sys/kern/subr_cpufreq.c

1.8.16.1     rmind /*	$NetBSD: subr_cpufreq.c,v 1.8.16.1 2014/05/18 17:46:07 rmind Exp $ */
     1.1    jruoho
     1.1    jruoho /*-
     1.1    jruoho  * Copyright (c) 2011 The NetBSD Foundation, Inc.
     1.1    jruoho  * All rights reserved.
     1.1    jruoho  *
     1.1    jruoho  * This code is derived from software contributed to The NetBSD Foundation
     1.1    jruoho  * by Jukka Ruohonen.
     1.1    jruoho  *
     1.1    jruoho  * Redistribution and use in source and binary forms, with or without
     1.1    jruoho  * modification, are permitted provided that the following conditions
     1.1    jruoho  * are met:
     1.1    jruoho  *
     1.1    jruoho  * 1. Redistributions of source code must retain the above copyright
     1.1    jruoho  *    notice, this list of conditions and the following disclaimer.
     1.1    jruoho  * 2. Redistributions in binary form must reproduce the above copyright
     1.1    jruoho  *    notice, this list of conditions and the following disclaimer in the
     1.1    jruoho  *    documentation and/or other materials provided with the distribution.
     1.1    jruoho  *
     1.1    jruoho  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
     1.1    jruoho  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     1.1    jruoho  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     1.1    jruoho  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
     1.1    jruoho  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
     1.1    jruoho  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
     1.1    jruoho  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
     1.1    jruoho  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
     1.1    jruoho  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
     1.1    jruoho  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
     1.1    jruoho  * POSSIBILITY OF SUCH DAMAGE.
     1.1    jruoho  */
     1.1    jruoho #include <sys/cdefs.h>
1.8.16.1     rmind __KERNEL_RCSID(0, "$NetBSD: subr_cpufreq.c,v 1.8.16.1 2014/05/18 17:46:07 rmind Exp $");
     1.1    jruoho
     1.1    jruoho #include <sys/param.h>
     1.1    jruoho #include <sys/cpu.h>
     1.1    jruoho #include <sys/cpufreq.h>
     1.8    jruoho #include <sys/kernel.h>
     1.1    jruoho #include <sys/kmem.h>
     1.1    jruoho #include <sys/mutex.h>
     1.1    jruoho #include <sys/time.h>
     1.1    jruoho #include <sys/xcall.h>
     1.1    jruoho
     1.1    jruoho static int	 cpufreq_latency(void);
     1.1    jruoho static uint32_t	 cpufreq_get_max(void);
     1.1    jruoho static uint32_t	 cpufreq_get_min(void);
     1.1    jruoho static uint32_t	 cpufreq_get_raw(struct cpu_info *);
     1.1    jruoho static void	 cpufreq_get_state_raw(uint32_t, struct cpufreq_state *);
     1.1    jruoho static void	 cpufreq_set_raw(struct cpu_info *, uint32_t);
     1.1    jruoho static void	 cpufreq_set_all_raw(uint32_t);
     1.1    jruoho
     1.3    jruoho static kmutex_t		cpufreq_lock __cacheline_aligned;
     1.3    jruoho static struct cpufreq  *cf_backend __read_mostly = NULL;
     1.1    jruoho
     1.2    jruoho void
     1.1    jruoho cpufreq_init(void)
     1.1    jruoho {
     1.1    jruoho
     1.1    jruoho 	mutex_init(&cpufreq_lock, MUTEX_DEFAULT, IPL_NONE);
     1.3    jruoho 	cf_backend = kmem_zalloc(sizeof(*cf_backend), KM_SLEEP);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho int
     1.1    jruoho cpufreq_register(struct cpufreq *cf)
     1.1    jruoho {
     1.8    jruoho 	uint32_t c, i, j, k, m;
     1.1    jruoho 	int rv;
     1.1    jruoho
     1.8    jruoho 	if (cold != 0)
     1.8    jruoho 		return EBUSY;
     1.8    jruoho
     1.1    jruoho 	KASSERT(cf != NULL);
     1.3    jruoho 	KASSERT(cf_backend != NULL);
     1.1    jruoho 	KASSERT(cf->cf_get_freq != NULL);
     1.1    jruoho 	KASSERT(cf->cf_set_freq != NULL);
     1.1    jruoho 	KASSERT(cf->cf_state_count > 0);
     1.1    jruoho 	KASSERT(cf->cf_state_count < CPUFREQ_STATE_MAX);
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf_backend->cf_init != false) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return EALREADY;
     1.1    jruoho 	}
     1.1    jruoho
     1.3    jruoho 	cf_backend->cf_init = true;
     1.1    jruoho 	cf_backend->cf_mp = cf->cf_mp;
     1.1    jruoho 	cf_backend->cf_cookie = cf->cf_cookie;
     1.1    jruoho 	cf_backend->cf_get_freq = cf->cf_get_freq;
     1.1    jruoho 	cf_backend->cf_set_freq = cf->cf_set_freq;
     1.1    jruoho
     1.1    jruoho 	(void)strlcpy(cf_backend->cf_name, cf->cf_name, sizeof(cf->cf_name));
     1.1    jruoho
     1.1    jruoho 	/*
     1.1    jruoho 	 * Sanity check the values and verify descending order.
