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

 /*
  * Copyright (c) 2016-2017 Nordic Semiconductor ASA
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <soc.h>
 #include <clock_control.h>
 #include <system_timer.h>
 #include <drivers/clock_control/nrf5_clock_control.h>
 #include <arch/arm/cortex_m/cmsis.h>
 #include <sys_clock.h>

 extern void youve_print(void);
 /*
  * Convenience defines.
  */
 #define SYS_CLOCK_RTC          NRF_RTC1
 #define RTC_COUNTER            SYS_CLOCK_RTC->COUNTER
 #define RTC_CC_VALUE           SYS_CLOCK_RTC->CC[0]
 #define RTC_CC_EVENT           SYS_CLOCK_RTC->EVENTS_COMPARE[0]

 /* Minimum delta between current counter and CC register that the RTC is able
  * to handle
  */
 #define RTC_MIN_DELTA          2
 #define RTC_MASK               0x00FFFFFF
 /* Maximum difference for RTC counter values used. Half the maximum value is
  * selected to be able to detect overflow (a negative value has the same
  * representation as a large positive value).
  */
 #define RTC_HALF               (RTC_MASK / 2)

 #define RTC_TICKS_PER_SYS_TICK ((u32_t)((((u64_t)1000000UL / \
 				 sys_clock_ticks_per_sec) * \
 				1000000000UL) / 30517578125UL) & RTC_MASK)

 extern s32_t _sys_idle_elapsed_ticks;

 /*
  * rtc_past holds the value of RTC_COUNTER at the time the last sys tick was
  * announced, in RTC ticks. It is therefore always a multiple of
  * RTC_TICKS_PER_SYS_TICK.
  */
 static u32_t rtc_past;

 #ifdef CONFIG_TICKLESS_IDLE
 /*
  * Holds the maximum sys ticks the kernel expects to see in the next
  * _sys_clock_tick_announce().
  */
 static u32_t expected_sys_ticks;
 #endif /* CONFIG_TICKLESS_IDLE */

 #ifdef CONFIG_TICKLESS_KERNEL
 int32_t _get_max_clock_time(void);
 #endif /* CONFIG_TICKLESS_KERNEL */

 /*
  * Set RTC Counter Compare (CC) register to a given value in RTC ticks.
  */
 static void rtc_compare_set(u32_t rtc_ticks)
 {
 	u32_t rtc_now;

 	/* Try to set CC value. We assume the procedure is always successful. */
 	RTC_CC_VALUE = rtc_ticks;
 	rtc_now = RTC_COUNTER;

 	/* The following checks if the CC register was set to a valid value.
 	 * The first test checks if the distance between the current RTC counter
 	 * and the value (in the future) set in the CC register is too small to
 	 * guarantee a compare event being triggered.
 	 * The second test checks if the current RTC counter is higher than the
 	 * value written to the CC register, i.e. the CC value is in the past,
 	 * by checking if the unsigned subtraction wraps around.
 	 * If either of the above are true then instead of waiting for the CC
 	 * event to trigger in the form of an interrupt, trigger it directly
 	 * using the NVIC.
 	 */
 	if ((((rtc_ticks - rtc_now) & RTC_MASK) < RTC_MIN_DELTA) ||
 	    (((rtc_ticks - rtc_now) & RTC_MASK) > RTC_HALF)) {
 		NVIC_SetPendingIRQ(NRF5_IRQ_RTC1_IRQn);
 	}
 }
 #ifndef CONFIG_TICKLESS_KERNEL
 /*
  * @brief Announces the number of sys ticks, if any, that have passed since the
  * last announcement, and programs the RTC to trigger the interrupt on the next
  * sys tick.
  *
  * This function is not reentrant. It is called from:
  *
  * * _timer_idle_exit(), which in turn is called with interrupts disabled when
  * an interrupt fires.
  * * rtc1_nrf5_isr(), which runs with interrupts enabled but at that time the
  * device cannot be idle and hence _timer_idle_exit() cannot be called.
  *
  * Since this function can be preempted, we need to take some provisions to
  * announce all expected sys ticks that have passed.
  *
  */
 static void rtc_announce_set_next(void)
 {
 	u32_t rtc_now, rtc_elapsed, sys_elapsed;

 	/* Read the RTC counter one single time in the beginning, so that an
 	 * increase in the counter during this procedure leads to no race
 	 * conditions.
 	 */
 	rtc_now = RTC_COUNTER;

 	/* Calculate how many RTC ticks elapsed since the last sys tick. */
 	rtc_elapsed = (rtc_now - rtc_past) & RTC_MASK;

 	/* If no sys ticks have elapsed, there is no point in incrementing the
 	 * counters or announcing it.
 	 */
 	if (rtc_elapsed >= RTC_TICKS_PER_SYS_TICK) {
 #ifdef CONFIG_TICKLESS_IDLE
 		/* Calculate how many sys ticks elapsed since the last sys tick
 		 * and notify the kernel if necessary.
 		 */
 		sys_elapsed = rtc_elapsed / RTC_TICKS_PER_SYS_TICK;

 		if (sys_elapsed > expected_sys_ticks) {
 			/* Never announce more sys ticks than the kernel asked
 			 * to be idle for. The remainder will be announced when
 			 * the RTC ISR runs after rtc_compare_set() is called
 			 * after the first announcement.
 			 */
 			sys_elapsed = expected_sys_ticks;
 		}
 #else
 		/* Never announce more than one sys tick if tickless idle is not
 		 * configured.
 		 */
 		sys_elapsed = 1;
 #endif /* CONFIG_TICKLESS_IDLE */

