sys/kern/sched_m2.c

1.4   yamt /*	$NetBSD: sched_m2.c,v 1.5 2007/10/14 13:56:32 yamt Exp $	*/
1.1  rmind
1.1  rmind /*
1.1  rmind  * Copyright (c) 2007, Mindaugas Rasiukevicius
1.1  rmind  *
1.1  rmind  * Redistribution and use in source and binary forms, with or without
1.1  rmind  * modification, are permitted provided that the following conditions
1.1  rmind  * are met:
1.1  rmind  * 1. Redistributions of source code must retain the above copyright
1.1  rmind  *    notice, this list of conditions and the following disclaimer.
1.1  rmind  * 2. Redistributions in binary form must reproduce the above copyright
1.1  rmind  *    notice, this list of conditions and the following disclaimer in the
1.1  rmind  *    documentation and/or other materials provided with the distribution.
1.1  rmind  *
1.1  rmind  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
1.1  rmind  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  rmind  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  rmind  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  rmind  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  rmind  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  rmind  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  rmind  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  rmind  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  rmind  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  rmind  * POSSIBILITY OF SUCH DAMAGE.
1.1  rmind  */
1.1  rmind
1.1  rmind /*
1.1  rmind  * TODO:
1.1  rmind  *  - Implementation of fair share queue;
1.1  rmind  *  - Support for NUMA;
1.1  rmind  */
1.1  rmind
1.1  rmind #include <sys/cdefs.h>
1.4   yamt __KERNEL_RCSID(0, "$NetBSD: sched_m2.c,v 1.5 2007/10/14 13:56:32 yamt Exp $");
1.1  rmind
1.1  rmind #include <sys/param.h>
1.1  rmind
1.1  rmind #include <sys/cpu.h>
1.1  rmind #include <sys/callout.h>
1.1  rmind #include <sys/errno.h>
1.1  rmind #include <sys/kernel.h>
1.1  rmind #include <sys/kmem.h>
1.1  rmind #include <sys/lwp.h>
1.1  rmind #include <sys/mutex.h>
1.1  rmind #include <sys/pool.h>
1.1  rmind #include <sys/proc.h>
1.1  rmind #include <sys/resource.h>
1.1  rmind #include <sys/resourcevar.h>
1.1  rmind #include <sys/sched.h>
1.1  rmind #include <sys/syscallargs.h>
1.1  rmind #include <sys/sysctl.h>
1.1  rmind #include <sys/types.h>
1.1  rmind
1.1  rmind #include <machine/cpu.h>
1.1  rmind
1.1  rmind /*
1.5   yamt  * XXX: Some definitions below will disappear
1.1  rmind  * XXX: with the merge of vmlocking branch.
1.1  rmind  */
1.1  rmind #define	PRI_MAX		MAXPRI
1.1  rmind #define	PRI_COUNT	(PRI_MAX + 1)			/* 0 .. 127  -> 128 */
1.1  rmind #define	PRI_RT_COUNT	(50)				/* 0 .. 49   -> 50  */
1.1  rmind #define	PRI_TS_COUNT	(PRI_COUNT - PRI_RT_COUNT)	/* 50 .. 127 -> 78  */
1.1  rmind
1.1  rmind #define	PRI_DEFAULT	70				/* 70 */
1.1  rmind #define	PRI_REALTIME	50				/* 50 */
1.1  rmind #define	PRI_HTS_RANGE	10				/* 50 .. 60  -> 10 */
1.1  rmind
1.1  rmind /*
1.1  rmind  * Bits per map.
1.1  rmind  */
1.1  rmind #define	BITMAP_SHIFT		5		/* 32 bits */
1.1  rmind #define	BITMAP_SIZE		PRI_COUNT >> BITMAP_SHIFT
1.1  rmind
1.1  rmind /*
1.1  rmind  * Time-slices and priorities.
1.1  rmind  */
1.1  rmind static u_int	min_ts;			/* Minimal time-slice */
1.1  rmind static u_int	max_ts;			/* Maximal time-slice */
1.1  rmind static u_int	rt_ts;			/* Real-time time-slice */
1.1  rmind static u_int	ts_map[PRI_COUNT];	/* Map of time-slices */
1.1  rmind static pri_t	high_pri[PRI_COUNT];	/* Map for priority increase */
1.1  rmind
1.1  rmind /*
1.1  rmind  * Migration and balancing.
1.1  rmind  */
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind static u_int	cacheht_time;		/* Cache hotness time */
1.1  rmind static u_int	min_catch;		/* Minimal LWP count for catching */
1.1  rmind
1.1  rmind static u_int		balance_period;	/* Balance period */
1.1  rmind static struct callout	balance_ch;	/* Callout of balancer */
1.1  rmind
1.1  rmind static struct cpu_info * volatile worker_ci;
1.1  rmind
1.1  rmind #define CACHE_HOT(sil)		(sil->sl_lrtime && \
1.1  rmind     (hardclock_ticks - sil->sl_lrtime < cacheht_time))
1.1  rmind
1.1  rmind #endif
1.1  rmind
1.1  rmind /*
1.1  rmind  * Structures, runqueue.
