drivers/timer/arcv2_timer0.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2014-2015 Wind River Systems, Inc.
  * Copyright (c) 2018 Synopsys Inc, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */
 #include <zephyr/device.h>
 #include <zephyr/drivers/timer/system_timer.h>
 #include <zephyr/sys_clock.h>
 #include <zephyr/spinlock.h>
 #include <zephyr/arch/arc/v2/aux_regs.h>
 /*
  * note: This implementation assumes Timer0 is present. Be sure
  * to build the ARC CPU with Timer0.
  *
  * If secureshield is present and secure firmware is configured,
  * use secure Timer 0
  */

 #ifdef CONFIG_ARC_SECURE_FIRMWARE

 #undef _ARC_V2_TMR0_COUNT
 #undef _ARC_V2_TMR0_CONTROL
 #undef _ARC_V2_TMR0_LIMIT

 #define _ARC_V2_TMR0_COUNT _ARC_V2_S_TMR0_COUNT
 #define _ARC_V2_TMR0_CONTROL _ARC_V2_S_TMR0_CONTROL
 #define _ARC_V2_TMR0_LIMIT _ARC_V2_S_TMR0_LIMIT
 #define IRQ_TIMER0 DT_IRQN(DT_NODELABEL(sectimer0))

 #else
 #define IRQ_TIMER0 DT_IRQN(DT_NODELABEL(timer0))
 #endif

 #define _ARC_V2_TMR_CTRL_IE 0x1 /* interrupt enable */
 #define _ARC_V2_TMR_CTRL_NH 0x2 /* count only while not halted */
 #define _ARC_V2_TMR_CTRL_W  0x4 /* watchdog mode enable */
 #define _ARC_V2_TMR_CTRL_IP 0x8 /* interrupt pending flag */

 /* Minimum cycles in the future to try to program. */
 #define MIN_DELAY 1024
 /* arc timer has 32 bit, here use 31 bit to avoid the possible
  * overflow,e.g, 0xffffffff + any value will cause overflow
  */
 #define COUNTER_MAX 0x7fffffff
 #define TIMER_STOPPED 0x0
 #define CYC_PER_TICK (sys_clock_hw_cycles_per_sec()	\
 		      / CONFIG_SYS_CLOCK_TICKS_PER_SEC)

 #define MAX_TICKS ((COUNTER_MAX / CYC_PER_TICK) - 1)
 #define MAX_CYCLES (MAX_TICKS * CYC_PER_TICK)

 #define TICKLESS (IS_ENABLED(CONFIG_TICKLESS_KERNEL))

 #define SMP_TIMER_DRIVER (CONFIG_SMP && CONFIG_MP_NUM_CPUS > 1)

 #if defined(CONFIG_TEST)
 const int32_t z_sys_timer_irq_for_test = IRQ_TIMER0;
 #endif
 static struct k_spinlock lock;


 #if SMP_TIMER_DRIVER
 volatile static uint64_t last_time;
 volatile static uint64_t start_time;

 #else
 static uint32_t last_load;


 /*
  * This local variable holds the amount of timer cycles elapsed
  * and it is updated in timer_int_handler and sys_clock_set_timeout().
  *
  * Note:
  *  At an arbitrary point in time the "current" value of the
  *  HW timer is calculated as:
  *
  * t = cycle_counter + elapsed();
  */
 static uint32_t cycle_count;

 /*
  * This local variable holds the amount of elapsed HW cycles
  * that have been announced to the kernel.
  */
 static uint32_t announced_cycles;


 /*
  * This local variable holds the amount of elapsed HW cycles due to
  * timer wraps ('overflows') and is used in the calculation
  * in elapsed() function, as well as in the updates to cycle_count.
  *
  * Note:
  * Each time cycle_count is updated with the value from overflow_cycles,
  * the overflow_cycles must be reset to zero.
  */
 static volatile uint32_t overflow_cycles;
 #endif

