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rt-thread
/
include
/
rtthread.h
rt-thread
/
include
/
rtthread.h
rtthread.h 31.74 KB
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/*
* Copyright (c) 2006-2024 RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2006年03月18日 Bernard the first version
* 2006年04月26日 Bernard add semaphore APIs
* 2006年08月10日 Bernard add version information
* 2007年01月28日 Bernard rename RT_OBJECT_Class_Static to RT_Object_Class_Static
* 2007年03月03日 Bernard clean up the definitions to rtdef.h
* 2010年04月11日 yi.qiu add module feature
* 2013年06月24日 Bernard add rt_kprintf re-define when not use RT_USING_CONSOLE.
* 2016年08月09日 ArdaFu add new thread and interrupt hook.
* 2018年11月22日 Jesven add all cpu's lock and ipi handler
* 2021年02月28日 Meco Man add RT_KSERVICE_USING_STDLIB
* 2021年11月14日 Meco Man add rtlegacy.h for compatibility
* 2022年06月04日 Meco Man remove strnlen
* 2023年05月20日 Bernard add rtatomic.h header file to included files.
* 2023年06月30日 ChuShicheng move debug check from the rtdebug.h
* 2023年10月16日 Shell Support a new backtrace framework
* 2023年12月10日 xqyjlj fix spinlock in up
* 2024年01月25日 Shell Add rt_susp_list for IPC primitives
* 2024年03月10日 Meco Man move std libc related functions to rtklibc
*/
#ifndef __RT_THREAD_H__
#define __RT_THREAD_H__
#include <rtconfig.h>
#include <rtdef.h>
#include <rtservice.h>
#include <rtm.h>
#include <rtatomic.h>
#include <rtklibc.h>
#ifdef RT_USING_LEGACY
#include <rtlegacy.h>
#endif
#ifdef RT_USING_FINSH
#include <finsh.h>
#endif /* RT_USING_FINSH */
#ifdef __cplusplus
extern "C" {
#endif
#ifdef __GNUC__
int entry(void);
#endif
/*
* kernel object interface
*/
struct rt_object_information *
rt_object_get_information(enum rt_object_class_type type);
int rt_object_get_length(enum rt_object_class_type type);
int rt_object_get_pointers(enum rt_object_class_type type, rt_object_t *pointers, int maxlen);
void rt_object_init(struct rt_object *object,
enum rt_object_class_type type,
const char *name);
void rt_object_detach(rt_object_t object);
#ifdef RT_USING_HEAP
rt_object_t rt_object_allocate(enum rt_object_class_type type, const char *name);
void rt_object_delete(rt_object_t object);
/* custom object */
rt_object_t rt_custom_object_create(const char *name, void *data, rt_err_t (*data_destroy)(void *));
rt_err_t rt_custom_object_destroy(rt_object_t obj);
#endif /* RT_USING_HEAP */
rt_bool_t rt_object_is_systemobject(rt_object_t object);
rt_uint8_t rt_object_get_type(rt_object_t object);
rt_err_t rt_object_for_each(rt_uint8_t type, rt_object_iter_t iter, void *data);
rt_object_t rt_object_find(const char *name, rt_uint8_t type);
rt_err_t rt_object_get_name(rt_object_t object, char *name, rt_uint8_t name_size);
#ifdef RT_USING_HOOK
void rt_object_attach_sethook(void (*hook)(struct rt_object *object));
void rt_object_detach_sethook(void (*hook)(struct rt_object *object));
void rt_object_trytake_sethook(void (*hook)(struct rt_object *object));
void rt_object_take_sethook(void (*hook)(struct rt_object *object));
void rt_object_put_sethook(void (*hook)(struct rt_object *object));
#endif /* RT_USING_HOOK */
/**
* @addtogroup group_clock_management
* @{
*/
/*
* clock & timer interface
*/
rt_tick_t rt_tick_get(void);
rt_tick_t rt_tick_get_delta(rt_tick_t base);
void rt_tick_set(rt_tick_t tick);
void rt_tick_increase(void);
void rt_tick_increase_tick(rt_tick_t tick);
rt_tick_t rt_tick_from_millisecond(rt_int32_t ms);
rt_tick_t rt_tick_get_millisecond(void);
#ifdef RT_USING_HOOK
void rt_tick_sethook(void (*hook)(void));
