kernel/microkernel/k_idle.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 1997-2010, 2012-2014 Wind River Systems, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 /**
  * @file
  * @brief Microkernel idle logic
  *
  * Microkernel idle logic. Different forms of idling are performed by the idle
  * task, depending on how the kernel is configured.
  */

 #include <micro_private.h>
 #include <nano_private.h>
 #include <arch/cpu.h>
 #include <toolchain.h>
 #include <sections.h>
 #include <microkernel.h>
 #include <misc/util.h>
 #include <drivers/system_timer.h>

 #if defined(CONFIG_WORKLOAD_MONITOR)

 static unsigned int _k_workload_slice = 0x0;
 static unsigned int _k_workload_ticks = 0x0;
 static unsigned int _k_workload_ref_time = 0x0;
 static unsigned int _k_workload_t0 = 0x0;
 static unsigned int _k_workload_t1 = 0x0;
 static volatile unsigned int _k_workload_n0 = 0x0;
 static volatile unsigned int _k_workload_n1 = 0x0;
 static volatile unsigned int _k_workload_i = 0x0;
 static volatile unsigned int _k_workload_i0 = 0x0;
 static volatile unsigned int _k_workload_delta = 0x0;
 static volatile unsigned int _k_workload_start_time = 0x0;
 static volatile unsigned int _k_workload_end_time = 0x0;

 #ifdef WL_SCALE
 static extern uint32_t _k_workload_scale;
 #endif

 /**
  *
  * @brief Shared code between workload calibration and monitoring
  *
  * Perform idle task "dummy work".
  *
  * This routine increments _k_workload_i and checks it against _k_workload_n1.
  * _k_workload_n1 is updated by the system tick handler, and both are kept
  * in close synchronization.
  *
  * @return N/A
  *
  */
 static void workload_loop(void)
 {
 	volatile int x = 87654321;
 	volatile int y = 4;

 	/* loop never terminates, except during calibration phase */

 	while (++_k_workload_i != _k_workload_n1) {
 		unsigned int s_iCountDummyProc = 0;

 		while (64 != s_iCountDummyProc++) { /* 64 == 2^6 */
 			x >>= y;
 			x <<= y;
 			y++;
 			x >>= y;
 			x <<= y;
 			y--;
 		}
 	}
 }

 /**
  *
  * @brief Calibrate the workload monitoring subsystem
  *
  * Measures the time required to do a fixed amount of "dummy work", and
  * sets default values for the workload measuring period.
  *
  * @return N/A
  *
  */
 void _k_workload_monitor_calibrate(void)
 {
 	_k_workload_n0 = _k_workload_i = 0;
 	_k_workload_n1 = 1000;

 	_k_workload_t0 = sys_cycle_get_32();
 	workload_loop();
 	_k_workload_t1 = sys_cycle_get_32();

 	_k_workload_delta = _k_workload_t1 - _k_workload_t0;
 	_k_workload_i0 = _k_workload_i;
 #ifdef WL_SCALE
 	_k_workload_ref_time =
 		(_k_workload_t1 - _k_workload_t0) >> (_k_workload_scale);
 #else
 	_k_workload_ref_time = (_k_workload_t1 - _k_workload_t0) >> (4 + 6);
 #endif

 	_k_workload_slice = 100;
 	_k_workload_ticks = 100;
 }

 /**
  *
  * @brief Workload monitor tick handler
  *
  * If workload monitor is configured this routine updates the global variables
  * it uses to record the passage of time.
  *
  * @return N/A
  *
  */
 void _k_workload_monitor_update(void)
 {
 	if (--_k_workload_ticks == 0) {
 		_k_workload_t0 = _k_workload_t1;
 		_k_workload_t1 = sys_cycle_get_32();
 		_k_workload_n0 = _k_workload_n1;
 		_k_workload_n1 = _k_workload_i - 1;
 		_k_workload_ticks = _k_workload_slice;
 	}
 }

 /**
  *
  * @brief Workload monitor "start idling" handler
  *
  * Records time when idle task was selected for execution by the microkernel.
  *
  * @return N/A
  */
 void _k_workload_monitor_idle_start(void)
 {
 	_k_workload_start_time = sys_cycle_get_32();
 }

