drivers/cpuidle/governors/teo.c - kernel/common - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * Timer events oriented CPU idle governor
  *
  * Copyright (C) 2018 - 2021 Intel Corporation
  * Author: Rafael J. Wysocki <[email protected]>
  */

 /**
  * DOC: teo-description
  *
  * The idea of this governor is based on the observation that on many systems
  * timer events are two or more orders of magnitude more frequent than any
  * other interrupts, so they are likely to be the most significant cause of CPU
  * wakeups from idle states.  Moreover, information about what happened in the
  * (relatively recent) past can be used to estimate whether or not the deepest
  * idle state with target residency within the (known) time till the closest
  * timer event, referred to as the sleep length, is likely to be suitable for
  * the upcoming CPU idle period and, if not, then which of the shallower idle
  * states to choose instead of it.
  *
  * Of course, non-timer wakeup sources are more important in some use cases
  * which can be covered by taking a few most recent idle time intervals of the
  * CPU into account.  However, even in that context it is not necessary to
  * consider idle duration values greater than the sleep length, because the
  * closest timer will ultimately wake up the CPU anyway unless it is woken up
  * earlier.
  *
  * Thus this governor estimates whether or not the prospective idle duration of
  * a CPU is likely to be significantly shorter than the sleep length and selects
  * an idle state for it accordingly.
  *
  * The computations carried out by this governor are based on using bins whose
  * boundaries are aligned with the target residency parameter values of the CPU
  * idle states provided by the %CPUIdle driver in the ascending order.  That is,
  * the first bin spans from 0 up to, but not including, the target residency of
  * the second idle state (idle state 1), the second bin spans from the target
  * residency of idle state 1 up to, but not including, the target residency of
  * idle state 2, the third bin spans from the target residency of idle state 2
  * up to, but not including, the target residency of idle state 3 and so on.
  * The last bin spans from the target residency of the deepest idle state
  * supplied by the driver to infinity.
  *
  * Two metrics called "hits" and "intercepts" are associated with each bin.
  * They are updated every time before selecting an idle state for the given CPU
  * in accordance with what happened last time.
  *
  * The "hits" metric reflects the relative frequency of situations in which the
  * sleep length and the idle duration measured after CPU wakeup fall into the
  * same bin (that is, the CPU appears to wake up "on time" relative to the sleep
  * length).  In turn, the "intercepts" metric reflects the relative frequency of
  * situations in which the measured idle duration is so much shorter than the
  * sleep length that the bin it falls into corresponds to an idle state
  * shallower than the one whose bin is fallen into by the sleep length (these
  * situations are referred to as "intercepts" below).
  *
  * In addition to the metrics described above, the governor counts recent
  * intercepts (that is, intercepts that have occurred during the last
  * %NR_RECENT invocations of it for the given CPU) for each bin.
  *
  * In order to select an idle state for a CPU, the governor takes the following
  * steps (modulo the possible latency constraint that must be taken into account
  * too):
  *
  * 1. Find the deepest CPU idle state whose target residency does not exceed
  *    the current sleep length (the candidate idle state) and compute 3 sums as
  *    follows:
  *
  *    - The sum of the "hits" and "intercepts" metrics for the candidate state
  *      and all of the deeper idle states (it represents the cases in which the
  *      CPU was idle long enough to avoid being intercepted if the sleep length
  *      had been equal to the current one).
  *
  *    - The sum of the "intercepts" metrics for all of the idle states shallower
  *      than the candidate one (it represents the cases in which the CPU was not
  *      idle long enough to avoid being intercepted if the sleep length had been
  *      equal to the current one).
  *
  *    - The sum of the numbers of recent intercepts for all of the idle states
  *      shallower than the candidate one.
  *
  * 2. If the second sum is greater than the first one or the third sum is
  *    greater than %NR_RECENT / 2, the CPU is likely to wake up early, so look
  *    for an alternative idle state to select.
  *
  *    - Traverse the idle states shallower than the candidate one in the
  *      descending order.
  *
  *    - For each of them compute the sum of the "intercepts" metrics and the sum
  *      of the numbers of recent intercepts over all of the idle states between
  *      it and the candidate one (including the former and excluding the
  *      latter).
  *
  *    - If each of these sums that needs to be taken into account (because the
  *      check related to it has indicated that the CPU is likely to wake up
  *      early) is greater than a half of the corresponding sum computed in step
  *      1 (which means that the target residency of the state in question had
  *      not exceeded the idle duration in over a half of the relevant cases),
  *      select the given idle state instead of the candidate one.
  *
  * 3. By default, select the candidate state.
  */