#endif /* RT_USING_HOOK */
void rt_system_timer_init(void);
void rt_system_timer_thread_init(void);
void rt_timer_init(rt_timer_t timer,
const char *name,
void (*timeout)(void *parameter),
void *parameter,
rt_tick_t time,
rt_uint8_t flag);
rt_err_t rt_timer_detach(rt_timer_t timer);
#ifdef RT_USING_HEAP
rt_timer_t rt_timer_create(const char *name,
void (*timeout)(void *parameter),
void *parameter,
rt_tick_t time,
rt_uint8_t flag);
rt_err_t rt_timer_delete(rt_timer_t timer);
#endif /* RT_USING_HEAP */
rt_err_t rt_timer_start(rt_timer_t timer);
rt_err_t rt_timer_stop(rt_timer_t timer);
rt_err_t rt_timer_control(rt_timer_t timer, int cmd, void *arg);
rt_tick_t rt_timer_next_timeout_tick(void);
void rt_timer_check(void);
#ifdef RT_USING_HOOK
void rt_timer_enter_sethook(void (*hook)(struct rt_timer *timer));
void rt_timer_exit_sethook(void (*hook)(struct rt_timer *timer));
#endif /* RT_USING_HOOK */
/**@}*/
/*
* thread interface
*/
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);
rt_err_t rt_thread_detach(rt_thread_t thread);
#ifdef RT_USING_HEAP
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);
rt_err_t rt_thread_delete(rt_thread_t thread);
#endif /* RT_USING_HEAP */
rt_err_t rt_thread_close(rt_thread_t thread);
rt_thread_t rt_thread_self(void);
rt_thread_t rt_thread_find(char *name);
rt_err_t rt_thread_startup(rt_thread_t thread);
rt_err_t rt_thread_yield(void);
rt_err_t rt_thread_delay(rt_tick_t tick);
rt_err_t rt_thread_delay_until(rt_tick_t *tick, rt_tick_t inc_tick);
rt_err_t rt_thread_mdelay(rt_int32_t ms);
rt_err_t rt_thread_control(rt_thread_t thread, int cmd, void *arg);
rt_err_t rt_thread_suspend(rt_thread_t thread);
rt_err_t rt_thread_suspend_with_flag(rt_thread_t thread, int suspend_flag);
rt_err_t rt_thread_resume(rt_thread_t thread);
#ifdef RT_USING_SMART
rt_err_t rt_thread_wakeup(rt_thread_t thread);
void rt_thread_wakeup_set(struct rt_thread *thread, rt_wakeup_func_t func, void* user_data);
#endif /* RT_USING_SMART */
rt_err_t rt_thread_get_name(rt_thread_t thread, char *name, rt_uint8_t name_size);
#ifdef RT_USING_CPU_USAGE_TRACER
rt_uint8_t rt_thread_get_usage(rt_thread_t thread);
#endif /* RT_USING_CPU_USAGE_TRACER */
#ifdef RT_USING_SIGNALS
void rt_thread_alloc_sig(rt_thread_t tid);
void rt_thread_free_sig(rt_thread_t tid);
int rt_thread_kill(rt_thread_t tid, int sig);
#endif /* RT_USING_SIGNALS */
#ifdef RT_USING_HOOK
void rt_thread_suspend_sethook(void (*hook)(rt_thread_t thread));
void rt_thread_resume_sethook (void (*hook)(rt_thread_t thread));
/**
* @ingroup group_thread_management
*
* @brief Sets a hook function when a thread is initialized.
*
* @param thread is the target thread that initializing
*/
typedef void (*rt_thread_inited_hookproto_t)(rt_thread_t thread);
RT_OBJECT_HOOKLIST_DECLARE(rt_thread_inited_hookproto_t, rt_thread_inited);
#endif /* RT_USING_HOOK */
/*
* idle thread interface
*/
void rt_thread_idle_init(void);
#if defined(RT_USING_HOOK) || defined(RT_USING_IDLE_HOOK)
// FIXME: Have to write doxygen comment here for rt_thread_idle_sethook
// but not in src/idle.c. Because the `rt_align(RT_ALIGN_SIZE)` in src/idle.c
// will make doxygen building failed.
/**
* @ingroup group_thread_management
*
* @brief This function sets a hook function to idle thread loop. When the system performs
* idle loop, this hook function should be invoked.
*
* @param hook the specified hook function.
*
* @return `RT_EOK`: set OK.
* `-RT_EFULL`: hook list is full.
*
* @note the hook function must be simple and never be blocked or suspend.
