sys/kern/subr_kcpuset.c

1.9   matt /*	$NetBSD: subr_kcpuset.c,v 1.9 2013/07/17 22:36:26 matt Exp $	*/
1.1  rmind
1.1  rmind /*-
1.1  rmind  * Copyright (c) 2011 The NetBSD Foundation, Inc.
1.1  rmind  * All rights reserved.
1.1  rmind  *
1.1  rmind  * This code is derived from software contributed to The NetBSD Foundation
1.1  rmind  * by 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 NETBSD FOUNDATION, INC. 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  * Kernel CPU set implementation.
1.1  rmind  *
1.1  rmind  * Interface can be used by kernel subsystems as a unified dynamic CPU
1.1  rmind  * bitset implementation handling many CPUs.  Facility also supports early
1.1  rmind  * use by MD code on boot, as it fixups bitsets on further boot.
1.1  rmind  *
1.1  rmind  * TODO:
1.1  rmind  * - Handle "reverse" bitset on fixup/grow.
1.1  rmind  */
1.1  rmind
1.1  rmind #include <sys/cdefs.h>
1.9   matt __KERNEL_RCSID(0, "$NetBSD: subr_kcpuset.c,v 1.9 2013/07/17 22:36:26 matt Exp $");
1.1  rmind
1.1  rmind #include <sys/param.h>
1.1  rmind #include <sys/types.h>
1.1  rmind
1.1  rmind #include <sys/atomic.h>
1.1  rmind #include <sys/sched.h>
1.1  rmind #include <sys/kcpuset.h>
1.1  rmind #include <sys/pool.h>
1.1  rmind
1.1  rmind /* Number of CPUs to support. */
1.1  rmind #define	KC_MAXCPUS		roundup2(MAXCPUS, 32)
1.1  rmind
1.1  rmind /*
1.1  rmind  * Structure of dynamic CPU set in the kernel.
1.1  rmind  */
1.1  rmind struct kcpuset {
1.1  rmind 	uint32_t		bits[0];
1.1  rmind };
1.1  rmind
1.1  rmind typedef struct kcpuset_impl {
1.1  rmind 	/* Reference count. */
1.1  rmind 	u_int			kc_refcnt;
1.1  rmind 	/* Next to free, if non-NULL (used when multiple references). */
1.1  rmind 	struct kcpuset *	kc_next;
1.1  rmind 	/* Actual variable-sized field of bits. */
1.1  rmind 	struct kcpuset		kc_field;
1.1  rmind } kcpuset_impl_t;
1.1  rmind
1.1  rmind #define	KC_BITS_OFF		(offsetof(struct kcpuset_impl, kc_field))
1.1  rmind #define	KC_GETSTRUCT(b)		((kcpuset_impl_t *)((char *)(b) - KC_BITS_OFF))
1.9   matt #define	KC_GETCSTRUCT(b)	((const kcpuset_impl_t *)((const char *)(b) - KC_BITS_OFF))
1.1  rmind
1.1  rmind /* Sizes of a single bitset. */
1.1  rmind #define	KC_SHIFT		5
1.1  rmind #define	KC_MASK			31
1.1  rmind
1.1  rmind /* An array of noted early kcpuset creations and data. */
1.1  rmind #define	KC_SAVE_NITEMS		8
1.1  rmind
1.1  rmind /* Structures for early boot mechanism (must be statically initialised). */
1.1  rmind static kcpuset_t **		kc_noted_early[KC_SAVE_NITEMS];
1.1  rmind static uint32_t			kc_bits_early[KC_SAVE_NITEMS];
1.1  rmind static int			kc_last_idx = 0;
1.1  rmind static bool			kc_initialised = false;
1.1  rmind
1.1  rmind #define	KC_BITSIZE_EARLY	sizeof(kc_bits_early[0])
1.4  rmind #define	KC_NFIELDS_EARLY	1
1.1  rmind
1.1  rmind /*
1.1  rmind  * The size of whole bitset fields and amount of fields.