     1.1    jruoho 	 */
     1.3    jruoho 	for (c = i = 0; i < cf->cf_state_count; i++) {
     1.1    jruoho
     1.1    jruoho 		CTASSERT(CPUFREQ_STATE_ENABLED != 0);
     1.1    jruoho 		CTASSERT(CPUFREQ_STATE_DISABLED != 0);
     1.1    jruoho
     1.1    jruoho 		if (cf->cf_state[i].cfs_freq == 0)
     1.1    jruoho 			continue;
     1.1    jruoho
     1.3    jruoho 		if (cf->cf_state[i].cfs_freq > 9999 &&
     1.3    jruoho 		    cf->cf_state[i].cfs_freq != CPUFREQ_STATE_ENABLED &&
     1.3    jruoho 		    cf->cf_state[i].cfs_freq != CPUFREQ_STATE_DISABLED)
     1.3    jruoho 			continue;
     1.3    jruoho
     1.1    jruoho 		for (j = k = 0; j < i; j++) {
     1.1    jruoho
     1.1    jruoho 			if (cf->cf_state[i].cfs_freq >=
     1.1    jruoho 			    cf->cf_state[j].cfs_freq) {
     1.1    jruoho 				k = 1;
     1.1    jruoho 				break;
     1.1    jruoho 			}
     1.1    jruoho 		}
     1.1    jruoho
     1.1    jruoho 		if (k != 0)
     1.1    jruoho 			continue;
     1.1    jruoho
     1.3    jruoho 		cf_backend->cf_state[c].cfs_index = c;
     1.3    jruoho 		cf_backend->cf_state[c].cfs_freq = cf->cf_state[i].cfs_freq;
     1.3    jruoho 		cf_backend->cf_state[c].cfs_power = cf->cf_state[i].cfs_power;
     1.1    jruoho
     1.3    jruoho 		c++;
     1.1    jruoho 	}
     1.1    jruoho
     1.3    jruoho 	cf_backend->cf_state_count = c;
     1.1    jruoho
     1.1    jruoho 	if (cf_backend->cf_state_count == 0) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		cpufreq_deregister();
     1.1    jruoho 		return EINVAL;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	rv = cpufreq_latency();
     1.1    jruoho
     1.1    jruoho 	if (rv != 0) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		cpufreq_deregister();
     1.1    jruoho 		return rv;
     1.1    jruoho 	}
     1.1    jruoho
     1.8    jruoho 	m = cpufreq_get_max();
     1.8    jruoho 	cpufreq_set_all_raw(m);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho
     1.1    jruoho 	return 0;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho void
     1.1    jruoho cpufreq_deregister(void)
     1.1    jruoho {
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.3    jruoho 	memset(cf_backend, 0, sizeof(*cf_backend));
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static int
     1.1    jruoho cpufreq_latency(void)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.7  christos 	struct timespec nta, ntb;
     1.1    jruoho 	const uint32_t n = 10;
     1.1    jruoho 	uint32_t i, j, l, m;
     1.1    jruoho 	uint64_t s;
     1.1    jruoho
     1.1    jruoho 	l = cpufreq_get_min();
     1.1    jruoho 	m = cpufreq_get_max();
     1.1    jruoho
     1.1    jruoho 	/*
     1.1    jruoho 	 * For each state, sample the average transition
     1.1    jruoho 	 * latency required to set the state for all CPUs.
     1.1    jruoho 	 */
     1.1    jruoho 	for (i = 0; i < cf->cf_state_count; i++) {
     1.1    jruoho
     1.1    jruoho 		for (s = 0, j = 0; j < n; j++) {
     1.1    jruoho
     1.1    jruoho 			/*
     1.1    jruoho 			 * Attempt to exclude possible
     1.1    jruoho 			 * caching done by the backend.
