366 lines
9.5 KiB
C
366 lines
9.5 KiB
C
/*
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* Copyright (c) 1997-2016 Wind River Systems, Inc.
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include <zephyr/kernel.h>
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#include <zephyr/init.h>
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#include <zephyr/internal/syscall_handler.h>
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#include <stdbool.h>
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#include <zephyr/spinlock.h>
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#include <ksched.h>
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#include <wait_q.h>
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static struct k_spinlock lock;
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#ifdef CONFIG_OBJ_CORE_TIMER
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static struct k_obj_type obj_type_timer;
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#endif /* CONFIG_OBJ_CORE_TIMER */
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/**
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* @brief Handle expiration of a kernel timer object.
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*
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* @param t Timeout used by the timer.
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*/
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void z_timer_expiration_handler(struct _timeout *t)
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{
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struct k_timer *timer = CONTAINER_OF(t, struct k_timer, timeout);
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struct k_thread *thread;
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k_spinlock_key_t key = k_spin_lock(&lock);
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/* In sys_clock_announce(), when a timeout expires, it is first removed
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* from the timeout list, then its expiration handler is called (with
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* unlocked interrupts). For kernel timers, the expiration handler is
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* this function. Usually, the timeout structure related to the timer
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* that is handled here will not be linked to the timeout list at this
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* point. But it may happen that before this function is executed and
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* interrupts are locked again, a given timer gets restarted from an
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* interrupt context that has a priority higher than the system timer
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* interrupt. Then, the timeout structure for this timer will turn out
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* to be linked to the timeout list. And in such case, since the timer
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* was restarted, its expiration handler should not be executed then,
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* so the function exits immediately.
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*/
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if (sys_dnode_is_linked(&t->node)) {
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k_spin_unlock(&lock, key);
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return;
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}
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/*
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* if the timer is periodic, start it again; don't add _TICK_ALIGN
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* since we're already aligned to a tick boundary
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*/
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if (!K_TIMEOUT_EQ(timer->period, K_NO_WAIT) &&
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!K_TIMEOUT_EQ(timer->period, K_FOREVER)) {
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k_timeout_t next = timer->period;
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/* see note about z_add_timeout() in z_impl_k_timer_start() */
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next.ticks = MAX(next.ticks - 1, 0);
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#ifdef CONFIG_TIMEOUT_64BIT
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/* Exploit the fact that uptime during a kernel
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* timeout handler reflects the time of the scheduled
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* event and not real time to get some inexpensive
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* protection against late interrupts. If we're
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* delayed for any reason, we still end up calculating
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* the next expiration as a regular stride from where
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* we "should" have run. Requires absolute timeouts.
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* (Note offset by one: we're nominally at the
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* beginning of a tick, so need to defeat the "round
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* down" behavior on timeout addition).
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*/
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next = K_TIMEOUT_ABS_TICKS(k_uptime_ticks() + 1 + next.ticks);
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#endif /* CONFIG_TIMEOUT_64BIT */
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z_add_timeout(&timer->timeout, z_timer_expiration_handler,
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next);
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}
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/* update timer's status */
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timer->status += 1U;
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/* invoke timer expiry function */
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if (timer->expiry_fn != NULL) {
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/* Unlock for user handler. */
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k_spin_unlock(&lock, key);
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timer->expiry_fn(timer);
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key = k_spin_lock(&lock);
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}
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if (!IS_ENABLED(CONFIG_MULTITHREADING)) {
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k_spin_unlock(&lock, key);
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return;
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}
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thread = z_waitq_head(&timer->wait_q);
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if (thread == NULL) {
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k_spin_unlock(&lock, key);
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return;
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}
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z_unpend_thread_no_timeout(thread);
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arch_thread_return_value_set(thread, 0);
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k_spin_unlock(&lock, key);
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z_ready_thread(thread);
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}
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void k_timer_init(struct k_timer *timer,
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k_timer_expiry_t expiry_fn,
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k_timer_stop_t stop_fn)
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{
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timer->expiry_fn = expiry_fn;
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timer->stop_fn = stop_fn;
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timer->status = 0U;
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if (IS_ENABLED(CONFIG_MULTITHREADING)) {
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z_waitq_init(&timer->wait_q);
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}
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z_init_timeout(&timer->timeout);
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SYS_PORT_TRACING_OBJ_INIT(k_timer, timer);
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timer->user_data = NULL;
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k_object_init(timer);
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#ifdef CONFIG_OBJ_CORE_TIMER
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k_obj_core_init_and_link(K_OBJ_CORE(timer), &obj_type_timer);
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#endif /* CONFIG_OBJ_CORE_TIMER */
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}
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void z_impl_k_timer_start(struct k_timer *timer, k_timeout_t duration,
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k_timeout_t period)
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{
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SYS_PORT_TRACING_OBJ_FUNC(k_timer, start, timer, duration, period);
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/* Acquire spinlock to ensure safety during concurrent calls to
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* k_timer_start for scheduling or rescheduling. This is necessary
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* since k_timer_start can be preempted, especially for the same
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* timer instance.
