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/*
* Copyright (c) 2006-2022, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2006-03-28 Bernard first version
* 2006-04-29 Bernard implement thread timer
* 2006-04-30 Bernard added THREAD_DEBUG
* 2006-05-27 Bernard fixed the rt_thread_yield bug
* 2006-06-03 Bernard fixed the thread timer init bug
* 2006-08-10 Bernard fixed the timer bug in thread_sleep
* 2006-09-03 Bernard changed rt_timer_delete to rt_timer_detach
* 2006-09-03 Bernard implement rt_thread_detach
* 2008-02-16 Bernard fixed the rt_thread_timeout bug
* 2010-03-21 Bernard change the errno of rt_thread_delay/sleep to
* RT_EOK.
* 2010-11-10 Bernard add cleanup callback function in thread exit.
* 2011-09-01 Bernard fixed rt_thread_exit issue when the current
* thread preempted, which reported by Jiaxing Lee.
* 2011-09-08 Bernard fixed the scheduling issue in rt_thread_startup.
* 2012-12-29 Bernard fixed compiling warning.
* 2016-08-09 ArdaFu add thread suspend and resume hook.
* 2017-04-10 armink fixed the rt_thread_delete and rt_thread_detach
* bug when thread has not startup.
* 2018-11-22 Jesven yield is same to rt_schedule
* add support for tasks bound to cpu
* 2021-02-24 Meco Man rearrange rt_thread_control() - schedule the thread when close it
* 2021-11-15 THEWON Remove duplicate work between idle and _thread_exit
* 2021-12-27 Meco Man remove .init_priority
* 2022-01-07 Gabriel Moving __on_rt_xxxxx_hook to thread.c
* 2022-01-24 THEWON let _thread_sleep return thread->error when using signal
* 2022-10-15 Bernard add nested mutex feature
* 2023-09-15 xqyjlj perf rt_hw_interrupt_disable/enable
* 2023-12-10 xqyjlj fix thread_exit/detach/delete
* fix rt_thread_delay
*/
#include <rthw.h>
#include <rtthread.h>
#include <stddef.h>
#define DBG_TAG "kernel.thread"
#define DBG_LVL DBG_INFO
#include <rtdbg.h>
#if defined(RT_USING_HOOK) && defined(RT_HOOK_USING_FUNC_PTR)
static void (*rt_thread_suspend_hook)(rt_thread_t thread);
static void (*rt_thread_resume_hook) (rt_thread_t thread);
/**
* @brief This function sets a hook function when the system suspend a thread.
*
* @note The hook function must be simple and never be blocked or suspend.
*
* @param hook is the specified hook function.
*/
void rt_thread_suspend_sethook(void (*hook)(rt_thread_t thread))
{
rt_thread_suspend_hook = hook;
}
/**
* @brief This function sets a hook function when the system resume a thread.
*
* @note The hook function must be simple and never be blocked or suspend.
*
* @param hook is the specified hook function.
*/
void rt_thread_resume_sethook(void (*hook)(rt_thread_t thread))
{
rt_thread_resume_hook = hook;
}
RT_OBJECT_HOOKLIST_DEFINE(rt_thread_inited);
#endif /* defined(RT_USING_HOOK) && defined(RT_HOOK_USING_FUNC_PTR) */
static void _thread_exit(void)
{
struct rt_thread *thread;
rt_base_t critical_level;
/* get current thread */
thread = rt_thread_self();
critical_level = rt_enter_critical();
rt_thread_close(thread);
/* insert to defunct thread list */
rt_thread_defunct_enqueue(thread);
rt_exit_critical_safe(critical_level);
/* switch to next task */
rt_schedule();
}
/**
* @brief This function is the timeout function for thread, normally which is invoked
* when thread is timeout to wait some resource.
*
* @param parameter is the parameter of thread timeout function
*/
static void _thread_timeout(void *parameter)
{
struct rt_thread *thread;
rt_sched_lock_level_t slvl;
thread = (struct rt_thread *)parameter;
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
rt_sched_lock(&slvl);
/**
* resume of the thread and stop of the thread timer should be an atomic
* operation. So we don't expected that thread had resumed.
