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153d7f3fca
The patch below moves the cpu hotplugging higher up in the cpufreq layering; this is needed to avoid recursive taking of the cpu hotplug lock and to otherwise detangle the mess. The new rules are: 1. you must do lock_cpu_hotplug() around the following functions: __cpufreq_driver_target __cpufreq_governor (for CPUFREQ_GOV_LIMITS operation only) __cpufreq_set_policy 2. governer methods (.governer) must NOT take the lock_cpu_hotplug() lock in any way; they are called with the lock taken already 3. if your governer spawns a thread that does things, like calling __cpufreq_driver_target, your thread must honor rule #1. 4. the policy lock and other cpufreq internal locks nest within the lock_cpu_hotplug() lock. I'm not entirely happy about how the __cpufreq_governor rule ended up (conditional locking rule depending on the argument) but basically all callers pass this as a constant so it's not too horrible. The patch also removes the cpufreq_governor() function since during the locking audit it turned out to be entirely unused (so no need to fix it) The patch works on my testbox, but it could use more testing (otoh... it can't be much worse than the current code) Signed-off-by: Arjan van de Ven <arjan@linux.intel.com> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
457 lines
12 KiB
C
457 lines
12 KiB
C
/*
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* drivers/cpufreq/cpufreq_ondemand.c
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*
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* Copyright (C) 2001 Russell King
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* (C) 2003 Venkatesh Pallipadi <venkatesh.pallipadi@intel.com>.
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* Jun Nakajima <jun.nakajima@intel.com>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License version 2 as
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* published by the Free Software Foundation.
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*/
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#include <linux/kernel.h>
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#include <linux/module.h>
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#include <linux/init.h>
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#include <linux/cpufreq.h>
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#include <linux/cpu.h>
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#include <linux/jiffies.h>
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#include <linux/kernel_stat.h>
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#include <linux/mutex.h>
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/*
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* dbs is used in this file as a shortform for demandbased switching
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* It helps to keep variable names smaller, simpler
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*/
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#define DEF_FREQUENCY_UP_THRESHOLD (80)
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#define MIN_FREQUENCY_UP_THRESHOLD (11)
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#define MAX_FREQUENCY_UP_THRESHOLD (100)
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/*
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* The polling frequency of this governor depends on the capability of
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* the processor. Default polling frequency is 1000 times the transition
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* latency of the processor. The governor will work on any processor with
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* transition latency <= 10mS, using appropriate sampling
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* rate.
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* For CPUs with transition latency > 10mS (mostly drivers with CPUFREQ_ETERNAL)
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* this governor will not work.
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* All times here are in uS.
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*/
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static unsigned int def_sampling_rate;
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#define MIN_SAMPLING_RATE_RATIO (2)
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/* for correct statistics, we need at least 10 ticks between each measure */
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#define MIN_STAT_SAMPLING_RATE (MIN_SAMPLING_RATE_RATIO * jiffies_to_usecs(10))
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#define MIN_SAMPLING_RATE (def_sampling_rate / MIN_SAMPLING_RATE_RATIO)
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#define MAX_SAMPLING_RATE (500 * def_sampling_rate)
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#define DEF_SAMPLING_RATE_LATENCY_MULTIPLIER (1000)
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#define TRANSITION_LATENCY_LIMIT (10 * 1000)
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static void do_dbs_timer(void *data);
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struct cpu_dbs_info_s {
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cputime64_t prev_cpu_idle;
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cputime64_t prev_cpu_wall;
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struct cpufreq_policy *cur_policy;
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struct work_struct work;
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unsigned int enable;
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};
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static DEFINE_PER_CPU(struct cpu_dbs_info_s, cpu_dbs_info);
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static unsigned int dbs_enable; /* number of CPUs using this policy */
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/*
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* DEADLOCK ALERT! There is a ordering requirement between cpu_hotplug
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* lock and dbs_mutex. cpu_hotplug lock should always be held before
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* dbs_mutex. If any function that can potentially take cpu_hotplug lock
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* (like __cpufreq_driver_target()) is being called with dbs_mutex taken, then
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* cpu_hotplug lock should be taken before that. Note that cpu_hotplug lock
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* is recursive for the same process. -Venki
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*/
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static DEFINE_MUTEX(dbs_mutex);
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static struct workqueue_struct *kondemand_wq;
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struct dbs_tuners {
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unsigned int sampling_rate;
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unsigned int up_threshold;
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unsigned int ignore_nice;
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};
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static struct dbs_tuners dbs_tuners_ins = {
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.up_threshold = DEF_FREQUENCY_UP_THRESHOLD,
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.ignore_nice = 0,
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};
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static inline cputime64_t get_cpu_idle_time(unsigned int cpu)
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{
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cputime64_t retval;
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retval = cputime64_add(kstat_cpu(cpu).cpustat.idle,
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kstat_cpu(cpu).cpustat.iowait);
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if (dbs_tuners_ins.ignore_nice)
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retval = cputime64_add(retval, kstat_cpu(cpu).cpustat.nice);
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return retval;
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}
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/************************** sysfs interface ************************/
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static ssize_t show_sampling_rate_max(struct cpufreq_policy *policy, char *buf)
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{
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return sprintf (buf, "%u\n", MAX_SAMPLING_RATE);
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}
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static ssize_t show_sampling_rate_min(struct cpufreq_policy *policy, char *buf)
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{
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return sprintf (buf, "%u\n", MIN_SAMPLING_RATE);
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}