 #include <linux/cpuidle.h>
 #include <linux/jiffies.h>
 #include <linux/kernel.h>
 #include <linux/sched/clock.h>
 #include <linux/tick.h>

 /*
  * The PULSE value is added to metrics when they grow and the DECAY_SHIFT value
  * is used for decreasing metrics on a regular basis.
  */
 #define PULSE		1024
 #define DECAY_SHIFT	3

 /*
  * Number of the most recent idle duration values to take into consideration for
  * the detection of recent early wakeup patterns.
  */
 #define NR_RECENT	9

 /**
  * struct teo_bin - Metrics used by the TEO cpuidle governor.
  * @intercepts: The "intercepts" metric.
  * @hits: The "hits" metric.
  * @recent: The number of recent "intercepts".
  */
 struct teo_bin {
 	unsigned int intercepts;
 	unsigned int hits;
 	unsigned int recent;
 };

 /**
  * struct teo_cpu - CPU data used by the TEO cpuidle governor.
  * @time_span_ns: Time between idle state selection and post-wakeup update.
  * @sleep_length_ns: Time till the closest timer event (at the selection time).
  * @state_bins: Idle state data bins for this CPU.
  * @total: Grand total of the "intercepts" and "hits" mertics for all bins.
  * @next_recent_idx: Index of the next @recent_idx entry to update.
  * @recent_idx: Indices of bins corresponding to recent "intercepts".
  */
 struct teo_cpu {
 	s64 time_span_ns;
 	s64 sleep_length_ns;
 	struct teo_bin state_bins[CPUIDLE_STATE_MAX];
 	unsigned int total;
 	int next_recent_idx;
 	int recent_idx[NR_RECENT];
 };

 static DEFINE_PER_CPU(struct teo_cpu, teo_cpus);

 /**
  * teo_update - Update CPU metrics after wakeup.
  * @drv: cpuidle driver containing state data.
  * @dev: Target CPU.
  */
 static void teo_update(struct cpuidle_driver *drv, struct cpuidle_device *dev)
 {
 	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);
 	int i, idx_timer = 0, idx_duration = 0;
 	u64 measured_ns;

 	if (cpu_data->time_span_ns >= cpu_data->sleep_length_ns) {
 		/*
 		 * One of the safety nets has triggered or the wakeup was close
 		 * enough to the closest timer event expected at the idle state
 		 * selection time to be discarded.
 		 */
 		measured_ns = U64_MAX;
 	} else {
 		u64 lat_ns = drv->states[dev->last_state_idx].exit_latency_ns;

 		/*
 		 * The computations below are to determine whether or not the
 		 * (saved) time till the next timer event and the measured idle
 		 * duration fall into the same "bin", so use last_residency_ns
 		 * for that instead of time_span_ns which includes the cpuidle
 		 * overhead.
 		 */
 		measured_ns = dev->last_residency_ns;
 		/*
 		 * The delay between the wakeup and the first instruction
 		 * executed by the CPU is not likely to be worst-case every
 		 * time, so take 1/2 of the exit latency as a very rough
 		 * approximation of the average of it.
 		 */
 		if (measured_ns >= lat_ns)
 			measured_ns -= lat_ns / 2;
 		else
 			measured_ns /= 2;
 	}

 	cpu_data->total = 0;

 	/*
 	 * Decay the "hits" and "intercepts" metrics for all of the bins and
 	 * find the bins that the sleep length and the measured idle duration
 	 * fall into.
 	 */
 	for (i = 0; i < drv->state_count; i++) {
 		s64 target_residency_ns = drv->states[i].target_residency_ns;
 		struct teo_bin *bin = &cpu_data->state_bins[i];

 		bin->hits -= bin->hits >> DECAY_SHIFT;
 		bin->intercepts -= bin->intercepts >> DECAY_SHIFT;

 		cpu_data->total += bin->hits + bin->intercepts;

 		if (target_residency_ns <= cpu_data->sleep_length_ns) {
 			idx_timer = i;
 			if (target_residency_ns <= measured_ns)
 				idx_duration = i;
 		}
 	}

 	i = cpu_data->next_recent_idx++;
 	if (cpu_data->next_recent_idx >= NR_RECENT)
 		cpu_data->next_recent_idx = 0;

 	if (cpu_data->recent_idx[i] >= 0)
 		cpu_data->state_bins[cpu_data->recent_idx[i]].recent--;