 		/* Store RTC_COUNTER floored to the last sys tick. This is
 		 * done, so that ISR can properly calculate that 1 sys tick
 		 * has passed.
 		 */
 		rtc_past = (rtc_past +
 				(sys_elapsed * RTC_TICKS_PER_SYS_TICK)
 			   ) & RTC_MASK;

 		_sys_idle_elapsed_ticks = sys_elapsed;
 		_sys_clock_tick_announce();
 	}

 	/* Set the RTC to the next sys tick */
 	rtc_compare_set(rtc_past + RTC_TICKS_PER_SYS_TICK);
 }
 #endif

 #ifdef CONFIG_TICKLESS_IDLE
 /**
  * @brief Place system timer into idle state.
  *
  * Re-program the timer to enter into the idle state for the given number of
  * sys ticks, counted from the previous sys tick. The timer will fire in the
  * number of sys ticks supplied or the maximum number of sys ticks (converted
  * to RTC ticks) that can be programmed into the hardware.
  *
  * This will only be called from idle context, with IRQs disabled.
  *
  * A value of -1 will result in the maximum number of sys ticks.
  *
  * Example 1: Idle sleep is entered:
  *
  * sys tick timeline:       (1)    (2)    (3)    (4)    (5)    (6)
  * rtc tick timeline : 0----100----200----300----400----500----600
  *                               ******************
  *                              150
  *
  * a) The last sys tick was announced at 100
  * b) The idle context enters sleep at 150, between sys tick 1 and 2, with
  * sys_ticks = 3.
  * c) The RTC is programmed to fire at sys tick 1 + 3 = 4 (RTC tick 400)
  *
  * @return N/A
  */
 void _timer_idle_enter(s32_t sys_ticks)
 {
 #ifdef CONFIG_TICKLESS_KERNEL
 	if (sys_ticks != K_FOREVER) {
 		/* Need to reprograme timer if current program is smaller*/
 		if (sys_ticks > expected_sys_ticks) {
 			_set_time(sys_ticks);
 		}
 	} else {
 		expected_sys_ticks = 0;
 		/* Set time to largest possile RTC Tick*/
 		_set_time(_get_max_clock_time());
 	}
 #else
 	/* Restrict ticks to max supported by RTC without risking overflow*/
 	if ((sys_ticks < 0) ||
 		(sys_ticks > (RTC_HALF / RTC_TICKS_PER_SYS_TICK))) {
 		sys_ticks = RTC_HALF / RTC_TICKS_PER_SYS_TICK;
 	}

 	expected_sys_ticks = sys_ticks;

 	/* If ticks is 0, the RTC interrupt handler will be set pending
 	 * immediately, meaning that we will not go to sleep.
 	 */
 	rtc_compare_set(rtc_past + (sys_ticks * RTC_TICKS_PER_SYS_TICK));
 #endif
 }


 #ifdef CONFIG_TICKLESS_KERNEL

 /**
  * @brief provides total systicks programmed.
  *
  * returns : total number of sys ticks programmed.
  */

 uint32_t _get_program_time(void)
 {
 	return expected_sys_ticks;
 }

 /**
  * @brief provides total systicks remaining since last programming of RTC.
  *
  * returns : total number of sys ticks remaining since last RTC programming.
  */

 uint32_t _get_remaining_program_time(void)
 {

 	if (!expected_sys_ticks) {
 		return 0;
 	}

 	return (expected_sys_ticks - _get_elapsed_program_time());
 }

 /**
  * @brief provides total systicks passed since last programming of RTC.
  *
  * returns : total number of sys ticks passed since last RTC programming.
  */

 uint32_t _get_elapsed_program_time(void)
 {
 	u32_t rtc_now, rtc_prev, rtc_elapsed;

 	if (!expected_sys_ticks) {
 		return 0;
 	}

 	rtc_now = RTC_COUNTER;

 	/* Discard value of  RTC_COUNTER read at LFCLK transition */
 	do {
 		/* Number of RTC cycles passed since last RTC Programing*/
 		rtc_elapsed = (rtc_now - rtc_past) & RTC_MASK;
 		rtc_prev = rtc_now;
 		rtc_now = RTC_COUNTER;
 	} while (rtc_prev != rtc_now);

 	/*Convert number of Machine cycles to SYS TICS*/
 	return (rtc_elapsed / RTC_TICKS_PER_SYS_TICK);
 }


 /**
  * @brief Sets interrupt for rtc compare value for systick time.
  *
  * This Function does following:-
  * 1. Updates expected_sys_ticks equal to time.
  * 2. Update kernel book keeping for time passed since device bootup.
  * 3. Calls routine to set rtc interrupt.
  */

 void _set_time(uint32_t time)
 {
 	if (!time) {
 		expected_sys_ticks = 0;
 		return;
 	}

