/*
ChibiOS - Copyright (C) 2006..2016 Giovanni Di Sirio.
This file is part of ChibiOS.
ChibiOS is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
ChibiOS is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
/**
* @file chthreads.c
* @brief Threads code.
*
* @addtogroup threads
* @details Threads related APIs and services.
*
Operation mode
* A thread is an abstraction of an independent instructions flow.
* In ChibiOS/RT a thread is represented by a "C" function owning
* a processor context, state informations and a dedicated stack
* area. In this scenario static variables are shared among all
* threads while automatic variables are local to the thread.
* Operations defined for threads:
* - Create, a thread is started on the specified thread
* function. This operation is available in multiple variants,
* both static and dynamic.
* - Exit, a thread terminates by returning from its top
* level function or invoking a specific API, the thread can
* return a value that can be retrieved by other threads.
* - Wait, a thread waits for the termination of another
* thread and retrieves its return value.
* - Resume, a thread created in suspended state is started.
* - Sleep, the execution of a thread is suspended for the
* specified amount of time or the specified future absolute time
* is reached.
* - SetPriority, a thread changes its own priority level.
* - Yield, a thread voluntarily renounces to its time slot.
* .
* @{
*/
#include "ch.h"
/*===========================================================================*/
/* Module local definitions. */
/*===========================================================================*/
/*===========================================================================*/
/* Module exported variables. */
/*===========================================================================*/
/*===========================================================================*/
/* Module local types. */
/*===========================================================================*/
/*===========================================================================*/
/* Module local variables. */
/*===========================================================================*/
/*===========================================================================*/
/* Module local functions. */
/*===========================================================================*/
/*===========================================================================*/
/* Module exported functions. */
/*===========================================================================*/
/**
* @brief Initializes a thread structure.
* @note This is an internal functions, do not use it in application code.
*
* @param[in] tp pointer to the thread
* @param[in] name thread name
* @param[in] prio the priority level for the new thread
* @return The same thread pointer passed as parameter.
*
* @notapi
*/
thread_t *_thread_init(thread_t *tp, const char *name, tprio_t prio) {
tp->prio = prio;
tp->state = CH_STATE_WTSTART;
tp->flags = CH_FLAG_MODE_STATIC;
#if CH_CFG_TIME_QUANTUM > 0
tp->preempt = (tslices_t)CH_CFG_TIME_QUANTUM;
#endif
#if CH_CFG_USE_MUTEXES == TRUE
tp->realprio = prio;
tp->mtxlist = NULL;
#endif
#if CH_CFG_USE_EVENTS == TRUE
tp->epending = (eventmask_t)0;
#endif
#if CH_DBG_THREADS_PROFILING == TRUE
tp->time = (systime_t)0;
#endif
#if CH_CFG_USE_REGISTRY == TRUE
tp->refs = (trefs_t)1;
tp->name = name;
REG_INSERT(tp);
#else
(void)name;
#endif
#if CH_CFG_USE_WAITEXIT == TRUE
list_init(&tp->waiting);
#endif
#if CH_CFG_USE_MESSAGES == TRUE
queue_init(&tp->msgqueue);
#endif
#if CH_DBG_STATISTICS == TRUE
chTMObjectInit(&tp->stats);
#endif
CH_CFG_THREAD_INIT_HOOK(tp);
return tp;
}
#if (CH_DBG_FILL_THREADS == TRUE) || defined(__DOXYGEN__)
/**
* @brief Memory fill utility.
*
* @param[in] startp first address to fill
* @param[in] endp last address to fill +1
* @param[in] v filler value
*
* @notapi
*/
void _thread_memfill(uint8_t *startp, uint8_t *endp, uint8_t v) {
while (startp < endp) {
*startp++ = v;
}
}
#endif /* CH_DBG_FILL_THREADS */
/**
* @brief Creates a new thread into a static memory area.
* @details The new thread is initialized but not inserted in the ready list,
* the initial state is @p CH_STATE_WTSTART.
* @post The created thread has a reference counter set to one, it is
* caller responsibility to call @p chThdRelease() or @p chthdWait()
* in order to release the reference. The thread persists in the
* registry until its reference counter reaches zero.