 	/*
 	 * If the measured idle duration falls into the same bin as the sleep
 	 * length, this is a "hit", so update the "hits" metric for that bin.
 	 * Otherwise, update the "intercepts" metric for the bin fallen into by
 	 * the measured idle duration.
 	 */
 	if (idx_timer == idx_duration) {
 		cpu_data->state_bins[idx_timer].hits += PULSE;
 		cpu_data->recent_idx[i] = -1;
 	} else {
 		cpu_data->state_bins[idx_duration].intercepts += PULSE;
 		cpu_data->state_bins[idx_duration].recent++;
 		cpu_data->recent_idx[i] = idx_duration;
 	}

 	cpu_data->total += PULSE;
 }

 static bool teo_time_ok(u64 interval_ns)
 {
 	return !tick_nohz_tick_stopped() || interval_ns >= TICK_NSEC;
 }

 static s64 teo_middle_of_bin(int idx, struct cpuidle_driver *drv)
 {
 	return (drv->states[idx].target_residency_ns +
 		drv->states[idx+1].target_residency_ns) / 2;
 }

 /**
  * teo_find_shallower_state - Find shallower idle state matching given duration.
  * @drv: cpuidle driver containing state data.
  * @dev: Target CPU.
  * @state_idx: Index of the capping idle state.
  * @duration_ns: Idle duration value to match.
  */
 static int teo_find_shallower_state(struct cpuidle_driver *drv,
 				    struct cpuidle_device *dev, int state_idx,
 				    s64 duration_ns)
 {
 	int i;

 	for (i = state_idx - 1; i >= 0; i--) {
 		if (dev->states_usage[i].disable)
 			continue;

 		state_idx = i;
 		if (drv->states[i].target_residency_ns <= duration_ns)
 			break;
 	}
 	return state_idx;
 }

 /**
  * teo_select - Selects the next idle state to enter.
  * @drv: cpuidle driver containing state data.
  * @dev: Target CPU.
  * @stop_tick: Indication on whether or not to stop the scheduler tick.
  */
 static int teo_select(struct cpuidle_driver *drv, struct cpuidle_device *dev,
 		      bool *stop_tick)
 {
 	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);
 	s64 latency_req = cpuidle_governor_latency_req(dev->cpu);
 	unsigned int idx_intercept_sum = 0;
 	unsigned int intercept_sum = 0;
 	unsigned int idx_recent_sum = 0;
 	unsigned int recent_sum = 0;
 	unsigned int idx_hit_sum = 0;
 	unsigned int hit_sum = 0;
 	int constraint_idx = 0;
 	int idx0 = 0, idx = -1;
 	bool alt_intercepts, alt_recent;
 	ktime_t delta_tick;
 	s64 duration_ns;
 	int i;

 	if (dev->last_state_idx >= 0) {
 		teo_update(drv, dev);
 		dev->last_state_idx = -1;
 	}

 	cpu_data->time_span_ns = local_clock();

 	duration_ns = tick_nohz_get_sleep_length(&delta_tick);
 	cpu_data->sleep_length_ns = duration_ns;

 	/* Check if there is any choice in the first place. */
 	if (drv->state_count < 2) {
 		idx = 0;
 		goto end;
 	}
 	if (!dev->states_usage[0].disable) {
 		idx = 0;
 		if (drv->states[1].target_residency_ns > duration_ns)
 			goto end;
 	}

 	/*
 	 * Find the deepest idle state whose target residency does not exceed
 	 * the current sleep length and the deepest idle state not deeper than
 	 * the former whose exit latency does not exceed the current latency
 	 * constraint.  Compute the sums of metrics for early wakeup pattern
 	 * detection.
 	 */
 	for (i = 1; i < drv->state_count; i++) {
 		struct teo_bin *prev_bin = &cpu_data->state_bins[i-1];
 		struct cpuidle_state *s = &drv->states[i];

 		/*
 		 * Update the sums of idle state mertics for all of the states
 		 * shallower than the current one.
 		 */
 		intercept_sum += prev_bin->intercepts;
 		hit_sum += prev_bin->hits;
 		recent_sum += prev_bin->recent;

 		if (dev->states_usage[i].disable)
 			continue;

 		if (idx < 0) {
 			idx = i; /* first enabled state */
 			idx0 = i;
 		}

 		if (s->target_residency_ns > duration_ns)
 			break;

 		idx = i;

 		if (s->exit_latency_ns <= latency_req)
 			constraint_idx = i;

 		idx_intercept_sum = intercept_sum;
 		idx_hit_sum = hit_sum;
 		idx_recent_sum = recent_sum;
 	}

 	/* Avoid unnecessary overhead. */
 	if (idx < 0) {
 		idx = 0; /* No states enabled, must use 0. */
 		goto end;
 	} else if (idx == idx0) {
 		goto end;
 	}