 	/* Update expected_sys_ticls to time to programe*/
 	expected_sys_ticks = time;
 	_sys_clock_tick_count = _get_elapsed_clock_time();
 	/* Update rtc_past to track rtc timer count*/
 	rtc_past = (_sys_clock_tick_count * RTC_TICKS_PER_SYS_TICK) & RTC_MASK;

 	expected_sys_ticks = expected_sys_ticks > _get_max_clock_time() ?
 				_get_max_clock_time() : expected_sys_ticks;

 	/* Programe RTC compare register to generate interrupt*/
 	rtc_compare_set(rtc_past +
 			(expected_sys_ticks * RTC_TICKS_PER_SYS_TICK));

 }

 /**
  * @brief provides time remaining to reach rtc count overflow.
  *
  * This function returns how many sys RTC remaining for rtc to overflow.
  * This will be required when we will program RTC compare value to maximum
  * possible value.
  *
  * returns : difference between current systick and Maximum possible systick.
  */
 int32_t _get_max_clock_time(void)
 {
 	u32_t rtc_now, rtc_prev, rtc_away, sys_away = 0;

 	rtc_now = RTC_COUNTER;
 	/* Discard value of  RTC_COUNTER read at LFCLK transition */
 	do {
 		rtc_away = (RTC_MASK - rtc_now);
 		rtc_away = rtc_away > RTC_HALF ? RTC_HALF : rtc_away;
 		rtc_prev = rtc_now;
 		/* Calculate time to programe into RTC*/
 		rtc_now = RTC_COUNTER;
 	} while (rtc_now != rtc_prev);

 	/* Convert RTC Ticks to SYS TICKS*/
 	if (rtc_away >= RTC_TICKS_PER_SYS_TICK) {
 		sys_away = rtc_away / RTC_TICKS_PER_SYS_TICK;
 	}
 	return sys_away;
 }

 /**
  * @brief Enable sys Clock.
  *
  * This is used to program RTC clock to maximum Clock time in case Clock to
  * remain On.
  */
 void _enable_sys_clock(void)
 {
 	if (!expected_sys_ticks) {
 		/* Programe sys tick to Maximum possible value*/
 		_set_time(_get_max_clock_time());
 	}
 }

 /**
  * @brief provides total systicks passed since device bootup.
  *
  * returns : total number of sys ticks passed since device bootup.
  */

 uint64_t _get_elapsed_clock_time(void)
 {
 	u64_t elapsed;
 	u32_t rtc_now, rtc_elapsed, rtc_prev, sys_elapsed;

 	rtc_now = RTC_COUNTER;

 	/* Discard value of  RTC_COUNTER read at LFCLK transition */
 	do {
 		/* Calculate number of rtc cycles elapsed since RTC programing*/
 		rtc_elapsed = (rtc_now - rtc_past) & RTC_MASK;
 		elapsed = _sys_clock_tick_count;
 		rtc_prev = rtc_now;
 		rtc_now = RTC_COUNTER;
 	} while (rtc_now != rtc_prev);

 	if (rtc_elapsed >= RTC_TICKS_PER_SYS_TICK) {
 		/* Convert RTC cycles to SYS TICKS*/
 		sys_elapsed = rtc_elapsed / RTC_TICKS_PER_SYS_TICK;
 		/* Update total number of SYS_TICKS passed*/
 		elapsed += sys_elapsed;
 	}
 	return elapsed;
 }
 #endif


 /**
  *
  * @brief Handling of tickless idle when interrupted
  *
  * The function will be called by _sys_power_save_idle_exit(), called from
  * _arch_isr_direct_pm() for 'direct' interrupts, or from _isr_wrapper for
  * regular ones, which is called on every IRQ handler if the device was
  * idle, and optionally called when a 'direct' IRQ handler executes if the
  * device was idle.
  *
  * Example 1: Idle sleep is interrupted before time:
  *
  * sys tick timeline:       (1)    (2)    (3)    (4)    (5)    (6)
  * rtc tick timeline : 0----100----200----300----400----500----600
  *                               **************!***
  *                              150           350
  *
  * Assume that _timer_idle_enter() is called at 150 (1) to sleep for 3
  * sys ticks. The last sys tick was announced at 100.
  *
  * On wakeup (non-RTC IRQ at 350):
  *
  * a) Notify how many sys ticks have passed, i.e., 350 - 150 / 100 = 2.
  * b) Schedule next sys tick at 400.
  *
  */
 void _timer_idle_exit(void)
 {
 #ifdef CONFIG_TICKLESS_KERNEL
 	if (!expected_sys_ticks && _sys_clock_always_on) {
 		_set_time(_get_max_clock_time());
 	}
 #else
 	/* Clear the event flag and interrupt in case we woke up on the RTC
 	 * interrupt. No need to run the RTC ISR since everything that needs
 	 * to run in the ISR will be done in this call.
 	 */
 	RTC_CC_EVENT = 0;
 	NVIC_ClearPendingIRQ(NRF5_IRQ_RTC1_IRQn);

 	rtc_announce_set_next();

 	/* After exiting idle, the kernel no longer expects more than one sys
 	 * ticks to have passed when _sys_clock_tick_announce() is called.
 	 */
 	expected_sys_ticks = 1;
 #endif
 }
 #endif /* CONFIG_TICKLESS_IDLE */

