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

 /*
  * Copyright (c) 2018 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/kernel.h>
 #include <zephyr/spinlock.h>
 #include <ksched.h>
 #include <zephyr/timeout_q.h>
 #include <zephyr/syscall_handler.h>
 #include <zephyr/drivers/timer/system_timer.h>
 #include <zephyr/sys_clock.h>

 static uint64_t curr_tick;

 static sys_dlist_t timeout_list = SYS_DLIST_STATIC_INIT(&timeout_list);

 static struct k_spinlock timeout_lock;

 #define MAX_WAIT (IS_ENABLED(CONFIG_SYSTEM_CLOCK_SLOPPY_IDLE) \
 		  ? K_TICKS_FOREVER : INT_MAX)

 /* Cycles left to process in the currently-executing sys_clock_announce() */
 static int announce_remaining;

 #if defined(CONFIG_TIMER_READS_ITS_FREQUENCY_AT_RUNTIME)
 int z_clock_hw_cycles_per_sec = CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC;

 #ifdef CONFIG_USERSPACE
 static inline int z_vrfy_sys_clock_hw_cycles_per_sec_runtime_get(void)
 {
 	return z_impl_sys_clock_hw_cycles_per_sec_runtime_get();
 }
 #include <syscalls/sys_clock_hw_cycles_per_sec_runtime_get_mrsh.c>
 #endif /* CONFIG_USERSPACE */
 #endif /* CONFIG_TIMER_READS_ITS_FREQUENCY_AT_RUNTIME */

 static struct _timeout *first(void)
 {
 	sys_dnode_t *t = sys_dlist_peek_head(&timeout_list);

 	return t == NULL ? NULL : CONTAINER_OF(t, struct _timeout, node);
 }

 static struct _timeout *next(struct _timeout *t)
 {
 	sys_dnode_t *n = sys_dlist_peek_next(&timeout_list, &t->node);

 	return n == NULL ? NULL : CONTAINER_OF(n, struct _timeout, node);
 }

 static void remove_timeout(struct _timeout *t)
 {
 	if (next(t) != NULL) {
 		next(t)->dticks += t->dticks;
 	}

 	sys_dlist_remove(&t->node);
 }

 static int32_t elapsed(void)
 {
 	return announce_remaining == 0 ? sys_clock_elapsed() : 0U;
 }

 static int32_t next_timeout(void)
 {
 	struct _timeout *to = first();
 	int32_t ticks_elapsed = elapsed();
 	int32_t ret;

 	if ((to == NULL) ||
 	    ((int64_t)(to->dticks - ticks_elapsed) > (int64_t)INT_MAX)) {
 		ret = MAX_WAIT;
 	} else {
 		ret = MAX(0, to->dticks - ticks_elapsed);
 	}

 #ifdef CONFIG_TIMESLICING
 	if (_current_cpu->slice_ticks && _current_cpu->slice_ticks < ret) {
 		ret = _current_cpu->slice_ticks;
 	}
 #endif
 	return ret;
 }

 void z_add_timeout(struct _timeout *to, _timeout_func_t fn,
 		   k_timeout_t timeout)
 {
 	if (K_TIMEOUT_EQ(timeout, K_FOREVER)) {
 		return;
 	}

 #ifdef CONFIG_KERNEL_COHERENCE
 	__ASSERT_NO_MSG(arch_mem_coherent(to));
 #endif

 	__ASSERT(!sys_dnode_is_linked(&to->node), "");
 	to->fn = fn;

 	LOCKED(&timeout_lock) {
 		struct _timeout *t;

 		if (IS_ENABLED(CONFIG_TIMEOUT_64BIT) &&
 		    Z_TICK_ABS(timeout.ticks) >= 0) {
 			k_ticks_t ticks = Z_TICK_ABS(timeout.ticks) - curr_tick;

 			to->dticks = MAX(1, ticks);
 		} else {
 			to->dticks = timeout.ticks + 1 + elapsed();
 		}