* @post The initialized thread can be subsequently started by invoking
* @p chThdStart(), @p chThdStartI() or @p chSchWakeupS()
* depending on the execution context.
* @note A thread can terminate by calling @p chThdExit() or by simply
* returning from its main function.
* @note Threads created using this function do not obey to the
* @p CH_DBG_FILL_THREADS debug option because it would keep
* the kernel locked for too much time.
*
* @param[out] tdp pointer to the thread descriptor
* @return The pointer to the @p thread_t structure allocated for
* the thread into the working space area.
*
* @iclass
*/
thread_t *chThdCreateSuspendedI(const thread_descriptor_t *tdp) {
thread_t *tp;
chDbgCheckClassI();
chDbgCheck(tdp != NULL);
chDbgCheck(MEM_IS_ALIGNED(tdp->wbase, PORT_WORKING_AREA_ALIGN) &&
MEM_IS_ALIGNED(tdp->wend, PORT_STACK_ALIGN) &&
(tdp->wend > tdp->wbase) &&
(((size_t)tdp->wend - (size_t)tdp->wbase) >= THD_WORKING_AREA_SIZE(0)));
chDbgCheck((tdp->prio <= HIGHPRIO) && (tdp->funcp != NULL));
/* The thread structure is laid out in the upper part of the thread
workspace. The thread position structure is aligned to the required
stack alignment because it represents the stack top.*/
tp = (thread_t *)((uint8_t *)tdp->wend -
MEM_ALIGN_NEXT(sizeof (thread_t), PORT_STACK_ALIGN));
#if (CH_DBG_ENABLE_STACK_CHECK == TRUE) || (CH_CFG_USE_DYNAMIC == TRUE)
/* Stack boundary.*/
tp->wabase = tdp->wbase;
#endif
/* Setting up the port-dependent part of the working area.*/
PORT_SETUP_CONTEXT(tp, tdp->wbase, tp, tdp->funcp, tdp->arg);
/* The driver object is initialized but not started.*/
return _thread_init(tp, tdp->name, tdp->prio);
}
/**
* @brief Creates a new thread into a static memory area.
* @details The new thread is initialized but not inserted in the ready list,
* the initial state is @p CH_STATE_WTSTART.
* @post The created thread has a reference counter set to one, it is
* caller responsibility to call @p chThdRelease() or @p chthdWait()
* in order to release the reference. The thread persists in the
* registry until its reference counter reaches zero.
* @post The initialized thread can be subsequently started by invoking
* @p chThdStart(), @p chThdStartI() or @p chSchWakeupS()
* depending on the execution context.
* @note A thread can terminate by calling @p chThdExit() or by simply
* returning from its main function.
*
* @param[out] tdp pointer to the thread descriptor
* @return The pointer to the @p thread_t structure allocated for
* the thread into the working space area.
*
* @api
*/
thread_t *chThdCreateSuspended(const thread_descriptor_t *tdp) {
thread_t *tp;
#if CH_CFG_USE_REGISTRY == TRUE
chDbgAssert(chRegFindThreadByWorkingArea(tdp->wbase) == NULL,
"working area in use");
#endif
#if CH_DBG_FILL_THREADS == TRUE
_thread_memfill((uint8_t *)tdp->wbase,
(uint8_t *)tdp->wend,
CH_DBG_STACK_FILL_VALUE);
#endif
chSysLock();
tp = chThdCreateSuspendedI(tdp);
chSysUnlock();
return tp;
}
/**
* @brief Creates a new thread into a static memory area.
* @details The new thread is initialized and make ready to execute.
* @post The created thread has a reference counter set to one, it is
* caller responsibility to call @p chThdRelease() or @p chthdWait()
* in order to release the reference. The thread persists in the
* registry until its reference counter reaches zero.
* @post The initialized thread can be subsequently started by invoking
* @p chThdStart(), @p chThdStartI() or @p chSchWakeupS()
* depending on the execution context.
* @note A thread can terminate by calling @p chThdExit() or by simply
* returning from its main function.