*/
rt_err_t rt_thread_idle_sethook(void (*hook)(void));
rt_err_t rt_thread_idle_delhook(void (*hook)(void));
#endif /* defined(RT_USING_HOOK) || defined(RT_USING_IDLE_HOOK) */
rt_thread_t rt_thread_idle_gethandler(void);
rt_bool_t rt_thread_is_idle_thread(rt_thread_t thread);
/*
* schedule service
*/
void rt_system_scheduler_init(void);
void rt_system_scheduler_start(void);
void rt_schedule(void);
void rt_scheduler_do_irq_switch(void *context);
#ifdef RT_USING_OVERFLOW_CHECK
void rt_scheduler_stack_check(struct rt_thread *thread);
#define RT_SCHEDULER_STACK_CHECK(thr) rt_scheduler_stack_check(thr)
#else /* !RT_USING_OVERFLOW_CHECK */
#define RT_SCHEDULER_STACK_CHECK(thr)
#endif /* RT_USING_OVERFLOW_CHECK */
rt_base_t rt_enter_critical(void);
void rt_exit_critical(void);
void rt_exit_critical_safe(rt_base_t critical_level);
rt_uint16_t rt_critical_level(void);
#ifdef RT_USING_HOOK
void rt_scheduler_stack_overflow_sethook(rt_err_t (*hook)(struct rt_thread *thread));
void rt_scheduler_sethook(void (*hook)(rt_thread_t from, rt_thread_t to));
void rt_scheduler_switch_sethook(void (*hook)(struct rt_thread *tid));
#endif /* RT_USING_HOOK */
#ifdef RT_USING_SMP
void rt_secondary_cpu_entry(void);
void rt_scheduler_ipi_handler(int vector, void *param);
#endif /* RT_USING_SMP */
/**
* @addtogroup group_signal
* @{
*/
#ifdef RT_USING_SIGNALS
void rt_signal_mask(int signo);
void rt_signal_unmask(int signo);
void *rt_signal_check(void* context);
rt_sighandler_t rt_signal_install(int signo, rt_sighandler_t handler);
int rt_signal_wait(const rt_sigset_t *set, rt_siginfo_t *si, rt_int32_t timeout);
int rt_system_signal_init(void);
#endif /* RT_USING_SIGNALS */
/**@}*/
/**
* @addtogroup group_memory_management
* @{
*/
/*
* memory management interface
*/
#ifdef RT_USING_MEMPOOL
/*
* memory pool interface
*/
rt_err_t rt_mp_init(struct rt_mempool *mp,
const char *name,
void *start,
rt_size_t size,
rt_size_t block_size);
rt_err_t rt_mp_detach(struct rt_mempool *mp);
#ifdef RT_USING_HEAP
rt_mp_t rt_mp_create(const char *name,
rt_size_t block_count,
rt_size_t block_size);
rt_err_t rt_mp_delete(rt_mp_t mp);
#endif /* RT_USING_HEAP */
void *rt_mp_alloc(rt_mp_t mp, rt_int32_t time);
void rt_mp_free(void *block);
#ifdef RT_USING_HOOK
void rt_mp_alloc_sethook(void (*hook)(struct rt_mempool *mp, void *block));
void rt_mp_free_sethook(void (*hook)(struct rt_mempool *mp, void *block));
#endif /* RT_USING_HOOK */
#endif /* RT_USING_MEMPOOL */
#ifdef RT_USING_HEAP
/*
* heap memory interface
*/
void rt_system_heap_init(void *begin_addr, void *end_addr);
void rt_system_heap_init_generic(void *begin_addr, void *end_addr);
void *rt_malloc(rt_size_t size);
void rt_free(void *ptr);
void *rt_realloc(void *ptr, rt_size_t newsize);
void *rt_calloc(rt_size_t count, rt_size_t size);
void *rt_malloc_align(rt_size_t size, rt_size_t align);
void rt_free_align(void *ptr);
void rt_memory_info(rt_size_t *total,
rt_size_t *used,
rt_size_t *max_used);
#if defined(RT_USING_SLAB) && defined(RT_USING_SLAB_AS_HEAP)
void *rt_page_alloc(rt_size_t npages);
void rt_page_free(void *addr, rt_size_t npages);
#endif /* defined(RT_USING_SLAB) && defined(RT_USING_SLAB_AS_HEAP) */
/**
* @ingroup group_hook
* @{
*/
#ifdef RT_USING_HOOK
void rt_malloc_sethook(void (*hook)(void **ptr, rt_size_t size));
void rt_realloc_set_entry_hook(void (*hook)(void **ptr, rt_size_t size));
void rt_realloc_set_exit_hook(void (*hook)(void **ptr, rt_size_t size));