 /**
  * @brief Get contents of Timer0 count register
  *
  * @return Current Timer0 count
  */
 static ALWAYS_INLINE uint32_t timer0_count_register_get(void)
 {
 	return z_arc_v2_aux_reg_read(_ARC_V2_TMR0_COUNT);
 }

 /**
  * @brief Set Timer0 count register to the specified value
  */
 static ALWAYS_INLINE void timer0_count_register_set(uint32_t value)
 {
 	z_arc_v2_aux_reg_write(_ARC_V2_TMR0_COUNT, value);
 }

 /**
  * @brief Get contents of Timer0 control register
  *
  * @return Contents of Timer0 control register.
  */
 static ALWAYS_INLINE uint32_t timer0_control_register_get(void)
 {
 	return z_arc_v2_aux_reg_read(_ARC_V2_TMR0_CONTROL);
 }

 /**
  * @brief Set Timer0 control register to the specified value
  */
 static ALWAYS_INLINE void timer0_control_register_set(uint32_t value)
 {
 	z_arc_v2_aux_reg_write(_ARC_V2_TMR0_CONTROL, value);
 }

 /**
  * @brief Get contents of Timer0 limit register
  *
  * @return Contents of Timer0 limit register.
  */
 static ALWAYS_INLINE uint32_t timer0_limit_register_get(void)
 {
 	return z_arc_v2_aux_reg_read(_ARC_V2_TMR0_LIMIT);
 }

 /**
  * @brief Set Timer0 limit register to the specified value
  */
 static ALWAYS_INLINE void timer0_limit_register_set(uint32_t count)
 {
 	z_arc_v2_aux_reg_write(_ARC_V2_TMR0_LIMIT, count);
 }

 #if !SMP_TIMER_DRIVER
 /* This internal function calculates the amount of HW cycles that have
  * elapsed since the last time the absolute HW cycles counter has been
  * updated. 'cycle_count' may be updated either by the ISR, or
  * in sys_clock_set_timeout().
  *
  * Additionally, the function updates the 'overflow_cycles' counter, that
  * holds the amount of elapsed HW cycles due to (possibly) multiple
  * timer wraps (overflows).
  *
  * Prerequisites:
  * - reprogramming of LIMIT must be clearing the COUNT
  * - ISR must be clearing the 'overflow_cycles' counter.
  * - no more than one counter-wrap has occurred between
  *     - the timer reset or the last time the function was called
  *     - and until the current call of the function is completed.
  * - the function is invoked with interrupts disabled.
  */
 static uint32_t elapsed(void)
 {
 	uint32_t val, ctrl;

 	do {
 		val =  timer0_count_register_get();
 		ctrl = timer0_control_register_get();
 	} while (timer0_count_register_get() < val);

 	if (ctrl & _ARC_V2_TMR_CTRL_IP) {
 		overflow_cycles += last_load;
 		/* clear the IP bit of the control register */
 		timer0_control_register_set(_ARC_V2_TMR_CTRL_NH |
 					    _ARC_V2_TMR_CTRL_IE);
 		/* use sw triggered irq to remember the timer irq request
 		 * which may be cleared by the above operation. when elapsed ()
 		 * is called in timer_int_handler, no need to do this.
 		 */
 		if (!z_arc_v2_irq_unit_is_in_isr() ||
 		    z_arc_v2_aux_reg_read(_ARC_V2_ICAUSE) != IRQ_TIMER0) {
 			z_arc_v2_aux_reg_write(_ARC_V2_AUX_IRQ_HINT,
 					       IRQ_TIMER0);
 		}
 	}

 	return val + overflow_cycles;
 }
 #endif

 /**
  * @brief System clock periodic tick handler
  *
  * This routine handles the system clock tick interrupt. It always
  * announces one tick when TICKLESS is not enabled, or multiple ticks
  * when TICKLESS is enabled.
  */
 static void timer_int_handler(const void *unused)
 {
 	ARG_UNUSED(unused);
 	uint32_t dticks;