* @note Threads created using this function do not obey to the
* @p CH_DBG_FILL_THREADS debug option because it would keep
* the kernel locked for too much time.
*
* @param[out] tdp pointer to the thread descriptor
* @return The pointer to the @p thread_t structure allocated for
* the thread into the working space area.
*
* @iclass
*/
thread_t *chThdCreateI(const thread_descriptor_t *tdp) {
return chSchReadyI(chThdCreateSuspendedI(tdp));
}
/**
* @brief Creates a new thread into a static memory area.
* @details The new thread is initialized and make ready to execute.
* @post The created thread has a reference counter set to one, it is
* caller responsibility to call @p chThdRelease() or @p chthdWait()
* in order to release the reference. The thread persists in the
* registry until its reference counter reaches zero.
* @note A thread can terminate by calling @p chThdExit() or by simply
* returning from its main function.
*
* @param[out] tdp pointer to the thread descriptor
* @return The pointer to the @p thread_t structure allocated for
* the thread into the working space area.
*
* @iclass
*/
thread_t *chThdCreate(const thread_descriptor_t *tdp) {
thread_t *tp;
#if CH_CFG_USE_REGISTRY == TRUE
chDbgAssert(chRegFindThreadByWorkingArea(tdp->wbase) == NULL,
"working area in use");
#endif
#if CH_DBG_FILL_THREADS == TRUE
_thread_memfill((uint8_t *)tdp->wbase,
(uint8_t *)tdp->wend,
CH_DBG_STACK_FILL_VALUE);
#endif
chSysLock();
tp = chThdCreateSuspendedI(tdp);
chSchWakeupS(tp, MSG_OK);
chSysUnlock();
return tp;
}
/**
* @brief Creates a new thread into a static memory area.
* @post The created thread has a reference counter set to one, it is
* caller responsibility to call @p chThdRelease() or @p chthdWait()
* in order to release the reference. The thread persists in the
* registry until its reference counter reaches zero.
* @note A thread can terminate by calling @p chThdExit() or by simply
* returning from its main function.
*
* @param[out] wsp pointer to a working area dedicated to the thread stack
* @param[in] size size of the working area
* @param[in] prio the priority level for the new thread
* @param[in] pf the thread function
* @param[in] arg an argument passed to the thread function. It can be
* @p NULL.
* @return The pointer to the @p thread_t structure allocated for
* the thread into the working space area.
*
* @api
*/
thread_t *chThdCreateStatic(void *wsp, size_t size,
tprio_t prio, tfunc_t pf, void *arg) {
thread_t *tp;
chDbgCheck((wsp != NULL) &&
MEM_IS_ALIGNED(wsp, PORT_WORKING_AREA_ALIGN) &&
(size >= THD_WORKING_AREA_SIZE(0)) &&
MEM_IS_ALIGNED(size, PORT_STACK_ALIGN) &&
(prio <= HIGHPRIO) && (pf != NULL));
#if CH_CFG_USE_REGISTRY == TRUE
chDbgAssert(chRegFindThreadByWorkingArea(wsp) == NULL,
"working area in use");
#endif
#if CH_DBG_FILL_THREADS == TRUE
_thread_memfill((uint8_t *)wsp,
(uint8_t *)wsp + size,
CH_DBG_STACK_FILL_VALUE);
#endif
chSysLock();
/* The thread structure is laid out in the upper part of the thread
workspace. The thread position structure is aligned to the required
stack alignment because it represents the stack top.*/
tp = (thread_t *)((uint8_t *)wsp + size -
MEM_ALIGN_NEXT(sizeof (thread_t), PORT_STACK_ALIGN));
#if (CH_DBG_ENABLE_STACK_CHECK == TRUE) || (CH_CFG_USE_DYNAMIC == TRUE)
/* Stack boundary.*/
tp->wabase = (stkalign_t *)wsp;
#endif
/* Setting up the port-dependent part of the working area.*/
PORT_SETUP_CONTEXT(tp, wsp, tp, pf, arg);
tp = _thread_init(tp, "noname", prio);
/* Starting the thread immediately.*/
chSchWakeupS(tp, MSG_OK);
chSysUnlock();
return tp;
}
/**
* @brief Resumes a thread created with @p chThdCreateI().