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#define define_one_ro(_name) \
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static struct freq_attr _name = \
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__ATTR(_name, 0444, show_##_name, NULL)
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define_one_ro(sampling_rate_max);
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define_one_ro(sampling_rate_min);
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/* cpufreq_ondemand Governor Tunables */
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#define show_one(file_name, object) \
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static ssize_t show_##file_name \
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(struct cpufreq_policy *unused, char *buf) \
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{ \
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return sprintf(buf, "%u\n", dbs_tuners_ins.object); \
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}
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show_one(sampling_rate, sampling_rate);
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show_one(up_threshold, up_threshold);
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show_one(ignore_nice_load, ignore_nice);
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static ssize_t store_sampling_rate(struct cpufreq_policy *unused,
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const char *buf, size_t count)
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{
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unsigned int input;
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int ret;
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ret = sscanf(buf, "%u", &input);
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mutex_lock(&dbs_mutex);
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if (ret != 1 || input > MAX_SAMPLING_RATE || input < MIN_SAMPLING_RATE) {
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mutex_unlock(&dbs_mutex);
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return -EINVAL;
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}
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dbs_tuners_ins.sampling_rate = input;
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mutex_unlock(&dbs_mutex);
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return count;
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}
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static ssize_t store_up_threshold(struct cpufreq_policy *unused,
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const char *buf, size_t count)
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{
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unsigned int input;
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int ret;
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ret = sscanf(buf, "%u", &input);
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mutex_lock(&dbs_mutex);
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if (ret != 1 || input > MAX_FREQUENCY_UP_THRESHOLD ||
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input < MIN_FREQUENCY_UP_THRESHOLD) {
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mutex_unlock(&dbs_mutex);
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return -EINVAL;
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}
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dbs_tuners_ins.up_threshold = input;
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mutex_unlock(&dbs_mutex);
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return count;
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}
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static ssize_t store_ignore_nice_load(struct cpufreq_policy *policy,
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const char *buf, size_t count)
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{
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unsigned int input;
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int ret;
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unsigned int j;
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ret = sscanf(buf, "%u", &input);
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if ( ret != 1 )
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return -EINVAL;
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if ( input > 1 )
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input = 1;
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mutex_lock(&dbs_mutex);
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if ( input == dbs_tuners_ins.ignore_nice ) { /* nothing to do */
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mutex_unlock(&dbs_mutex);
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return count;
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}
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dbs_tuners_ins.ignore_nice = input;
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/* we need to re-evaluate prev_cpu_idle */
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for_each_online_cpu(j) {
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struct cpu_dbs_info_s *dbs_info;
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dbs_info = &per_cpu(cpu_dbs_info, j);
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dbs_info->prev_cpu_idle = get_cpu_idle_time(j);
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dbs_info->prev_cpu_wall = get_jiffies_64();
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}
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mutex_unlock(&dbs_mutex);
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return count;
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}
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#define define_one_rw(_name) \
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static struct freq_attr _name = \
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__ATTR(_name, 0644, show_##_name, store_##_name)
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define_one_rw(sampling_rate);
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define_one_rw(up_threshold);
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define_one_rw(ignore_nice_load);
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static struct attribute * dbs_attributes[] = {
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&sampling_rate_max.attr,
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&sampling_rate_min.attr,
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&sampling_rate.attr,
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&up_threshold.attr,
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&ignore_nice_load.attr,
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NULL
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};
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static struct attribute_group dbs_attr_group = {
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.attrs = dbs_attributes,
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.name = "ondemand",
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};
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/************************** sysfs end ************************/
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static void dbs_check_cpu(struct cpu_dbs_info_s *this_dbs_info)
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{
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unsigned int idle_ticks, total_ticks;
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unsigned int load;
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cputime64_t cur_jiffies;
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struct cpufreq_policy *policy;
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unsigned int j;
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if (!this_dbs_info->enable)
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return;
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policy = this_dbs_info->cur_policy;
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cur_jiffies = jiffies64_to_cputime64(get_jiffies_64());
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total_ticks = (unsigned int) cputime64_sub(cur_jiffies,
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this_dbs_info->prev_cpu_wall);
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this_dbs_info->prev_cpu_wall = cur_jiffies;
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if (!total_ticks)
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return;
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/*
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* Every sampling_rate, we check, if current idle time is less
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* than 20% (default), then we try to increase frequency
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* Every sampling_rate, we look for a the lowest
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* frequency which can sustain the load while keeping idle time over
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* 30%. If such a frequency exist, we try to decrease to this frequency.