 	/*
 	 * If the sum of the intercepts metric for all of the idle states
 	 * shallower than the current candidate one (idx) is greater than the
 	 * sum of the intercepts and hits metrics for the candidate state and
 	 * all of the deeper states, or the sum of the numbers of recent
 	 * intercepts over all of the states shallower than the candidate one
 	 * is greater than a half of the number of recent events taken into
 	 * account, the CPU is likely to wake up early, so find an alternative
 	 * idle state to select.
 	 */
 	alt_intercepts = 2 * idx_intercept_sum > cpu_data->total - idx_hit_sum;
 	alt_recent = idx_recent_sum > NR_RECENT / 2;
 	if (alt_recent || alt_intercepts) {
 		s64 first_suitable_span_ns = duration_ns;
 		int first_suitable_idx = idx;

 		/*
 		 * Look for the deepest idle state whose target residency had
 		 * not exceeded the idle duration in over a half of the relevant
 		 * cases (both with respect to intercepts overall and with
 		 * respect to the recent intercepts only) in the past.
 		 *
 		 * Take the possible latency constraint and duration limitation
 		 * present if the tick has been stopped already into account.
 		 */
 		intercept_sum = 0;
 		recent_sum = 0;

 		for (i = idx - 1; i >= 0; i--) {
 			struct teo_bin *bin = &cpu_data->state_bins[i];
 			s64 span_ns;

 			intercept_sum += bin->intercepts;
 			recent_sum += bin->recent;

 			span_ns = teo_middle_of_bin(i, drv);

 			if ((!alt_recent || 2 * recent_sum > idx_recent_sum) &&
 			    (!alt_intercepts ||
 			     2 * intercept_sum > idx_intercept_sum)) {
 				if (teo_time_ok(span_ns) &&
 				    !dev->states_usage[i].disable) {
 					idx = i;
 					duration_ns = span_ns;
 				} else {
 					/*
 					 * The current state is too shallow or
 					 * disabled, so take the first enabled
 					 * deeper state with suitable time span.
 					 */
 					idx = first_suitable_idx;
 					duration_ns = first_suitable_span_ns;
 				}
 				break;
 			}

 			if (dev->states_usage[i].disable)
 				continue;

 			if (!teo_time_ok(span_ns)) {
 				/*
 				 * The current state is too shallow, but if an
 				 * alternative candidate state has been found,
 				 * it may still turn out to be a better choice.
 				 */
 				if (first_suitable_idx != idx)
 					continue;

 				break;
 			}

 			first_suitable_span_ns = span_ns;
 			first_suitable_idx = i;
 		}
 	}

 	/*
 	 * If there is a latency constraint, it may be necessary to select an
 	 * idle state shallower than the current candidate one.
 	 */
 	if (idx > constraint_idx)
 		idx = constraint_idx;

 end:
 	/*
 	 * Don't stop the tick if the selected state is a polling one or if the
 	 * expected idle duration is shorter than the tick period length.
 	 */
 	if (((drv->states[idx].flags & CPUIDLE_FLAG_POLLING) ||
 	    duration_ns < TICK_NSEC) && !tick_nohz_tick_stopped()) {
 		*stop_tick = false;

 		/*
 		 * The tick is not going to be stopped, so if the target
 		 * residency of the state to be returned is not within the time
 		 * till the closest timer including the tick, try to correct
 		 * that.
 		 */
 		if (idx > idx0 &&
 		    drv->states[idx].target_residency_ns > delta_tick)
 			idx = teo_find_shallower_state(drv, dev, idx, delta_tick);
 	}

 	return idx;
 }

 /**
  * teo_reflect - Note that governor data for the CPU need to be updated.
  * @dev: Target CPU.
  * @state: Entered state.
  */
 static void teo_reflect(struct cpuidle_device *dev, int state)
 {
 	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);

 	dev->last_state_idx = state;
 	/*
 	 * If the wakeup was not "natural", but triggered by one of the safety
 	 * nets, assume that the CPU might have been idle for the entire sleep
 	 * length time.
 	 */
 	if (dev->poll_time_limit ||
 	    (tick_nohz_idle_got_tick() && cpu_data->sleep_length_ns > TICK_NSEC)) {
 		dev->poll_time_limit = false;
 		cpu_data->time_span_ns = cpu_data->sleep_length_ns;
 	} else {
 		cpu_data->time_span_ns = local_clock() - cpu_data->time_span_ns;
 	}
 }