*
* @param[in] tp pointer to the thread
* @return The pointer to the @p thread_t structure allocated for
* the thread into the working space area.
*
* @api
*/
thread_t *chThdStart(thread_t *tp) {
chSysLock();
chDbgAssert(tp->state == CH_STATE_WTSTART, "wrong state");
chSchWakeupS(tp, MSG_OK);
chSysUnlock();
return tp;
}
#if (CH_CFG_USE_REGISTRY == TRUE) || defined(__DOXYGEN__)
/**
* @brief Adds a reference to a thread object.
* @pre The configuration option @p CH_CFG_USE_DYNAMIC must be enabled in
* order to use this function.
*
* @param[in] tp pointer to the thread
* @return The same thread pointer passed as parameter
* representing the new reference.
*
* @api
*/
thread_t *chThdAddRef(thread_t *tp) {
chSysLock();
chDbgAssert(tp->refs < (trefs_t)255, "too many references");
tp->refs++;
chSysUnlock();
return tp;
}
/**
* @brief Releases a reference to a thread object.
* @details If the references counter reaches zero and the thread
* is in the @p CH_STATE_FINAL state then the thread's memory is
* returned to the proper allocator and the thread is removed
* from the registry.
* Threads whose counter reaches zero and are still active become
* "detached" and will be removed from registry on termination.
* @pre The configuration option @p CH_CFG_USE_DYNAMIC must be enabled in
* order to use this function.
* @note Static threads are not affected.
*
* @param[in] tp pointer to the thread
*
* @api
*/
void chThdRelease(thread_t *tp) {
chSysLock();
chDbgAssert(tp->refs > (trefs_t)0, "not referenced");
tp->refs--;
/* If the references counter reaches zero and the thread is in its
terminated state then the memory can be returned to the proper
allocator.*/
if ((tp->refs == (trefs_t)0) && (tp->state == CH_STATE_FINAL)) {
REG_REMOVE(tp);
chSysUnlock();
#if CH_CFG_USE_DYNAMIC == TRUE
switch (tp->flags & CH_FLAG_MODE_MASK) {
#if CH_CFG_USE_HEAP == TRUE
case CH_FLAG_MODE_HEAP:
chHeapFree(chThdGetWorkingAreaX(tp));
break;
#endif
#if CH_CFG_USE_MEMPOOLS == TRUE
case CH_FLAG_MODE_MPOOL:
chPoolFree(tp->mpool, chThdGetWorkingAreaX(tp));
break;
#endif
default:
/* Nothing else to do for static threads.*/
break;
}
#endif /* CH_CFG_USE_DYNAMIC == TRUE */
return;
}
chSysUnlock();
}
#endif /* CH_CFG_USE_REGISTRY == TRUE */
/**
* @brief Terminates the current thread.
* @details The thread goes in the @p CH_STATE_FINAL state holding the
* specified exit status code, other threads can retrieve the
* exit status code by invoking the function @p chThdWait().
* @post Eventual code after this function will never be executed,
* this function never returns. The compiler has no way to
* know this so do not assume that the compiler would remove
* the dead code.
*
* @param[in] msg thread exit code
*
* @api
*/
void chThdExit(msg_t msg) {
chSysLock();
chThdExitS(msg);
/* The thread never returns here.*/
}
/**
* @brief Terminates the current thread.
* @details The thread goes in the @p CH_STATE_FINAL state holding the
* specified exit status code, other threads can retrieve the
* exit status code by invoking the function @p chThdWait().
* @post Exiting a non-static thread that does not have references
* (detached) causes the thread to remain in the registry.
* It can only be removed by performing a registry scan operation.
* @post Eventual code after this function will never be executed,
* this function never returns. The compiler has no way to
* know this so do not assume that the compiler would remove
* the dead code.