1.1  rmind  * The whole size must statically initialise for early case.
1.1  rmind  */
1.1  rmind static size_t			kc_bitsize __read_mostly = KC_BITSIZE_EARLY;
1.1  rmind static size_t			kc_nfields __read_mostly = KC_NFIELDS_EARLY;
1.1  rmind
1.1  rmind static pool_cache_t		kc_cache __read_mostly;
1.1  rmind
1.3  rmind static kcpuset_t *		kcpuset_create_raw(bool);
1.1  rmind
1.1  rmind /*
1.1  rmind  * kcpuset_sysinit: initialize the subsystem, transfer early boot cases
1.1  rmind  * to dynamically allocated sets.
1.1  rmind  */
1.1  rmind void
1.1  rmind kcpuset_sysinit(void)
1.1  rmind {
1.1  rmind 	kcpuset_t *kc_dynamic[KC_SAVE_NITEMS], *kcp;
1.1  rmind 	int i, s;
1.1  rmind
1.1  rmind 	/* Set a kcpuset_t sizes. */
1.1  rmind 	kc_nfields = (KC_MAXCPUS >> KC_SHIFT);
1.1  rmind 	kc_bitsize = sizeof(uint32_t) * kc_nfields;
1.4  rmind 	KASSERT(kc_nfields != 0 && kc_bitsize != 0);
1.1  rmind
1.1  rmind 	kc_cache = pool_cache_init(sizeof(kcpuset_impl_t) + kc_bitsize,
1.1  rmind 	    coherency_unit, 0, 0, "kcpuset", NULL, IPL_NONE, NULL, NULL, NULL);
1.1  rmind
1.1  rmind 	/* First, pre-allocate kcpuset entries. */
1.1  rmind 	for (i = 0; i < kc_last_idx; i++) {
1.3  rmind 		kcp = kcpuset_create_raw(true);
1.1  rmind 		kc_dynamic[i] = kcp;
1.1  rmind 	}
1.1  rmind
1.1  rmind 	/*
1.1  rmind 	 * Prepare to convert all early noted kcpuset uses to dynamic sets.
1.1  rmind 	 * All processors, except the one we are currently running (primary),
1.1  rmind 	 * must not be spinned yet.  Since MD facilities can use kcpuset,
1.1  rmind 	 * raise the IPL to high.
1.1  rmind 	 */
1.1  rmind 	KASSERT(mp_online == false);
1.1  rmind
1.1  rmind 	s = splhigh();
1.1  rmind 	for (i = 0; i < kc_last_idx; i++) {
1.1  rmind 		/*
1.1  rmind 		 * Transfer the bits from early static storage to the kcpuset.
1.1  rmind 		 */
1.1  rmind 		KASSERT(kc_bitsize >= KC_BITSIZE_EARLY);
1.1  rmind 		memcpy(kc_dynamic[i], &kc_bits_early[i], KC_BITSIZE_EARLY);
1.1  rmind
1.1  rmind 		/*
1.1  rmind 		 * Store the new pointer, pointing to the allocated kcpuset.
1.1  rmind 		 * Note: we are not in an interrupt context and it is the only
1.1  rmind 		 * CPU running - thus store is safe (e.g. no need for pointer
1.1  rmind 		 * variable to be volatile).
1.1  rmind 		 */
1.1  rmind 		*kc_noted_early[i] = kc_dynamic[i];
1.1  rmind 	}
1.1  rmind 	kc_initialised = true;
1.1  rmind 	kc_last_idx = 0;
1.1  rmind 	splx(s);
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * kcpuset_early_ptr: note an early boot use by saving the pointer and
1.1  rmind  * returning a pointer to a static, temporary bit field.
1.1  rmind  */
1.1  rmind static kcpuset_t *
1.1  rmind kcpuset_early_ptr(kcpuset_t **kcptr)
1.1  rmind {
1.1  rmind 	kcpuset_t *kcp;
1.1  rmind 	int s;
1.1  rmind
1.1  rmind 	s = splhigh();
1.1  rmind 	if (kc_last_idx < KC_SAVE_NITEMS) {
1.1  rmind 		/*
1.1  rmind 		 * Save the pointer, return pointer to static early field.