*/
RT_ASSERT(rt_sched_thread_is_suspended(thread));
/* set error number */
thread->error = -RT_ETIMEOUT;
/* remove from suspend list */
rt_list_remove(&RT_THREAD_LIST_NODE(thread));
/* insert to schedule ready list */
rt_sched_insert_thread(thread);
/* do schedule and release the scheduler lock */
rt_sched_unlock_n_resched(slvl);
}
#ifdef RT_USING_MUTEX
static void _thread_detach_from_mutex(rt_thread_t thread)
{
rt_list_t *node;
rt_list_t *tmp_list;
struct rt_mutex *mutex;
rt_base_t level;
level = rt_spin_lock_irqsave(&thread->spinlock);
/* check if thread is waiting on a mutex */
if ((thread->pending_object) &&
(rt_object_get_type(thread->pending_object) == RT_Object_Class_Mutex))
{
/* remove it from its waiting list */
struct rt_mutex *mutex = (struct rt_mutex*)thread->pending_object;
rt_mutex_drop_thread(mutex, thread);
thread->pending_object = RT_NULL;
}
/* free taken mutex after detaching from waiting, so we don't lost mutex just got */
rt_list_for_each_safe(node, tmp_list, &(thread->taken_object_list))
{
mutex = rt_list_entry(node, struct rt_mutex, taken_list);
rt_mutex_release(mutex);
}
rt_spin_unlock_irqrestore(&thread->spinlock, level);
}
#else
static void _thread_detach_from_mutex(rt_thread_t thread) {}
#endif
static rt_err_t _thread_init(struct rt_thread *thread,
const char *name,
void (*entry)(void *parameter),
void *parameter,
void *stack_start,
rt_uint32_t stack_size,
rt_uint8_t priority,
rt_uint32_t tick)
{
RT_UNUSED(name);
rt_sched_thread_init_ctx(thread, tick, priority);
#ifdef RT_USING_MEM_PROTECTION
thread->mem_regions = RT_NULL;
#endif
#ifdef RT_USING_SMART
thread->wakeup_handle.func = RT_NULL;
#endif
thread->entry = (void *)entry;
thread->parameter = parameter;
/* stack init */
thread->stack_addr = stack_start;
thread->stack_size = stack_size;
/* init thread stack */
rt_memset(thread->stack_addr, '#', thread->stack_size);
#ifdef RT_USING_HW_STACK_GUARD
rt_hw_stack_guard_init(thread);
#endif
#ifdef ARCH_CPU_STACK_GROWS_UPWARD
thread->sp = (void *)rt_hw_stack_init(thread->entry, thread->parameter,
(void *)((char *)thread->stack_addr),
(void *)_thread_exit);
#else
thread->sp = (void *)rt_hw_stack_init(thread->entry, thread->parameter,
(rt_uint8_t *)((char *)thread->stack_addr + thread->stack_size - sizeof(rt_ubase_t)),
(void *)_thread_exit);
#endif /* ARCH_CPU_STACK_GROWS_UPWARD */
#ifdef RT_USING_MUTEX
rt_list_init(&thread->taken_object_list);
thread->pending_object = RT_NULL;
#endif
#ifdef RT_USING_EVENT
thread->event_set = 0;
thread->event_info = 0;
#endif /* RT_USING_EVENT */
/* error and flags */
thread->error = RT_EOK;
/* lock init */
#ifdef RT_USING_SMP
rt_atomic_store(&thread->cpus_lock_nest, 0);
#endif
/* initialize cleanup function and user data */
thread->cleanup = 0;
thread->user_data = 0;
/* initialize thread timer */
rt_timer_init(&(thread->thread_timer),
thread->parent.name,
_thread_timeout,
thread,
0,
RT_TIMER_FLAG_ONE_SHOT | RT_TIMER_FLAG_THREAD_TIMER);
/* initialize signal */
#ifdef RT_USING_SIGNALS
thread->sig_mask = 0x00;
thread->sig_pending = 0x00;
#ifndef RT_USING_SMP
thread->sig_ret = RT_NULL;
#endif /* RT_USING_SMP */
thread->sig_vectors = RT_NULL;
thread->si_list = RT_NULL;
#endif /* RT_USING_SIGNALS */
#ifdef RT_USING_SMART
thread->tid_ref_count = 0;
thread->lwp = RT_NULL;
thread->susp_recycler = RT_NULL;
thread->robust_list = RT_NULL;
rt_list_init(&(thread->sibling));
/* lwp thread-signal init */
rt_memset(&thread->signal.sigset_mask, 0, sizeof(lwp_sigset_t));
rt_memset(&thread->signal.sig_queue.sigset_pending, 0, sizeof(lwp_sigset_t));
rt_list_init(&thread->signal.sig_queue.siginfo_list);
rt_memset(&thread->user_ctx, 0, sizeof thread->user_ctx);
/* initialize user_time and system_time */
thread->user_time = 0;
thread->system_time = 0;
#endif
#ifdef RT_USING_CPU_USAGE
thread->duration_tick = 0;
#endif /* RT_USING_CPU_USAGE */
#ifdef RT_USING_PTHREADS
thread->pthread_data = RT_NULL;
#endif /* RT_USING_PTHREADS */
#ifdef RT_USING_MODULE
thread->parent.module_id = 0;
#endif /* RT_USING_MODULE */
rt_spin_lock_init(&thread->spinlock);
RT_OBJECT_HOOKLIST_CALL(rt_thread_inited, (thread));
return RT_EOK;
}
/**
* @addtogroup Thread
*/
/**@{*/
/**
* @brief This function will initialize a thread. It's used to initialize a
* static thread object.