 /*
  * @brief Announces the number of sys ticks that have passed since the last
  * announcement, if any, and programs the RTC to trigger the interrupt on the
  * next sys tick.
  *
  * The ISR is set pending due to a regular sys tick and after exiting idle mode
  * as scheduled.
  *
  * Since this ISR can be preempted, we need to take some provisions to announce
  * all expected sys ticks that have passed.
  *
  * Consider the following example:
  *
  * sys tick timeline:       (1)    (2)    (3)    (4)    (5)    (6)
  * rtc tick timeline : 0----100----200----300----400----500----600
  *                                         !**********
  *                                                  450
  *
  * The last sys tick was anounced at 200, i.e, rtc_past = 200. The ISR is
  * executed at the next sys tick, i.e. 300. The following sys tick is due at
  * 400. However, the ISR is preempted for a number of sys ticks, until 450 in
  * this example. The ISR will then announce the number of sys ticks it was
  * delayed (2), and schedule the next sys tick (5) at 500.
  */
 static void rtc1_nrf5_isr(void *arg)
 {

 	ARG_UNUSED(arg);
 	RTC_CC_EVENT = 0;

 #ifdef CONFIG_EXECUTION_BENCHMARKING
 	extern void read_timer_start_of_tick_handler(void);
 	read_timer_start_of_tick_handler();
 #endif

 #ifdef CONFIG_TICKLESS_KERNEL
 	_sys_idle_elapsed_ticks = expected_sys_ticks;
 	/* Initialize expected sys tick,
 	 * It will be later updated based on next timeout.
 	 */
 	expected_sys_ticks = 0;
 	/* Anounce elapsed of _sys_idle_elapsed_ticks systicks*/
 	_sys_clock_tick_announce();
 #else
 	rtc_announce_set_next();
 #endif

 #ifdef CONFIG_EXECUTION_BENCHMARKING
 	extern void read_timer_end_of_tick_handler(void);
 	read_timer_end_of_tick_handler();
 #endif

 }

 int _sys_clock_driver_init(struct device *device)
 {
 	struct device *clock;

 	ARG_UNUSED(device);

 	clock = device_get_binding(CONFIG_CLOCK_CONTROL_NRF5_K32SRC_DRV_NAME);
 	if (!clock) {
 		return -1;
 	}

 	clock_control_on(clock, (void *)CLOCK_CONTROL_NRF5_K32SRC);

 	rtc_past = 0;

 #ifdef CONFIG_TICKLESS_IDLE
 	expected_sys_ticks = 1;
 #endif /* CONFIG_TICKLESS_IDLE */

 	/* TODO: replace with counter driver to access RTC */
 	SYS_CLOCK_RTC->PRESCALER = 0;
 	SYS_CLOCK_RTC->CC[0] = RTC_TICKS_PER_SYS_TICK;
 	SYS_CLOCK_RTC->EVTENSET = RTC_EVTENSET_COMPARE0_Msk;
 	SYS_CLOCK_RTC->INTENSET = RTC_INTENSET_COMPARE0_Msk;

 	/* Clear the event flag and possible pending interrupt */
 	RTC_CC_EVENT = 0;
 	NVIC_ClearPendingIRQ(NRF5_IRQ_RTC1_IRQn);

 	IRQ_CONNECT(NRF5_IRQ_RTC1_IRQn, 1, rtc1_nrf5_isr, 0, 0);
 	irq_enable(NRF5_IRQ_RTC1_IRQn);

 	SYS_CLOCK_RTC->TASKS_CLEAR = 1;
 	SYS_CLOCK_RTC->TASKS_START = 1;

 	return 0;
 }

 u32_t _timer_cycle_get_32(void)
 {
 	u32_t elapsed_cycles;
 	u32_t sys_clock_tick_count;
 	u32_t rtc_prev;
 	u32_t rtc_now;

 	rtc_now = RTC_COUNTER;
 	/* Discard value of  RTC_COUNTER read at LFCLK transition */
 	do {
 		sys_clock_tick_count = _sys_clock_tick_count;
 		elapsed_cycles = (rtc_now - (sys_clock_tick_count *
 					     RTC_TICKS_PER_SYS_TICK)) &
 				 RTC_MASK;
 		rtc_prev = rtc_now;
 		rtc_now = RTC_COUNTER;
 	} while (rtc_now != rtc_prev);

 	return (sys_clock_tick_count * sys_clock_hw_cycles_per_tick) +
 	       elapsed_cycles;
 }

 #ifdef CONFIG_SYSTEM_CLOCK_DISABLE
 /**
  *
  * @brief Stop announcing sys ticks into the kernel
  *
  * This routine disables the RTC1 so that timer interrupts are no
  * longer delivered.
  *
  * @return N/A
  */
 void sys_clock_disable(void)
 {
 	unsigned int key;

 	key = irq_lock();

 	irq_disable(NRF5_IRQ_RTC1_IRQn);

 	SYS_CLOCK_RTC->EVTENCLR = RTC_EVTENCLR_COMPARE0_Msk;
 	SYS_CLOCK_RTC->INTENCLR = RTC_INTENCLR_COMPARE0_Msk;