 		for (t = first(); t != NULL; t = next(t)) {
 			if (t->dticks > to->dticks) {
 				t->dticks -= to->dticks;
 				sys_dlist_insert(&t->node, &to->node);
 				break;
 			}
 			to->dticks -= t->dticks;
 		}

 		if (t == NULL) {
 			sys_dlist_append(&timeout_list, &to->node);
 		}

 		if (to == first()) {
 #if CONFIG_TIMESLICING
 			/*
 			 * This is not ideal, since it does not
 			 * account the time elapsed since the
 			 * last announcement, and slice_ticks is based
 			 * on that. It means that the time remaining for
 			 * the next announcement can be less than
 			 * slice_ticks.
 			 */
 			int32_t next_time = next_timeout();

 			if (next_time == 0 ||
 			    _current_cpu->slice_ticks != next_time) {
 				sys_clock_set_timeout(next_time, false);
 			}
 #else
 			sys_clock_set_timeout(next_timeout(), false);
 #endif	/* CONFIG_TIMESLICING */
 		}
 	}
 }

 int z_abort_timeout(struct _timeout *to)
 {
 	int ret = -EINVAL;

 	LOCKED(&timeout_lock) {
 		if (sys_dnode_is_linked(&to->node)) {
 			remove_timeout(to);
 			ret = 0;
 		}
 	}

 	return ret;
 }

 /* must be locked */
 static k_ticks_t timeout_rem(const struct _timeout *timeout)
 {
 	k_ticks_t ticks = 0;

 	if (z_is_inactive_timeout(timeout)) {
 		return 0;
 	}

 	for (struct _timeout *t = first(); t != NULL; t = next(t)) {
 		ticks += t->dticks;
 		if (timeout == t) {
 			break;
 		}
 	}

 	return ticks - elapsed();
 }

 k_ticks_t z_timeout_remaining(const struct _timeout *timeout)
 {
 	k_ticks_t ticks = 0;

 	LOCKED(&timeout_lock) {
 		ticks = timeout_rem(timeout);
 	}

 	return ticks;
 }

 k_ticks_t z_timeout_expires(const struct _timeout *timeout)
 {
 	k_ticks_t ticks = 0;

 	LOCKED(&timeout_lock) {
 		ticks = curr_tick + timeout_rem(timeout);
 	}

 	return ticks;
 }

 int32_t z_get_next_timeout_expiry(void)
 {
 	int32_t ret = (int32_t) K_TICKS_FOREVER;

 	LOCKED(&timeout_lock) {
 		ret = next_timeout();
 	}
 	return ret;
 }

 void z_set_timeout_expiry(int32_t ticks, bool is_idle)
 {
 	LOCKED(&timeout_lock) {
 		int next_to = next_timeout();
 		bool sooner = (next_to == K_TICKS_FOREVER)
 			      || (ticks <= next_to);
 		bool imminent = next_to <= 1;

 		/* Only set new timeouts when they are sooner than
 		 * what we have.  Also don't try to set a timeout when
 		 * one is about to expire: drivers have internal logic
 		 * that will bump the timeout to the "next" tick if
 		 * it's not considered to be settable as directed.
 		 * SMP can't use this optimization though: we don't
 		 * know when context switches happen until interrupt
 		 * exit and so can't get the timeslicing clamp folded
 		 * in.
 		 */
 		if (!imminent && (sooner || IS_ENABLED(CONFIG_SMP))) {
 			sys_clock_set_timeout(MIN(ticks, next_to), is_idle);
 		}
 	}
 }

 void sys_clock_announce(int32_t ticks)
 {
 #ifdef CONFIG_TIMESLICING
 	z_time_slice(ticks);
 #endif

 	k_spinlock_key_t key = k_spin_lock(&timeout_lock);