 /**
  * teo_enable_device - Initialize the governor's data for the target CPU.
  * @drv: cpuidle driver (not used).
  * @dev: Target CPU.
  */
 static int teo_enable_device(struct cpuidle_driver *drv,
 			     struct cpuidle_device *dev)
 {
 	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);
 	int i;

 	memset(cpu_data, 0, sizeof(*cpu_data));

 	for (i = 0; i < NR_RECENT; i++)
 		cpu_data->recent_idx[i] = -1;

 	return 0;
 }

 static struct cpuidle_governor teo_governor = {
 	.name =		"teo",
 	.rating =	19,
 	.enable =	teo_enable_device,
 	.select =	teo_select,
 	.reflect =	teo_reflect,
 };

 static int __init teo_governor_init(void)
 {
 	return cpuidle_register_governor(&teo_governor);
 }

 postcore_initcall(teo_governor_init);
	// SPDX-License-Identifier: GPL-2.0
	/*
	* Timer events oriented CPU idle governor
	*
	* Copyright (C) 2018 - 2021 Intel Corporation
	* Author: Rafael J. Wysocki <[email protected]>
	*/

	/**
	* DOC: teo-description
	*
	* The idea of this governor is based on the observation that on many systems
	* timer events are two or more orders of magnitude more frequent than any
	* other interrupts, so they are likely to be the most significant cause of CPU
	* wakeups from idle states. Moreover, information about what happened in the
	* (relatively recent) past can be used to estimate whether or not the deepest
	* idle state with target residency within the (known) time till the closest
	* timer event, referred to as the sleep length, is likely to be suitable for
	* the upcoming CPU idle period and, if not, then which of the shallower idle
	* states to choose instead of it.
	*
	* Of course, non-timer wakeup sources are more important in some use cases
	* which can be covered by taking a few most recent idle time intervals of the
	* CPU into account. However, even in that context it is not necessary to
	* consider idle duration values greater than the sleep length, because the
	* closest timer will ultimately wake up the CPU anyway unless it is woken up
	* earlier.
	*
	* Thus this governor estimates whether or not the prospective idle duration of
	* a CPU is likely to be significantly shorter than the sleep length and selects
	* an idle state for it accordingly.
	*
	* The computations carried out by this governor are based on using bins whose
	* boundaries are aligned with the target residency parameter values of the CPU
	* idle states provided by the %CPUIdle driver in the ascending order. That is,
	* the first bin spans from 0 up to, but not including, the target residency of
	* the second idle state (idle state 1), the second bin spans from the target
	* residency of idle state 1 up to, but not including, the target residency of
	* idle state 2, the third bin spans from the target residency of idle state 2
	* up to, but not including, the target residency of idle state 3 and so on.
	* The last bin spans from the target residency of the deepest idle state
	* supplied by the driver to infinity.
	*
	* Two metrics called "hits" and "intercepts" are associated with each bin.
	* They are updated every time before selecting an idle state for the given CPU
	* in accordance with what happened last time.
	*
	* The "hits" metric reflects the relative frequency of situations in which the
	* sleep length and the idle duration measured after CPU wakeup fall into the
	* same bin (that is, the CPU appears to wake up "on time" relative to the sleep
	* length). In turn, the "intercepts" metric reflects the relative frequency of
	* situations in which the measured idle duration is so much shorter than the
	* sleep length that the bin it falls into corresponds to an idle state
	* shallower than the one whose bin is fallen into by the sleep length (these
	* situations are referred to as "intercepts" below).
	*
	* In addition to the metrics described above, the governor counts recent
	* intercepts (that is, intercepts that have occurred during the last
	* %NR_RECENT invocations of it for the given CPU) for each bin.
	*
	* In order to select an idle state for a CPU, the governor takes the following
	* steps (modulo the possible latency constraint that must be taken into account
	* too):
	*
	* 1. Find the deepest CPU idle state whose target residency does not exceed
	* the current sleep length (the candidate idle state) and compute 3 sums as
	* follows:
	*
	* - The sum of the "hits" and "intercepts" metrics for the candidate state
	* and all of the deeper idle states (it represents the cases in which the
	* CPU was idle long enough to avoid being intercepted if the sleep length
	* had been equal to the current one).
	*
	* - The sum of the "intercepts" metrics for all of the idle states shallower
	* than the candidate one (it represents the cases in which the CPU was not
	* idle long enough to avoid being intercepted if the sleep length had been
	* equal to the current one).
	*
	* - The sum of the numbers of recent intercepts for all of the idle states
	* shallower than the candidate one.
	*
	* 2. If the second sum is greater than the first one or the third sum is
	* greater than %NR_RECENT / 2, the CPU is likely to wake up early, so look
	* for an alternative idle state to select.
	*
	* - Traverse the idle states shallower than the candidate one in the
	* descending order.
	*
	* - For each of them compute the sum of the "intercepts" metrics and the sum
	* of the numbers of recent intercepts over all of the idle states between
	* it and the candidate one (including the former and excluding the
	* latter).
	*
	* - If each of these sums that needs to be taken into account (because the
	* check related to it has indicated that the CPU is likely to wake up
	* early) is greater than a half of the corresponding sum computed in step
	* 1 (which means that the target residency of the state in question had
	* not exceeded the idle duration in over a half of the relevant cases),
	* select the given idle state instead of the candidate one.
	*
	* 3. By default, select the candidate state.
	*/