 #if defined(CONFIG_SMP) && CONFIG_MP_NUM_CPUS > 1
 	uint64_t curr_time;
 	k_spinlock_key_t key;

 	/* clear the IP bit of the control register */
 	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH |
 				    _ARC_V2_TMR_CTRL_IE);
 	key = k_spin_lock(&lock);
 	/* gfrc is the wall clock */
 	curr_time = z_arc_connect_gfrc_read();

 	dticks = (curr_time - last_time) / CYC_PER_TICK;
 	/* last_time should be aligned to ticks */
 	last_time += dticks * CYC_PER_TICK;

 	k_spin_unlock(&lock, key);

 	sys_clock_announce(dticks);
 #else
 	/* timer_int_handler may be triggered by timer irq or
 	 * software helper irq
 	 */

 	/* irq with higher priority may call sys_clock_set_timeout
 	 * so need a lock here
 	 */
 	uint32_t key;

 	key = arch_irq_lock();

 	elapsed();
 	cycle_count += overflow_cycles;
 	overflow_cycles = 0;

 	arch_irq_unlock(key);

 	dticks = (cycle_count - announced_cycles) / CYC_PER_TICK;
 	announced_cycles += dticks * CYC_PER_TICK;
 	sys_clock_announce(TICKLESS ? dticks : 1);
 #endif

 }

 void sys_clock_set_timeout(int32_t ticks, bool idle)
 {
 	/* If the kernel allows us to miss tick announcements in idle,
 	 * then shut off the counter. (Note: we can assume if idle==true
 	 * that interrupts are already disabled)
 	 */
 #if SMP_TIMER_DRIVER
 	/* as 64-bits GFRC is used as wall clock, it's ok to ignore idle
 	 * systick will not be missed.
 	 * However for single core using 32-bits arc timer, idle cannot
 	 * be ignored, as 32-bits timer will overflow in a not-long time.
 	 */
 	if (IS_ENABLED(CONFIG_TICKLESS_KERNEL) && ticks == K_TICKS_FOREVER) {
 		timer0_control_register_set(0);
 		timer0_count_register_set(0);
 		timer0_limit_register_set(0);
 		return;
 	}

 #if defined(CONFIG_TICKLESS_KERNEL)
 	uint32_t delay;
 	uint32_t key;

 	ticks = MIN(MAX_TICKS, ticks);

 	/* Desired delay in the future
 	 * use MIN_DEALY here can trigger the timer
 	 * irq more soon, no need to go to CYC_PER_TICK
 	 * later.
 	 */
 	delay = MAX(ticks * CYC_PER_TICK, MIN_DELAY);

 	key = arch_irq_lock();

 	timer0_limit_register_set(delay - 1);
 	timer0_count_register_set(0);
 	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH |
 						_ARC_V2_TMR_CTRL_IE);

 	arch_irq_unlock(key);
 #endif
 #else
 	if (IS_ENABLED(CONFIG_TICKLESS_KERNEL) && idle && ticks == K_TICKS_FOREVER) {
 		timer0_control_register_set(0);
 		timer0_count_register_set(0);
 		timer0_limit_register_set(0);
 		last_load = TIMER_STOPPED;
 		return;
 	}

 #if defined(CONFIG_TICKLESS_KERNEL)
 	uint32_t delay;
 	uint32_t unannounced;

 	ticks = MIN(MAX_TICKS, (uint32_t)(MAX((int32_t)(ticks - 1), 0)));

 	k_spinlock_key_t key = k_spin_lock(&lock);


 	cycle_count += elapsed();
 	/* clear counter early to avoid cycle loss as few as possible,
 	 * between cycle_count and clearing 0, few cycles are possible
 	 * to loss
 	 */
 	timer0_count_register_set(0);
 	overflow_cycles = 0U;