 	/* We release the lock around the callbacks below, so on SMP
 	 * systems someone might be already running the loop.  Don't
 	 * race (which will cause paralllel execution of "sequential"
 	 * timeouts and confuse apps), just increment the tick count
 	 * and return.
 	 */
 	if (IS_ENABLED(CONFIG_SMP) && (announce_remaining != 0)) {
 		announce_remaining += ticks;
 		k_spin_unlock(&timeout_lock, key);
 		return;
 	}

 	announce_remaining = ticks;

 	while (first() != NULL && first()->dticks <= announce_remaining) {
 		struct _timeout *t = first();
 		int dt = t->dticks;

 		curr_tick += dt;
 		t->dticks = 0;
 		remove_timeout(t);

 		k_spin_unlock(&timeout_lock, key);
 		t->fn(t);
 		key = k_spin_lock(&timeout_lock);
 		announce_remaining -= dt;
 	}

 	if (first() != NULL) {
 		first()->dticks -= announce_remaining;
 	}

 	curr_tick += announce_remaining;
 	announce_remaining = 0;

 	sys_clock_set_timeout(next_timeout(), false);

 	k_spin_unlock(&timeout_lock, key);
 }

 int64_t sys_clock_tick_get(void)
 {
 	uint64_t t = 0U;

 	LOCKED(&timeout_lock) {
 		t = curr_tick + elapsed();
 	}
 	return t;
 }

 uint32_t sys_clock_tick_get_32(void)
 {
 #ifdef CONFIG_TICKLESS_KERNEL
 	return (uint32_t)sys_clock_tick_get();
 #else
 	return (uint32_t)curr_tick;
 #endif
 }

 int64_t z_impl_k_uptime_ticks(void)
 {
 	return sys_clock_tick_get();
 }

 #ifdef CONFIG_USERSPACE
 static inline int64_t z_vrfy_k_uptime_ticks(void)
 {
 	return z_impl_k_uptime_ticks();
 }
 #include <syscalls/k_uptime_ticks_mrsh.c>
 #endif

 void z_impl_k_busy_wait(uint32_t usec_to_wait)
 {
 	SYS_PORT_TRACING_FUNC_ENTER(k_thread, busy_wait, usec_to_wait);
 	if (usec_to_wait == 0U) {
 		SYS_PORT_TRACING_FUNC_EXIT(k_thread, busy_wait, usec_to_wait);
 		return;
 	}

 #if !defined(CONFIG_ARCH_HAS_CUSTOM_BUSY_WAIT)
 	uint32_t start_cycles = k_cycle_get_32();

 	/* use 64-bit math to prevent overflow when multiplying */
 	uint32_t cycles_to_wait = (uint32_t)(
 		(uint64_t)usec_to_wait *
 		(uint64_t)sys_clock_hw_cycles_per_sec() /
 		(uint64_t)USEC_PER_SEC
 	);

 	for (;;) {
 		uint32_t current_cycles = k_cycle_get_32();

 		/* this handles the rollover on an unsigned 32-bit value */
 		if ((current_cycles - start_cycles) >= cycles_to_wait) {
 			break;
 		}
 	}
 #else
 	arch_busy_wait(usec_to_wait);
 #endif /* CONFIG_ARCH_HAS_CUSTOM_BUSY_WAIT */
 	SYS_PORT_TRACING_FUNC_EXIT(k_thread, busy_wait, usec_to_wait);
 }

 #ifdef CONFIG_USERSPACE
 static inline void z_vrfy_k_busy_wait(uint32_t usec_to_wait)
 {
 	z_impl_k_busy_wait(usec_to_wait);
 }
 #include <syscalls/k_busy_wait_mrsh.c>
 #endif /* CONFIG_USERSPACE */

 /* Returns the uptime expiration (relative to an unlocked "now"!) of a
  * timeout object.  When used correctly, this should be called once,
  * synchronously with the user passing a new timeout value.  It should
  * not be used iteratively to adjust a timeout.
  */
 uint64_t sys_clock_timeout_end_calc(k_timeout_t timeout)
 {
 	k_ticks_t dt;

 	if (K_TIMEOUT_EQ(timeout, K_FOREVER)) {
 		return UINT64_MAX;
 	} else if (K_TIMEOUT_EQ(timeout, K_NO_WAIT)) {
 		return sys_clock_tick_get();
 	} else {

 		dt = timeout.ticks;