1.1  rmind  */
1.1  rmind
1.1  rmind typedef struct {
1.1  rmind 	TAILQ_HEAD(, lwp) q_head;
1.1  rmind } queue_t;
1.1  rmind
1.1  rmind typedef struct {
1.1  rmind 	/* Lock and bitmap */
1.1  rmind 	kmutex_t	r_rq_mutex;
1.1  rmind 	uint32_t	r_bitmap[BITMAP_SIZE];
1.1  rmind 	/* Counters */
1.1  rmind 	u_int		r_count;	/* Count of the threads */
1.1  rmind 	pri_t		r_highest_pri;	/* Highest priority */
1.1  rmind 	u_int		r_avgcount;	/* Average count of threads */
1.1  rmind 	u_int		r_mcount;	/* Count of migratable threads */
1.1  rmind 	/* Runqueues */
1.1  rmind 	queue_t		r_rt_queue[PRI_RT_COUNT];
1.1  rmind 	queue_t		r_ts_queue[PRI_TS_COUNT];
1.1  rmind } runqueue_t;
1.1  rmind
1.1  rmind typedef struct {
1.1  rmind 	u_int		sl_flags;
1.1  rmind 	u_int		sl_timeslice;	/* Time-slice of thread */
1.1  rmind 	u_int		sl_slept;	/* Saved sleep time for sleep sum */
1.1  rmind 	u_int		sl_slpsum;	/* Sum of sleep time */
1.1  rmind 	u_int		sl_rtime;	/* Saved start time of run */
1.1  rmind 	u_int		sl_rtsum;	/* Sum of the run time */
1.1  rmind 	u_int		sl_lrtime;	/* Last run time */
1.1  rmind } sched_info_lwp_t;
1.1  rmind
1.1  rmind /* Flags */
1.1  rmind #define	SL_BATCH	0x01
1.1  rmind
1.1  rmind /* Pool of the scheduler-specific structures for threads */
1.1  rmind static struct pool	sil_pool;
1.1  rmind
1.1  rmind /*
1.1  rmind  * Prototypes.
1.1  rmind  */
1.1  rmind
1.1  rmind static inline void *	sched_getrq(runqueue_t *, const pri_t);
1.1  rmind static inline void	sched_newts(struct lwp *);
1.1  rmind static void		sched_precalcts(void);
1.1  rmind
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind static struct lwp *	sched_catchlwp(void);
1.1  rmind static void		sched_balance(void *);
1.1  rmind #endif
1.1  rmind
1.1  rmind /*
1.1  rmind  * Initialization and setup.
1.1  rmind  */
1.1  rmind
1.1  rmind void
1.1  rmind sched_rqinit(void)
1.1  rmind {
1.1  rmind 	struct cpu_info *ci = curcpu();
1.1  rmind
1.1  rmind 	if (hz < 100) {
1.1  rmind 		panic("sched_rqinit: value of HZ is too low\n");
1.1  rmind 	}
1.1  rmind
1.1  rmind 	/* Default timing ranges */
1.1  rmind 	min_ts = mstohz(50);			/* ~50ms  */
1.1  rmind 	max_ts = mstohz(150);			/* ~150ms */
1.1  rmind 	rt_ts = mstohz(100);			/* ~100ms */
1.1  rmind 	sched_precalcts();
1.1  rmind
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind 	/* Balancing */
1.1  rmind 	worker_ci = ci;
1.1  rmind 	cacheht_time = mstohz(5);		/* ~5 ms  */
1.1  rmind 	balance_period = mstohz(300);		/* ~300ms */
1.1  rmind 	min_catch = ~0;
1.1  rmind #endif
1.1  rmind
1.1  rmind 	/* Pool of the scheduler-specific structures */
1.1  rmind 	pool_init(&sil_pool, sizeof(sched_info_lwp_t), 0, 0, 0,
1.1  rmind 	    "lwpsd", &pool_allocator_nointr, IPL_NONE);
1.1  rmind
1.1  rmind 	/* Attach the primary CPU here */
1.1  rmind 	sched_cpuattach(ci);
1.1  rmind
1.1  rmind 	/* Initialize the scheduler structure of the primary LWP */
1.1  rmind 	lwp0.l_mutex = &ci->ci_schedstate.spc_lwplock;
1.1  rmind 	sched_lwp_fork(&lwp0);
1.1  rmind 	sched_newts(&lwp0);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_setup(void)
1.1  rmind {
1.1  rmind
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind 	/* Minimal count of LWPs for catching: log2(count of CPUs) */
1.1  rmind 	min_catch = min(ffs(ncpu) - 1, 4);
1.1  rmind
1.1  rmind 	/* Initialize balancing callout and run it */
1.1  rmind 	callout_init(&balance_ch, CALLOUT_MPSAFE);
1.1  rmind 	callout_setfunc(&balance_ch, sched_balance, NULL);
1.1  rmind 	callout_schedule(&balance_ch, balance_period);
1.1  rmind #endif
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_cpuattach(struct cpu_info *ci)
1.1  rmind {
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	void *rq_ptr;
1.1  rmind 	u_int i, size;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Allocate the run queue.
1.1  rmind 	 * XXX: Estimate cache behaviour more..
1.1  rmind 	 */
1.1  rmind 	size = roundup(sizeof(runqueue_t), CACHE_LINE_SIZE) + CACHE_LINE_SIZE;
1.1  rmind 	rq_ptr = kmem_zalloc(size, KM_NOSLEEP);
1.1  rmind 	if (rq_ptr == NULL) {
1.1  rmind 		panic("scheduler: could not allocate the runqueue");
1.1  rmind 	}
1.1  rmind 	/* XXX: Save the original pointer for future.. */
1.1  rmind 	ci_rq = (void *)(roundup((intptr_t)(rq_ptr), CACHE_LINE_SIZE));
1.1  rmind
1.1  rmind 	/* Initialize run queues */
1.1  rmind 	mutex_init(&ci_rq->r_rq_mutex, MUTEX_SPIN, IPL_SCHED);
1.1  rmind 	for (i = 0; i < PRI_RT_COUNT; i++)
1.1  rmind 		TAILQ_INIT(&ci_rq->r_rt_queue[i].q_head);
1.1  rmind 	for (i = 0; i < PRI_TS_COUNT; i++)
1.1  rmind 		TAILQ_INIT(&ci_rq->r_ts_queue[i].q_head);
1.1  rmind 	ci_rq->r_highest_pri = PRI_MAX;
1.1  rmind
1.1  rmind 	ci->ci_schedstate.spc_sched_info = ci_rq;
1.1  rmind 	ci->ci_schedstate.spc_mutex = &ci_rq->r_rq_mutex;
1.1  rmind }
1.1  rmind
1.1  rmind /* Pre-calculate the time-slices for the priorities */
1.1  rmind static void
1.1  rmind sched_precalcts(void)
1.1  rmind {
1.1  rmind 	pri_t p;
1.1  rmind 	u_int i;
1.1  rmind
1.1  rmind 	for (p = 0; p < PRI_REALTIME; p++) {
1.1  rmind 		ts_map[p] = rt_ts;
1.1  rmind 		high_pri[p] = p;
1.1  rmind 	}
1.1  rmind
1.1  rmind 	for (p = PRI_REALTIME, i = 0; p < PRI_COUNT; p++, i++) {
1.1  rmind 		ts_map[p] = min_ts +
1.1  rmind 		    (i * 100 / (PRI_TS_COUNT - 1) * (max_ts - min_ts) / 100);
1.1  rmind 		high_pri[p] = PRI_REALTIME + (i * PRI_HTS_RANGE /
1.1  rmind 		    (PRI_MAX - PRI_REALTIME));
1.1  rmind 	}
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Hooks.