 	/* normal case */
 	unannounced = cycle_count - announced_cycles;

 	if ((int32_t)unannounced < 0) {
 		/* We haven't announced for more than half the 32-bit
 		 * wrap duration, because new timeouts keep being set
 		 * before the existing one fires. Force an announce
 		 * to avoid loss of a wrap event, making sure the
 		 * delay is at least the minimum delay possible.
 		 */
 		last_load = MIN_DELAY;
 	} else {
 		/* Desired delay in the future */
 		delay = ticks * CYC_PER_TICK;

 		/* Round delay up to next tick boundary */
 		delay += unannounced;
 		delay =
 		 ((delay + CYC_PER_TICK - 1) / CYC_PER_TICK) * CYC_PER_TICK;

 		delay -= unannounced;
 		delay = MAX(delay, MIN_DELAY);

 		last_load = MIN(delay, MAX_CYCLES);
 	}

 	timer0_limit_register_set(last_load - 1);
 	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH | _ARC_V2_TMR_CTRL_IE);

 	k_spin_unlock(&lock, key);
 #endif
 #endif
 }

 uint32_t sys_clock_elapsed(void)
 {
 	if (!TICKLESS) {
 		return 0;
 	}

 	uint32_t cyc;
 	k_spinlock_key_t key = k_spin_lock(&lock);

 #if SMP_TIMER_DRIVER
 	cyc = (z_arc_connect_gfrc_read() - last_time);
 #else
 	cyc =  elapsed() + cycle_count - announced_cycles;
 #endif

 	k_spin_unlock(&lock, key);

 	return cyc / CYC_PER_TICK;
 }

 uint32_t sys_clock_cycle_get_32(void)
 {
 #if SMP_TIMER_DRIVER
 	return z_arc_connect_gfrc_read() - start_time;
 #else
 	k_spinlock_key_t key = k_spin_lock(&lock);
 	uint32_t ret = elapsed() + cycle_count;

 	k_spin_unlock(&lock, key);
 	return ret;
 #endif
 }

 #if SMP_TIMER_DRIVER
 void smp_timer_init(void)
 {
 	/* set the initial status of timer0 of each slave core
 	 */
 	timer0_control_register_set(0);
 	timer0_count_register_set(0);
 	timer0_limit_register_set(0);

 	z_irq_priority_set(IRQ_TIMER0, CONFIG_ARCV2_TIMER_IRQ_PRIORITY, 0);
 	irq_enable(IRQ_TIMER0);
 }
 #endif

 /**
  *
  * @brief Initialize and enable the system clock
  *
  * This routine is used to program the ARCv2 timer to deliver interrupts at the
  * rate specified via the CYC_PER_TICK.
  *
  * @return 0
  */
 static int sys_clock_driver_init(const struct device *dev)
 {
 	ARG_UNUSED(dev);

 	/* ensure that the timer will not generate interrupts */
 	timer0_control_register_set(0);

 #if SMP_TIMER_DRIVER
 	IRQ_CONNECT(IRQ_TIMER0, CONFIG_ARCV2_TIMER_IRQ_PRIORITY,
 		    timer_int_handler, NULL, 0);

 	timer0_limit_register_set(CYC_PER_TICK - 1);
 	last_time = z_arc_connect_gfrc_read();
 	start_time = last_time;
 #else
 	last_load = CYC_PER_TICK;
 	overflow_cycles = 0;
 	announced_cycles = 0;

 	IRQ_CONNECT(IRQ_TIMER0, CONFIG_ARCV2_TIMER_IRQ_PRIORITY,
 		    timer_int_handler, NULL, 0);

 	timer0_limit_register_set(last_load - 1);
 #endif
 	timer0_count_register_set(0);
 	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH | _ARC_V2_TMR_CTRL_IE);