 /**
  *
  * @brief Workload monitor "end idling" handler
  *
  * Records time when idle task was no longer selected for execution by the
  * microkernel, and updates amount of time spent idling.
  *
  * @return N/A
  */
 void _k_workload_monitor_idle_end(void)
 {
 	_k_workload_end_time = sys_cycle_get_32();
 	_k_workload_i += (_k_workload_i0 *
 		(_k_workload_end_time - _k_workload_start_time)) / _k_workload_delta;
 }

 /**
  *
  * @brief Process request to read the processor workload
  *
  * Computes workload, or uses 0 if workload monitoring is not configured.
  *
  * @return N/A
  */
 void _k_workload_get(struct k_args *P)
 {
 	unsigned int k, t;
 	signed int iret;

 	k = (_k_workload_i - _k_workload_n0) * _k_workload_ref_time;
 #ifdef WL_SCALE
 	t = (sys_cycle_get_32() - _k_workload_t0) >> (_k_workload_scale);
 #else
 	t = (sys_cycle_get_32() - _k_workload_t0) >> (4 + 6);
 #endif

 	iret = MSEC_PER_SEC - k / t;

 	/*
 	 * Due to calibration at startup, <iret> could be slightly negative.
 	 * Ensure a negative value is never returned.
 	 */

 	if (iret < 0) {
 		iret = 0;
 	}

 	P->args.u1.rval = iret;
 }
 #else
 void _k_workload_get(struct k_args *P)
 {
 	P->args.u1.rval = 0;
 }

 #endif /* CONFIG_WORKLOAD_MONITOR */


 int task_workload_get(void)
 {
 	struct k_args A;

 	A.Comm = _K_SVC_WORKLOAD_GET;
 	KERNEL_ENTRY(&A);
 	return A.args.u1.rval;
 }


 void sys_workload_time_slice_set(int32_t t)
 {
 #ifdef CONFIG_WORKLOAD_MONITOR
 	if (t < 10) {
 		t = 10;
 	}
 	if (t > 1000) {
 		t = 1000;
 	}
 	_k_workload_slice = t;
 #else
 	ARG_UNUSED(t);
 #endif
 }

 unsigned char _sys_power_save_flag = 1;

 #if defined(CONFIG_ADVANCED_POWER_MANAGEMENT)

 #include <nanokernel.h>
 #include <microkernel/base_api.h>
 #ifdef CONFIG_ADVANCED_IDLE
 #include <advidle.h>
 #endif
 #if defined(CONFIG_TICKLESS_IDLE)
 #include <drivers/system_timer.h>
 #endif

 extern void nano_cpu_set_idle(int32_t ticks);

 #if defined(CONFIG_TICKLESS_IDLE)
 /*
  * Idle time must be this value or higher for timer to go into tickless idle
  * state.
  */
 int32_t _sys_idle_threshold_ticks = CONFIG_TICKLESS_IDLE_THRESH;
 #endif /* CONFIG_TICKLESS_IDLE */

 /**
  *
  * @brief Power management policy when kernel begins idling
  *
  * This routine implements the power management policy based on the time
  * until the timer expires, in system ticks.
  * Routine is invoked from the idle task with interrupts disabled
  *
  * @return N/A
  */
 void _sys_power_save_idle(int32_t ticks)
 {
 #if defined(CONFIG_TICKLESS_IDLE)
 	if ((ticks == TICKS_UNLIMITED) || ticks >= _sys_idle_threshold_ticks) {
 		/*
 		 * Stop generating system timer interrupts until it's time for
 		 * the next scheduled microkernel timer to expire.
 		 */

 		_timer_idle_enter(ticks);
 	}
 #endif /* CONFIG_TICKLESS_IDLE */

 	nano_cpu_set_idle(ticks);
 #ifdef CONFIG_ADVANCED_IDLE
 	/*
 	 * Call the suspend hook function, which checks if the system should
 	 * enter deep sleep or low power state. The function will return a
 	 * non-zero value if system was put in deep sleep or low power state.
 	 * If the time available is too short to go to deep sleep or
 	 * low power state, then the function returns zero immediately
 	 * and we do normal idle processing.
 	 *
 	 * This function can turn off devices without entering deep sleep
 	 * or cpu low power state.  In this case it should return zero to
 	 * let kernel enter its own tickless idle wait.
 	 *
 	 * This function is entered with interrupts disabled. If the function
 	 * returns a non-zero value then it should re-enable interrupts before
 	 * returning.
 	 */
 	if (_sys_soc_suspend(ticks) == 0) {
 		nano_cpu_idle();
 	}
 #else
 	nano_cpu_idle();
 #endif /* CONFIG_ADVANCED_IDLE */
 }