1.1  rmind  */
1.1  rmind
1.1  rmind void
1.1  rmind sched_proc_fork(struct proc *parent, struct proc *child)
1.1  rmind {
1.1  rmind 	struct lwp *l;
1.1  rmind
1.1  rmind 	LIST_FOREACH(l, &child->p_lwps, l_sibling) {
1.1  rmind 		lwp_lock(l);
1.1  rmind 		sched_newts(l);
1.1  rmind 		lwp_unlock(l);
1.1  rmind 	}
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_proc_exit(struct proc *child, struct proc *parent)
1.1  rmind {
1.1  rmind
1.1  rmind 	/* Dummy */
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_lwp_fork(struct lwp *l)
1.1  rmind {
1.1  rmind
1.1  rmind 	KASSERT(l->l_sched_info == NULL);
1.1  rmind 	l->l_sched_info = pool_get(&sil_pool, PR_WAITOK);
1.1  rmind 	memset(l->l_sched_info, 0, sizeof(sched_info_lwp_t));
1.1  rmind 	if (l->l_usrpri >= PRI_REALTIME) /* XXX: For now only.. */
1.1  rmind 		l->l_usrpri = l->l_priority = PRI_DEFAULT;
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_lwp_exit(struct lwp *l)
1.1  rmind {
1.1  rmind
1.1  rmind 	KASSERT(l->l_sched_info != NULL);
1.1  rmind 	pool_put(&sil_pool, l->l_sched_info);
1.1  rmind 	l->l_sched_info = NULL;
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_setrunnable(struct lwp *l)
1.1  rmind {
1.1  rmind
1.1  rmind 	/* Dummy */
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_schedclock(struct lwp *l)
1.1  rmind {
1.1  rmind
1.1  rmind 	/* Dummy */
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Priorities and time-slice.
1.1  rmind  */
1.1  rmind
1.1  rmind void
1.1  rmind sched_nice(struct proc *p, int prio)
1.1  rmind {
1.1  rmind 	int nprio;
1.1  rmind 	struct lwp *l;
1.1  rmind
1.1  rmind 	KASSERT(mutex_owned(&p->p_stmutex));
1.1  rmind
1.1  rmind 	p->p_nice = prio;
1.1  rmind 	nprio = max(PRI_DEFAULT + p->p_nice, PRI_REALTIME);
1.1  rmind
1.1  rmind 	LIST_FOREACH(l, &p->p_lwps, l_sibling) {
1.1  rmind 		lwp_lock(l);
1.1  rmind 		lwp_changepri(l, nprio);
1.1  rmind 		lwp_unlock(l);
1.1  rmind 	}
1.1  rmind }
1.1  rmind
1.1  rmind /* Recalculate the time-slice */
1.1  rmind static inline void
1.1  rmind sched_newts(struct lwp *l)
1.1  rmind {
1.1  rmind 	sched_info_lwp_t *sil = l->l_sched_info;
1.1  rmind
1.1  rmind 	sil->sl_timeslice = ts_map[lwp_eprio(l)];
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Control of the runqueue.
1.1  rmind  */
1.1  rmind
1.1  rmind static inline void *
1.1  rmind sched_getrq(runqueue_t *ci_rq, const pri_t prio)
1.1  rmind {
1.1  rmind
1.1  rmind 	KASSERT(prio < PRI_COUNT);
1.1  rmind 	return (prio < PRI_REALTIME) ?
1.1  rmind 	    &ci_rq->r_rt_queue[prio].q_head :
1.1  rmind 	    &ci_rq->r_ts_queue[prio - PRI_REALTIME].q_head;
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_enqueue(struct lwp *l, bool swtch)
1.1  rmind {
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	sched_info_lwp_t *sil = l->l_sched_info;
1.1  rmind 	TAILQ_HEAD(, lwp) *q_head;
1.1  rmind 	const pri_t eprio = lwp_eprio(l);
1.1  rmind
1.1  rmind 	ci_rq = l->l_cpu->ci_schedstate.spc_sched_info;
1.1  rmind 	KASSERT(lwp_locked(l, l->l_cpu->ci_schedstate.spc_mutex));
1.1  rmind
1.1  rmind 	/* Update the last run time on switch */
1.1  rmind 	if (swtch == true) {
1.1  rmind 		sil->sl_lrtime = hardclock_ticks;
1.1  rmind 		sil->sl_rtsum += (hardclock_ticks - sil->sl_rtime);
1.1  rmind 	} else
1.1  rmind 		sil->sl_lrtime = 0;
1.1  rmind
1.1  rmind 	/* Enqueue the thread */
1.1  rmind 	q_head = sched_getrq(ci_rq, eprio);
1.1  rmind 	if (TAILQ_EMPTY(q_head)) {
1.1  rmind 		u_int i;
1.1  rmind 		uint32_t q;
1.1  rmind
1.1  rmind 		/* Mark bit */
1.1  rmind 		i = eprio >> BITMAP_SHIFT;
1.1  rmind 		q = eprio - (i << BITMAP_SHIFT);
1.1  rmind 		KASSERT((ci_rq->r_bitmap[i] & (1 << q)) == 0);
1.1  rmind 		ci_rq->r_bitmap[i] |= 1 << q;
1.1  rmind 	}
1.1  rmind 	TAILQ_INSERT_TAIL(q_head, l, l_runq);
1.1  rmind 	ci_rq->r_count++;
1.1  rmind 	if ((l->l_flag & LW_BOUND) == 0)
1.1  rmind 		ci_rq->r_mcount++;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Update the value of highest priority in the runqueue,
1.1  rmind 	 * if priority of this thread is higher.