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*
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* Any frequency increase takes it to the maximum frequency.
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* Frequency reduction happens at minimum steps of
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* 5% (default) of current frequency
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*/
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/* Get Idle Time */
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idle_ticks = UINT_MAX;
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for_each_cpu_mask(j, policy->cpus) {
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cputime64_t total_idle_ticks;
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unsigned int tmp_idle_ticks;
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struct cpu_dbs_info_s *j_dbs_info;
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j_dbs_info = &per_cpu(cpu_dbs_info, j);
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total_idle_ticks = get_cpu_idle_time(j);
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tmp_idle_ticks = (unsigned int) cputime64_sub(total_idle_ticks,
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j_dbs_info->prev_cpu_idle);
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j_dbs_info->prev_cpu_idle = total_idle_ticks;
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if (tmp_idle_ticks < idle_ticks)
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idle_ticks = tmp_idle_ticks;
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}
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load = (100 * (total_ticks - idle_ticks)) / total_ticks;
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/* Check for frequency increase */
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if (load > dbs_tuners_ins.up_threshold) {
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/* if we are already at full speed then break out early */
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if (policy->cur == policy->max)
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return;
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__cpufreq_driver_target(policy, policy->max,
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CPUFREQ_RELATION_H);
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return;
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}
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/* Check for frequency decrease */
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/* if we cannot reduce the frequency anymore, break out early */
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if (policy->cur == policy->min)
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return;
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/*
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* The optimal frequency is the frequency that is the lowest that
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* can support the current CPU usage without triggering the up
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* policy. To be safe, we focus 10 points under the threshold.
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*/
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if (load < (dbs_tuners_ins.up_threshold - 10)) {
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unsigned int freq_next;
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freq_next = (policy->cur * load) /
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(dbs_tuners_ins.up_threshold - 10);
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__cpufreq_driver_target(policy, freq_next, CPUFREQ_RELATION_L);
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}
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}
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static void do_dbs_timer(void *data)
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{
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unsigned int cpu = smp_processor_id();
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struct cpu_dbs_info_s *dbs_info = &per_cpu(cpu_dbs_info, cpu);
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if (!dbs_info->enable)
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return;
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lock_cpu_hotplug();
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dbs_check_cpu(dbs_info);
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unlock_cpu_hotplug();
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queue_delayed_work_on(cpu, kondemand_wq, &dbs_info->work,
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usecs_to_jiffies(dbs_tuners_ins.sampling_rate));
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}
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static inline void dbs_timer_init(unsigned int cpu)
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{
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struct cpu_dbs_info_s *dbs_info = &per_cpu(cpu_dbs_info, cpu);
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INIT_WORK(&dbs_info->work, do_dbs_timer, 0);
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queue_delayed_work_on(cpu, kondemand_wq, &dbs_info->work,
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usecs_to_jiffies(dbs_tuners_ins.sampling_rate));
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return;
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}
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static inline void dbs_timer_exit(struct cpu_dbs_info_s *dbs_info)
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{
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dbs_info->enable = 0;
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cancel_delayed_work(&dbs_info->work);
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flush_workqueue(kondemand_wq);
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}
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static int cpufreq_governor_dbs(struct cpufreq_policy *policy,
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unsigned int event)
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{
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unsigned int cpu = policy->cpu;
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struct cpu_dbs_info_s *this_dbs_info;
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unsigned int j;
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this_dbs_info = &per_cpu(cpu_dbs_info, cpu);
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switch (event) {
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case CPUFREQ_GOV_START:
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if ((!cpu_online(cpu)) || (!policy->cur))
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return -EINVAL;
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if (policy->cpuinfo.transition_latency >
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(TRANSITION_LATENCY_LIMIT * 1000)) {
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printk(KERN_WARNING "ondemand governor failed to load "