 		if (IS_ENABLED(CONFIG_TIMEOUT_64BIT) && Z_TICK_ABS(dt) >= 0) {
 			return Z_TICK_ABS(dt);
 		}
 		return sys_clock_tick_get() + MAX(1, dt);
 	}
 }
	/*
	* Copyright (c) 2018 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/kernel.h>
	#include <zephyr/spinlock.h>
	#include <ksched.h>
	#include <zephyr/timeout_q.h>
	#include <zephyr/syscall_handler.h>
	#include <zephyr/drivers/timer/system_timer.h>
	#include <zephyr/sys_clock.h>

	static uint64_t curr_tick;

	static sys_dlist_t timeout_list = SYS_DLIST_STATIC_INIT(&timeout_list);

	static struct k_spinlock timeout_lock;

	#define MAX_WAIT (IS_ENABLED(CONFIG_SYSTEM_CLOCK_SLOPPY_IDLE) \
	? K_TICKS_FOREVER : INT_MAX)

	/* Cycles left to process in the currently-executing sys_clock_announce() */
	static int announce_remaining;

	#if defined(CONFIG_TIMER_READS_ITS_FREQUENCY_AT_RUNTIME)
	int z_clock_hw_cycles_per_sec = CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC;

	#ifdef CONFIG_USERSPACE
	static inline int z_vrfy_sys_clock_hw_cycles_per_sec_runtime_get(void)
	{
	return z_impl_sys_clock_hw_cycles_per_sec_runtime_get();
	}
	#include <syscalls/sys_clock_hw_cycles_per_sec_runtime_get_mrsh.c>
	#endif /* CONFIG_USERSPACE */
	#endif /* CONFIG_TIMER_READS_ITS_FREQUENCY_AT_RUNTIME */

	static struct _timeout *first(void)
	{
	sys_dnode_t *t = sys_dlist_peek_head(&timeout_list);

	return t == NULL ? NULL : CONTAINER_OF(t, struct _timeout, node);
	}

	static struct _timeout next(struct _timeout t)
	{
	sys_dnode_t *n = sys_dlist_peek_next(&timeout_list, &t->node);

	return n == NULL ? NULL : CONTAINER_OF(n, struct _timeout, node);
	}

	static void remove_timeout(struct _timeout *t)
	{
	if (next(t) != NULL) {
	next(t)->dticks += t->dticks;
	}

	sys_dlist_remove(&t->node);
	}

	static int32_t elapsed(void)
	{
	return announce_remaining == 0 ? sys_clock_elapsed() : 0U;
	}

	static int32_t next_timeout(void)
	{
	struct _timeout *to = first();
	int32_t ticks_elapsed = elapsed();
	int32_t ret;

	if ((to == NULL) \|\|
	((int64_t)(to->dticks - ticks_elapsed) > (int64_t)INT_MAX)) {
	ret = MAX_WAIT;
	} else {
	ret = MAX(0, to->dticks - ticks_elapsed);
	}

	#ifdef CONFIG_TIMESLICING
	if (_current_cpu->slice_ticks && _current_cpu->slice_ticks < ret) {
	ret = _current_cpu->slice_ticks;
	}
	#endif
	return ret;
	}

	void z_add_timeout(struct _timeout *to, _timeout_func_t fn,
	k_timeout_t timeout)
	{
	if (K_TIMEOUT_EQ(timeout, K_FOREVER)) {
	return;
	}

	#ifdef CONFIG_KERNEL_COHERENCE
	__ASSERT_NO_MSG(arch_mem_coherent(to));
	#endif

	__ASSERT(!sys_dnode_is_linked(&to->node), "");
	to->fn = fn;

	LOCKED(&timeout_lock) {
	struct _timeout *t;

	if (IS_ENABLED(CONFIG_TIMEOUT_64BIT) &&
	Z_TICK_ABS(timeout.ticks) >= 0) {
	k_ticks_t ticks = Z_TICK_ABS(timeout.ticks) - curr_tick;