 	SYS_CLOCK_RTC->TASKS_STOP = 1;
 	SYS_CLOCK_RTC->TASKS_CLEAR = 1;

 	irq_unlock(key);

 	/* TODO: turn off (release) 32 KHz clock source.
 	 * Turning off of 32 KHz clock source is not implemented in clock
 	 * driver.
 	 */
 }
 #endif /* CONFIG_SYSTEM_CLOCK_DISABLE */
	/*
	* Copyright (c) 2016-2017 Nordic Semiconductor ASA
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <soc.h>
	#include <clock_control.h>
	#include <system_timer.h>
	#include <drivers/clock_control/nrf5_clock_control.h>
	#include <arch/arm/cortex_m/cmsis.h>
	#include <sys_clock.h>

	extern void youve_print(void);
	/*
	* Convenience defines.
	*/
	#define SYS_CLOCK_RTC NRF_RTC1
	#define RTC_COUNTER SYS_CLOCK_RTC->COUNTER
	#define RTC_CC_VALUE SYS_CLOCK_RTC->CC[0]
	#define RTC_CC_EVENT SYS_CLOCK_RTC->EVENTS_COMPARE[0]

	/* Minimum delta between current counter and CC register that the RTC is able
	* to handle
	*/
	#define RTC_MIN_DELTA 2
	#define RTC_MASK 0x00FFFFFF
	/* Maximum difference for RTC counter values used. Half the maximum value is
	* selected to be able to detect overflow (a negative value has the same
	* representation as a large positive value).
	*/
	#define RTC_HALF (RTC_MASK / 2)

	#define RTC_TICKS_PER_SYS_TICK ((u32_t)((((u64_t)1000000UL / \
	sys_clock_ticks_per_sec) * \
	1000000000UL) / 30517578125UL) & RTC_MASK)

	extern s32_t _sys_idle_elapsed_ticks;

	/*
	* rtc_past holds the value of RTC_COUNTER at the time the last sys tick was
	* announced, in RTC ticks. It is therefore always a multiple of
	* RTC_TICKS_PER_SYS_TICK.
	*/
	static u32_t rtc_past;

	#ifdef CONFIG_TICKLESS_IDLE
	/*
	* Holds the maximum sys ticks the kernel expects to see in the next
	* _sys_clock_tick_announce().
	*/
	static u32_t expected_sys_ticks;
	#endif /* CONFIG_TICKLESS_IDLE */

	#ifdef CONFIG_TICKLESS_KERNEL
	int32_t _get_max_clock_time(void);
	#endif /* CONFIG_TICKLESS_KERNEL */

	/*
	* Set RTC Counter Compare (CC) register to a given value in RTC ticks.
	*/
	static void rtc_compare_set(u32_t rtc_ticks)
	{
	u32_t rtc_now;

	/* Try to set CC value. We assume the procedure is always successful. */
	RTC_CC_VALUE = rtc_ticks;
	rtc_now = RTC_COUNTER;

	/* The following checks if the CC register was set to a valid value.
	* The first test checks if the distance between the current RTC counter
	* and the value (in the future) set in the CC register is too small to
	* guarantee a compare event being triggered.
	* The second test checks if the current RTC counter is higher than the
	* value written to the CC register, i.e. the CC value is in the past,
	* by checking if the unsigned subtraction wraps around.
	* If either of the above are true then instead of waiting for the CC
	* event to trigger in the form of an interrupt, trigger it directly
	* using the NVIC.
	*/
	if ((((rtc_ticks - rtc_now) & RTC_MASK) < RTC_MIN_DELTA) \|\|
	(((rtc_ticks - rtc_now) & RTC_MASK) > RTC_HALF)) {
	NVIC_SetPendingIRQ(NRF5_IRQ_RTC1_IRQn);
	}
	}
	#ifndef CONFIG_TICKLESS_KERNEL
	/*
	* @brief Announces the number of sys ticks, if any, that have passed since the
	* last announcement, and programs the RTC to trigger the interrupt on the next
	* sys tick.
	*
	* This function is not reentrant. It is called from:
	*
	* * _timer_idle_exit(), which in turn is called with interrupts disabled when
	* an interrupt fires.
	* * rtc1_nrf5_isr(), which runs with interrupts enabled but at that time the
	* device cannot be idle and hence _timer_idle_exit() cannot be called.
	*
	* Since this function can be preempted, we need to take some provisions to
	* announce all expected sys ticks that have passed.
	*
	*/
	static void rtc_announce_set_next(void)
	{
	u32_t rtc_now, rtc_elapsed, sys_elapsed;

	/* Read the RTC counter one single time in the beginning, so that an
	* increase in the counter during this procedure leads to no race
	* conditions.
	*/
	rtc_now = RTC_COUNTER;

	/* Calculate how many RTC ticks elapsed since the last sys tick. */
	rtc_elapsed = (rtc_now - rtc_past) & RTC_MASK;