1.1  rmind 		 * Need to zero it out.
1.1  rmind 		 */
1.5  rmind 		kc_noted_early[kc_last_idx] = kcptr;
1.1  rmind 		kcp = (kcpuset_t *)&kc_bits_early[kc_last_idx];
1.5  rmind 		kc_last_idx++;
1.1  rmind 		memset(kcp, 0, KC_BITSIZE_EARLY);
1.1  rmind 		KASSERT(kc_bitsize == KC_BITSIZE_EARLY);
1.1  rmind 	} else {
1.1  rmind 		panic("kcpuset(9): all early-use entries exhausted; "
1.1  rmind 		    "increase KC_SAVE_NITEMS\n");
1.1  rmind 	}
1.1  rmind 	splx(s);
1.1  rmind
1.1  rmind 	return kcp;
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Routines to create or destroy the CPU set.
1.1  rmind  * Early boot case is handled.
1.1  rmind  */
1.1  rmind
1.1  rmind static kcpuset_t *
1.3  rmind kcpuset_create_raw(bool zero)
1.1  rmind {
1.1  rmind 	kcpuset_impl_t *kc;
1.1  rmind
1.1  rmind 	kc = pool_cache_get(kc_cache, PR_WAITOK);
1.1  rmind 	kc->kc_refcnt = 1;
1.1  rmind 	kc->kc_next = NULL;
1.1  rmind
1.3  rmind 	if (zero) {
1.3  rmind 		memset(&kc->kc_field, 0, kc_bitsize);
1.3  rmind 	}
1.3  rmind
1.1  rmind 	/* Note: return pointer to the actual field of bits. */
1.1  rmind 	KASSERT((uint8_t *)kc + KC_BITS_OFF == (uint8_t *)&kc->kc_field);
1.1  rmind 	return &kc->kc_field;
1.1  rmind }
1.1  rmind
1.1  rmind void
1.3  rmind kcpuset_create(kcpuset_t **retkcp, bool zero)
1.1  rmind {
1.1  rmind 	if (__predict_false(!kc_initialised)) {
1.1  rmind 		/* Early boot use - special case. */
1.1  rmind 		*retkcp = kcpuset_early_ptr(retkcp);
1.1  rmind 		return;
1.1  rmind 	}
1.3  rmind 	*retkcp = kcpuset_create_raw(zero);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.9   matt kcpuset_clone(kcpuset_t **retkcp, const kcpuset_t *kcp)
1.9   matt {
1.9   matt 	kcpuset_create(retkcp, false);
1.9   matt 	memcpy(*retkcp, kcp, kc_bitsize);
1.9   matt }
1.9   matt
1.9   matt void
1.1  rmind kcpuset_destroy(kcpuset_t *kcp)
1.1  rmind {
1.2  rmind 	kcpuset_impl_t *kc;
1.1  rmind
1.1  rmind 	KASSERT(kc_initialised);
1.1  rmind 	KASSERT(kcp != NULL);
1.1  rmind
1.1  rmind 	do {
1.2  rmind 		kc = KC_GETSTRUCT(kcp);
1.2  rmind 		kcp = kc->kc_next;
1.1  rmind 		pool_cache_put(kc_cache, kc);
1.2  rmind 	} while (kcp);
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.4  rmind  * Routines to reference/unreference the CPU set.
1.1  rmind  * Note: early boot case is not supported by these routines.