1.1  rmind 	 */
1.1  rmind 	if (eprio < ci_rq->r_highest_pri)
1.1  rmind 		ci_rq->r_highest_pri = eprio;
1.1  rmind
1.1  rmind 	sched_newts(l);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_dequeue(struct lwp *l)
1.1  rmind {
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	TAILQ_HEAD(, lwp) *q_head;
1.1  rmind 	const pri_t eprio = lwp_eprio(l);
1.1  rmind
1.1  rmind 	ci_rq = l->l_cpu->ci_schedstate.spc_sched_info;
1.1  rmind 	KASSERT(lwp_locked(l, l->l_cpu->ci_schedstate.spc_mutex));
1.1  rmind 	KASSERT(ci_rq->r_highest_pri <= eprio);
1.1  rmind 	KASSERT(ci_rq->r_bitmap[eprio >> BITMAP_SHIFT] != 0);
1.1  rmind 	KASSERT(ci_rq->r_count > 0);
1.1  rmind
1.1  rmind 	ci_rq->r_count--;
1.1  rmind 	if ((l->l_flag & LW_BOUND) == 0)
1.1  rmind 		ci_rq->r_mcount--;
1.1  rmind
1.1  rmind 	q_head = sched_getrq(ci_rq, eprio);
1.1  rmind 	TAILQ_REMOVE(q_head, l, l_runq);
1.1  rmind 	if (TAILQ_EMPTY(q_head)) {
1.1  rmind 		u_int i;
1.1  rmind 		uint32_t q;
1.1  rmind
1.1  rmind 		/* Unmark bit */
1.1  rmind 		i = eprio >> BITMAP_SHIFT;
1.1  rmind 		q = eprio - (i << BITMAP_SHIFT);
1.1  rmind 		KASSERT((ci_rq->r_bitmap[i] & (1 << q)) != 0);
1.1  rmind 		ci_rq->r_bitmap[i] &= ~(1 << q);
1.1  rmind
1.1  rmind 		/*
1.1  rmind 		 * Update the value of highest priority in the runqueue, in a
1.1  rmind 		 * case it was a last thread in the queue of highest priority.
1.1  rmind 		 */
1.1  rmind 		if (eprio != ci_rq->r_highest_pri)
1.1  rmind 			return;
1.1  rmind
1.1  rmind 		do {
1.1  rmind 			q = ffs(ci_rq->r_bitmap[i]);
1.1  rmind 			if (q) {
1.1  rmind 				ci_rq->r_highest_pri =
1.1  rmind 				    (i << BITMAP_SHIFT) + q - 1;
1.1  rmind 				return;
1.1  rmind 			}
1.1  rmind 		} while (++i < BITMAP_SIZE);
1.1  rmind
1.1  rmind 		/* If not found - set the maximal value */
1.1  rmind 		ci_rq->r_highest_pri = PRI_MAX;
1.1  rmind 	}
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_slept(struct lwp *l)
1.1  rmind {
1.1  rmind 	sched_info_lwp_t *sil = l->l_sched_info;
1.1  rmind
1.1  rmind 	/* Save the time when thread has slept */
1.1  rmind 	sil->sl_slept = hardclock_ticks;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * If thread is not a real-time and batch flag is not marked,
1.1  rmind 	 * increase the the priority, and run with lower time-quantum.
1.1  rmind 	 */
1.1  rmind 	if (l->l_usrpri > PRI_REALTIME && (sil->sl_flags & SL_BATCH) == 0)
1.1  rmind 		l->l_usrpri--;
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_wakeup(struct lwp *l)
1.1  rmind {
1.1  rmind 	sched_info_lwp_t *sil = l->l_sched_info;
1.1  rmind
1.1  rmind 	/* Update sleep time delta */
1.1  rmind 	sil->sl_slpsum += (l->l_slptime == 0) ?
1.1  rmind 	    (hardclock_ticks - sil->sl_slept) : hz;
1.1  rmind
1.1  rmind 	/* If thread was sleeping a second or more - set a high priority */
1.1  rmind 	if (l->l_slptime > 1 || (hardclock_ticks - sil->sl_slept) >= hz)
1.1  rmind 		l->l_usrpri = l->l_priority = high_pri[l->l_usrpri];
1.1  rmind
1.1  rmind 	/* Also, consider looking for a better CPU to wake up */
1.1  rmind 	if ((l->l_flag & (LW_BOUND | LW_SYSTEM)) == 0)
1.1  rmind 		l->l_cpu = sched_takecpu(l);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind sched_pstats_hook(struct lwp *l)
1.1  rmind {
1.1  rmind 	sched_info_lwp_t *sil = l->l_sched_info;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Set that thread is more CPU-bound, if sum of run time exceeds the
1.1  rmind 	 * sum of sleep time.  If it is CPU-bound not a first time - decrease
1.1  rmind 	 * the priority.
1.1  rmind 	 */
1.1  rmind 	if (sil->sl_rtsum > sil->sl_slpsum) {
1.1  rmind 		if ((sil->sl_flags & SL_BATCH) && (l->l_usrpri < PRI_MAX))
1.1  rmind 			l->l_usrpri++;
1.1  rmind 		sil->sl_flags |= SL_BATCH;
1.1  rmind 	} else {
1.1  rmind 		sil->sl_flags &= ~SL_BATCH;
1.1  rmind 	}
1.1  rmind 	sil->sl_slpsum = 0;
1.1  rmind 	sil->sl_rtsum = 0;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Estimate only threads on time-sharing run queue, also,
1.1  rmind 	 * ignore the highest time-sharing priority.