	to->dticks = MAX(1, ticks);
	} else {
	to->dticks = timeout.ticks + 1 + elapsed();
	}

	for (t = first(); t != NULL; t = next(t)) {
	if (t->dticks > to->dticks) {
	t->dticks -= to->dticks;
	sys_dlist_insert(&t->node, &to->node);
	break;
	}
	to->dticks -= t->dticks;
	}

	if (t == NULL) {
	sys_dlist_append(&timeout_list, &to->node);
	}

	if (to == first()) {
	#if CONFIG_TIMESLICING
	/*
	* This is not ideal, since it does not
	* account the time elapsed since the
	* last announcement, and slice_ticks is based
	* on that. It means that the time remaining for
	* the next announcement can be less than
	* slice_ticks.
	*/
	int32_t next_time = next_timeout();

	if (next_time == 0 \|\|
	_current_cpu->slice_ticks != next_time) {
	sys_clock_set_timeout(next_time, false);
	}
	#else
	sys_clock_set_timeout(next_timeout(), false);
	#endif /* CONFIG_TIMESLICING */
	}
	}
	}

	int z_abort_timeout(struct _timeout *to)
	{
	int ret = -EINVAL;

	LOCKED(&timeout_lock) {
	if (sys_dnode_is_linked(&to->node)) {
	remove_timeout(to);
	ret = 0;
	}
	}

	return ret;
	}

	/* must be locked */
	static k_ticks_t timeout_rem(const struct _timeout *timeout)
	{
	k_ticks_t ticks = 0;

	if (z_is_inactive_timeout(timeout)) {
	return 0;
	}

	for (struct _timeout *t = first(); t != NULL; t = next(t)) {
	ticks += t->dticks;
	if (timeout == t) {
	break;
	}
	}

	return ticks - elapsed();
	}

	k_ticks_t z_timeout_remaining(const struct _timeout *timeout)
	{
	k_ticks_t ticks = 0;

	LOCKED(&timeout_lock) {
	ticks = timeout_rem(timeout);
	}

	return ticks;
	}

	k_ticks_t z_timeout_expires(const struct _timeout *timeout)
	{
	k_ticks_t ticks = 0;

	LOCKED(&timeout_lock) {
	ticks = curr_tick + timeout_rem(timeout);
	}

	return ticks;
	}

	int32_t z_get_next_timeout_expiry(void)
	{
	int32_t ret = (int32_t) K_TICKS_FOREVER;

	LOCKED(&timeout_lock) {
	ret = next_timeout();
	}
	return ret;
	}

	void z_set_timeout_expiry(int32_t ticks, bool is_idle)
	{
	LOCKED(&timeout_lock) {
	int next_to = next_timeout();
	bool sooner = (next_to == K_TICKS_FOREVER)
	\|\| (ticks <= next_to);
	bool imminent = next_to <= 1;

	/* Only set new timeouts when they are sooner than
	* what we have. Also don't try to set a timeout when
	* one is about to expire: drivers have internal logic
	* that will bump the timeout to the "next" tick if
	* it's not considered to be settable as directed.
	* SMP can't use this optimization though: we don't
	* know when context switches happen until interrupt
	* exit and so can't get the timeslicing clamp folded
	* in.
	*/
	if (!imminent && (sooner \|\| IS_ENABLED(CONFIG_SMP))) {
	sys_clock_set_timeout(MIN(ticks, next_to), is_idle);
	}
	}
	}

	void sys_clock_announce(int32_t ticks)
	{
	#ifdef CONFIG_TIMESLICING
	z_time_slice(ticks);
	#endif

	k_spinlock_key_t key = k_spin_lock(&timeout_lock);