 /**
  *
  * @brief Power management policy when kernel stops idling
  *
  * This routine is invoked when the kernel leaves the idle state.
  * Routine can be modified to wake up other devices.
  * The routine is invoked from interrupt thread, with interrupts disabled.
  *
  * @return N/A
  */
 void _sys_power_save_idle_exit(int32_t ticks)
 {
 #ifdef CONFIG_ADVANCED_IDLE
 	/* Any idle wait based on CPU low power state will be exited by
 	 * interrupt. This function is called within that interrupt's
 	 * context.  _sys_soc_resume() needs to be called here mainly
 	 * to handle exit from CPU low power states. This gives an
 	 * oppurtunity for device states altered in _sys_soc_suspend()
 	 * to be restored before the kernel schedules another thread.
 	 * _sys_soc_resume() is not called from here for deep sleep
 	 * exit. Deep sleep recovery happens at cold boot path.
 	 */
 	_sys_soc_resume();
 #endif
 #ifdef CONFIG_TICKLESS_IDLE
 	if ((ticks == TICKS_UNLIMITED) || ticks >= _sys_idle_threshold_ticks) {
 		/* Resume normal periodic system timer interrupts */

 		_timer_idle_exit();
 	}
 #else
 	ARG_UNUSED(ticks);
 #endif /* CONFIG_TICKLESS_IDLE */
 }

 /**
  *
  * @brief Obtain number of ticks until next timer expires
  *
  * Must be called with interrupts locked to prevent the timer queues from
  * changing.
  *
  * @return Number of ticks until next timer expires.
  *
  */
 static inline int32_t _get_next_timer_expiry(void)
 {
 	uint32_t closest_deadline = (uint32_t)TICKS_UNLIMITED;

 	if (_k_timer_list_head) {
 		closest_deadline = _k_timer_list_head->duration;
 	}

 	return (int32_t)min(closest_deadline, _nano_get_earliest_deadline());
 }
 #endif

 /**
  *
  * @brief Power saving when idle
  *
  * If _sys_power_save_flag is non-zero, this routine keeps the system in a low
  * power state whenever the kernel is idle. If it is zero, this routine will
  * fall through and _k_kernel_idle() will try the next idling mechanism.
  *
  * @return N/A
  *
  */
 static void _power_save(void)
 {
 	if (_sys_power_save_flag) {
 		for (;;) {
 			irq_lock();
 #ifdef CONFIG_ADVANCED_POWER_MANAGEMENT
 			_sys_power_save_idle(_get_next_timer_expiry());
 #else
 			/*
 			 * nano_cpu_idle() is invoked here directly only if APM
 			 * is disabled. Otherwise the microkernel decides
 			 * either to invoke it or to implement advanced idle
 			 * functionality
 			 */

 			nano_cpu_idle();
 #endif
 		}

 		/*
 		 * Code analyzers may complain that _power_save() uses an
 		 * infinite loop unless we indicate that this is intentional
 		 */

 		CODE_UNREACHABLE;
 	}
 }

 /* Specify what work to do when idle task is "busy waiting" */

 #ifdef CONFIG_WORKLOAD_MONITOR
 #define DO_IDLE_WORK()	workload_loop()
 #else
 #define DO_IDLE_WORK()	do { /* do nothing */ } while (0)
 #endif

 /**
  *
  * @brief Microkernel idle task
  *
  * If power save is on, we sleep; if power save is off, we "busy wait".
  *
  * @return N/A
  *
  */
 int _k_kernel_idle(void)
 {
 	_power_save(); /* never returns if power saving is enabled */

 #ifdef CONFIG_BOOT_TIME_MEASUREMENT
 	/* record timestamp when idling begins */

 	extern uint64_t __idle_tsc;