     1.1    jruoho 			 */
     1.1    jruoho 			if (i == 0)
     1.1    jruoho 				cpufreq_set_all_raw(l);
     1.1    jruoho 			else {
     1.1    jruoho 				cpufreq_set_all_raw(m);
     1.1    jruoho 			}
     1.1    jruoho
     1.7  christos 			nanotime(&nta);
     1.1    jruoho 			cpufreq_set_all_raw(cf->cf_state[i].cfs_freq);
     1.7  christos 			nanotime(&ntb);
     1.7  christos 			timespecsub(&ntb, &nta, &ntb);
     1.1    jruoho
     1.1    jruoho 			if (ntb.tv_sec != 0 ||
     1.7  christos 			    ntb.tv_nsec > CPUFREQ_LATENCY_MAX)
     1.1    jruoho 				continue;
     1.1    jruoho
     1.1    jruoho 			if (s >= UINT64_MAX - CPUFREQ_LATENCY_MAX)
     1.1    jruoho 				break;
     1.1    jruoho
     1.7  christos 			/* Convert to microseconds to prevent overflow */
     1.7  christos 			s += ntb.tv_nsec / 1000;
     1.1    jruoho 		}
     1.1    jruoho
     1.1    jruoho 		/*
     1.1    jruoho 		 * Consider the backend unsuitable if
     1.1    jruoho 		 * the transition latency was too high.
     1.1    jruoho 		 */
     1.1    jruoho 		if (s == 0)
     1.1    jruoho 			return EMSGSIZE;
     1.1    jruoho
     1.1    jruoho 		cf->cf_state[i].cfs_latency = s / n;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	return 0;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho void
     1.1    jruoho cpufreq_suspend(struct cpu_info *ci)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	uint32_t l, s;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf->cf_init != true) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	l = cpufreq_get_min();
     1.1    jruoho 	s = cpufreq_get_raw(ci);
     1.1    jruoho
     1.1    jruoho 	cpufreq_set_raw(ci, l);
     1.1    jruoho 	cf->cf_state_saved = s;
     1.1    jruoho
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho void
     1.1    jruoho cpufreq_resume(struct cpu_info *ci)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf->cf_init != true || cf->cf_state_saved == 0) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	cpufreq_set_raw(ci, cf->cf_state_saved);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho uint32_t
     1.1    jruoho cpufreq_get(struct cpu_info *ci)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	uint32_t freq;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf->cf_init != true) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return 0;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	freq = cpufreq_get_raw(ci);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho
     1.1    jruoho 	return freq;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static uint32_t
     1.1    jruoho cpufreq_get_max(void)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.3    jruoho 	KASSERT(cf->cf_init != false);
     1.1    jruoho 	KASSERT(mutex_owned(&cpufreq_lock) != 0);
     1.1    jruoho
     1.1    jruoho 	return cf->cf_state[0].cfs_freq;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static uint32_t
     1.1    jruoho cpufreq_get_min(void)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.3    jruoho 	KASSERT(cf->cf_init != false);
     1.1    jruoho 	KASSERT(mutex_owned(&cpufreq_lock) != 0);
     1.1    jruoho
     1.1    jruoho 	return cf->cf_state[cf->cf_state_count - 1].cfs_freq;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static uint32_t
     1.1    jruoho cpufreq_get_raw(struct cpu_info *ci)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	uint32_t freq = 0;
     1.1    jruoho 	uint64_t xc;
     1.1    jruoho
     1.3    jruoho 	KASSERT(cf->cf_init != false);
     1.1    jruoho 	KASSERT(mutex_owned(&cpufreq_lock) != 0);
     1.1    jruoho
     1.1    jruoho 	xc = xc_unicast(0, (*cf->cf_get_freq), cf->cf_cookie, &freq, ci);
     1.1    jruoho 	xc_wait(xc);
     1.1    jruoho
     1.1    jruoho 	return freq;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho int
     1.3    jruoho cpufreq_get_backend(struct cpufreq *dst)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf->cf_init != true || dst == NULL) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return ENODEV;
     1.1    jruoho 	}
     1.1    jruoho
     1.3    jruoho 	memcpy(dst, cf, sizeof(*cf));
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho
     1.1    jruoho 	return 0;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho int
     1.1    jruoho cpufreq_get_state(uint32_t freq, struct cpufreq_state *cfs)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf->cf_init != true || cfs == NULL) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return ENODEV;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	cpufreq_get_state_raw(freq, cfs);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho
     1.1    jruoho 	return 0;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho int
     1.1    jruoho cpufreq_get_state_index(uint32_t index, struct cpufreq_state *cfs)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (cf->cf_init != true || cfs == NULL) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return ENODEV;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	if (index >= cf->cf_state_count) {
1.8.16.1     rmind 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return EINVAL;
     1.1    jruoho 	}
     1.1    jruoho
     1.3    jruoho 	memcpy(cfs, &cf->cf_state[index], sizeof(*cfs));
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho
     1.1    jruoho 	return 0;
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static void
     1.1    jruoho cpufreq_get_state_raw(uint32_t freq, struct cpufreq_state *cfs)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	uint32_t f, hi, i = 0, lo = 0;
     1.1    jruoho
     1.1    jruoho 	KASSERT(mutex_owned(&cpufreq_lock) != 0);
     1.3    jruoho 	KASSERT(cf->cf_init != false && cfs != NULL);
     1.1    jruoho
     1.1    jruoho 	hi = cf->cf_state_count;
     1.1    jruoho
     1.1    jruoho 	while (lo < hi) {
     1.1    jruoho
     1.1    jruoho 		i = (lo + hi) >> 1;
     1.1    jruoho 		f = cf->cf_state[i].cfs_freq;
     1.1    jruoho
     1.1    jruoho 		if (freq == f)
     1.1    jruoho 			break;
     1.1    jruoho 		else if (freq > f)
     1.1    jruoho 			hi = i;
     1.1    jruoho 		else {
     1.1    jruoho 			lo = i + 1;
     1.1    jruoho 		}
     1.1    jruoho 	}
     1.1    jruoho
     1.3    jruoho 	memcpy(cfs, &cf->cf_state[i], sizeof(*cfs));
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho void
     1.1    jruoho cpufreq_set(struct cpu_info *ci, uint32_t freq)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (__predict_false(cf->cf_init != true)) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	cpufreq_set_raw(ci, freq);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static void
     1.1    jruoho cpufreq_set_raw(struct cpu_info *ci, uint32_t freq)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	uint64_t xc;
     1.1    jruoho
     1.3    jruoho 	KASSERT(cf->cf_init != false);
     1.1    jruoho 	KASSERT(mutex_owned(&cpufreq_lock) != 0);
     1.1    jruoho
     1.1    jruoho 	xc = xc_unicast(0, (*cf->cf_set_freq), cf->cf_cookie, &freq, ci);
     1.1    jruoho 	xc_wait(xc);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho void
     1.1    jruoho cpufreq_set_all(uint32_t freq)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (__predict_false(cf->cf_init != true)) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	cpufreq_set_all_raw(freq);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static void
     1.1    jruoho cpufreq_set_all_raw(uint32_t freq)
     1.1    jruoho {
     1.1    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	uint64_t xc;
     1.1    jruoho
     1.3    jruoho 	KASSERT(cf->cf_init != false);
     1.1    jruoho 	KASSERT(mutex_owned(&cpufreq_lock) != 0);
     1.1    jruoho
     1.1    jruoho 	xc = xc_broadcast(0, (*cf->cf_set_freq), cf->cf_cookie, &freq);
     1.1    jruoho 	xc_wait(xc);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho #ifdef notyet
     1.1    jruoho void
     1.1    jruoho cpufreq_set_higher(struct cpu_info *ci)
     1.1    jruoho {
     1.1    jruoho 	cpufreq_set_step(ci, -1);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho void
     1.1    jruoho cpufreq_set_lower(struct cpu_info *ci)
     1.1    jruoho {
     1.1    jruoho 	cpufreq_set_step(ci, 1);
     1.1    jruoho }
     1.1    jruoho
     1.1    jruoho static void
     1.1    jruoho cpufreq_set_step(struct cpu_info *ci, int32_t step)
     1.1    jruoho {
     1.3    jruoho 	struct cpufreq *cf = cf_backend;
     1.1    jruoho 	struct cpufreq_state cfs;
     1.1    jruoho 	uint32_t freq;
     1.1    jruoho 	int32_t index;
     1.1    jruoho
     1.1    jruoho 	mutex_enter(&cpufreq_lock);
     1.1    jruoho
     1.3    jruoho 	if (__predict_false(cf->cf_init != true)) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	freq = cpufreq_get_raw(ci);
     1.1    jruoho
     1.1    jruoho 	if (__predict_false(freq == 0)) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	cpufreq_get_state_raw(freq, &cfs);
     1.1    jruoho 	index = cfs.cfs_index + step;
     1.1    jruoho
     1.1    jruoho 	if (index < 0 || index >= (int32_t)cf->cf_state_count) {
     1.1    jruoho 		mutex_exit(&cpufreq_lock);
     1.1    jruoho 		return;
     1.1    jruoho 	}
     1.1    jruoho
     1.1    jruoho 	cpufreq_set_raw(ci, cf->cf_state[index].cfs_freq);
     1.1    jruoho 	mutex_exit(&cpufreq_lock);
     1.1    jruoho }
     1.1    jruoho #endif