	/* If no sys ticks have elapsed, there is no point in incrementing the
	* counters or announcing it.
	*/
	if (rtc_elapsed >= RTC_TICKS_PER_SYS_TICK) {
	#ifdef CONFIG_TICKLESS_IDLE
	/* Calculate how many sys ticks elapsed since the last sys tick
	* and notify the kernel if necessary.
	*/
	sys_elapsed = rtc_elapsed / RTC_TICKS_PER_SYS_TICK;

	if (sys_elapsed > expected_sys_ticks) {
	/* Never announce more sys ticks than the kernel asked
	* to be idle for. The remainder will be announced when
	* the RTC ISR runs after rtc_compare_set() is called
	* after the first announcement.
	*/
	sys_elapsed = expected_sys_ticks;
	}
	#else
	/* Never announce more than one sys tick if tickless idle is not
	* configured.
	*/
	sys_elapsed = 1;
	#endif /* CONFIG_TICKLESS_IDLE */

	/* Store RTC_COUNTER floored to the last sys tick. This is
	* done, so that ISR can properly calculate that 1 sys tick
	* has passed.
	*/
	rtc_past = (rtc_past +
	(sys_elapsed * RTC_TICKS_PER_SYS_TICK)
	) & RTC_MASK;

	_sys_idle_elapsed_ticks = sys_elapsed;
	_sys_clock_tick_announce();
	}

	/* Set the RTC to the next sys tick */
	rtc_compare_set(rtc_past + RTC_TICKS_PER_SYS_TICK);
	}
	#endif

	#ifdef CONFIG_TICKLESS_IDLE
	/**
	* @brief Place system timer into idle state.
	*
	* Re-program the timer to enter into the idle state for the given number of
	* sys ticks, counted from the previous sys tick. The timer will fire in the
	* number of sys ticks supplied or the maximum number of sys ticks (converted
	* to RTC ticks) that can be programmed into the hardware.
	*
	* This will only be called from idle context, with IRQs disabled.
	*
	* A value of -1 will result in the maximum number of sys ticks.
	*
	* Example 1: Idle sleep is entered:
	*
	* sys tick timeline: (1) (2) (3) (4) (5) (6)
	* rtc tick timeline : 0----100----200----300----400----500----600
	* ******************
	* 150
	*
	* a) The last sys tick was announced at 100
	* b) The idle context enters sleep at 150, between sys tick 1 and 2, with
	* sys_ticks = 3.
	* c) The RTC is programmed to fire at sys tick 1 + 3 = 4 (RTC tick 400)
	*
	* @return N/A
	*/
	void _timer_idle_enter(s32_t sys_ticks)
	{
	#ifdef CONFIG_TICKLESS_KERNEL
	if (sys_ticks != K_FOREVER) {
	/* Need to reprograme timer if current program is smaller*/
	if (sys_ticks > expected_sys_ticks) {
	_set_time(sys_ticks);
	}
	} else {
	expected_sys_ticks = 0;
	/* Set time to largest possile RTC Tick*/
	_set_time(_get_max_clock_time());
	}
	#else
	/* Restrict ticks to max supported by RTC without risking overflow*/
	if ((sys_ticks < 0) \|\|
	(sys_ticks > (RTC_HALF / RTC_TICKS_PER_SYS_TICK))) {
	sys_ticks = RTC_HALF / RTC_TICKS_PER_SYS_TICK;
	}

	expected_sys_ticks = sys_ticks;

	/* If ticks is 0, the RTC interrupt handler will be set pending
	* immediately, meaning that we will not go to sleep.
	*/
	rtc_compare_set(rtc_past + (sys_ticks * RTC_TICKS_PER_SYS_TICK));
	#endif
	}


	#ifdef CONFIG_TICKLESS_KERNEL

	/**
	* @brief provides total systicks programmed.
	*
	* returns : total number of sys ticks programmed.
	*/

	uint32_t _get_program_time(void)
	{
	return expected_sys_ticks;
	}

	/**
	* @brief provides total systicks remaining since last programming of RTC.
	*
	* returns : total number of sys ticks remaining since last RTC programming.
	*/

	uint32_t _get_remaining_program_time(void)
	{

	if (!expected_sys_ticks) {
	return 0;
	}

	return (expected_sys_ticks - _get_elapsed_program_time());
	}

	/**
	* @brief provides total systicks passed since last programming of RTC.
	*
	* returns : total number of sys ticks passed since last RTC programming.
	*/

	uint32_t _get_elapsed_program_time(void)
	{
	u32_t rtc_now, rtc_prev, rtc_elapsed;

	if (!expected_sys_ticks) {
	return 0;
	}

	rtc_now = RTC_COUNTER;

	/* Discard value of RTC_COUNTER read at LFCLK transition */
	do {
	/* Number of RTC cycles passed since last RTC Programing*/
	rtc_elapsed = (rtc_now - rtc_past) & RTC_MASK;
	rtc_prev = rtc_now;
	rtc_now = RTC_COUNTER;
	} while (rtc_prev != rtc_now);

	/Convert number of Machine cycles to SYS TICS/
	return (rtc_elapsed / RTC_TICKS_PER_SYS_TICK);
	}


	/**
	* @brief Sets interrupt for rtc compare value for systick time.
	*
	* This Function does following:-
	* 1. Updates expected_sys_ticks equal to time.
	* 2. Update kernel book keeping for time passed since device bootup.
	* 3. Calls routine to set rtc interrupt.
	*/

	void _set_time(uint32_t time)
	{
	if (!time) {
	expected_sys_ticks = 0;
	return;
	}