void rt_free_sethook(void (*hook)(void **ptr));
#endif /* RT_USING_HOOK */
/**@}*/
#endif /* RT_USING_HEAP */
#ifdef RT_USING_SMALL_MEM
/**
* small memory object interface
*/
rt_smem_t rt_smem_init(const char *name,
void *begin_addr,
rt_size_t size);
rt_err_t rt_smem_detach(rt_smem_t m);
void *rt_smem_alloc(rt_smem_t m, rt_size_t size);
void *rt_smem_realloc(rt_smem_t m, void *rmem, rt_size_t newsize);
void rt_smem_free(void *rmem);
#endif /* RT_USING_SMALL_MEM */
#ifdef RT_USING_MEMHEAP
/**
* memory heap object interface
*/
rt_err_t rt_memheap_init(struct rt_memheap *memheap,
const char *name,
void *start_addr,
rt_size_t size);
rt_err_t rt_memheap_detach(struct rt_memheap *heap);
void *rt_memheap_alloc(struct rt_memheap *heap, rt_size_t size);
void *rt_memheap_realloc(struct rt_memheap *heap, void *ptr, rt_size_t newsize);
void rt_memheap_free(void *ptr);
void rt_memheap_info(struct rt_memheap *heap,
rt_size_t *total,
rt_size_t *used,
rt_size_t *max_used);
#endif /* RT_USING_MEMHEAP */
#ifdef RT_USING_MEMHEAP_AS_HEAP
/**
* memory heap as heap
*/
void *_memheap_alloc(struct rt_memheap *heap, rt_size_t size);
void _memheap_free(void *rmem);
void *_memheap_realloc(struct rt_memheap *heap, void *rmem, rt_size_t newsize);
#endif
#ifdef RT_USING_SLAB
/**
* slab object interface
*/
rt_slab_t rt_slab_init(const char *name, void *begin_addr, rt_size_t size);
rt_err_t rt_slab_detach(rt_slab_t m);
void *rt_slab_page_alloc(rt_slab_t m, rt_size_t npages);
void rt_slab_page_free(rt_slab_t m, void *addr, rt_size_t npages);
void *rt_slab_alloc(rt_slab_t m, rt_size_t size);
void *rt_slab_realloc(rt_slab_t m, void *ptr, rt_size_t size);
void rt_slab_free(rt_slab_t m, void *ptr);
#endif /* RT_USING_SLAB */
/**@}*/
/**
* @addtogroup group_thread_comm
* @{
*/
/**
* Suspend list - A basic building block for IPC primitives which interacts with
* scheduler directly. Its API is similar to a FIFO list.
*
* Note: don't use in application codes directly
*/
void rt_susp_list_print(rt_list_t *list);
/* reserve thread error while resuming it */
#define RT_THREAD_RESUME_RES_THR_ERR (-1)
struct rt_thread *rt_susp_list_dequeue(rt_list_t *susp_list, rt_err_t thread_error);
rt_err_t rt_susp_list_resume_all(rt_list_t *susp_list, rt_err_t thread_error);
rt_err_t rt_susp_list_resume_all_irq(rt_list_t *susp_list,
rt_err_t thread_error,
struct rt_spinlock *lock);
/* suspend and enqueue */
rt_err_t rt_thread_suspend_to_list(rt_thread_t thread, rt_list_t *susp_list, int ipc_flags, int suspend_flag);
/* only for a suspended thread, and caller must hold the scheduler lock */
rt_err_t rt_susp_list_enqueue(rt_list_t *susp_list, rt_thread_t thread, int ipc_flags);
/**
* @addtogroup group_semaphore Semaphore
* @{
*/
#ifdef RT_USING_SEMAPHORE
/*
* semaphore interface
*/
rt_err_t rt_sem_init(rt_sem_t sem,
const char *name,
rt_uint32_t value,
rt_uint8_t flag);
rt_err_t rt_sem_detach(rt_sem_t sem);
#ifdef RT_USING_HEAP
rt_sem_t rt_sem_create(const char *name, rt_uint32_t value, rt_uint8_t flag);
rt_err_t rt_sem_delete(rt_sem_t sem);
#endif /* RT_USING_HEAP */
rt_err_t rt_sem_take(rt_sem_t sem, rt_int32_t timeout);
rt_err_t rt_sem_take_interruptible(rt_sem_t sem, rt_int32_t timeout);
rt_err_t rt_sem_take_killable(rt_sem_t sem, rt_int32_t timeout);
rt_err_t rt_sem_trytake(rt_sem_t sem);
rt_err_t rt_sem_release(rt_sem_t sem);
rt_err_t rt_sem_control(rt_sem_t sem, int cmd, void *arg);
#endif /* RT_USING_SEMAPHORE */
/**@}*/
/**
* @addtogroup group_mutex Mutex
* @{