 	/* everything has been configured: safe to enable the interrupt */

 	irq_enable(IRQ_TIMER0);

 	return 0;
 }

 SYS_INIT(sys_clock_driver_init, PRE_KERNEL_2,
 	 CONFIG_SYSTEM_CLOCK_INIT_PRIORITY);
	/*
	* Copyright (c) 2014-2015 Wind River Systems, Inc.
	* Copyright (c) 2018 Synopsys Inc, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/
	#include <zephyr/device.h>
	#include <zephyr/drivers/timer/system_timer.h>
	#include <zephyr/sys_clock.h>
	#include <zephyr/spinlock.h>
	#include <zephyr/arch/arc/v2/aux_regs.h>
	/*
	* note: This implementation assumes Timer0 is present. Be sure
	* to build the ARC CPU with Timer0.
	*
	* If secureshield is present and secure firmware is configured,
	* use secure Timer 0
	*/

	#ifdef CONFIG_ARC_SECURE_FIRMWARE

	#undef _ARC_V2_TMR0_COUNT
	#undef _ARC_V2_TMR0_CONTROL
	#undef _ARC_V2_TMR0_LIMIT

	#define _ARC_V2_TMR0_COUNT _ARC_V2_S_TMR0_COUNT
	#define _ARC_V2_TMR0_CONTROL _ARC_V2_S_TMR0_CONTROL
	#define _ARC_V2_TMR0_LIMIT _ARC_V2_S_TMR0_LIMIT
	#define IRQ_TIMER0 DT_IRQN(DT_NODELABEL(sectimer0))

	#else
	#define IRQ_TIMER0 DT_IRQN(DT_NODELABEL(timer0))
	#endif

	#define _ARC_V2_TMR_CTRL_IE 0x1 /* interrupt enable */
	#define _ARC_V2_TMR_CTRL_NH 0x2 /* count only while not halted */
	#define _ARC_V2_TMR_CTRL_W 0x4 /* watchdog mode enable */
	#define _ARC_V2_TMR_CTRL_IP 0x8 /* interrupt pending flag */

	/* Minimum cycles in the future to try to program. */
	#define MIN_DELAY 1024
	/* arc timer has 32 bit, here use 31 bit to avoid the possible
	* overflow,e.g, 0xffffffff + any value will cause overflow
	*/
	#define COUNTER_MAX 0x7fffffff
	#define TIMER_STOPPED 0x0
	#define CYC_PER_TICK (sys_clock_hw_cycles_per_sec() \
	/ CONFIG_SYS_CLOCK_TICKS_PER_SEC)

	#define MAX_TICKS ((COUNTER_MAX / CYC_PER_TICK) - 1)
	#define MAX_CYCLES (MAX_TICKS * CYC_PER_TICK)

	#define TICKLESS (IS_ENABLED(CONFIG_TICKLESS_KERNEL))

	#define SMP_TIMER_DRIVER (CONFIG_SMP && CONFIG_MP_NUM_CPUS > 1)

	#if defined(CONFIG_TEST)
	const int32_t z_sys_timer_irq_for_test = IRQ_TIMER0;
	#endif
	static struct k_spinlock lock;


	#if SMP_TIMER_DRIVER
	volatile static uint64_t last_time;
	volatile static uint64_t start_time;

	#else
	static uint32_t last_load;


	/*
	* This local variable holds the amount of timer cycles elapsed
	* and it is updated in timer_int_handler and sys_clock_set_timeout().
	*
	* Note:
	* At an arbitrary point in time the "current" value of the
	* HW timer is calculated as:
	*
	* t = cycle_counter + elapsed();
	*/
	static uint32_t cycle_count;

	/*
	* This local variable holds the amount of elapsed HW cycles
	* that have been announced to the kernel.
	*/
	static uint32_t announced_cycles;