1.1  rmind 	 */
1.1  rmind 	if (l->l_stat != LSRUN || l->l_usrpri <= PRI_REALTIME)
1.1  rmind 		return;
1.1  rmind
1.1  rmind 	/* If thread was not ran a second or more - set a high priority */
1.1  rmind 	if (sil->sl_lrtime && (hardclock_ticks - sil->sl_lrtime >= hz))
1.1  rmind 		lwp_changepri(l, high_pri[l->l_usrpri]);
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Migration and balancing.
1.1  rmind  */
1.1  rmind
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind
1.1  rmind /* Check if LWP can migrate to the chosen CPU */
1.1  rmind static inline bool
1.1  rmind sched_migratable(const struct lwp *l, const struct cpu_info *ci)
1.1  rmind {
1.1  rmind
1.1  rmind 	if (ci->ci_schedstate.spc_flags & SPCF_OFFLINE)
1.1  rmind 		return false;
1.1  rmind
1.1  rmind 	if ((l->l_flag & LW_BOUND) == 0)
1.1  rmind 		return true;
1.1  rmind #if 0
1.1  rmind 	return cpu_in_pset(ci, l->l_psid);
1.1  rmind #else
1.1  rmind 	return false;
1.1  rmind #endif
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Estimate the migration of LWP to the other CPU.
1.1  rmind  * Take and return the CPU, if migration is needed.
1.1  rmind  */
1.1  rmind struct cpu_info *
1.1  rmind sched_takecpu(struct lwp *l)
1.1  rmind {
1.1  rmind 	struct cpu_info *ci, *tci = NULL;
1.1  rmind 	struct schedstate_percpu *spc;
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	sched_info_lwp_t *sil;
1.1  rmind 	CPU_INFO_ITERATOR cii;
1.1  rmind 	pri_t eprio, lpri;
1.1  rmind
1.1  rmind 	ci = l->l_cpu;
1.1  rmind 	spc = &ci->ci_schedstate;
1.1  rmind 	ci_rq = spc->spc_sched_info;
1.1  rmind
1.1  rmind 	/* CPU of this thread is idling - run there */
1.1  rmind 	if (ci_rq->r_count == 0)
1.1  rmind 		return ci;
1.1  rmind
1.1  rmind 	eprio = lwp_eprio(l);
1.1  rmind 	sil = l->l_sched_info;
1.1  rmind
1.1  rmind 	/* Stay if thread is cache-hot */
1.1  rmind 	if (l->l_stat == LSSLEEP && l->l_slptime <= 1 &&
1.1  rmind 	    CACHE_HOT(sil) && eprio <= spc->spc_curpriority)
1.1  rmind 		return ci;
1.1  rmind
1.1  rmind 	/* Run on current CPU if priority of thread is higher */
1.1  rmind 	ci = curcpu();
1.1  rmind 	spc = &ci->ci_schedstate;
1.1  rmind 	if (eprio < spc->spc_curpriority && sched_migratable(l, ci))
1.1  rmind 		return ci;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Look for the CPU with the lowest priority thread.  In case of
1.1  rmind 	 * equal the priority - check the lower count of the threads.
1.1  rmind 	 */
1.1  rmind 	lpri = 0;
1.1  rmind 	ci_rq = NULL;
1.1  rmind 	tci = l->l_cpu;
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci)) {
1.1  rmind 		runqueue_t *ici_rq;
1.1  rmind 		pri_t pri;
1.1  rmind
1.1  rmind 		spc = &ci->ci_schedstate;
1.1  rmind 		ici_rq = spc->spc_sched_info;
1.1  rmind 		pri = min(spc->spc_curpriority, ici_rq->r_highest_pri);
1.1  rmind 		if (pri < lpri)
1.1  rmind 			continue;
1.1  rmind
1.1  rmind 		if (pri == lpri && ci_rq && ci_rq->r_count < ici_rq->r_count)
1.1  rmind 			continue;
1.1  rmind
1.1  rmind 		if (sched_migratable(l, ci) == false)
1.1  rmind 			continue;
1.1  rmind
1.1  rmind 		lpri = pri;
1.1  rmind 		tci = ci;
1.1  rmind 		ci_rq = ici_rq;
1.1  rmind 	}
1.1  rmind
1.1  rmind 	return tci;
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Tries to catch an LWP from the runqueue of other CPU.
1.1  rmind  */
1.1  rmind static struct lwp *
1.1  rmind sched_catchlwp(void)
1.1  rmind {
1.1  rmind 	struct cpu_info *curci = curcpu(), *ci = worker_ci;
1.1  rmind 	TAILQ_HEAD(, lwp) *q_head;
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	struct lwp *l;
1.1  rmind
1.1  rmind 	if (curci == ci)
1.1  rmind 		return NULL;
1.1  rmind
1.1  rmind 	/* Lockless check */
1.1  rmind 	ci_rq = ci->ci_schedstate.spc_sched_info;
1.1  rmind 	if (ci_rq->r_count < min_catch)
1.1  rmind 		return NULL;
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Double-lock the runqueues.