	#include <linux/cpuidle.h>
	#include <linux/jiffies.h>
	#include <linux/kernel.h>
	#include <linux/sched/clock.h>
	#include <linux/tick.h>

	/*
	* The PULSE value is added to metrics when they grow and the DECAY_SHIFT value
	* is used for decreasing metrics on a regular basis.
	*/
	#define PULSE 1024
	#define DECAY_SHIFT 3

	/*
	* Number of the most recent idle duration values to take into consideration for
	* the detection of recent early wakeup patterns.
	*/
	#define NR_RECENT 9

	/**
	* struct teo_bin - Metrics used by the TEO cpuidle governor.
	* @intercepts: The "intercepts" metric.
	* @hits: The "hits" metric.
	* @recent: The number of recent "intercepts".
	*/
	struct teo_bin {
	unsigned int intercepts;
	unsigned int hits;
	unsigned int recent;
	};

	/**
	* struct teo_cpu - CPU data used by the TEO cpuidle governor.
	* @time_span_ns: Time between idle state selection and post-wakeup update.
	* @sleep_length_ns: Time till the closest timer event (at the selection time).
	* @state_bins: Idle state data bins for this CPU.
	* @total: Grand total of the "intercepts" and "hits" mertics for all bins.
	* @next_recent_idx: Index of the next @recent_idx entry to update.
	* @recent_idx: Indices of bins corresponding to recent "intercepts".
	*/
	struct teo_cpu {
	s64 time_span_ns;
	s64 sleep_length_ns;
	struct teo_bin state_bins[CPUIDLE_STATE_MAX];
	unsigned int total;
	int next_recent_idx;
	int recent_idx[NR_RECENT];
	};

	static DEFINE_PER_CPU(struct teo_cpu, teo_cpus);

	/**
	* teo_update - Update CPU metrics after wakeup.
	* @drv: cpuidle driver containing state data.
	* @dev: Target CPU.
	*/
	static void teo_update(struct cpuidle_driver drv, struct cpuidle_device dev)
	{
	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);
	int i, idx_timer = 0, idx_duration = 0;
	u64 measured_ns;

	if (cpu_data->time_span_ns >= cpu_data->sleep_length_ns) {
	/*
	* One of the safety nets has triggered or the wakeup was close
	* enough to the closest timer event expected at the idle state
	* selection time to be discarded.
	*/
	measured_ns = U64_MAX;
	} else {
	u64 lat_ns = drv->states[dev->last_state_idx].exit_latency_ns;

	/*
	* The computations below are to determine whether or not the
	* (saved) time till the next timer event and the measured idle
	* duration fall into the same "bin", so use last_residency_ns
	* for that instead of time_span_ns which includes the cpuidle
	* overhead.
	*/
	measured_ns = dev->last_residency_ns;
	/*
	* The delay between the wakeup and the first instruction
	* executed by the CPU is not likely to be worst-case every
	* time, so take 1/2 of the exit latency as a very rough
	* approximation of the average of it.
	*/
	if (measured_ns >= lat_ns)
	measured_ns -= lat_ns / 2;
	else
	measured_ns /= 2;
	}

	cpu_data->total = 0;

	/*
	* Decay the "hits" and "intercepts" metrics for all of the bins and
	* find the bins that the sleep length and the measured idle duration
	* fall into.
	*/
	for (i = 0; i < drv->state_count; i++) {
	s64 target_residency_ns = drv->states[i].target_residency_ns;
	struct teo_bin *bin = &cpu_data->state_bins[i];

	bin->hits -= bin->hits >> DECAY_SHIFT;
	bin->intercepts -= bin->intercepts >> DECAY_SHIFT;

	cpu_data->total += bin->hits + bin->intercepts;

	if (target_residency_ns <= cpu_data->sleep_length_ns) {
	idx_timer = i;
	if (target_residency_ns <= measured_ns)
	idx_duration = i;
	}
	}

	i = cpu_data->next_recent_idx++;
	if (cpu_data->next_recent_idx >= NR_RECENT)
	cpu_data->next_recent_idx = 0;

	if (cpu_data->recent_idx[i] >= 0)
	cpu_data->state_bins[cpu_data->recent_idx[i]].recent--;