1.1  rmind  */
1.1  rmind
1.1  rmind void
1.1  rmind kcpuset_use(kcpuset_t *kcp)
1.1  rmind {
1.1  rmind 	kcpuset_impl_t *kc = KC_GETSTRUCT(kcp);
1.1  rmind
1.1  rmind 	KASSERT(kc_initialised);
1.1  rmind 	atomic_inc_uint(&kc->kc_refcnt);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind kcpuset_unuse(kcpuset_t *kcp, kcpuset_t **lst)
1.1  rmind {
1.1  rmind 	kcpuset_impl_t *kc = KC_GETSTRUCT(kcp);
1.1  rmind
1.1  rmind 	KASSERT(kc_initialised);
1.1  rmind 	KASSERT(kc->kc_refcnt > 0);
1.1  rmind
1.1  rmind 	if (atomic_dec_uint_nv(&kc->kc_refcnt) != 0) {
1.1  rmind 		return;
1.1  rmind 	}
1.1  rmind 	KASSERT(kc->kc_next == NULL);
1.1  rmind 	if (lst == NULL) {
1.1  rmind 		kcpuset_destroy(kcp);
1.1  rmind 		return;
1.1  rmind 	}
1.1  rmind 	kc->kc_next = *lst;
1.1  rmind 	*lst = kcp;
1.1  rmind }
1.1  rmind
1.1  rmind /*
1.1  rmind  * Routines to transfer the CPU set from / to userspace.
1.1  rmind  * Note: early boot case is not supported by these routines.
1.1  rmind  */
1.1  rmind
1.1  rmind int
1.1  rmind kcpuset_copyin(const cpuset_t *ucp, kcpuset_t *kcp, size_t len)
1.1  rmind {
1.5  rmind 	kcpuset_impl_t *kc __unused = KC_GETSTRUCT(kcp);
1.1  rmind
1.1  rmind 	KASSERT(kc_initialised);
1.1  rmind 	KASSERT(kc->kc_refcnt > 0);
1.1  rmind 	KASSERT(kc->kc_next == NULL);
1.1  rmind
1.5  rmind 	if (len > kc_bitsize) { /* XXX */
1.1  rmind 		return EINVAL;
1.1  rmind 	}
1.5  rmind 	return copyin(ucp, kcp, len);
1.1  rmind }
1.1  rmind
1.1  rmind int
1.1  rmind kcpuset_copyout(kcpuset_t *kcp, cpuset_t *ucp, size_t len)
1.1  rmind {
1.5  rmind 	kcpuset_impl_t *kc __unused = KC_GETSTRUCT(kcp);
1.1  rmind
1.1  rmind 	KASSERT(kc_initialised);
1.1  rmind 	KASSERT(kc->kc_refcnt > 0);
1.1  rmind 	KASSERT(kc->kc_next == NULL);
1.1  rmind
1.5  rmind 	if (len > kc_bitsize) { /* XXX */
1.1  rmind 		return EINVAL;
1.1  rmind 	}
1.5  rmind 	return copyout(kcp, ucp, len);
1.1  rmind }
1.1  rmind
1.6  rmind void
1.8  rmind kcpuset_export_u32(const kcpuset_t *kcp, uint32_t *bitfield, size_t len)
1.6  rmind {
1.6  rmind 	size_t rlen = MIN(kc_bitsize, len);
1.6  rmind
1.6  rmind 	KASSERT(kcp != NULL);
1.6  rmind 	memcpy(bitfield, kcp->bits, rlen);
1.6  rmind }
1.6  rmind
1.1  rmind /*
1.4  rmind  * Routines to change bit field - zero, fill, copy, set, unset, etc.