 	__idle_tsc = _NanoTscRead();
 #endif

 	for (;;) {
 		DO_IDLE_WORK();
 	}

 	/*
 	 * Code analyzers may complain that _k_kernel_idle() uses an infinite
 	 * loop unless we indicate that this is intentional
 	 */

 	CODE_UNREACHABLE;
 }
	/*
	* Copyright (c) 1997-2010, 2012-2014 Wind River Systems, Inc.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	/**
	* @file
	* @brief Microkernel idle logic
	*
	* Microkernel idle logic. Different forms of idling are performed by the idle
	* task, depending on how the kernel is configured.
	*/

	#include <micro_private.h>
	#include <nano_private.h>
	#include <arch/cpu.h>
	#include <toolchain.h>
	#include <sections.h>
	#include <microkernel.h>
	#include <misc/util.h>
	#include <drivers/system_timer.h>

	#if defined(CONFIG_WORKLOAD_MONITOR)

	static unsigned int _k_workload_slice = 0x0;
	static unsigned int _k_workload_ticks = 0x0;
	static unsigned int _k_workload_ref_time = 0x0;
	static unsigned int _k_workload_t0 = 0x0;
	static unsigned int _k_workload_t1 = 0x0;
	static volatile unsigned int _k_workload_n0 = 0x0;
	static volatile unsigned int _k_workload_n1 = 0x0;
	static volatile unsigned int _k_workload_i = 0x0;
	static volatile unsigned int _k_workload_i0 = 0x0;
	static volatile unsigned int _k_workload_delta = 0x0;
	static volatile unsigned int _k_workload_start_time = 0x0;
	static volatile unsigned int _k_workload_end_time = 0x0;

	#ifdef WL_SCALE
	static extern uint32_t _k_workload_scale;
	#endif

	/**
	*
	* @brief Shared code between workload calibration and monitoring
	*
	* Perform idle task "dummy work".
	*
	* This routine increments _k_workload_i and checks it against _k_workload_n1.
	* _k_workload_n1 is updated by the system tick handler, and both are kept
	* in close synchronization.
	*
	* @return N/A
	*
	*/
	static void workload_loop(void)
	{
	volatile int x = 87654321;
	volatile int y = 4;

	/* loop never terminates, except during calibration phase */

	while (++_k_workload_i != _k_workload_n1) {
	unsigned int s_iCountDummyProc = 0;

	while (64 != s_iCountDummyProc++) { /* 64 == 2^6 */
	x >>= y;
	x <<= y;
	y++;
	x >>= y;
	x <<= y;
	y--;
	}
	}
	}

	/**
	*
	* @brief Calibrate the workload monitoring subsystem
	*
	* Measures the time required to do a fixed amount of "dummy work", and
	* sets default values for the workload measuring period.
	*
	* @return N/A
	*
	*/
	void _k_workload_monitor_calibrate(void)
	{
	_k_workload_n0 = _k_workload_i = 0;
	_k_workload_n1 = 1000;

	_k_workload_t0 = sys_cycle_get_32();
	workload_loop();
	_k_workload_t1 = sys_cycle_get_32();

	_k_workload_delta = _k_workload_t1 - _k_workload_t0;
	_k_workload_i0 = _k_workload_i;
	#ifdef WL_SCALE
	_k_workload_ref_time =
	(_k_workload_t1 - _k_workload_t0) >> (_k_workload_scale);
	#else
	_k_workload_ref_time = (_k_workload_t1 - _k_workload_t0) >> (4 + 6);
	#endif

	_k_workload_slice = 100;
	_k_workload_ticks = 100;
	}

	/**
	*
	* @brief Workload monitor tick handler
	*
	* If workload monitor is configured this routine updates the global variables
	* it uses to record the passage of time.
	*
	* @return N/A
	*
	*/
	void _k_workload_monitor_update(void)
	{
	if (--_k_workload_ticks == 0) {
	_k_workload_t0 = _k_workload_t1;
	_k_workload_t1 = sys_cycle_get_32();
	_k_workload_n0 = _k_workload_n1;
	_k_workload_n1 = _k_workload_i - 1;
	_k_workload_ticks = _k_workload_slice;
	}
	}

	/**
	*
	* @brief Workload monitor "start idling" handler
	*
	* Records time when idle task was selected for execution by the microkernel.
	*
	* @return N/A
	*/
	void _k_workload_monitor_idle_start(void)
	{
	_k_workload_start_time = sys_cycle_get_32();
	}