1.1  rmind 	 */
1.3  rmind 	if (curci < ci) {
1.1  rmind 		spc_lock(ci);
1.1  rmind 	} else if (!mutex_tryenter(ci->ci_schedstate.spc_mutex)) {
1.1  rmind 		const runqueue_t *cur_rq = curci->ci_schedstate.spc_sched_info;
1.1  rmind
1.1  rmind 		spc_unlock(curci);
1.1  rmind 		spc_lock(ci);
1.1  rmind 		spc_lock(curci);
1.1  rmind
1.1  rmind 		if (cur_rq->r_count) {
1.1  rmind 			spc_unlock(ci);
1.1  rmind 			return NULL;
1.1  rmind 		}
1.1  rmind 	}
1.1  rmind
1.1  rmind 	if (ci_rq->r_count < min_catch) {
1.1  rmind 		spc_unlock(ci);
1.1  rmind 		return NULL;
1.1  rmind 	}
1.1  rmind
1.1  rmind 	/* Take the highest priority thread */
1.1  rmind 	q_head = sched_getrq(ci_rq, ci_rq->r_highest_pri);
1.1  rmind 	l = TAILQ_FIRST(q_head);
1.1  rmind
1.1  rmind 	for (;;) {
1.1  rmind 		sched_info_lwp_t *sil;
1.1  rmind
1.1  rmind 		/* Check the first and next result from the queue */
1.1  rmind 		if (l == NULL)
1.1  rmind 			break;
1.1  rmind
1.1  rmind 		/* Look for threads, whose are allowed to migrate */
1.1  rmind 		sil = l->l_sched_info;
1.1  rmind 		if ((l->l_flag & LW_SYSTEM) || CACHE_HOT(sil) ||
1.1  rmind 		    sched_migratable(l, curci) == false) {
1.1  rmind 			l = TAILQ_NEXT(l, l_runq);
1.1  rmind 			continue;
1.1  rmind 		}
1.1  rmind 		/* Recheck if chosen thread is still on the runqueue */
1.1  rmind 		if (l->l_stat == LSRUN && (l->l_flag & LW_INMEM)) {
1.1  rmind 			sched_dequeue(l);
1.1  rmind 			l->l_cpu = curci;
1.1  rmind 			lwp_setlock(l, curci->ci_schedstate.spc_mutex);
1.1  rmind 			sched_enqueue(l, false);
1.1  rmind 			break;
1.1  rmind 		}
1.1  rmind 		l = TAILQ_NEXT(l, l_runq);
1.1  rmind 	}
1.1  rmind 	spc_unlock(ci);
1.1  rmind
1.1  rmind 	return l;
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Periodical calculations for balancing.
1.1  rmind  */
1.1  rmind static void
1.1  rmind sched_balance(void *nocallout)
1.1  rmind {
1.1  rmind 	struct cpu_info *ci, *hci;
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	CPU_INFO_ITERATOR cii;
1.1  rmind 	u_int highest;
1.1  rmind
1.1  rmind 	hci = curcpu();
1.1  rmind 	highest = 0;
1.1  rmind
1.1  rmind 	/* Make lockless countings */
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci)) {
1.1  rmind 		ci_rq = ci->ci_schedstate.spc_sched_info;
1.1  rmind
1.1  rmind 		/* Average count of the threads */
1.1  rmind 		ci_rq->r_avgcount = (ci_rq->r_avgcount + ci_rq->r_mcount) >> 1;
1.1  rmind
1.1  rmind 		/* Look for CPU with the highest average */
1.1  rmind 		if (ci_rq->r_avgcount > highest) {
1.1  rmind 			hci = ci;
1.1  rmind 			highest = ci_rq->r_avgcount;
1.1  rmind 		}
1.1  rmind 	}
1.1  rmind
1.1  rmind 	/* Update the worker */
1.1  rmind 	worker_ci = hci;
1.1  rmind
1.1  rmind 	if (nocallout == NULL)
1.1  rmind 		callout_schedule(&balance_ch, balance_period);
1.1  rmind }
1.1  rmind
1.1  rmind #else
1.1  rmind
1.1  rmind struct cpu_info *
1.1  rmind sched_takecpu(struct lwp *l)
1.1  rmind {
1.1  rmind
1.1  rmind 	return l->l_cpu;
1.1  rmind }
1.1  rmind
1.1  rmind #endif	/* MULTIPROCESSOR */
1.1  rmind
1.1  rmind /*
1.1  rmind  * Scheduler mill.
1.1  rmind  */
1.1  rmind struct lwp *
1.1  rmind sched_nextlwp(void)
1.1  rmind {
1.1  rmind 	struct cpu_info *ci = curcpu();
1.1  rmind 	struct schedstate_percpu *spc;
1.1  rmind 	TAILQ_HEAD(, lwp) *q_head;
1.1  rmind 	sched_info_lwp_t *sil;
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	struct lwp *l;
1.1  rmind
1.1  rmind 	spc = &ci->ci_schedstate;
1.1  rmind 	ci_rq = ci->ci_schedstate.spc_sched_info;
1.1  rmind
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind 	/* If runqueue is empty, try to catch some thread from other CPU */
1.1  rmind 	if (spc->spc_flags & SPCF_OFFLINE) {
1.1  rmind 		if (ci_rq->r_mcount == 0)
1.1  rmind 			return NULL;
1.1  rmind 	} else if (ci_rq->r_count == 0) {
1.1  rmind 		/* Reset the counter, and call the balancer */
1.1  rmind 		ci_rq->r_avgcount = 0;
1.1  rmind 		sched_balance(ci);
1.1  rmind
1.1  rmind 		/* The re-locking will be done inside */
1.1  rmind 		return sched_catchlwp();
1.1  rmind 	}
1.1  rmind #else
1.1  rmind 	if (ci_rq->r_count == 0)
1.1  rmind 		return NULL;
1.1  rmind #endif
1.1  rmind
1.1  rmind 	/* Take the highest priority thread */
1.1  rmind 	KASSERT(ci_rq->r_bitmap[ci_rq->r_highest_pri >> BITMAP_SHIFT]);
1.1  rmind 	q_head = sched_getrq(ci_rq, ci_rq->r_highest_pri);
1.1  rmind 	l = TAILQ_FIRST(q_head);
1.1  rmind 	KASSERT(l != NULL);
1.1  rmind
1.1  rmind 	/* Update the counters */
1.1  rmind 	sil = l->l_sched_info;
1.1  rmind 	KASSERT(sil->sl_timeslice >= min_ts);
1.1  rmind 	KASSERT(sil->sl_timeslice <= max_ts);
1.1  rmind 	spc->spc_ticks = sil->sl_timeslice;
1.1  rmind 	sil->sl_rtime = hardclock_ticks;
1.1  rmind
1.1  rmind 	return l;
1.1  rmind }
1.1  rmind
1.1  rmind bool
1.1  rmind sched_curcpu_runnable_p(void)
1.1  rmind {
1.1  rmind 	const struct cpu_info *ci = curcpu();
1.1  rmind 	const runqueue_t *ci_rq = ci->ci_schedstate.spc_sched_info;
1.1  rmind
1.1  rmind 	if (ci->ci_schedstate.spc_flags & SPCF_OFFLINE)
1.1  rmind 		return ci_rq->r_mcount;
1.1  rmind
1.1  rmind 	return ci_rq->r_count;
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Time-driven events.