*/
#ifdef RT_USING_MUTEX
/*
* mutex interface
*/
rt_err_t rt_mutex_init(rt_mutex_t mutex, const char *name, rt_uint8_t flag);
rt_err_t rt_mutex_detach(rt_mutex_t mutex);
#ifdef RT_USING_HEAP
rt_mutex_t rt_mutex_create(const char *name, rt_uint8_t flag);
rt_err_t rt_mutex_delete(rt_mutex_t mutex);
#endif /* RT_USING_HEAP */
void rt_mutex_drop_thread(rt_mutex_t mutex, rt_thread_t thread);
rt_uint8_t rt_mutex_setprioceiling(rt_mutex_t mutex, rt_uint8_t priority);
rt_uint8_t rt_mutex_getprioceiling(rt_mutex_t mutex);
rt_err_t rt_mutex_take(rt_mutex_t mutex, rt_int32_t timeout);
rt_err_t rt_mutex_trytake(rt_mutex_t mutex);
rt_err_t rt_mutex_take_interruptible(rt_mutex_t mutex, rt_int32_t time);
rt_err_t rt_mutex_take_killable(rt_mutex_t mutex, rt_int32_t time);
rt_err_t rt_mutex_release(rt_mutex_t mutex);
rt_err_t rt_mutex_control(rt_mutex_t mutex, int cmd, void *arg);
rt_inline rt_thread_t rt_mutex_get_owner(rt_mutex_t mutex)
{
return mutex->owner;
}
rt_inline rt_ubase_t rt_mutex_get_hold(rt_mutex_t mutex)
{
return mutex->hold;
}
#endif /* RT_USING_MUTEX */
/**@}*/
/**
* @addtogroup group_event Event
* @{
*/
#ifdef RT_USING_EVENT
/*
* event interface
*/
rt_err_t rt_event_init(rt_event_t event, const char *name, rt_uint8_t flag);
rt_err_t rt_event_detach(rt_event_t event);
#ifdef RT_USING_HEAP
rt_event_t rt_event_create(const char *name, rt_uint8_t flag);
rt_err_t rt_event_delete(rt_event_t event);
#endif /* RT_USING_HEAP */
rt_err_t rt_event_send(rt_event_t event, rt_uint32_t set);
rt_err_t rt_event_recv(rt_event_t event,
rt_uint32_t set,
rt_uint8_t opt,
rt_int32_t timeout,
rt_uint32_t *recved);
rt_err_t rt_event_recv_interruptible(rt_event_t event,
rt_uint32_t set,
rt_uint8_t opt,
rt_int32_t timeout,
rt_uint32_t *recved);
rt_err_t rt_event_recv_killable(rt_event_t event,
rt_uint32_t set,
rt_uint8_t opt,
rt_int32_t timeout,
rt_uint32_t *recved);
rt_err_t rt_event_control(rt_event_t event, int cmd, void *arg);
#endif /* RT_USING_EVENT */
/**@}*/
/**
* @addtogroup group_mailbox MailBox
* @{
*/
#ifdef RT_USING_MAILBOX
/*
* mailbox interface
*/
rt_err_t rt_mb_init(rt_mailbox_t mb,
const char *name,
void *msgpool,
rt_size_t size,
rt_uint8_t flag);
rt_err_t rt_mb_detach(rt_mailbox_t mb);
#ifdef RT_USING_HEAP
rt_mailbox_t rt_mb_create(const char *name, rt_size_t size, rt_uint8_t flag);
rt_err_t rt_mb_delete(rt_mailbox_t mb);
#endif /* RT_USING_HEAP */
rt_err_t rt_mb_send(rt_mailbox_t mb, rt_ubase_t value);
rt_err_t rt_mb_send_interruptible(rt_mailbox_t mb, rt_ubase_t value);
rt_err_t rt_mb_send_killable(rt_mailbox_t mb, rt_ubase_t value);
rt_err_t rt_mb_send_wait(rt_mailbox_t mb,
rt_ubase_t value,
rt_int32_t timeout);
rt_err_t rt_mb_send_wait_interruptible(rt_mailbox_t mb,
rt_ubase_t value,
rt_int32_t timeout);
rt_err_t rt_mb_send_wait_killable(rt_mailbox_t mb,
rt_ubase_t value,
rt_int32_t timeout);
rt_err_t rt_mb_urgent(rt_mailbox_t mb, rt_ubase_t value);
rt_err_t rt_mb_recv(rt_mailbox_t mb, rt_ubase_t *value, rt_int32_t timeout);
rt_err_t rt_mb_recv_interruptible(rt_mailbox_t mb, rt_ubase_t *value, rt_int32_t timeout);
rt_err_t rt_mb_recv_killable(rt_mailbox_t mb, rt_ubase_t *value, rt_int32_t timeout);
rt_err_t rt_mb_control(rt_mailbox_t mb, int cmd, void *arg);
#endif /* RT_USING_MAILBOX */
/**@}*/
/**
* @addtogroup group_messagequeue Message Queue
* @{
*/
#ifdef RT_USING_MESSAGEQUEUE
struct rt_mq_message
{
struct rt_mq_message *next;
rt_ssize_t length;
#ifdef RT_USING_MESSAGEQUEUE_PRIORITY