*
* @param thread is the static thread object.
*
* @param name is the name of thread, which shall be unique.
*
* @param entry is the entry function of thread.
*
* @param parameter is the parameter of thread enter function.
*
* @param stack_start is the start address of thread stack.
*
* @param stack_size is the size of thread stack.
*
* @param priority is the priority of thread.
*
* @param tick is the time slice if there are same priority thread.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_init(struct rt_thread *thread,
const char *name,
void (*entry)(void *parameter),
void *parameter,
void *stack_start,
rt_uint32_t stack_size,
rt_uint8_t priority,
rt_uint32_t tick)
{
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(stack_start != RT_NULL);
RT_ASSERT(tick != 0);
/* initialize thread object */
rt_object_init((rt_object_t)thread, RT_Object_Class_Thread, name);
return _thread_init(thread,
name,
entry,
parameter,
stack_start,
stack_size,
priority,
tick);
}
RTM_EXPORT(rt_thread_init);
/**
* @brief This function will return self thread object.
*
* @return The self thread object.
*/
rt_thread_t rt_thread_self(void)
{
#ifndef RT_USING_SMP
return rt_cpu_self()->current_thread;
#elif defined (ARCH_USING_HW_THREAD_SELF)
return rt_hw_thread_self();
#else /* !ARCH_USING_HW_THREAD_SELF */
rt_thread_t self;
rt_base_t lock;
lock = rt_hw_local_irq_disable();
self = rt_cpu_self()->current_thread;
rt_hw_local_irq_enable(lock);
return self;
#endif /* ARCH_USING_HW_THREAD_SELF */
}
RTM_EXPORT(rt_thread_self);
/**
* @brief This function will start a thread and put it to system ready queue.
*
* @param thread is the thread to be started.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_startup(rt_thread_t thread)
{
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT((RT_SCHED_CTX(thread).stat & RT_THREAD_STAT_MASK) == RT_THREAD_INIT);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
LOG_D("startup a thread:%s with priority:%d",
thread->parent.name, thread->current_priority);
/* calculate priority attribute and reset thread stat to suspend */
rt_sched_thread_startup(thread);
/* resume and do a schedule if scheduler is available */
rt_thread_resume(thread);
return RT_EOK;
}
RTM_EXPORT(rt_thread_startup);
/**
* @brief This function will close a thread. The thread object will be removed from
* thread queue and detached/deleted from the system object management.
* It's different from rt_thread_delete or rt_thread_detach that this will not enqueue
* the closing thread to cleanup queue.
*
* @param thread is the thread to be closed.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_close(rt_thread_t thread)
{
rt_sched_lock_level_t slvl;
rt_uint8_t thread_status;
/* forbid scheduling on current core if closing current thread */
RT_ASSERT(thread != rt_thread_self() || rt_critical_level());
/* before checking status of scheduler */
rt_sched_lock(&slvl);
/* check if thread is already closed */
thread_status = rt_sched_thread_get_stat(thread);
if (thread_status != RT_THREAD_CLOSE)
{
if (thread_status != RT_THREAD_INIT)
{
/* remove from schedule */
rt_sched_remove_thread(thread);
}
/* release thread timer */
rt_timer_detach(&(thread->thread_timer));
/* change stat */
rt_sched_thread_close(thread);
}
/* scheduler works are done */
rt_sched_unlock(slvl);
return RT_EOK;
}
RTM_EXPORT(rt_thread_close);
static rt_err_t _thread_detach(rt_thread_t thread);
/**
* @brief This function will detach a thread. The thread object will be removed from
* thread queue and detached/deleted from the system object management.