1.1  rmind  */
1.4  rmind
1.1  rmind void
1.1  rmind kcpuset_zero(kcpuset_t *kcp)
1.1  rmind {
1.1  rmind
1.1  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(kcp)->kc_refcnt > 0);
1.1  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(kcp)->kc_next == NULL);
1.1  rmind 	memset(kcp, 0, kc_bitsize);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind kcpuset_fill(kcpuset_t *kcp)
1.1  rmind {
1.1  rmind
1.1  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(kcp)->kc_refcnt > 0);
1.1  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(kcp)->kc_next == NULL);
1.1  rmind 	memset(kcp, ~0, kc_bitsize);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.9   matt kcpuset_copy(kcpuset_t *dkcp, const kcpuset_t *skcp)
1.4  rmind {
1.4  rmind
1.4  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(dkcp)->kc_refcnt > 0);
1.4  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(dkcp)->kc_next == NULL);
1.4  rmind 	memcpy(dkcp, skcp, kc_bitsize);
1.4  rmind }
1.4  rmind
1.4  rmind void
1.1  rmind kcpuset_set(kcpuset_t *kcp, cpuid_t i)
1.1  rmind {
1.1  rmind 	const size_t j = i >> KC_SHIFT;
1.1  rmind
1.1  rmind 	KASSERT(!kc_initialised || KC_GETSTRUCT(kcp)->kc_next == NULL);
1.1  rmind 	KASSERT(j < kc_nfields);
1.1  rmind
1.1  rmind 	kcp->bits[j] |= 1 << (i & KC_MASK);
1.1  rmind }
1.1  rmind
1.1  rmind void
1.1  rmind kcpuset_clear(kcpuset_t *kcp, cpuid_t i)
1.1  rmind {
1.1  rmind 	const size_t j = i >> KC_SHIFT;
1.1  rmind
1.9   matt 	KASSERT(!kc_initialised || KC_GETCSTRUCT(kcp)->kc_next == NULL);
1.1  rmind 	KASSERT(j < kc_nfields);
1.1  rmind
1.1  rmind 	kcp->bits[j] &= ~(1 << (i & KC_MASK));
1.1  rmind }
1.1  rmind
1.4  rmind bool
1.9   matt kcpuset_isset(const kcpuset_t *kcp, cpuid_t i)
1.1  rmind {
1.1  rmind 	const size_t j = i >> KC_SHIFT;
1.1  rmind
1.1  rmind 	KASSERT(kcp != NULL);
1.9   matt 	KASSERT(!kc_initialised || KC_GETCSTRUCT(kcp)->kc_refcnt > 0);
1.9   matt 	KASSERT(!kc_initialised || KC_GETCSTRUCT(kcp)->kc_next == NULL);
1.1  rmind 	KASSERT(j < kc_nfields);
1.1  rmind
1.1  rmind 	return ((1 << (i & KC_MASK)) & kcp->bits[j]) != 0;
1.1  rmind }
1.1  rmind
1.1  rmind bool
1.9   matt kcpuset_isotherset(const kcpuset_t *kcp, cpuid_t i)
1.4  rmind {
1.4  rmind 	const size_t j2 = i >> KC_SHIFT;
1.4  rmind 	const uint32_t mask = ~(1 << (i & KC_MASK));
1.4  rmind
1.4  rmind 	for (size_t j = 0; j < kc_nfields; j++) {
1.4  rmind 		const uint32_t bits = kcp->bits[j];
1.4  rmind 		if (bits && (j != j2 || (bits & mask) != 0)) {
1.4  rmind 			return true;
1.4  rmind 		}
1.4  rmind 	}
1.4  rmind 	return false;
1.4  rmind }
1.4  rmind
1.4  rmind bool
1.9   matt kcpuset_iszero(const kcpuset_t *kcp)
1.1  rmind {
1.1  rmind
1.1  rmind 	for (size_t j = 0; j < kc_nfields; j++) {
1.1  rmind 		if (kcp->bits[j] != 0) {
1.1  rmind 			return false;
1.1  rmind 		}
1.1  rmind 	}
1.1  rmind 	return true;
1.1  rmind }
1.1  rmind
1.1  rmind bool
1.1  rmind kcpuset_match(const kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.1  rmind {
1.1  rmind
1.1  rmind 	return memcmp(kcp1, kcp2, kc_bitsize) == 0;
1.1  rmind }
1.3  rmind