rt_int32_t prio;
#endif /* RT_USING_MESSAGEQUEUE_PRIORITY */
};
#define RT_MQ_BUF_SIZE(msg_size, max_msgs) \
((RT_ALIGN((msg_size), RT_ALIGN_SIZE) + sizeof(struct rt_mq_message)) * (max_msgs))
/*
* message queue interface
*/
rt_err_t rt_mq_init(rt_mq_t mq,
const char *name,
void *msgpool,
rt_size_t msg_size,
rt_size_t pool_size,
rt_uint8_t flag);
rt_err_t rt_mq_detach(rt_mq_t mq);
#ifdef RT_USING_HEAP
rt_mq_t rt_mq_create(const char *name,
rt_size_t msg_size,
rt_size_t max_msgs,
rt_uint8_t flag);
rt_err_t rt_mq_delete(rt_mq_t mq);
#endif /* RT_USING_HEAP */
rt_err_t rt_mq_send(rt_mq_t mq, const void *buffer, rt_size_t size);
rt_err_t rt_mq_send_interruptible(rt_mq_t mq, const void *buffer, rt_size_t size);
rt_err_t rt_mq_send_killable(rt_mq_t mq, const void *buffer, rt_size_t size);
rt_err_t rt_mq_send_wait(rt_mq_t mq,
const void *buffer,
rt_size_t size,
rt_int32_t timeout);
rt_err_t rt_mq_send_wait_interruptible(rt_mq_t mq,
const void *buffer,
rt_size_t size,
rt_int32_t timeout);
rt_err_t rt_mq_send_wait_killable(rt_mq_t mq,
const void *buffer,
rt_size_t size,
rt_int32_t timeout);
rt_err_t rt_mq_urgent(rt_mq_t mq, const void *buffer, rt_size_t size);
rt_ssize_t rt_mq_recv(rt_mq_t mq,
void *buffer,
rt_size_t size,
rt_int32_t timeout);
rt_ssize_t rt_mq_recv_interruptible(rt_mq_t mq,
void *buffer,
rt_size_t size,
rt_int32_t timeout);
rt_ssize_t rt_mq_recv_killable(rt_mq_t mq,
void *buffer,
rt_size_t size,
rt_int32_t timeout);
rt_err_t rt_mq_control(rt_mq_t mq, int cmd, void *arg);
#ifdef RT_USING_MESSAGEQUEUE_PRIORITY
rt_err_t rt_mq_send_wait_prio(rt_mq_t mq,
const void *buffer,
rt_size_t size,
rt_int32_t prio,
rt_int32_t timeout,
int suspend_flag);
rt_ssize_t rt_mq_recv_prio(rt_mq_t mq,
void *buffer,
rt_size_t size,
rt_int32_t *prio,
rt_int32_t timeout,
int suspend_flag);
#endif /* RT_USING_MESSAGEQUEUE_PRIORITY */
#endif /* RT_USING_MESSAGEQUEUE */
/**@}*/
/* defunct */
void rt_thread_defunct_init(void);
void rt_thread_defunct_enqueue(rt_thread_t thread);
rt_thread_t rt_thread_defunct_dequeue(void);
void rt_defunct_execute(void);
/*
* spinlock
*/
struct rt_spinlock;
void rt_spin_lock_init(struct rt_spinlock *lock);
void rt_spin_lock(struct rt_spinlock *lock);
void rt_spin_unlock(struct rt_spinlock *lock);
rt_base_t rt_spin_lock_irqsave(struct rt_spinlock *lock);
void rt_spin_unlock_irqrestore(struct rt_spinlock *lock, rt_base_t level);
/**@}*/
#ifdef RT_USING_DEVICE
/**
* @addtogroup group_device_driver
* @{
*/
/*
* device (I/O) system interface
*/
rt_device_t rt_device_find(const char *name);
rt_err_t rt_device_register(rt_device_t dev,
const char *name,
rt_uint16_t flags);
rt_err_t rt_device_unregister(rt_device_t dev);
#ifdef RT_USING_HEAP
rt_device_t rt_device_create(int type, int attach_size);
void rt_device_destroy(rt_device_t device);
#endif /* RT_USING_HEAP */
rt_err_t
rt_device_set_rx_indicate(rt_device_t dev,
rt_err_t (*rx_ind)(rt_device_t dev, rt_size_t size));
rt_err_t
rt_device_set_tx_complete(rt_device_t dev,
rt_err_t (*tx_done)(rt_device_t dev, void *buffer));
rt_err_t rt_device_init (rt_device_t dev);
rt_err_t rt_device_open (rt_device_t dev, rt_uint16_t oflag);
rt_err_t rt_device_close(rt_device_t dev);
rt_ssize_t rt_device_read(rt_device_t dev,
rt_off_t pos,
void *buffer,
rt_size_t size);
rt_ssize_t rt_device_write(rt_device_t dev,
rt_off_t pos,
const void *buffer,
rt_size_t size);
rt_err_t rt_device_control(rt_device_t dev, int cmd, void *arg);
/**@}*/
#endif /* RT_USING_DEVICE */