*
* @param thread is the thread to be deleted.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_detach(rt_thread_t thread)
{
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
RT_ASSERT(rt_object_is_systemobject((rt_object_t)thread));
return _thread_detach(thread);
}
RTM_EXPORT(rt_thread_detach);
static rt_err_t _thread_detach(rt_thread_t thread)
{
rt_err_t error;
rt_base_t critical_level;
/**
* forbid scheduling on current core before returning since current thread
* may be detached from scheduler.
*/
critical_level = rt_enter_critical();
error = rt_thread_close(thread);
_thread_detach_from_mutex(thread);
/* insert to defunct thread list */
rt_thread_defunct_enqueue(thread);
rt_exit_critical_safe(critical_level);
return error;
}
#ifdef RT_USING_HEAP
/**
* @brief This function will create a thread object and allocate thread object memory.
* and stack.
*
* @param name is the name of thread, which shall be unique.
*
* @param entry is the entry function of thread.
*
* @param parameter is the parameter of thread enter function.
*
* @param stack_size is the size of thread stack.
*
* @param priority is the priority of thread.
*
* @param tick is the time slice if there are same priority thread.
*
* @return If the return value is a rt_thread structure pointer, the function is successfully executed.
* If the return value is RT_NULL, it means this operation failed.
*/
rt_thread_t rt_thread_create(const char *name,
void (*entry)(void *parameter),
void *parameter,
rt_uint32_t stack_size,
rt_uint8_t priority,
rt_uint32_t tick)
{
/* parameter check */
RT_ASSERT(tick != 0);
struct rt_thread *thread;
void *stack_start;
thread = (struct rt_thread *)rt_object_allocate(RT_Object_Class_Thread,
name);
if (thread == RT_NULL)
return RT_NULL;
stack_start = (void *)RT_KERNEL_MALLOC(stack_size);
if (stack_start == RT_NULL)
{
/* allocate stack failure */
rt_object_delete((rt_object_t)thread);
return RT_NULL;
}
_thread_init(thread,
name,
entry,
parameter,
stack_start,
stack_size,
priority,
tick);
return thread;
}
RTM_EXPORT(rt_thread_create);
/**
* @brief This function will delete a thread. The thread object will be removed from
* thread queue and deleted from system object management in the idle thread.
*
* @param thread is the thread to be deleted.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_delete(rt_thread_t thread)
{
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
RT_ASSERT(rt_object_is_systemobject((rt_object_t)thread) == RT_FALSE);
return _thread_detach(thread);
}
RTM_EXPORT(rt_thread_delete);
#endif /* RT_USING_HEAP */
/**
* @brief This function will let current thread yield processor, and scheduler will
* choose the highest thread to run. After yield processor, the current thread
* is still in READY state.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_yield(void)
{
rt_sched_lock_level_t slvl;
rt_sched_lock(&slvl);
rt_sched_thread_yield(rt_thread_self());
rt_sched_unlock_n_resched(slvl);
return RT_EOK;
}
RTM_EXPORT(rt_thread_yield);
/**
* @brief This function will let current thread sleep for some ticks. Change current thread state to suspend,
* when the thread timer reaches the tick value, scheduler will awaken this thread.
*
* @param tick is the sleep ticks.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
static rt_err_t _thread_sleep(rt_tick_t tick)
{
struct rt_thread *thread;
rt_base_t critical_level;
int err;
if (tick == 0)
{
return -RT_EINVAL;
}
/* set to current thread */
thread = rt_thread_self();
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
/* current context checking */
RT_DEBUG_SCHEDULER_AVAILABLE(RT_TRUE);
/* reset thread error */
thread->error = RT_EOK;
/* lock scheduler since current thread may be suspended */
critical_level = rt_enter_critical();
/* suspend thread */
err = rt_thread_suspend_with_flag(thread, RT_INTERRUPTIBLE);
/* reset the timeout of thread timer and start it */
if (err == RT_EOK)
{
rt_timer_control(&(thread->thread_timer), RT_TIMER_CTRL_SET_TIME, &tick);
rt_timer_start(&(thread->thread_timer));
thread->error = -RT_EINTR;
/* notify a pending rescheduling */
rt_schedule();
/* exit critical and do a rescheduling */
rt_exit_critical_safe(critical_level);
/* clear error number of this thread to RT_EOK */
if (thread->error == -RT_ETIMEOUT)
thread->error = RT_EOK;
}
else
{
rt_exit_critical_safe(critical_level);
}
return err;
}
/**
* @brief This function will let current thread delay for some ticks.