	/* We release the lock around the callbacks below, so on SMP
	* systems someone might be already running the loop. Don't
	* race (which will cause paralllel execution of "sequential"
	* timeouts and confuse apps), just increment the tick count
	* and return.
	*/
	if (IS_ENABLED(CONFIG_SMP) && (announce_remaining != 0)) {
	announce_remaining += ticks;
	k_spin_unlock(&timeout_lock, key);
	return;
	}

	announce_remaining = ticks;

	while (first() != NULL && first()->dticks <= announce_remaining) {
	struct _timeout *t = first();
	int dt = t->dticks;

	curr_tick += dt;
	t->dticks = 0;
	remove_timeout(t);

	k_spin_unlock(&timeout_lock, key);
	t->fn(t);
	key = k_spin_lock(&timeout_lock);
	announce_remaining -= dt;
	}

	if (first() != NULL) {
	first()->dticks -= announce_remaining;
	}

	curr_tick += announce_remaining;
	announce_remaining = 0;

	sys_clock_set_timeout(next_timeout(), false);

	k_spin_unlock(&timeout_lock, key);
	}

	int64_t sys_clock_tick_get(void)
	{
	uint64_t t = 0U;

	LOCKED(&timeout_lock) {
	t = curr_tick + elapsed();
	}
	return t;
	}

	uint32_t sys_clock_tick_get_32(void)
	{
	#ifdef CONFIG_TICKLESS_KERNEL
	return (uint32_t)sys_clock_tick_get();
	#else
	return (uint32_t)curr_tick;
	#endif
	}

	int64_t z_impl_k_uptime_ticks(void)
	{
	return sys_clock_tick_get();
	}

	#ifdef CONFIG_USERSPACE
	static inline int64_t z_vrfy_k_uptime_ticks(void)
	{
	return z_impl_k_uptime_ticks();
	}
	#include <syscalls/k_uptime_ticks_mrsh.c>
	#endif

	void z_impl_k_busy_wait(uint32_t usec_to_wait)
	{
	SYS_PORT_TRACING_FUNC_ENTER(k_thread, busy_wait, usec_to_wait);
	if (usec_to_wait == 0U) {
	SYS_PORT_TRACING_FUNC_EXIT(k_thread, busy_wait, usec_to_wait);
	return;
	}

	#if !defined(CONFIG_ARCH_HAS_CUSTOM_BUSY_WAIT)
	uint32_t start_cycles = k_cycle_get_32();

	/* use 64-bit math to prevent overflow when multiplying */
	uint32_t cycles_to_wait = (uint32_t)(
	(uint64_t)usec_to_wait *
	(uint64_t)sys_clock_hw_cycles_per_sec() /
	(uint64_t)USEC_PER_SEC
	);

	for (;;) {
	uint32_t current_cycles = k_cycle_get_32();

	/* this handles the rollover on an unsigned 32-bit value */
	if ((current_cycles - start_cycles) >= cycles_to_wait) {
	break;
	}
	}
	#else
	arch_busy_wait(usec_to_wait);
	#endif /* CONFIG_ARCH_HAS_CUSTOM_BUSY_WAIT */
	SYS_PORT_TRACING_FUNC_EXIT(k_thread, busy_wait, usec_to_wait);
	}

	#ifdef CONFIG_USERSPACE
	static inline void z_vrfy_k_busy_wait(uint32_t usec_to_wait)
	{
	z_impl_k_busy_wait(usec_to_wait);
	}
	#include <syscalls/k_busy_wait_mrsh.c>
	#endif /* CONFIG_USERSPACE */

	/* Returns the uptime expiration (relative to an unlocked "now"!) of a
	* timeout object. When used correctly, this should be called once,
	* synchronously with the user passing a new timeout value. It should
	* not be used iteratively to adjust a timeout.
	*/
	uint64_t sys_clock_timeout_end_calc(k_timeout_t timeout)
	{
	k_ticks_t dt;

	if (K_TIMEOUT_EQ(timeout, K_FOREVER)) {
	return UINT64_MAX;
	} else if (K_TIMEOUT_EQ(timeout, K_NO_WAIT)) {
	return sys_clock_tick_get();
	} else {

	dt = timeout.ticks;

	if (IS_ENABLED(CONFIG_TIMEOUT_64BIT) && Z_TICK_ABS(dt) >= 0) {
	return Z_TICK_ABS(dt);
	}
	return sys_clock_tick_get() + MAX(1, dt);
	}
	}