*
* @param[in] msg thread exit code
*
* @sclass
*/
void chThdExitS(msg_t msg) {
thread_t *tp = currp;
/* Storing exit message.*/
tp->u.exitcode = msg;
/* Exit handler hook.*/
CH_CFG_THREAD_EXIT_HOOK(tp);
#if CH_CFG_USE_WAITEXIT == TRUE
/* Waking up any waiting thread.*/
while (list_notempty(&tp->waiting)) {
(void) chSchReadyI(list_remove(&tp->waiting));
}
#endif
#if CH_CFG_USE_REGISTRY == TRUE
/* Static threads with no references are immediately removed from the
registry because there is no memory to recover.*/
#if CH_CFG_USE_DYNAMIC == TRUE
if ((tp->refs == (trefs_t)0) &&
((tp->flags & CH_FLAG_MODE_MASK) == CH_FLAG_MODE_STATIC)) {
REG_REMOVE(tp);
}
#else
if (tp->refs == (trefs_t)0) {
REG_REMOVE(tp);
}
#endif
#endif
/* Going into final state.*/
chSchGoSleepS(CH_STATE_FINAL);
/* The thread never returns here.*/
chDbgAssert(false, "zombies apocalypse");
}
#if (CH_CFG_USE_WAITEXIT == TRUE) || defined(__DOXYGEN__)
/**
* @brief Blocks the execution of the invoking thread until the specified
* thread terminates then the exit code is returned.
* @details This function waits for the specified thread to terminate then
* decrements its reference counter, if the counter reaches zero then
* the thread working area is returned to the proper allocator and
* the thread is removed from registry.
* @pre The configuration option @p CH_CFG_USE_WAITEXIT must be enabled in
* order to use this function.
* @post Enabling @p chThdWait() requires 2-4 (depending on the
* architecture) extra bytes in the @p thread_t structure.
* @note If @p CH_CFG_USE_DYNAMIC is not specified this function just waits
* for the thread termination, no memory allocators are involved.
*
* @param[in] tp pointer to the thread
* @return The exit code from the terminated thread.
*
* @api
*/
msg_t chThdWait(thread_t *tp) {
msg_t msg;
chDbgCheck(tp != NULL);
chSysLock();
chDbgAssert(tp != currp, "waiting self");
#if CH_CFG_USE_REGISTRY == TRUE
chDbgAssert(tp->refs > (trefs_t)0, "no references");
#endif
if (tp->state != CH_STATE_FINAL) {
list_insert(currp, &tp->waiting);
chSchGoSleepS(CH_STATE_WTEXIT);
}
msg = tp->u.exitcode;
chSysUnlock();
#if CH_CFG_USE_REGISTRY == TRUE
/* Releasing a reference to the thread.*/
chThdRelease(tp);
#endif
return msg;
}
#endif /* CH_CFG_USE_WAITEXIT */
/**
* @brief Changes the running thread priority level then reschedules if
* necessary.
* @note The function returns the real thread priority regardless of the
* current priority that could be higher than the real priority
* because the priority inheritance mechanism.
*
* @param[in] newprio the new priority level of the running thread
* @return The old priority level.
*
* @api
*/
tprio_t chThdSetPriority(tprio_t newprio) {
tprio_t oldprio;
chDbgCheck(newprio <= HIGHPRIO);
chSysLock();
#if CH_CFG_USE_MUTEXES == TRUE
oldprio = currp->realprio;
if ((currp->prio == currp->realprio) || (newprio > currp->prio)) {
currp->prio = newprio;
}
currp->realprio = newprio;
#else
oldprio = currp->prio;
currp->prio = newprio;
#endif
chSchRescheduleS();
chSysUnlock();
return oldprio;
}
/**
* @brief Requests a thread termination.
* @pre The target thread must be written to invoke periodically
* @p chThdShouldTerminate() and terminate cleanly if it returns
* @p true.
* @post The specified thread will terminate after detecting the termination
* condition.
*
* @param[in] tp pointer to the thread
*
* @api
*/
void chThdTerminate(thread_t *tp) {
chSysLock();
tp->flags |= CH_FLAG_TERMINATE;
chSysUnlock();
}
/**
* @brief Suspends the invoking thread for the specified time.
*
* @param[in] time the delay in system ticks, the special values are
* handled as follow:
* - @a TIME_INFINITE the thread enters an infinite sleep
* state.