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*/
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k_spinlock_key_t key = k_spin_lock(&lock);
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if (K_TIMEOUT_EQ(duration, K_FOREVER)) {
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k_spin_unlock(&lock, key);
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return;
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}
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/* z_add_timeout() always adds one to the incoming tick count
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* to round up to the next tick (by convention it waits for
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* "at least as long as the specified timeout"), but the
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* period interval is always guaranteed to be reset from
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* within the timer ISR, so no round up is desired and 1 is
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* subtracted in there.
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*
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* Note that the duration (!) value gets the same treatment
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* for backwards compatibility. This is unfortunate
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* (i.e. k_timer_start() doesn't treat its initial sleep
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* argument the same way k_sleep() does), but historical. The
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* timer_api test relies on this behavior.
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*/
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if (Z_TICK_ABS(duration.ticks) < 0) {
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duration.ticks = MAX(duration.ticks - 1, 0);
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}
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(void)z_abort_timeout(&timer->timeout);
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timer->period = period;
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timer->status = 0U;
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z_add_timeout(&timer->timeout, z_timer_expiration_handler,
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duration);
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k_spin_unlock(&lock, key);
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}
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#ifdef CONFIG_USERSPACE
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static inline void z_vrfy_k_timer_start(struct k_timer *timer,
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k_timeout_t duration,
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k_timeout_t period)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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z_impl_k_timer_start(timer, duration, period);
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}
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#include <syscalls/k_timer_start_mrsh.c>
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#endif /* CONFIG_USERSPACE */
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void z_impl_k_timer_stop(struct k_timer *timer)
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{
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SYS_PORT_TRACING_OBJ_FUNC(k_timer, stop, timer);
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bool inactive = (z_abort_timeout(&timer->timeout) != 0);
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if (inactive) {
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return;
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}
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if (timer->stop_fn != NULL) {
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timer->stop_fn(timer);
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}
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if (IS_ENABLED(CONFIG_MULTITHREADING)) {
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struct k_thread *pending_thread = z_unpend1_no_timeout(&timer->wait_q);
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if (pending_thread != NULL) {
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z_ready_thread(pending_thread);
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z_reschedule_unlocked();
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}
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}
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}
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#ifdef CONFIG_USERSPACE
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static inline void z_vrfy_k_timer_stop(struct k_timer *timer)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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z_impl_k_timer_stop(timer);
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}
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#include <syscalls/k_timer_stop_mrsh.c>
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#endif /* CONFIG_USERSPACE */
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uint32_t z_impl_k_timer_status_get(struct k_timer *timer)
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{
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k_spinlock_key_t key = k_spin_lock(&lock);
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uint32_t result = timer->status;
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timer->status = 0U;
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k_spin_unlock(&lock, key);
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return result;
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}
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#ifdef CONFIG_USERSPACE
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static inline uint32_t z_vrfy_k_timer_status_get(struct k_timer *timer)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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return z_impl_k_timer_status_get(timer);
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}
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#include <syscalls/k_timer_status_get_mrsh.c>
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#endif /* CONFIG_USERSPACE */
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uint32_t z_impl_k_timer_status_sync(struct k_timer *timer)
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{
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__ASSERT(!arch_is_in_isr(), "");
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SYS_PORT_TRACING_OBJ_FUNC_ENTER(k_timer, status_sync, timer);
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if (!IS_ENABLED(CONFIG_MULTITHREADING)) {
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uint32_t result;
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do {