1.9   matt bool
1.9   matt kcpuset_intersecting_p(const kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		if (kcp1->bits[j] & kcp2->bits[j])
1.9   matt 			return true;
1.9   matt 	}
1.9   matt 	return false;
1.9   matt }
1.9   matt
1.9   matt cpuid_t
1.9   matt kcpuset_ffs(const kcpuset_t *kcp)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		if (kcp->bits[j])
1.9   matt 			return 32 * j + ffs(kcp->bits[j]);
1.9   matt 	}
1.9   matt 	return 0;
1.9   matt }
1.9   matt
1.9   matt cpuid_t
1.9   matt kcpuset_ffs_intersecting(const kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		uint32_t bits = kcp1->bits[j] & kcp2->bits[j];
1.9   matt 		if (bits)
1.9   matt 			return 32 * j + ffs(bits);
1.9   matt 	}
1.9   matt 	return 0;
1.9   matt }
1.9   matt
1.3  rmind void
1.9   matt kcpuset_merge(kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.3  rmind {
1.3  rmind
1.3  rmind 	for (size_t j = 0; j < kc_nfields; j++) {
1.3  rmind 		kcp1->bits[j] |= kcp2->bits[j];
1.3  rmind 	}
1.3  rmind }
1.3  rmind
1.5  rmind void
1.9   matt kcpuset_intersect(kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.5  rmind {
1.5  rmind
1.5  rmind 	for (size_t j = 0; j < kc_nfields; j++) {
1.5  rmind 		kcp1->bits[j] &= kcp2->bits[j];
1.5  rmind 	}
1.5  rmind }
1.5  rmind
1.9   matt void
1.9   matt kcpuset_remove(kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		kcp1->bits[j] &= ~kcp2->bits[j];
1.9   matt 	}
1.9   matt }
1.9   matt
1.4  rmind int
1.4  rmind kcpuset_countset(kcpuset_t *kcp)
1.4  rmind {
1.4  rmind 	int count = 0;
1.4  rmind
1.4  rmind 	for (size_t j = 0; j < kc_nfields; j++) {
1.4  rmind 		count += popcount32(kcp->bits[j]);
1.4  rmind 	}
1.4  rmind 	return count;
1.4  rmind }
1.4  rmind
1.3  rmind /*
1.3  rmind  * Routines to set/clear the flags atomically.
1.3  rmind  */
1.3  rmind
1.3  rmind void
1.3  rmind kcpuset_atomic_set(kcpuset_t *kcp, cpuid_t i)
1.3  rmind {
1.3  rmind 	const size_t j = i >> KC_SHIFT;
1.3  rmind
1.3  rmind 	KASSERT(j < kc_nfields);
1.3  rmind 	atomic_or_32(&kcp->bits[j], 1 << (i & KC_MASK));
1.3  rmind }
1.3  rmind
1.3  rmind void
1.3  rmind kcpuset_atomic_clear(kcpuset_t *kcp, cpuid_t i)
1.3  rmind {
1.3  rmind 	const size_t j = i >> KC_SHIFT;
1.3  rmind
1.3  rmind 	KASSERT(j < kc_nfields);
1.3  rmind 	atomic_and_32(&kcp->bits[j], ~(1 << (i & KC_MASK)));
1.3  rmind }
1.9   matt
1.9   matt void
1.9   matt kcpuset_atomicly_intersect(kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		if (kcp2->bits[j])
1.9   matt 			atomic_and_32(&kcp1->bits[j], kcp2->bits[j]);
1.9   matt 	}
1.9   matt }
1.9   matt
1.9   matt void
1.9   matt kcpuset_atomicly_merge(kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		if (kcp2->bits[j])
1.9   matt 			atomic_or_32(&kcp1->bits[j], kcp2->bits[j]);
1.9   matt 	}
1.9   matt }
1.9   matt
1.9   matt void
1.9   matt kcpuset_atomicly_remove(kcpuset_t *kcp1, const kcpuset_t *kcp2)
1.9   matt {
1.9   matt
1.9   matt 	for (size_t j = 0; j < kc_nfields; j++) {
1.9   matt 		if (kcp2->bits[j])
1.9   matt 			atomic_and_32(&kcp1->bits[j], ~kcp2->bits[j]);
1.9   matt 	}
1.9   matt }