	/*
	* If the measured idle duration falls into the same bin as the sleep
	* length, this is a "hit", so update the "hits" metric for that bin.
	* Otherwise, update the "intercepts" metric for the bin fallen into by
	* the measured idle duration.
	*/
	if (idx_timer == idx_duration) {
	cpu_data->state_bins[idx_timer].hits += PULSE;
	cpu_data->recent_idx[i] = -1;
	} else {
	cpu_data->state_bins[idx_duration].intercepts += PULSE;
	cpu_data->state_bins[idx_duration].recent++;
	cpu_data->recent_idx[i] = idx_duration;
	}

	cpu_data->total += PULSE;
	}

	static bool teo_time_ok(u64 interval_ns)
	{
	return !tick_nohz_tick_stopped() \|\| interval_ns >= TICK_NSEC;
	}

	static s64 teo_middle_of_bin(int idx, struct cpuidle_driver *drv)
	{
	return (drv->states[idx].target_residency_ns +
	drv->states[idx+1].target_residency_ns) / 2;
	}

	/**
	* teo_find_shallower_state - Find shallower idle state matching given duration.
	* @drv: cpuidle driver containing state data.
	* @dev: Target CPU.
	* @state_idx: Index of the capping idle state.
	* @duration_ns: Idle duration value to match.
	*/
	static int teo_find_shallower_state(struct cpuidle_driver *drv,
	struct cpuidle_device *dev, int state_idx,
	s64 duration_ns)
	{
	int i;

	for (i = state_idx - 1; i >= 0; i--) {
	if (dev->states_usage[i].disable)
	continue;

	state_idx = i;
	if (drv->states[i].target_residency_ns <= duration_ns)
	break;
	}
	return state_idx;
	}

	/**
	* teo_select - Selects the next idle state to enter.
	* @drv: cpuidle driver containing state data.
	* @dev: Target CPU.
	* @stop_tick: Indication on whether or not to stop the scheduler tick.
	*/
	static int teo_select(struct cpuidle_driver drv, struct cpuidle_device dev,
	bool *stop_tick)
	{
	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);
	s64 latency_req = cpuidle_governor_latency_req(dev->cpu);
	unsigned int idx_intercept_sum = 0;
	unsigned int intercept_sum = 0;
	unsigned int idx_recent_sum = 0;
	unsigned int recent_sum = 0;
	unsigned int idx_hit_sum = 0;
	unsigned int hit_sum = 0;
	int constraint_idx = 0;
	int idx0 = 0, idx = -1;
	bool alt_intercepts, alt_recent;
	ktime_t delta_tick;
	s64 duration_ns;
	int i;

	if (dev->last_state_idx >= 0) {
	teo_update(drv, dev);
	dev->last_state_idx = -1;
	}

	cpu_data->time_span_ns = local_clock();

	duration_ns = tick_nohz_get_sleep_length(&delta_tick);
	cpu_data->sleep_length_ns = duration_ns;

	/* Check if there is any choice in the first place. */
	if (drv->state_count < 2) {
	idx = 0;
	goto end;
	}
	if (!dev->states_usage[0].disable) {
	idx = 0;
	if (drv->states[1].target_residency_ns > duration_ns)
	goto end;
	}

	/*
	* Find the deepest idle state whose target residency does not exceed
	* the current sleep length and the deepest idle state not deeper than
	* the former whose exit latency does not exceed the current latency
	* constraint. Compute the sums of metrics for early wakeup pattern
	* detection.
	*/
	for (i = 1; i < drv->state_count; i++) {
	struct teo_bin *prev_bin = &cpu_data->state_bins[i-1];
	struct cpuidle_state *s = &drv->states[i];

	/*
	* Update the sums of idle state mertics for all of the states
	* shallower than the current one.
	*/
	intercept_sum += prev_bin->intercepts;
	hit_sum += prev_bin->hits;
	recent_sum += prev_bin->recent;

	if (dev->states_usage[i].disable)
	continue;

	if (idx < 0) {
	idx = i; /* first enabled state */
	idx0 = i;
	}

	if (s->target_residency_ns > duration_ns)
	break;

	idx = i;

	if (s->exit_latency_ns <= latency_req)
	constraint_idx = i;

	idx_intercept_sum = intercept_sum;
	idx_hit_sum = hit_sum;
	idx_recent_sum = recent_sum;
	}

	/* Avoid unnecessary overhead. */
	if (idx < 0) {
	idx = 0; /* No states enabled, must use 0. */
	goto end;
	} else if (idx == idx0) {
	goto end;
	}