1.1  rmind  */
1.1  rmind
1.1  rmind /*
1.1  rmind  * Called once per time-quantum.  This routine is CPU-local and runs at
1.1  rmind  * IPL_SCHED, thus the locking is not needed.
1.1  rmind  */
1.1  rmind void
1.1  rmind sched_tick(struct cpu_info *ci)
1.1  rmind {
1.1  rmind 	const runqueue_t *ci_rq = ci->ci_schedstate.spc_sched_info;
1.1  rmind 	struct schedstate_percpu *spc = &ci->ci_schedstate;
1.1  rmind 	struct lwp *l = curlwp;
1.1  rmind 	sched_info_lwp_t *sil = l->l_sched_info;
1.1  rmind
1.2  rmind 	if (CURCPU_IDLE_P())
1.2  rmind 		return;
1.1  rmind
1.2  rmind 	switch (l->l_policy) {
1.2  rmind 	case SCHED_FIFO:
1.2  rmind 		/*
1.2  rmind 		 * Update the time-quantum, and continue running,
1.2  rmind 		 * if thread runs on FIFO real-time policy.
1.2  rmind 		 */
1.1  rmind 		spc->spc_ticks = sil->sl_timeslice;
1.1  rmind 		return;
1.2  rmind 	case SCHED_OTHER:
1.2  rmind 		/* Decrease the priority, and run with a higher time-quantum */
1.2  rmind 		if (l->l_usrpri < PRI_REALTIME)
1.2  rmind 			break;
1.2  rmind 		l->l_usrpri = min(l->l_usrpri + 1, PRI_MAX);
1.2  rmind 		l->l_priority = l->l_usrpri;
1.2  rmind 		break;
1.1  rmind 	}
1.1  rmind
1.1  rmind 	/*
1.2  rmind 	 * If there are higher priority threads or threads in the same queue,
1.2  rmind 	 * mark that thread should yield, otherwise, continue running.
1.1  rmind 	 */
1.2  rmind 	if (lwp_eprio(l) >= ci_rq->r_highest_pri) {
1.1  rmind 		spc->spc_flags |= SPCF_SHOULDYIELD;
1.1  rmind 		cpu_need_resched(ci, 0);
1.1  rmind 	} else
1.1  rmind 		spc->spc_ticks = sil->sl_timeslice;
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Sysctl nodes and initialization.
1.1  rmind  */
1.1  rmind
1.1  rmind static int
1.1  rmind sysctl_sched_mints(SYSCTLFN_ARGS)
1.1  rmind {
1.1  rmind 	struct sysctlnode node;
1.1  rmind 	struct cpu_info *ci;
1.1  rmind 	int error, newsize;
1.1  rmind 	CPU_INFO_ITERATOR cii;
1.1  rmind
1.1  rmind 	node = *rnode;
1.1  rmind 	node.sysctl_data = &newsize;
1.1  rmind
1.1  rmind 	newsize = hztoms(min_ts);
1.1  rmind 	error = sysctl_lookup(SYSCTLFN_CALL(&node));
1.1  rmind 	if (error || newp == NULL)
1.1  rmind 		return error;
1.1  rmind
1.1  rmind 	if (newsize < 1 || newsize > hz || newsize >= max_ts)
1.1  rmind 		return EINVAL;
1.1  rmind
1.1  rmind 	/* It is safe to do this in such order */
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci))
1.1  rmind 		spc_lock(ci);
1.1  rmind
1.1  rmind 	min_ts = mstohz(newsize);
1.1  rmind 	sched_precalcts();
1.1  rmind
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci))
1.1  rmind 		spc_unlock(ci);
1.1  rmind
1.1  rmind 	return 0;
1.1  rmind }
1.1  rmind
1.1  rmind static int
1.1  rmind sysctl_sched_maxts(SYSCTLFN_ARGS)
1.1  rmind {
1.1  rmind 	struct sysctlnode node;
1.1  rmind 	struct cpu_info *ci;
1.1  rmind 	int error, newsize;
1.1  rmind 	CPU_INFO_ITERATOR cii;
1.1  rmind
1.1  rmind 	node = *rnode;
1.1  rmind 	node.sysctl_data = &newsize;
1.1  rmind
1.1  rmind 	newsize = hztoms(max_ts);
1.1  rmind 	error = sysctl_lookup(SYSCTLFN_CALL(&node));
1.1  rmind 	if (error || newp == NULL)
1.1  rmind 		return error;
1.1  rmind
1.1  rmind 	if (newsize < 10 || newsize > hz || newsize <= min_ts)
1.1  rmind 		return EINVAL;
1.1  rmind
1.1  rmind 	/* It is safe to do this in such order */
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci))
1.1  rmind 		spc_lock(ci);
1.1  rmind
1.1  rmind 	max_ts = mstohz(newsize);
1.1  rmind 	sched_precalcts();
1.1  rmind
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci))
1.1  rmind 		spc_unlock(ci);
1.1  rmind
1.1  rmind 	return 0;
1.1  rmind }
1.1  rmind
1.1  rmind SYSCTL_SETUP(sysctl_sched_setup, "sysctl kern.sched subtree setup")
1.1  rmind {
1.1  rmind 	const struct sysctlnode *node = NULL;
1.1  rmind
1.1  rmind 	sysctl_createv(clog, 0, NULL, NULL,
1.1  rmind 		CTLFLAG_PERMANENT,
1.1  rmind 		CTLTYPE_NODE, "kern", NULL,
1.1  rmind 		NULL, 0, NULL, 0,
1.1  rmind 		CTL_KERN, CTL_EOL);
1.1  rmind 	sysctl_createv(clog, 0, NULL, &node,