*
* @param tick is the delay ticks.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_delay(rt_tick_t tick)
{
return _thread_sleep(tick);
}
RTM_EXPORT(rt_thread_delay);
/**
* @brief This function will let current thread delay until (*tick + inc_tick).
*
* @param tick is the tick of last wakeup.
*
* @param inc_tick is the increment tick.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_delay_until(rt_tick_t *tick, rt_tick_t inc_tick)
{
struct rt_thread *thread;
rt_tick_t cur_tick;
rt_base_t critical_level;
RT_ASSERT(tick != RT_NULL);
/* set to current thread */
thread = rt_thread_self();
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
/* reset thread error */
thread->error = RT_EOK;
/* disable interrupt */
critical_level = rt_enter_critical();
cur_tick = rt_tick_get();
if (cur_tick - *tick < inc_tick)
{
rt_tick_t left_tick;
*tick += inc_tick;
left_tick = *tick - cur_tick;
/* suspend thread */
rt_thread_suspend_with_flag(thread, RT_UNINTERRUPTIBLE);
/* reset the timeout of thread timer and start it */
rt_timer_control(&(thread->thread_timer), RT_TIMER_CTRL_SET_TIME, &left_tick);
rt_timer_start(&(thread->thread_timer));
rt_exit_critical_safe(critical_level);
rt_schedule();
/* clear error number of this thread to RT_EOK */
if (thread->error == -RT_ETIMEOUT)
{
thread->error = RT_EOK;
}
}
else
{
*tick = cur_tick;
rt_exit_critical_safe(critical_level);
}
return thread->error;
}
RTM_EXPORT(rt_thread_delay_until);
/**
* @brief This function will let current thread delay for some milliseconds.
*
* @param ms is the delay ms time.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_mdelay(rt_int32_t ms)
{
rt_tick_t tick;
tick = rt_tick_from_millisecond(ms);
return _thread_sleep(tick);
}
RTM_EXPORT(rt_thread_mdelay);
#ifdef RT_USING_SMP
#endif
/**
* @brief This function will control thread behaviors according to control command.
*
* @param thread is the specified thread to be controlled.
*
* @param cmd is the control command, which includes.
*
* RT_THREAD_CTRL_CHANGE_PRIORITY for changing priority level of thread.
*
* RT_THREAD_CTRL_STARTUP for starting a thread.
*
* RT_THREAD_CTRL_CLOSE for delete a thread.
*
* RT_THREAD_CTRL_BIND_CPU for bind the thread to a CPU.
*
* @param arg is the argument of control command.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_control(rt_thread_t thread, int cmd, void *arg)
{
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
switch (cmd)
{
case RT_THREAD_CTRL_CHANGE_PRIORITY:
{
rt_err_t error;
rt_sched_lock_level_t slvl;
rt_sched_lock(&slvl);
error = rt_sched_thread_change_priority(thread, *(rt_uint8_t *)arg);
rt_sched_unlock(slvl);
return error;
}
case RT_THREAD_CTRL_STARTUP:
{
return rt_thread_startup(thread);
}
case RT_THREAD_CTRL_CLOSE:
{
rt_err_t rt_err = -RT_EINVAL;
if (rt_object_is_systemobject((rt_object_t)thread) == RT_TRUE)
{
rt_err = rt_thread_detach(thread);
}
#ifdef RT_USING_HEAP
else
{
rt_err = rt_thread_delete(thread);
}
#endif /* RT_USING_HEAP */
rt_schedule();
return rt_err;
}
case RT_THREAD_CTRL_BIND_CPU:
{
rt_uint8_t cpu;
cpu = (rt_uint8_t)(size_t)arg;
return rt_sched_thread_bind_cpu(thread, cpu);
}
default:
break;
}
return RT_EOK;
}
RTM_EXPORT(rt_thread_control);
#ifdef RT_USING_SMART
#include <lwp_signal.h>
#endif
static void _thread_set_suspend_state(struct rt_thread *thread, int suspend_flag)
{
rt_uint8_t stat = RT_THREAD_SUSPEND_UNINTERRUPTIBLE;
RT_ASSERT(thread != RT_NULL);
switch (suspend_flag)
{
case RT_INTERRUPTIBLE:
stat = RT_THREAD_SUSPEND_INTERRUPTIBLE;
break;
case RT_KILLABLE:
stat = RT_THREAD_SUSPEND_KILLABLE;
break;
case RT_UNINTERRUPTIBLE:
stat = RT_THREAD_SUSPEND_UNINTERRUPTIBLE;
break;
default:
RT_ASSERT(0);
break;
}
RT_SCHED_CTX(thread).stat = stat | (RT_SCHED_CTX(thread).stat & ~RT_THREAD_STAT_MASK);
}
/**
* @brief This function will suspend the specified thread and change it to suspend state.