/*
* interrupt service
*/
/*
* rt_interrupt_enter and rt_interrupt_leave only can be called by BSP
*/
void rt_interrupt_enter(void);
void rt_interrupt_leave(void);
void rt_interrupt_context_push(rt_interrupt_context_t this_ctx);
void rt_interrupt_context_pop(void);
void *rt_interrupt_context_get(void);
/**
* CPU object
*/
struct rt_cpu *rt_cpu_self(void);
struct rt_cpu *rt_cpu_index(int index);
#ifdef RT_USING_SMP
/*
* smp cpus lock service
*/
rt_base_t rt_cpus_lock(void);
void rt_cpus_unlock(rt_base_t level);
void rt_cpus_lock_status_restore(struct rt_thread *thread);
#ifdef RT_USING_DEBUG
rt_base_t rt_cpu_get_id(void);
#else /* !RT_USING_DEBUG */
#define rt_cpu_get_id rt_hw_cpu_id
#endif /* RT_USING_DEBUG */
#else /* !RT_USING_SMP */
#define rt_cpu_get_id() (0)
#endif /* RT_USING_SMP */
/*
* the number of nested interrupts.
*/
rt_uint8_t rt_interrupt_get_nest(void);
#ifdef RT_USING_HOOK
void rt_interrupt_enter_sethook(void (*hook)(void));
void rt_interrupt_leave_sethook(void (*hook)(void));
#endif /* RT_USING_HOOK */
#ifdef RT_USING_COMPONENTS_INIT
void rt_components_init(void);
void rt_components_board_init(void);
#endif /* RT_USING_COMPONENTS_INIT */
/**
* @addtogroup group_kernel_service
* @{
*/
/*
* general kernel service
*/
#ifndef RT_USING_CONSOLE
#define rt_kprintf(...)
#define rt_kputs(str)
#else
int rt_kprintf(const char *fmt, ...);
void rt_kputs(const char *str);
#ifdef RT_USING_CONSOLE_OUTPUT_CTL
void rt_console_output_set_enabled(rt_bool_t enabled);
rt_bool_t rt_console_output_get_enabled(void);
#else
#define rt_console_output_set_enabled(enabled) ((void)0)
#define rt_console_output_get_enabled() (RT_TRUE)
#endif /* RT_USING_CONSOLE_OUTPUT_CTL */
#endif /* RT_USING_CONSOLE */
rt_err_t rt_backtrace(void);
rt_err_t rt_backtrace_thread(rt_thread_t thread);
rt_err_t rt_backtrace_frame(rt_thread_t thread, struct rt_hw_backtrace_frame *frame);
rt_err_t rt_backtrace_formatted_print(rt_ubase_t *buffer, long buflen);
rt_err_t rt_backtrace_to_buffer(rt_thread_t thread, struct rt_hw_backtrace_frame *frame,
long skip, rt_ubase_t *buffer, long buflen);
#if defined(RT_USING_DEVICE) && defined(RT_USING_CONSOLE)
rt_device_t rt_console_set_device(const char *name);
rt_device_t rt_console_get_device(void);
#ifdef RT_USING_THREADSAFE_PRINTF
rt_thread_t rt_console_current_user(void);
#else
rt_inline void *rt_console_current_user(void) { return RT_NULL; }
#endif /* RT_USING_THREADSAFE_PRINTF */
#endif /* defined(RT_USING_DEVICE) && defined(RT_USING_CONSOLE) */
int __rt_fls(int val);
int __rt_ffs(int value);
unsigned long __rt_ffsl(unsigned long value);
unsigned long __rt_clz(unsigned long value);
void rt_show_version(void);
#ifdef RT_DEBUGING_ASSERT
extern void (*rt_assert_hook)(const char *ex, const char *func, rt_size_t line);
void rt_assert_set_hook(void (*hook)(const char *ex, const char *func, rt_size_t line));
void rt_assert_handler(const char *ex, const char *func, rt_size_t line);
#define RT_ASSERT(EX) \
if (!(EX)) \
{ \
rt_assert_handler(#EX, __FUNCTION__, __LINE__); \
}
#else
#define RT_ASSERT(EX) {RT_UNUSED(EX);}
#endif /* RT_DEBUGING_ASSERT */
#ifdef RT_DEBUGING_CONTEXT
/* Macro to check current context */
#define RT_DEBUG_NOT_IN_INTERRUPT \
do \
{ \
if (rt_interrupt_get_nest() != 0) \
{ \
rt_kprintf("Function[%s] shall not be used in ISR\n", __FUNCTION__); \
RT_ASSERT(0) \
} \
} \
while (0)
/* "In thread context" means:
* 1) the scheduler has been started
* 2) not in interrupt context.
