat
== LSSLEEP
&& (lp
->lwp_flag
& LWP_BREAKTSLEEP
))
936 unsleep_and_wakeup_thread(lp
->lwp_thread
);
941 * The process is stopped due to some condition, usually because p_stat is
942 * set to SSTOP, but also possibly due to being traced.
944 * NOTE! If the caller sets SSTOP, the caller must also clear P_WAITED
945 * because the parent may check the child's status before the child actually
946 * gets to this routine.
948 * This routine is called with the current lwp only, typically just
949 * before returning to userland.
951 * Setting LWP_BREAKTSLEEP before entering the tsleep will cause a passive
952 * SIGCONT to break out of the tsleep.
957 struct lwp
*lp
= curthread
->td_lwp
;
958 struct proc
*p
= lp
->lwp_proc
;
962 * If LWP_WSTOP is set, we were sleeping
963 * while our process was stopped. At this point
964 * we were already counted as stopped.
966 if ((lp
->lwp_flag
& LWP_WSTOP
) == 0) {
968 * If we're the last thread to stop, signal
972 lp
->lwp_flag
|= LWP_WSTOP
;
973 wakeup(&p
->p_nstopped
);
974 if (p
->p_nstopped
== p
->p_nthreads
) {
975 p
->p_flag
&= ~P_WAITED
;
977 if ((p
->p_pptr
->p_sigacts
->ps_flag
& PS_NOCLDSTOP
) == 0)
978 ksignal(p
->p_pptr
, SIGCHLD
);
981 while (p
->p_stat
== SSTOP
) {
982 lp
->lwp_flag
|= LWP_BREAKTSLEEP
;
983 lp
->lwp_stat
= LSSTOP
;
984 tsleep(p
, 0, "stop", 0);
987 lp
->lwp_flag
&= ~LWP_WSTOP
;
992 * Yield / synchronous reschedule. This is a bit tricky because the trap
993 * code might have set a lazy release on the switch function. Setting
994 * P_PASSIVE_ACQ will ensure that the lazy release executes when we call
995 * switch, and that we are given a greater chance of affinity with our
998 * We call lwkt_setpri_self() to rotate our thread to the end of the lwkt
999 * run queue. lwkt_switch() will also execute any assigned passive release
1000 * (which usually calls release_curproc()), allowing a same/higher priority
1001 * process to be designated as the current process.
1003 * While it is possible for a lower priority process to be designated,
1004 * it's call to lwkt_maybe_switch() in acquire_curproc() will likely
1005 * round-robin back to us and we will be able to re-acquire the current
1006 * process designation.
1011 struct thread
*td
= curthread
;
1012 struct proc
*p
= td
->td_proc
;
1014 lwkt_setpri_self(td
->td_pri
& TDPRI_MASK
);
1016 p
->p_flag
|= P_PASSIVE_ACQ
;
1018 p
->p_flag
&= ~P_PASSIVE_ACQ
;
1025 * Compute a tenex style load average of a quantity on
1026 * 1, 5 and 15 minute intervals.
1028 static int loadav_count_runnable(struct lwp
*p
, void *data
);
1033 struct loadavg
*avg
;
1037 alllwp_scan(loadav_count_runnable
, &nrun
);
1039 for (i
= 0; i
< 3; i
++) {
1040 avg
->ldavg
[i
] = (cexp
[i
] * avg
->ldavg
[i
] +
1041 nrun
* FSCALE
* (FSCALE
- cexp
[i
])) >> FSHIFT
;
1045 * Schedule the next update to occur after 5 seconds, but add a
1046 * random variation to avoid synchronisation with processes that
1047 * run at regular intervals.
1049 callout_reset(&loadav_callout
, hz
* 4 + (int)(krandom() % (hz
* 2 + 1)),
1054 loadav_count_runnable(struct lwp
*lp
, void *data
)
1059 switch (lp
->lwp_stat
) {
1061 if ((td
= lp
->lwp_thread
) == NULL
)
1063 if (td
->td_flags
& TDF_BLOCKED
)
1075 sched_setup(void *dummy
)
1077 callout_init(&loadav_callout
);
1078 callout_init(&schedcpu_callout
);
1080 /* Kick off timeout driven events by calling first time. */