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k_spinlock_key_t key = k_spin_lock(&lock);
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if (!z_is_inactive_timeout(&timer->timeout)) {
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result = *(volatile uint32_t *)&timer->status;
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timer->status = 0U;
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k_spin_unlock(&lock, key);
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if (result > 0) {
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break;
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}
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} else {
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result = timer->status;
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k_spin_unlock(&lock, key);
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break;
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}
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} while (true);
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return result;
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}
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k_spinlock_key_t key = k_spin_lock(&lock);
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uint32_t result = timer->status;
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if (result == 0U) {
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if (!z_is_inactive_timeout(&timer->timeout)) {
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SYS_PORT_TRACING_OBJ_FUNC_BLOCKING(k_timer, status_sync, timer, K_FOREVER);
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/* wait for timer to expire or stop */
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(void)z_pend_curr(&lock, key, &timer->wait_q, K_FOREVER);
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/* get updated timer status */
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key = k_spin_lock(&lock);
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result = timer->status;
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} else {
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/* timer is already stopped */
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}
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} else {
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/* timer has already expired at least once */
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}
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timer->status = 0U;
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k_spin_unlock(&lock, key);
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/**
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* @note New tracing hook
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*/
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SYS_PORT_TRACING_OBJ_FUNC_EXIT(k_timer, status_sync, timer, result);
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return result;
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}
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#ifdef CONFIG_USERSPACE
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static inline uint32_t z_vrfy_k_timer_status_sync(struct k_timer *timer)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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return z_impl_k_timer_status_sync(timer);
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}
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#include <syscalls/k_timer_status_sync_mrsh.c>
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static inline k_ticks_t z_vrfy_k_timer_remaining_ticks(
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const struct k_timer *timer)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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return z_impl_k_timer_remaining_ticks(timer);
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}
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#include <syscalls/k_timer_remaining_ticks_mrsh.c>
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static inline k_ticks_t z_vrfy_k_timer_expires_ticks(
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const struct k_timer *timer)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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return z_impl_k_timer_expires_ticks(timer);
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}
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#include <syscalls/k_timer_expires_ticks_mrsh.c>
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static inline void *z_vrfy_k_timer_user_data_get(const struct k_timer *timer)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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return z_impl_k_timer_user_data_get(timer);
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}
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#include <syscalls/k_timer_user_data_get_mrsh.c>
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static inline void z_vrfy_k_timer_user_data_set(struct k_timer *timer,
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void *user_data)
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{
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K_OOPS(K_SYSCALL_OBJ(timer, K_OBJ_TIMER));
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z_impl_k_timer_user_data_set(timer, user_data);
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}
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#include <syscalls/k_timer_user_data_set_mrsh.c>
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#endif /* CONFIG_USERSPACE */
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#ifdef CONFIG_OBJ_CORE_TIMER
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static int init_timer_obj_core_list(void)
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{
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/* Initialize timer object type */
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z_obj_type_init(&obj_type_timer, K_OBJ_TYPE_TIMER_ID,
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offsetof(struct k_timer, obj_core));
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/* Initialize and link statically defined timers */
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STRUCT_SECTION_FOREACH(k_timer, timer) {
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k_obj_core_init_and_link(K_OBJ_CORE(timer), &obj_type_timer);
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}
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return 0;
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}
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SYS_INIT(init_timer_obj_core_list, PRE_KERNEL_1,
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CONFIG_KERNEL_INIT_PRIORITY_OBJECTS);
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#endif /* CONFIG_OBJ_CORE_TIMER */
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