	/**
	*
	* @brief Workload monitor "end idling" handler
	*
	* Records time when idle task was no longer selected for execution by the
	* microkernel, and updates amount of time spent idling.
	*
	* @return N/A
	*/
	void _k_workload_monitor_idle_end(void)
	{
	_k_workload_end_time = sys_cycle_get_32();
	_k_workload_i += (_k_workload_i0 *
	(_k_workload_end_time - _k_workload_start_time)) / _k_workload_delta;
	}

	/**
	*
	* @brief Process request to read the processor workload
	*
	* Computes workload, or uses 0 if workload monitoring is not configured.
	*
	* @return N/A
	*/
	void _k_workload_get(struct k_args *P)
	{
	unsigned int k, t;
	signed int iret;

	k = (_k_workload_i - _k_workload_n0) * _k_workload_ref_time;
	#ifdef WL_SCALE
	t = (sys_cycle_get_32() - _k_workload_t0) >> (_k_workload_scale);
	#else
	t = (sys_cycle_get_32() - _k_workload_t0) >> (4 + 6);
	#endif

	iret = MSEC_PER_SEC - k / t;

	/*
	* Due to calibration at startup, <iret> could be slightly negative.
	* Ensure a negative value is never returned.
	*/

	if (iret < 0) {
	iret = 0;
	}

	P->args.u1.rval = iret;
	}
	#else
	void _k_workload_get(struct k_args *P)
	{
	P->args.u1.rval = 0;
	}

	#endif /* CONFIG_WORKLOAD_MONITOR */


	int task_workload_get(void)
	{
	struct k_args A;

	A.Comm = _K_SVC_WORKLOAD_GET;
	KERNEL_ENTRY(&A);
	return A.args.u1.rval;
	}


	void sys_workload_time_slice_set(int32_t t)
	{
	#ifdef CONFIG_WORKLOAD_MONITOR
	if (t < 10) {
	t = 10;
	}
	if (t > 1000) {
	t = 1000;
	}
	_k_workload_slice = t;
	#else
	ARG_UNUSED(t);
	#endif
	}

	unsigned char _sys_power_save_flag = 1;

	#if defined(CONFIG_ADVANCED_POWER_MANAGEMENT)

	#include <nanokernel.h>
	#include <microkernel/base_api.h>
	#ifdef CONFIG_ADVANCED_IDLE
	#include <advidle.h>
	#endif
	#if defined(CONFIG_TICKLESS_IDLE)
	#include <drivers/system_timer.h>
	#endif

	extern void nano_cpu_set_idle(int32_t ticks);

	#if defined(CONFIG_TICKLESS_IDLE)
	/*
	* Idle time must be this value or higher for timer to go into tickless idle
	* state.
	*/
	int32_t _sys_idle_threshold_ticks = CONFIG_TICKLESS_IDLE_THRESH;
	#endif /* CONFIG_TICKLESS_IDLE */

	/**
	*
	* @brief Power management policy when kernel begins idling
	*
	* This routine implements the power management policy based on the time
	* until the timer expires, in system ticks.
	* Routine is invoked from the idle task with interrupts disabled
	*
	* @return N/A
	*/
	void _sys_power_save_idle(int32_t ticks)
	{
	#if defined(CONFIG_TICKLESS_IDLE)
	if ((ticks == TICKS_UNLIMITED) \|\| ticks >= _sys_idle_threshold_ticks) {
	/*
	* Stop generating system timer interrupts until it's time for
	* the next scheduled microkernel timer to expire.
	*/

	_timer_idle_enter(ticks);
	}
	#endif /* CONFIG_TICKLESS_IDLE */

	nano_cpu_set_idle(ticks);
	#ifdef CONFIG_ADVANCED_IDLE
	/*
	* Call the suspend hook function, which checks if the system should
	* enter deep sleep or low power state. The function will return a
	* non-zero value if system was put in deep sleep or low power state.
	* If the time available is too short to go to deep sleep or
	* low power state, then the function returns zero immediately
	* and we do normal idle processing.
	*
	* This function can turn off devices without entering deep sleep
	* or cpu low power state. In this case it should return zero to
	* let kernel enter its own tickless idle wait.
	*
	* This function is entered with interrupts disabled. If the function
	* returns a non-zero value then it should re-enable interrupts before
	* returning.
	*/
	if (_sys_soc_suspend(ticks) == 0) {
	nano_cpu_idle();
	}
	#else
	nano_cpu_idle();
	#endif /* CONFIG_ADVANCED_IDLE */
	}