	/*
	* This local variable holds the amount of elapsed HW cycles due to
	* timer wraps ('overflows') and is used in the calculation
	* in elapsed() function, as well as in the updates to cycle_count.
	*
	* Note:
	* Each time cycle_count is updated with the value from overflow_cycles,
	* the overflow_cycles must be reset to zero.
	*/
	static volatile uint32_t overflow_cycles;
	#endif

	/**
	* @brief Get contents of Timer0 count register
	*
	* @return Current Timer0 count
	*/
	static ALWAYS_INLINE uint32_t timer0_count_register_get(void)
	{
	return z_arc_v2_aux_reg_read(_ARC_V2_TMR0_COUNT);
	}

	/**
	* @brief Set Timer0 count register to the specified value
	*/
	static ALWAYS_INLINE void timer0_count_register_set(uint32_t value)
	{
	z_arc_v2_aux_reg_write(_ARC_V2_TMR0_COUNT, value);
	}

	/**
	* @brief Get contents of Timer0 control register
	*
	* @return Contents of Timer0 control register.
	*/
	static ALWAYS_INLINE uint32_t timer0_control_register_get(void)
	{
	return z_arc_v2_aux_reg_read(_ARC_V2_TMR0_CONTROL);
	}

	/**
	* @brief Set Timer0 control register to the specified value
	*/
	static ALWAYS_INLINE void timer0_control_register_set(uint32_t value)
	{
	z_arc_v2_aux_reg_write(_ARC_V2_TMR0_CONTROL, value);
	}

	/**
	* @brief Get contents of Timer0 limit register
	*
	* @return Contents of Timer0 limit register.
	*/
	static ALWAYS_INLINE uint32_t timer0_limit_register_get(void)
	{
	return z_arc_v2_aux_reg_read(_ARC_V2_TMR0_LIMIT);
	}

	/**
	* @brief Set Timer0 limit register to the specified value
	*/
	static ALWAYS_INLINE void timer0_limit_register_set(uint32_t count)
	{
	z_arc_v2_aux_reg_write(_ARC_V2_TMR0_LIMIT, count);
	}

	#if !SMP_TIMER_DRIVER
	/* This internal function calculates the amount of HW cycles that have
	* elapsed since the last time the absolute HW cycles counter has been
	* updated. 'cycle_count' may be updated either by the ISR, or
	* in sys_clock_set_timeout().
	*
	* Additionally, the function updates the 'overflow_cycles' counter, that
	* holds the amount of elapsed HW cycles due to (possibly) multiple
	* timer wraps (overflows).
	*
	* Prerequisites:
	* - reprogramming of LIMIT must be clearing the COUNT
	* - ISR must be clearing the 'overflow_cycles' counter.
	* - no more than one counter-wrap has occurred between
	* - the timer reset or the last time the function was called
	* - and until the current call of the function is completed.
	* - the function is invoked with interrupts disabled.
	*/
	static uint32_t elapsed(void)
	{
	uint32_t val, ctrl;

	do {
	val = timer0_count_register_get();
	ctrl = timer0_control_register_get();
	} while (timer0_count_register_get() < val);

	if (ctrl & _ARC_V2_TMR_CTRL_IP) {
	overflow_cycles += last_load;
	/* clear the IP bit of the control register */
	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH \|
	_ARC_V2_TMR_CTRL_IE);
	/* use sw triggered irq to remember the timer irq request
	* which may be cleared by the above operation. when elapsed ()
	* is called in timer_int_handler, no need to do this.
	*/
	if (!z_arc_v2_irq_unit_is_in_isr() \|\|
	z_arc_v2_aux_reg_read(_ARC_V2_ICAUSE) != IRQ_TIMER0) {
	z_arc_v2_aux_reg_write(_ARC_V2_AUX_IRQ_HINT,
	IRQ_TIMER0);
	}
	}

	return val + overflow_cycles;
	}
	#endif

	/**
	* @brief System clock periodic tick handler
	*
	* This routine handles the system clock tick interrupt. It always
	* announces one tick when TICKLESS is not enabled, or multiple ticks
	* when TICKLESS is enabled.
	*/
	static void timer_int_handler(const void *unused)
	{
	ARG_UNUSED(unused);
	uint32_t dticks;

