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zephyr/kernel/timeout.c
Andy Ross 1db9f18a08 kernel/timeout: Remove "clock_always_on", replace with "SLOPPY_IDLE" 
This is an oddball API.  It's untested.  In fact testing its proper
behavior requires very elaborate automation (you need a device outside
the Zephyr hardware to measure real world time, and a mechanism for
getting the device into and out of idle without using the timer
driver).  And this makes for needless difficulty managing code
coverage metrics.

It was always just a hint anyway.  Mark the old API deprecated and
replace it with a kconfig tunable.  The effect of that is just to
change the timeout value passed to the timer driver, where we can
manage code coverage metrics more easily (only one driver cares to
actually support this feature anyway).

Signed-off-by: Andy Ross <andrew.j.ross@intel.com>
2019-06-28 14:24:56 -07:00

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/*
* Copyright (c) 2018 Intel Corporation
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <timeout_q.h>
#include <drivers/timer/system_timer.h>
#include <sys_clock.h>
#include <spinlock.h>
#include <ksched.h>
#include <syscall_handler.h>
#define LOCKED(lck) for (k_spinlock_key_t __i = {}, \
__key = k_spin_lock(lck); \
__i.key == 0; \
k_spin_unlock(lck, __key), __i.key = 1)
static u64_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_FOREVER : INT_MAX)
/* Cycles left to process in the currently-executing z_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
Z_SYSCALL_HANDLER(z_clock_hw_cycles_per_sec_runtime_get)
{
return z_impl_z_clock_hw_cycles_per_sec_runtime_get();
}
#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 s32_t elapsed(void)
{
return announce_remaining == 0 ? z_clock_elapsed() : 0;
}
static s32_t next_timeout(void)
{
struct _timeout *to = first();
s32_t ret = to == NULL ? MAX_WAIT : MAX(0, to->dticks - 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, s32_t ticks)
{
__ASSERT(!sys_dnode_is_linked(&to->node), "");
to->fn = fn;
ticks = MAX(1, ticks);
LOCKED(&timeout_lock) {
struct _timeout *t;
to->dticks = ticks + elapsed();
for (t = first(); t != NULL; t = next(t)) {
__ASSERT(t->dticks >= 0, "");
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()) {
z_clock_set_timeout(next_timeout(), false);
}
}
}
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;
}
s32_t z_timeout_remaining(struct _timeout *timeout)
{
s32_t ticks = 0;
if (z_is_inactive_timeout(timeout)) {
return 0;
}
LOCKED(&timeout_lock) {
for (struct _timeout *t = first(); t != NULL; t = next(t)) {
ticks += t->dticks;
if (timeout == t) {
break;
}
}
}
return ticks - elapsed();
}
s32_t z_get_next_timeout_expiry(void)
{
s32_t ret = K_FOREVER;
LOCKED(&timeout_lock) {
ret = next_timeout();
}
return ret;
}
void z_set_timeout_expiry(s32_t ticks, bool idle)
{
LOCKED(&timeout_lock) {
int next = next_timeout();
bool sooner = (next == K_FOREVER) || (ticks < next);
bool imminent = next <= 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.
*/
if (sooner && !imminent) {
z_clock_set_timeout(ticks, idle);
}
}
}
void z_clock_announce(s32_t ticks)
{
#ifdef CONFIG_TIMESLICING
z_time_slice(ticks);
#endif
k_spinlock_key_t key = k_spin_lock(&timeout_lock);
announce_remaining = ticks;
while (first() != NULL && first()->dticks <= announce_remaining) {
struct _timeout *t = first();
int dt = t->dticks;
curr_tick += dt;
announce_remaining -= dt;
t->dticks = 0;
remove_timeout(t);
k_spin_unlock(&timeout_lock, key);
t->fn(t);
key = k_spin_lock(&timeout_lock);
}
if (first() != NULL) {
first()->dticks -= announce_remaining;
}
curr_tick += announce_remaining;
announce_remaining = 0;
z_clock_set_timeout(next_timeout(), false);
k_spin_unlock(&timeout_lock, key);
}
s64_t z_tick_get(void)
{
u64_t t = 0U;
LOCKED(&timeout_lock) {
t = curr_tick + z_clock_elapsed();
}
return t;
}
u32_t z_tick_get_32(void)
{
#ifdef CONFIG_TICKLESS_KERNEL
return (u32_t)z_tick_get();
#else
return (u32_t)curr_tick;
#endif
}
u32_t z_impl_k_uptime_get_32(void)
{
return __ticks_to_ms(z_tick_get_32());
}
#ifdef CONFIG_USERSPACE
Z_SYSCALL_HANDLER(k_uptime_get_32)
{
return z_impl_k_uptime_get_32();
}
#endif
s64_t z_impl_k_uptime_get(void)
{
return __ticks_to_ms(z_tick_get());
}
#ifdef CONFIG_USERSPACE
Z_SYSCALL_HANDLER(k_uptime_get, ret_p)
{
u64_t *ret = (u64_t *)ret_p;
Z_OOPS(Z_SYSCALL_MEMORY_WRITE(ret, sizeof(*ret)));
*ret = z_impl_k_uptime_get();
return 0;
}
#endif
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