	/**
	*
	* @brief Power management policy when kernel stops idling
	*
	* This routine is invoked when the kernel leaves the idle state.
	* Routine can be modified to wake up other devices.
	* The routine is invoked from interrupt thread, with interrupts disabled.
	*
	* @return N/A
	*/
	void _sys_power_save_idle_exit(int32_t ticks)
	{
	#ifdef CONFIG_ADVANCED_IDLE
	/* Any idle wait based on CPU low power state will be exited by
	* interrupt. This function is called within that interrupt's
	* context. _sys_soc_resume() needs to be called here mainly
	* to handle exit from CPU low power states. This gives an
	* oppurtunity for device states altered in _sys_soc_suspend()
	* to be restored before the kernel schedules another thread.
	* _sys_soc_resume() is not called from here for deep sleep
	* exit. Deep sleep recovery happens at cold boot path.
	*/
	_sys_soc_resume();
	#endif
	#ifdef CONFIG_TICKLESS_IDLE
	if ((ticks == TICKS_UNLIMITED) \|\| ticks >= _sys_idle_threshold_ticks) {
	/* Resume normal periodic system timer interrupts */

	_timer_idle_exit();
	}
	#else
	ARG_UNUSED(ticks);
	#endif /* CONFIG_TICKLESS_IDLE */
	}

	/**
	*
	* @brief Obtain number of ticks until next timer expires
	*
	* Must be called with interrupts locked to prevent the timer queues from
	* changing.
	*
	* @return Number of ticks until next timer expires.
	*
	*/
	static inline int32_t _get_next_timer_expiry(void)
	{
	uint32_t closest_deadline = (uint32_t)TICKS_UNLIMITED;

	if (_k_timer_list_head) {
	closest_deadline = _k_timer_list_head->duration;
	}

	return (int32_t)min(closest_deadline, _nano_get_earliest_deadline());
	}
	#endif

	/**
	*
	* @brief Power saving when idle
	*
	* If _sys_power_save_flag is non-zero, this routine keeps the system in a low
	* power state whenever the kernel is idle. If it is zero, this routine will
	* fall through and _k_kernel_idle() will try the next idling mechanism.
	*
	* @return N/A
	*
	*/
	static void _power_save(void)
	{
	if (_sys_power_save_flag) {
	for (;;) {
	irq_lock();
	#ifdef CONFIG_ADVANCED_POWER_MANAGEMENT
	_sys_power_save_idle(_get_next_timer_expiry());
	#else
	/*
	* nano_cpu_idle() is invoked here directly only if APM
	* is disabled. Otherwise the microkernel decides
	* either to invoke it or to implement advanced idle
	* functionality
	*/

	nano_cpu_idle();
	#endif
	}

	/*
	* Code analyzers may complain that _power_save() uses an
	* infinite loop unless we indicate that this is intentional
	*/

	CODE_UNREACHABLE;
	}
	}

	/* Specify what work to do when idle task is "busy waiting" */

	#ifdef CONFIG_WORKLOAD_MONITOR
	#define DO_IDLE_WORK() workload_loop()
	#else
	#define DO_IDLE_WORK() do { /* do nothing */ } while (0)
	#endif

	/**
	*
	* @brief Microkernel idle task
	*
	* If power save is on, we sleep; if power save is off, we "busy wait".
	*
	* @return N/A
	*
	*/
	int _k_kernel_idle(void)
	{
	_power_save(); /* never returns if power saving is enabled */

	#ifdef CONFIG_BOOT_TIME_MEASUREMENT
	/* record timestamp when idling begins */

	extern uint64_t __idle_tsc;

	__idle_tsc = _NanoTscRead();
	#endif

	for (;;) {
	DO_IDLE_WORK();
	}

	/*
	* Code analyzers may complain that _k_kernel_idle() uses an infinite
	* loop unless we indicate that this is intentional
	*/

	CODE_UNREACHABLE;
	}