	#if defined(CONFIG_SMP) && CONFIG_MP_NUM_CPUS > 1
	uint64_t curr_time;
	k_spinlock_key_t key;

	/* clear the IP bit of the control register */
	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH \|
	_ARC_V2_TMR_CTRL_IE);
	key = k_spin_lock(&lock);
	/* gfrc is the wall clock */
	curr_time = z_arc_connect_gfrc_read();

	dticks = (curr_time - last_time) / CYC_PER_TICK;
	/* last_time should be aligned to ticks */
	last_time += dticks * CYC_PER_TICK;

	k_spin_unlock(&lock, key);

	sys_clock_announce(dticks);
	#else
	/* timer_int_handler may be triggered by timer irq or
	* software helper irq
	*/

	/* irq with higher priority may call sys_clock_set_timeout
	* so need a lock here
	*/
	uint32_t key;

	key = arch_irq_lock();

	elapsed();
	cycle_count += overflow_cycles;
	overflow_cycles = 0;

	arch_irq_unlock(key);

	dticks = (cycle_count - announced_cycles) / CYC_PER_TICK;
	announced_cycles += dticks * CYC_PER_TICK;
	sys_clock_announce(TICKLESS ? dticks : 1);
	#endif

	}

	void sys_clock_set_timeout(int32_t ticks, bool idle)
	{
	/* If the kernel allows us to miss tick announcements in idle,
	* then shut off the counter. (Note: we can assume if idle==true
	* that interrupts are already disabled)
	*/
	#if SMP_TIMER_DRIVER
	/* as 64-bits GFRC is used as wall clock, it's ok to ignore idle
	* systick will not be missed.
	* However for single core using 32-bits arc timer, idle cannot
	* be ignored, as 32-bits timer will overflow in a not-long time.
	*/
	if (IS_ENABLED(CONFIG_TICKLESS_KERNEL) && ticks == K_TICKS_FOREVER) {
	timer0_control_register_set(0);
	timer0_count_register_set(0);
	timer0_limit_register_set(0);
	return;
	}

	#if defined(CONFIG_TICKLESS_KERNEL)
	uint32_t delay;
	uint32_t key;

	ticks = MIN(MAX_TICKS, ticks);

	/* Desired delay in the future
	* use MIN_DEALY here can trigger the timer
	* irq more soon, no need to go to CYC_PER_TICK
	* later.
	*/
	delay = MAX(ticks * CYC_PER_TICK, MIN_DELAY);

	key = arch_irq_lock();

	timer0_limit_register_set(delay - 1);
	timer0_count_register_set(0);
	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH \|
	_ARC_V2_TMR_CTRL_IE);

	arch_irq_unlock(key);
	#endif
	#else
	if (IS_ENABLED(CONFIG_TICKLESS_KERNEL) && idle && ticks == K_TICKS_FOREVER) {
	timer0_control_register_set(0);
	timer0_count_register_set(0);
	timer0_limit_register_set(0);
	last_load = TIMER_STOPPED;
	return;
	}

	#if defined(CONFIG_TICKLESS_KERNEL)
	uint32_t delay;
	uint32_t unannounced;

	ticks = MIN(MAX_TICKS, (uint32_t)(MAX((int32_t)(ticks - 1), 0)));

	k_spinlock_key_t key = k_spin_lock(&lock);


	cycle_count += elapsed();
	/* clear counter early to avoid cycle loss as few as possible,
	* between cycle_count and clearing 0, few cycles are possible
	* to loss
	*/
	timer0_count_register_set(0);
	overflow_cycles = 0U;