*
* @note This function ONLY can suspend current thread itself.
* rt_thread_suspend(rt_thread_self());
*
* Do not use the rt_thread_suspend to suspend other threads. You have no way of knowing what code a
* thread is executing when you suspend it. If you suspend a thread while sharing a resouce with
* other threads and occupying this resouce, starvation can occur very easily.
*
* @param thread the thread to be suspended.
* @param susp_list the list thread enqueued to. RT_NULL if no list.
* @param ipc_flags is a flag for the thread object to be suspended. It determines how the thread is suspended.
* The flag can be ONE of the following values:
* RT_IPC_FLAG_PRIO The pending threads will queue in order of priority.
* RT_IPC_FLAG_FIFO The pending threads will queue in the first-in-first-out method
* (also known as first-come-first-served (FCFS) scheduling strategy).
* NOTE: RT_IPC_FLAG_FIFO is a non-real-time scheduling mode. It is strongly recommended to use
* RT_IPC_FLAG_PRIO to ensure the thread is real-time UNLESS your applications concern about
* the first-in-first-out principle, and you clearly understand that all threads involved in
* this semaphore will become non-real-time threads.
* @param suspend_flag status flag of the thread to be suspended.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_suspend_to_list(rt_thread_t thread, rt_list_t *susp_list, int ipc_flags, int suspend_flag)
{
rt_base_t stat;
rt_sched_lock_level_t slvl;
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
RT_ASSERT(thread == rt_thread_self());
LOG_D("thread suspend: %s", thread->parent.name);
rt_sched_lock(&slvl);
stat = rt_sched_thread_get_stat(thread);
if ((stat != RT_THREAD_READY) && (stat != RT_THREAD_RUNNING))
{
LOG_D("thread suspend: thread disorder, 0x%2x", thread->stat);
rt_sched_unlock(slvl);
return -RT_ERROR;
}
if (stat == RT_THREAD_RUNNING)
{
/* not suspend running status thread on other core */
RT_ASSERT(thread == rt_thread_self());
}
#ifdef RT_USING_SMART
if (thread->lwp)
{
rt_sched_unlock(slvl);
/* check pending signals for thread before suspend */
if (lwp_thread_signal_suspend_check(thread, suspend_flag) == 0)
{
/* not to suspend */
return -RT_EINTR;
}
rt_sched_lock(&slvl);
if (stat == RT_THREAD_READY)
{
stat = rt_sched_thread_get_stat(thread);
if (stat != RT_THREAD_READY)
{
/* status updated while we check for signal */
rt_sched_unlock(slvl);
return -RT_ERROR;
}
}
}
#endif
/* change thread stat */
rt_sched_remove_thread(thread);
_thread_set_suspend_state(thread, suspend_flag);
if (susp_list)
{
/**
* enqueue thread on the push list before leaving critical region of
* scheduler, so we won't miss notification of async events.
*/
rt_susp_list_enqueue(susp_list, thread, ipc_flags);
}
/* stop thread timer anyway */
rt_sched_thread_timer_stop(thread);
rt_sched_unlock(slvl);
RT_OBJECT_HOOK_CALL(rt_thread_suspend_hook, (thread));
return RT_EOK;
}
RTM_EXPORT(rt_thread_suspend_to_list);
/**
* @brief This function will suspend the specified thread and change it to suspend state.
*
* @note This function ONLY can suspend current thread itself.