*/
#define RT_DEBUG_IN_THREAD_CONTEXT \
do \
{ \
if (rt_thread_self() == RT_NULL) \
{ \
rt_kprintf("Function[%s] shall not be used before scheduler start\n", \
__FUNCTION__); \
RT_ASSERT(0) \
} \
RT_DEBUG_NOT_IN_INTERRUPT; \
} \
while (0)
#if defined(RT_USING_SMP)
/**
* @brief Check whether disabled interrupts make scheduler unavailable.
*
* In SMP builds, some kernel-internal lockless wait paths may disable local
* interrupts while still using scheduler-related operations legally. Keep this
* IRQ-disabled context assertion for UP builds only.
*/
#define RT_DEBUG_SCHEDULER_IRQ_DISABLED() (RT_FALSE)
#else
/**
* @brief Check whether disabled interrupts make scheduler unavailable.
*
* In UP builds, globally disabled interrupts prevent normal scheduling and
* timeout progress, so blocking scheduler paths must reject this context.
*/
#define RT_DEBUG_SCHEDULER_IRQ_DISABLED() rt_hw_interrupt_is_disabled()
#endif /* defined(RT_USING_SMP) */
/* "scheduler available" means:
* 1) the scheduler has been started.
* 2) not in interrupt context.
* 3) scheduler is not locked.
* 4) interrupts are not disabled on UP.
*/
#define RT_DEBUG_SCHEDULER_AVAILABLE(need_check) \
do \
{ \
if (need_check) \
{ \
if ((rt_critical_level() != 0) || RT_DEBUG_SCHEDULER_IRQ_DISABLED()) \
{ \
rt_kprintf("Function[%s]: scheduler is not available\n", \
__FUNCTION__); \
RT_ASSERT(0) \
} \
RT_DEBUG_IN_THREAD_CONTEXT; \
} \
} \
while (0)
#else
#define RT_DEBUG_NOT_IN_INTERRUPT
#define RT_DEBUG_IN_THREAD_CONTEXT
#define RT_DEBUG_SCHEDULER_AVAILABLE(need_check)
#endif /* RT_DEBUGING_CONTEXT */
rt_inline rt_bool_t rt_in_thread_context(void)
{
return rt_thread_self() != RT_NULL && rt_interrupt_get_nest() == 0;
}
/* is scheduler available */
rt_inline rt_bool_t rt_scheduler_is_available(void)
{
return rt_critical_level() == 0 && rt_in_thread_context();
}
#ifdef RT_USING_SMP
/* is thread bond on core */
rt_inline rt_bool_t rt_sched_thread_is_binding(rt_thread_t thread)
{
if (thread == RT_NULL)
{
thread = rt_thread_self();
}
return !thread || RT_SCHED_CTX(thread).bind_cpu != RT_CPUS_NR;
}
#else
#define rt_sched_thread_is_binding(thread) (RT_TRUE)
#endif
/**@}*/
#ifdef __cplusplus
}
#endif
#endif /* __RT_THREAD_H__ */
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简介

RT-Thread是一个来自中国的开源物联网操作系统,它提供了非常强的可伸缩能力:从一个可以运行在ARM Cortex-M0芯片上的极小内核,到中等的ARM Cortex-M3/4/7系统,甚至是多核,64位的ARM Cortex-A,MIPS32/64处理器的功能丰富系统
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开源评估指数源自 OSS-Compass 评估体系,评估体系围绕以下三个维度对项目展开评估:

1. 开源生态

  • 生产力:来评估开源项目输出软件制品和开源价值的能力。
  • 创新力:用于评估开源软件及其生态系统的多样化程度。
  • 稳健性:用于评估开源项目面对多变的发展环境,抵御内外干扰并自我恢复的能力。

2. 协作、人、软件

  • 协作:代表了开源开发行为中协作的程度和深度。
  • 人:观察开源项目核心人员在开源项目中的影响力,并通过第三方视角考察用户和开发者对开源项目的评价。
  • 软件:从开源项目对外输出的制品评估其价值最终落脚点。也是开源评估最"古老"的主流方向之一"开源软件" 的具体表现。

3. 评估模型

    基于"开源生态"与"协作、人、软件"的维度,找到与该目标直接或间接相关的可量化指标,对开源项目健康与生态进行量化评估,最终形成开源评估指数。

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