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"due to too long transition latency\n");
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return -EINVAL;
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}
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if (this_dbs_info->enable) /* Already enabled */
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break;
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mutex_lock(&dbs_mutex);
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dbs_enable++;
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if (dbs_enable == 1) {
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kondemand_wq = create_workqueue("kondemand");
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if (!kondemand_wq) {
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printk(KERN_ERR "Creation of kondemand failed\n");
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dbs_enable--;
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mutex_unlock(&dbs_mutex);
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return -ENOSPC;
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}
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}
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for_each_cpu_mask(j, policy->cpus) {
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struct cpu_dbs_info_s *j_dbs_info;
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j_dbs_info = &per_cpu(cpu_dbs_info, j);
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j_dbs_info->cur_policy = policy;
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j_dbs_info->prev_cpu_idle = get_cpu_idle_time(j);
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j_dbs_info->prev_cpu_wall = get_jiffies_64();
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}
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this_dbs_info->enable = 1;
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sysfs_create_group(&policy->kobj, &dbs_attr_group);
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/*
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* Start the timerschedule work, when this governor
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* is used for first time
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*/
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if (dbs_enable == 1) {
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unsigned int latency;
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/* policy latency is in nS. Convert it to uS first */
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latency = policy->cpuinfo.transition_latency / 1000;
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if (latency == 0)
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latency = 1;
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def_sampling_rate = latency *
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DEF_SAMPLING_RATE_LATENCY_MULTIPLIER;
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if (def_sampling_rate < MIN_STAT_SAMPLING_RATE)
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def_sampling_rate = MIN_STAT_SAMPLING_RATE;
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dbs_tuners_ins.sampling_rate = def_sampling_rate;
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}
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dbs_timer_init(policy->cpu);
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mutex_unlock(&dbs_mutex);
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break;
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case CPUFREQ_GOV_STOP:
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mutex_lock(&dbs_mutex);
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dbs_timer_exit(this_dbs_info);
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sysfs_remove_group(&policy->kobj, &dbs_attr_group);
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dbs_enable--;
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if (dbs_enable == 0)
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destroy_workqueue(kondemand_wq);
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mutex_unlock(&dbs_mutex);
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break;
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case CPUFREQ_GOV_LIMITS:
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mutex_lock(&dbs_mutex);
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if (policy->max < this_dbs_info->cur_policy->cur)
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__cpufreq_driver_target(this_dbs_info->cur_policy,
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policy->max,
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CPUFREQ_RELATION_H);
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else if (policy->min > this_dbs_info->cur_policy->cur)
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__cpufreq_driver_target(this_dbs_info->cur_policy,
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policy->min,
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CPUFREQ_RELATION_L);
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mutex_unlock(&dbs_mutex);
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break;
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}
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return 0;
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}
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static struct cpufreq_governor cpufreq_gov_dbs = {
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.name = "ondemand",
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.governor = cpufreq_governor_dbs,
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.owner = THIS_MODULE,
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};
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static int __init cpufreq_gov_dbs_init(void)
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{
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return cpufreq_register_governor(&cpufreq_gov_dbs);
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}
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static void __exit cpufreq_gov_dbs_exit(void)
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{
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cpufreq_unregister_governor(&cpufreq_gov_dbs);
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}
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MODULE_AUTHOR("Venkatesh Pallipadi <venkatesh.pallipadi@intel.com>");
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MODULE_AUTHOR("Alexey Starikovskiy <alexey.y.starikovskiy@intel.com>");
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MODULE_DESCRIPTION("'cpufreq_ondemand' - A dynamic cpufreq governor for "
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"Low Latency Frequency Transition capable processors");
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MODULE_LICENSE("GPL");
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module_init(cpufreq_gov_dbs_init);
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module_exit(cpufreq_gov_dbs_exit);
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