* rt_thread_suspend(rt_thread_self());
*
* Do not use the rt_thread_suspend to suspend other threads. You have no way of knowing what code a
* thread is executing when you suspend it. If you suspend a thread while sharing a resouce with
* other threads and occupying this resouce, starvation can occur very easily.
*
* @param thread the thread to be suspended.
* @param suspend_flag status flag of the thread to be suspended.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_suspend_with_flag(rt_thread_t thread, int suspend_flag)
{
return rt_thread_suspend_to_list(thread, RT_NULL, 0, suspend_flag);
}
RTM_EXPORT(rt_thread_suspend_with_flag);
rt_err_t rt_thread_suspend(rt_thread_t thread)
{
return rt_thread_suspend_with_flag(thread, RT_UNINTERRUPTIBLE);
}
RTM_EXPORT(rt_thread_suspend);
/**
* @brief This function will resume a thread and put it to system ready queue.
*
* @param thread is the thread to be resumed.
*
* @return Return the operation status. If the return value is RT_EOK, the function is successfully executed.
* If the return value is any other values, it means this operation failed.
*/
rt_err_t rt_thread_resume(rt_thread_t thread)
{
rt_sched_lock_level_t slvl;
rt_err_t error;
/* parameter check */
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
LOG_D("thread resume: %s", thread->parent.name);
rt_sched_lock(&slvl);
error = rt_sched_thread_ready(thread);
if (!error)
{
error = rt_sched_unlock_n_resched(slvl);
/**
* RT_ESCHEDLOCKED indicates that the current thread is in a critical section,
* rather than 'thread' can't be resumed. Therefore, we can ignore this error.
*/
if (error == -RT_ESCHEDLOCKED)
{
error = RT_EOK;
}
}
else
{
rt_sched_unlock(slvl);
}
RT_OBJECT_HOOK_CALL(rt_thread_resume_hook, (thread));
return error;
}
RTM_EXPORT(rt_thread_resume);
#ifdef RT_USING_SMART
/**
* This function will wakeup a thread with customized operation.
*
* @param thread the thread to be resumed
*
* @return the operation status, RT_EOK on OK, -RT_ERROR on error
*/
rt_err_t rt_thread_wakeup(rt_thread_t thread)
{
rt_sched_lock_level_t slvl;
rt_err_t ret;
rt_wakeup_func_t func = RT_NULL;
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
rt_sched_lock(&slvl);
func = thread->wakeup_handle.func;
thread->wakeup_handle.func = RT_NULL;
rt_sched_unlock(slvl);
if (func)
{
ret = func(thread->wakeup_handle.user_data, thread);
}
else
{
ret = rt_thread_resume(thread);
}
return ret;
}
RTM_EXPORT(rt_thread_wakeup);
void rt_thread_wakeup_set(struct rt_thread *thread, rt_wakeup_func_t func, void* user_data)
{
rt_sched_lock_level_t slvl;
RT_ASSERT(thread != RT_NULL);
RT_ASSERT(rt_object_get_type((rt_object_t)thread) == RT_Object_Class_Thread);
rt_sched_lock(&slvl);
thread->wakeup_handle.func = func;
thread->wakeup_handle.user_data = user_data;
rt_sched_unlock(slvl);
}
RTM_EXPORT(rt_thread_wakeup_set);
#endif
/**
* @brief This function will find the specified thread.
*
* @note Please don't invoke this function in interrupt status.
*
* @param name is the name of thread finding.
*
* @return If the return value is a rt_thread structure pointer, the function is successfully executed.
* If the return value is RT_NULL, it means this operation failed.
*/
rt_thread_t rt_thread_find(char *name)
{
return (rt_thread_t)rt_object_find(name, RT_Object_Class_Thread);
}
RTM_EXPORT(rt_thread_find);
/**
* @brief This function will return the name of the specified thread
*
* @note Please don't invoke this function in interrupt status
*
* @param thread the thread to retrieve thread name
* @param name buffer to store the thread name string
* @param name_size maximum size of the buffer to store the thread name
*
* @return If the return value is RT_EOK, the function is successfully executed
* If the return value is -RT_EINVAL, it means this operation failed
*/
rt_err_t rt_thread_get_name(rt_thread_t thread, char *name, rt_uint8_t name_size)
{
return (thread == RT_NULL) ? -RT_EINVAL : rt_object_get_name(&thread->parent, name, name_size);
}
RTM_EXPORT(rt_thread_get_name);
/**@}*/
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