	/* Update expected_sys_ticls to time to programe*/
	expected_sys_ticks = time;
	_sys_clock_tick_count = _get_elapsed_clock_time();
	/* Update rtc_past to track rtc timer count*/
	rtc_past = (_sys_clock_tick_count * RTC_TICKS_PER_SYS_TICK) & RTC_MASK;

	expected_sys_ticks = expected_sys_ticks > _get_max_clock_time() ?
	_get_max_clock_time() : expected_sys_ticks;

	/* Programe RTC compare register to generate interrupt*/
	rtc_compare_set(rtc_past +
	(expected_sys_ticks * RTC_TICKS_PER_SYS_TICK));

	}

	/**
	* @brief provides time remaining to reach rtc count overflow.
	*
	* This function returns how many sys RTC remaining for rtc to overflow.
	* This will be required when we will program RTC compare value to maximum
	* possible value.
	*
	* returns : difference between current systick and Maximum possible systick.
	*/
	int32_t _get_max_clock_time(void)
	{
	u32_t rtc_now, rtc_prev, rtc_away, sys_away = 0;

	rtc_now = RTC_COUNTER;
	/* Discard value of RTC_COUNTER read at LFCLK transition */
	do {
	rtc_away = (RTC_MASK - rtc_now);
	rtc_away = rtc_away > RTC_HALF ? RTC_HALF : rtc_away;
	rtc_prev = rtc_now;
	/* Calculate time to programe into RTC*/
	rtc_now = RTC_COUNTER;
	} while (rtc_now != rtc_prev);

	/* Convert RTC Ticks to SYS TICKS*/
	if (rtc_away >= RTC_TICKS_PER_SYS_TICK) {
	sys_away = rtc_away / RTC_TICKS_PER_SYS_TICK;
	}
	return sys_away;
	}

	/**
	* @brief Enable sys Clock.
	*
	* This is used to program RTC clock to maximum Clock time in case Clock to
	* remain On.
	*/
	void _enable_sys_clock(void)
	{
	if (!expected_sys_ticks) {
	/* Programe sys tick to Maximum possible value*/
	_set_time(_get_max_clock_time());
	}
	}

	/**
	* @brief provides total systicks passed since device bootup.
	*
	* returns : total number of sys ticks passed since device bootup.
	*/

	uint64_t _get_elapsed_clock_time(void)
	{
	u64_t elapsed;
	u32_t rtc_now, rtc_elapsed, rtc_prev, sys_elapsed;

	rtc_now = RTC_COUNTER;

	/* Discard value of RTC_COUNTER read at LFCLK transition */
	do {
	/* Calculate number of rtc cycles elapsed since RTC programing*/
	rtc_elapsed = (rtc_now - rtc_past) & RTC_MASK;
	elapsed = _sys_clock_tick_count;
	rtc_prev = rtc_now;
	rtc_now = RTC_COUNTER;
	} while (rtc_now != rtc_prev);

	if (rtc_elapsed >= RTC_TICKS_PER_SYS_TICK) {
	/* Convert RTC cycles to SYS TICKS*/
	sys_elapsed = rtc_elapsed / RTC_TICKS_PER_SYS_TICK;
	/* Update total number of SYS_TICKS passed*/
	elapsed += sys_elapsed;
	}
	return elapsed;
	}
	#endif


	/**
	*
	* @brief Handling of tickless idle when interrupted
	*
	* The function will be called by _sys_power_save_idle_exit(), called from
	* _arch_isr_direct_pm() for 'direct' interrupts, or from _isr_wrapper for
	* regular ones, which is called on every IRQ handler if the device was
	* idle, and optionally called when a 'direct' IRQ handler executes if the
	* device was idle.
	*
	* Example 1: Idle sleep is interrupted before time:
	*
	* sys tick timeline: (1) (2) (3) (4) (5) (6)
	* rtc tick timeline : 0----100----200----300----400----500----600
	* ************!*
	* 150 350
	*
	* Assume that _timer_idle_enter() is called at 150 (1) to sleep for 3
	* sys ticks. The last sys tick was announced at 100.
	*
	* On wakeup (non-RTC IRQ at 350):
	*
	* a) Notify how many sys ticks have passed, i.e., 350 - 150 / 100 = 2.
	* b) Schedule next sys tick at 400.
	*
	*/
	void _timer_idle_exit(void)
	{
	#ifdef CONFIG_TICKLESS_KERNEL
	if (!expected_sys_ticks && _sys_clock_always_on) {
	_set_time(_get_max_clock_time());
	}
	#else
	/* Clear the event flag and interrupt in case we woke up on the RTC
	* interrupt. No need to run the RTC ISR since everything that needs
	* to run in the ISR will be done in this call.
	*/
	RTC_CC_EVENT = 0;
	NVIC_ClearPendingIRQ(NRF5_IRQ_RTC1_IRQn);

	rtc_announce_set_next();

	/* After exiting idle, the kernel no longer expects more than one sys
	* ticks to have passed when _sys_clock_tick_announce() is called.
	*/
	expected_sys_ticks = 1;
	#endif
	}
	#endif /* CONFIG_TICKLESS_IDLE */