1.1  rmind 		CTLFLAG_PERMANENT,
1.1  rmind 		CTLTYPE_NODE, "sched",
1.1  rmind 		SYSCTL_DESCR("Scheduler options"),
1.1  rmind 		NULL, 0, NULL, 0,
1.1  rmind 		CTL_KERN, CTL_CREATE, CTL_EOL);
1.1  rmind
1.1  rmind 	if (node == NULL)
1.1  rmind 		return;
1.1  rmind
1.1  rmind 	sysctl_createv(clog, 0, &node, NULL,
1.1  rmind 		CTLFLAG_PERMANENT,
1.1  rmind 		CTLTYPE_STRING, "name", NULL,
1.1  rmind 		NULL, 0, __UNCONST("M2"), 0,
1.1  rmind 		CTL_CREATE, CTL_EOL);
1.1  rmind 	sysctl_createv(clog, 0, &node, NULL,
1.1  rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
1.1  rmind 		CTLTYPE_INT, "maxts",
1.1  rmind 		SYSCTL_DESCR("Maximal time quantum (in microseconds)"),
1.1  rmind 		sysctl_sched_maxts, 0, &max_ts, 0,
1.1  rmind 		CTL_CREATE, CTL_EOL);
1.1  rmind 	sysctl_createv(clog, 0, &node, NULL,
1.1  rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
1.1  rmind 		CTLTYPE_INT, "mints",
1.1  rmind 		SYSCTL_DESCR("Minimal time quantum (in microseconds)"),
1.1  rmind 		sysctl_sched_mints, 0, &min_ts, 0,
1.1  rmind 		CTL_CREATE, CTL_EOL);
1.1  rmind
1.1  rmind #ifdef MULTIPROCESSOR
1.1  rmind 	sysctl_createv(clog, 0, &node, NULL,
1.1  rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
1.1  rmind 		CTLTYPE_INT, "cacheht_time",
1.1  rmind 		SYSCTL_DESCR("Cache hotness time"),
1.1  rmind 		NULL, 0, &cacheht_time, 0,
1.1  rmind 		CTL_CREATE, CTL_EOL);
1.1  rmind 	sysctl_createv(clog, 0, &node, NULL,
1.1  rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
1.1  rmind 		CTLTYPE_INT, "balance_period",
1.1  rmind 		SYSCTL_DESCR("Balance period"),
1.1  rmind 		NULL, 0, &balance_period, 0,
1.1  rmind 		CTL_CREATE, CTL_EOL);
1.1  rmind 	sysctl_createv(clog, 0, &node, NULL,
1.1  rmind 		CTLFLAG_PERMANENT | CTLFLAG_READWRITE,
1.1  rmind 		CTLTYPE_INT, "min_catch",
1.1  rmind 		SYSCTL_DESCR("Minimal count of threads for catching"),
1.1  rmind 		NULL, 0, &min_catch, 0,
1.1  rmind 		CTL_CREATE, CTL_EOL);
1.1  rmind #endif
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Debugging.
1.1  rmind  */
1.1  rmind
1.1  rmind #ifdef DDB
1.1  rmind
1.1  rmind void
1.1  rmind sched_print_runqueue(void (*pr)(const char *, ...))
1.1  rmind {
1.1  rmind 	runqueue_t *ci_rq;
1.1  rmind 	sched_info_lwp_t *sil;
1.1  rmind 	struct lwp *l;
1.1  rmind 	struct proc *p;
1.1  rmind 	int i;
1.1  rmind
1.1  rmind 	struct cpu_info *ci;
1.1  rmind 	CPU_INFO_ITERATOR cii;
1.1  rmind
1.1  rmind 	for (CPU_INFO_FOREACH(cii, ci)) {
1.1  rmind 		ci_rq = ci->ci_schedstate.spc_sched_info;
1.1  rmind
1.1  rmind 		(*pr)("Run-queue (CPU = %d):\n", ci->ci_cpuid);
1.1  rmind 		(*pr)(" pid.lid = %d.%d, threads count = %u, "
1.1  rmind 		    "avgcount = %u, highest pri = %d\n",
1.1  rmind 		    ci->ci_curlwp->l_proc->p_pid, ci->ci_curlwp->l_lid,
1.1  rmind 		    ci_rq->r_count, ci_rq->r_avgcount, ci_rq->r_highest_pri);
1.1  rmind 		i = 0;
1.1  rmind 		do {
1.1  rmind 			int b;
1.1  rmind 			b = ci_rq->r_bitmap[i];
1.1  rmind 			(*pr)(" bitmap[%d] => [ %d (0x%x) ]\n", i, ffs(b), b);
1.1  rmind 		} while (++i < BITMAP_SIZE);
1.1  rmind 	}
1.1  rmind
1.1  rmind 	(*pr)("   %5s %4s %4s %10s %3s %4s %11s %3s %s\n",
1.1  rmind 	    "LID", "PRI", "UPRI", "FL", "ST", "TS", "LWP", "CPU", "LRTIME");
1.1  rmind
1.1  rmind 	PROCLIST_FOREACH(p, &allproc) {
1.1  rmind 		(*pr)(" /- %d (%s)\n", (int)p->p_pid, p->p_comm);
1.1  rmind 		LIST_FOREACH(l, &p->p_lwps, l_sibling) {
1.1  rmind 			sil = l->l_sched_info;
1.1  rmind 			ci = l->l_cpu;
1.1  rmind 			(*pr)(" | %5d %4u %4u 0x%8.8x %3s %4u %11p %3d "
1.1  rmind 			    "%u ST=%d RT=%d %d\n",
1.1  rmind 			    (int)l->l_lid, l->l_priority, l->l_usrpri,
1.1  rmind 			    l->l_flag, l->l_stat == LSRUN ? "RQ" :
1.1  rmind 			    (l->l_stat == LSSLEEP ? "SQ" : "-"),
1.1  rmind 			    sil->sl_timeslice, l, ci->ci_cpuid,
1.1  rmind 			    (u_int)(hardclock_ticks - sil->sl_lrtime),
1.1  rmind 			    sil->sl_slpsum, sil->sl_rtsum, sil->sl_flags);
1.1  rmind 		}
1.1  rmind 	}
1.1  rmind }
1.1  rmind
1.1  rmind #endif /* defined(DDB) */