	/* normal case */
	unannounced = cycle_count - announced_cycles;

	if ((int32_t)unannounced < 0) {
	/* We haven't announced for more than half the 32-bit
	* wrap duration, because new timeouts keep being set
	* before the existing one fires. Force an announce
	* to avoid loss of a wrap event, making sure the
	* delay is at least the minimum delay possible.
	*/
	last_load = MIN_DELAY;
	} else {
	/* Desired delay in the future */
	delay = ticks * CYC_PER_TICK;

	/* Round delay up to next tick boundary */
	delay += unannounced;
	delay =
	((delay + CYC_PER_TICK - 1) / CYC_PER_TICK) * CYC_PER_TICK;

	delay -= unannounced;
	delay = MAX(delay, MIN_DELAY);

	last_load = MIN(delay, MAX_CYCLES);
	}

	timer0_limit_register_set(last_load - 1);
	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH \| _ARC_V2_TMR_CTRL_IE);

	k_spin_unlock(&lock, key);
	#endif
	#endif
	}

	uint32_t sys_clock_elapsed(void)
	{
	if (!TICKLESS) {
	return 0;
	}

	uint32_t cyc;
	k_spinlock_key_t key = k_spin_lock(&lock);

	#if SMP_TIMER_DRIVER
	cyc = (z_arc_connect_gfrc_read() - last_time);
	#else
	cyc = elapsed() + cycle_count - announced_cycles;
	#endif

	k_spin_unlock(&lock, key);

	return cyc / CYC_PER_TICK;
	}

	uint32_t sys_clock_cycle_get_32(void)
	{
	#if SMP_TIMER_DRIVER
	return z_arc_connect_gfrc_read() - start_time;
	#else
	k_spinlock_key_t key = k_spin_lock(&lock);
	uint32_t ret = elapsed() + cycle_count;

	k_spin_unlock(&lock, key);
	return ret;
	#endif
	}

	#if SMP_TIMER_DRIVER
	void smp_timer_init(void)
	{
	/* set the initial status of timer0 of each slave core
	*/
	timer0_control_register_set(0);
	timer0_count_register_set(0);
	timer0_limit_register_set(0);

	z_irq_priority_set(IRQ_TIMER0, CONFIG_ARCV2_TIMER_IRQ_PRIORITY, 0);
	irq_enable(IRQ_TIMER0);
	}
	#endif

	/**
	*
	* @brief Initialize and enable the system clock
	*
	* This routine is used to program the ARCv2 timer to deliver interrupts at the
	* rate specified via the CYC_PER_TICK.
	*
	* @return 0
	*/
	static int sys_clock_driver_init(const struct device *dev)
	{
	ARG_UNUSED(dev);

	/* ensure that the timer will not generate interrupts */
	timer0_control_register_set(0);

	#if SMP_TIMER_DRIVER
	IRQ_CONNECT(IRQ_TIMER0, CONFIG_ARCV2_TIMER_IRQ_PRIORITY,
	timer_int_handler, NULL, 0);

	timer0_limit_register_set(CYC_PER_TICK - 1);
	last_time = z_arc_connect_gfrc_read();
	start_time = last_time;
	#else
	last_load = CYC_PER_TICK;
	overflow_cycles = 0;
	announced_cycles = 0;

	IRQ_CONNECT(IRQ_TIMER0, CONFIG_ARCV2_TIMER_IRQ_PRIORITY,
	timer_int_handler, NULL, 0);

	timer0_limit_register_set(last_load - 1);
	#endif
	timer0_count_register_set(0);
	timer0_control_register_set(_ARC_V2_TMR_CTRL_NH \| _ARC_V2_TMR_CTRL_IE);

	/* everything has been configured: safe to enable the interrupt */

	irq_enable(IRQ_TIMER0);

	return 0;
	}

	SYS_INIT(sys_clock_driver_init, PRE_KERNEL_2,
	CONFIG_SYSTEM_CLOCK_INIT_PRIORITY);