	/*
	* @brief Announces the number of sys ticks that have passed since the last
	* announcement, if any, and programs the RTC to trigger the interrupt on the
	* next sys tick.
	*
	* The ISR is set pending due to a regular sys tick and after exiting idle mode
	* as scheduled.
	*
	* Since this ISR can be preempted, we need to take some provisions to announce
	* all expected sys ticks that have passed.
	*
	* Consider the following example:
	*
	* sys tick timeline: (1) (2) (3) (4) (5) (6)
	* rtc tick timeline : 0----100----200----300----400----500----600
	* !**********
	* 450
	*
	* The last sys tick was anounced at 200, i.e, rtc_past = 200. The ISR is
	* executed at the next sys tick, i.e. 300. The following sys tick is due at
	* 400. However, the ISR is preempted for a number of sys ticks, until 450 in
	* this example. The ISR will then announce the number of sys ticks it was
	* delayed (2), and schedule the next sys tick (5) at 500.
	*/
	static void rtc1_nrf5_isr(void *arg)
	{

	ARG_UNUSED(arg);
	RTC_CC_EVENT = 0;

	#ifdef CONFIG_EXECUTION_BENCHMARKING
	extern void read_timer_start_of_tick_handler(void);
	read_timer_start_of_tick_handler();
	#endif

	#ifdef CONFIG_TICKLESS_KERNEL
	_sys_idle_elapsed_ticks = expected_sys_ticks;
	/* Initialize expected sys tick,
	* It will be later updated based on next timeout.
	*/
	expected_sys_ticks = 0;
	/* Anounce elapsed of _sys_idle_elapsed_ticks systicks*/
	_sys_clock_tick_announce();
	#else
	rtc_announce_set_next();
	#endif

	#ifdef CONFIG_EXECUTION_BENCHMARKING
	extern void read_timer_end_of_tick_handler(void);
	read_timer_end_of_tick_handler();
	#endif

	}

	int _sys_clock_driver_init(struct device *device)
	{
	struct device *clock;

	ARG_UNUSED(device);

	clock = device_get_binding(CONFIG_CLOCK_CONTROL_NRF5_K32SRC_DRV_NAME);
	if (!clock) {
	return -1;
	}

	clock_control_on(clock, (void *)CLOCK_CONTROL_NRF5_K32SRC);

	rtc_past = 0;

	#ifdef CONFIG_TICKLESS_IDLE
	expected_sys_ticks = 1;
	#endif /* CONFIG_TICKLESS_IDLE */

	/* TODO: replace with counter driver to access RTC */
	SYS_CLOCK_RTC->PRESCALER = 0;
	SYS_CLOCK_RTC->CC[0] = RTC_TICKS_PER_SYS_TICK;
	SYS_CLOCK_RTC->EVTENSET = RTC_EVTENSET_COMPARE0_Msk;
	SYS_CLOCK_RTC->INTENSET = RTC_INTENSET_COMPARE0_Msk;

	/* Clear the event flag and possible pending interrupt */
	RTC_CC_EVENT = 0;
	NVIC_ClearPendingIRQ(NRF5_IRQ_RTC1_IRQn);

	IRQ_CONNECT(NRF5_IRQ_RTC1_IRQn, 1, rtc1_nrf5_isr, 0, 0);
	irq_enable(NRF5_IRQ_RTC1_IRQn);

	SYS_CLOCK_RTC->TASKS_CLEAR = 1;
	SYS_CLOCK_RTC->TASKS_START = 1;

	return 0;
	}

	u32_t _timer_cycle_get_32(void)
	{
	u32_t elapsed_cycles;
	u32_t sys_clock_tick_count;
	u32_t rtc_prev;
	u32_t rtc_now;

	rtc_now = RTC_COUNTER;
	/* Discard value of RTC_COUNTER read at LFCLK transition */
	do {
	sys_clock_tick_count = _sys_clock_tick_count;
	elapsed_cycles = (rtc_now - (sys_clock_tick_count *
	RTC_TICKS_PER_SYS_TICK)) &
	RTC_MASK;
	rtc_prev = rtc_now;
	rtc_now = RTC_COUNTER;
	} while (rtc_now != rtc_prev);

	return (sys_clock_tick_count * sys_clock_hw_cycles_per_tick) +
	elapsed_cycles;
	}

	#ifdef CONFIG_SYSTEM_CLOCK_DISABLE
	/**
	*
	* @brief Stop announcing sys ticks into the kernel
	*
	* This routine disables the RTC1 so that timer interrupts are no
	* longer delivered.
	*
	* @return N/A
	*/
	void sys_clock_disable(void)
	{
	unsigned int key;

	key = irq_lock();

	irq_disable(NRF5_IRQ_RTC1_IRQn);

	SYS_CLOCK_RTC->EVTENCLR = RTC_EVTENCLR_COMPARE0_Msk;
	SYS_CLOCK_RTC->INTENCLR = RTC_INTENCLR_COMPARE0_Msk;

	SYS_CLOCK_RTC->TASKS_STOP = 1;
	SYS_CLOCK_RTC->TASKS_CLEAR = 1;

	irq_unlock(key);

	/* TODO: turn off (release) 32 KHz clock source.
	* Turning off of 32 KHz clock source is not implemented in clock
	* driver.
	*/
	}
	#endif /* CONFIG_SYSTEM_CLOCK_DISABLE */