	/*
	* If the sum of the intercepts metric for all of the idle states
	* shallower than the current candidate one (idx) is greater than the
	* sum of the intercepts and hits metrics for the candidate state and
	* all of the deeper states, or the sum of the numbers of recent
	* intercepts over all of the states shallower than the candidate one
	* is greater than a half of the number of recent events taken into
	* account, the CPU is likely to wake up early, so find an alternative
	* idle state to select.
	*/
	alt_intercepts = 2 * idx_intercept_sum > cpu_data->total - idx_hit_sum;
	alt_recent = idx_recent_sum > NR_RECENT / 2;
	if (alt_recent \|\| alt_intercepts) {
	s64 first_suitable_span_ns = duration_ns;
	int first_suitable_idx = idx;

	/*
	* Look for the deepest idle state whose target residency had
	* not exceeded the idle duration in over a half of the relevant
	* cases (both with respect to intercepts overall and with
	* respect to the recent intercepts only) in the past.
	*
	* Take the possible latency constraint and duration limitation
	* present if the tick has been stopped already into account.
	*/
	intercept_sum = 0;
	recent_sum = 0;

	for (i = idx - 1; i >= 0; i--) {
	struct teo_bin *bin = &cpu_data->state_bins[i];
	s64 span_ns;

	intercept_sum += bin->intercepts;
	recent_sum += bin->recent;

	span_ns = teo_middle_of_bin(i, drv);

	if ((!alt_recent \|\| 2 * recent_sum > idx_recent_sum) &&
	(!alt_intercepts \|\|
	2 * intercept_sum > idx_intercept_sum)) {
	if (teo_time_ok(span_ns) &&
	!dev->states_usage[i].disable) {
	idx = i;
	duration_ns = span_ns;
	} else {
	/*
	* The current state is too shallow or
	* disabled, so take the first enabled
	* deeper state with suitable time span.
	*/
	idx = first_suitable_idx;
	duration_ns = first_suitable_span_ns;
	}
	break;
	}

	if (dev->states_usage[i].disable)
	continue;

	if (!teo_time_ok(span_ns)) {
	/*
	* The current state is too shallow, but if an
	* alternative candidate state has been found,
	* it may still turn out to be a better choice.
	*/
	if (first_suitable_idx != idx)
	continue;

	break;
	}

	first_suitable_span_ns = span_ns;
	first_suitable_idx = i;
	}
	}

	/*
	* If there is a latency constraint, it may be necessary to select an
	* idle state shallower than the current candidate one.
	*/
	if (idx > constraint_idx)
	idx = constraint_idx;

	end:
	/*
	* Don't stop the tick if the selected state is a polling one or if the
	* expected idle duration is shorter than the tick period length.
	*/
	if (((drv->states[idx].flags & CPUIDLE_FLAG_POLLING) \|\|
	duration_ns < TICK_NSEC) && !tick_nohz_tick_stopped()) {
	*stop_tick = false;

	/*
	* The tick is not going to be stopped, so if the target
	* residency of the state to be returned is not within the time
	* till the closest timer including the tick, try to correct
	* that.
	*/
	if (idx > idx0 &&
	drv->states[idx].target_residency_ns > delta_tick)
	idx = teo_find_shallower_state(drv, dev, idx, delta_tick);
	}

	return idx;
	}

	/**
	* teo_reflect - Note that governor data for the CPU need to be updated.
	* @dev: Target CPU.
	* @state: Entered state.
	*/
	static void teo_reflect(struct cpuidle_device *dev, int state)
	{
	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);

	dev->last_state_idx = state;
	/*
	* If the wakeup was not "natural", but triggered by one of the safety
	* nets, assume that the CPU might have been idle for the entire sleep
	* length time.
	*/
	if (dev->poll_time_limit \|\|
	(tick_nohz_idle_got_tick() && cpu_data->sleep_length_ns > TICK_NSEC)) {
	dev->poll_time_limit = false;
	cpu_data->time_span_ns = cpu_data->sleep_length_ns;
	} else {
	cpu_data->time_span_ns = local_clock() - cpu_data->time_span_ns;
	}
	}

	/**
	* teo_enable_device - Initialize the governor's data for the target CPU.
	* @drv: cpuidle driver (not used).
	* @dev: Target CPU.
	*/
	static int teo_enable_device(struct cpuidle_driver *drv,
	struct cpuidle_device *dev)
	{
	struct teo_cpu *cpu_data = per_cpu_ptr(&teo_cpus, dev->cpu);
	int i;

	memset(cpu_data, 0, sizeof(*cpu_data));

	for (i = 0; i < NR_RECENT; i++)
	cpu_data->recent_idx[i] = -1;

	return 0;
	}

	static struct cpuidle_governor teo_governor = {
	.name = "teo",
	.rating = 19,
	.enable = teo_enable_device,
	.select = teo_select,
	.reflect = teo_reflect,
	};

	static int __init teo_governor_init(void)
	{
	return cpuidle_register_governor(&teo_governor);
	}

	postcore_initcall(teo_governor_init);