* - @a TIME_IMMEDIATE this value is not allowed.
* .
*
* @api
*/
void chThdSleep(systime_t time) {
chSysLock();
chThdSleepS(time);
chSysUnlock();
}
/**
* @brief Suspends the invoking thread until the system time arrives to the
* specified value.
* @note The function has no concept of "past", all specifiable times
* are in the future, this means that if you call this function
* exceeding your calculated intervals then the function will
* return in a far future time, not immediately.
* @see chThdSleepUntilWindowed()
*
* @param[in] time absolute system time
*
* @api
*/
void chThdSleepUntil(systime_t time) {
chSysLock();
time -= chVTGetSystemTimeX();
if (time > (systime_t)0) {
chThdSleepS(time);
}
chSysUnlock();
}
/**
* @brief Suspends the invoking thread until the system time arrives to the
* specified value.
* @note The system time is assumed to be between @p prev and @p time
* else the call is assumed to have been called outside the
* allowed time interval, in this case no sleep is performed.
* @see chThdSleepUntil()
*
* @param[in] prev absolute system time of the previous deadline
* @param[in] next absolute system time of the next deadline
* @return the @p next parameter
*
* @api
*/
systime_t chThdSleepUntilWindowed(systime_t prev, systime_t next) {
systime_t time;
chSysLock();
time = chVTGetSystemTimeX();
if (chVTIsTimeWithinX(time, prev, next)) {
chThdSleepS(next - time);
}
chSysUnlock();
return next;
}
/**
* @brief Yields the time slot.
* @details Yields the CPU control to the next thread in the ready list with
* equal priority, if any.
*
* @api
*/
void chThdYield(void) {
chSysLock();
chSchDoYieldS();
chSysUnlock();
}
/**
* @brief Sends the current thread sleeping and sets a reference variable.
* @note This function must reschedule, it can only be called from thread
* context.
*
* @param[in] trp a pointer to a thread reference object
* @return The wake up message.
*
* @sclass
*/
msg_t chThdSuspendS(thread_reference_t *trp) {
thread_t *tp = chThdGetSelfX();
chDbgAssert(*trp == NULL, "not NULL");
*trp = tp;
tp->u.wttrp = trp;
chSchGoSleepS(CH_STATE_SUSPENDED);
return chThdGetSelfX()->u.rdymsg;
}
/**
* @brief Sends the current thread sleeping and sets a reference variable.
* @note This function must reschedule, it can only be called from thread
* context.
*
* @param[in] trp a pointer to a thread reference object
* @param[in] timeout the timeout in system ticks, the special values are
* handled as follow:
* - @a TIME_INFINITE the thread enters an infinite sleep
* state.
* - @a TIME_IMMEDIATE the thread is not enqueued and
* the function returns @p MSG_TIMEOUT as if a timeout
* occurred.
* .
* @return The wake up message.
* @retval MSG_TIMEOUT if the operation timed out.
*
* @sclass
*/
msg_t chThdSuspendTimeoutS(thread_reference_t *trp, systime_t timeout) {
thread_t *tp = chThdGetSelfX();
chDbgAssert(*trp == NULL, "not NULL");
if (TIME_IMMEDIATE == timeout) {
return MSG_TIMEOUT;
}
*trp = tp;
tp->u.wttrp = trp;
return chSchGoSleepTimeoutS(CH_STATE_SUSPENDED, timeout);
}
/**
* @brief Wakes up a thread waiting on a thread reference object.
* @note This function must not reschedule because it can be called from
* ISR context.
*
* @param[in] trp a pointer to a thread reference object
* @param[in] msg the message code
*
* @iclass
*/
void chThdResumeI(thread_reference_t *trp, msg_t msg) {
if (*trp != NULL) {
thread_t *tp = *trp;
chDbgAssert(tp->state == CH_STATE_SUSPENDED, "not CH_STATE_SUSPENDED");
*trp = NULL;
tp->u.rdymsg = msg;
(void) chSchReadyI(tp);
}
}
/**
* @brief Wakes up a thread waiting on a thread reference object.
* @note This function must reschedule, it can only be called from thread
* context.
*
* @param[in] trp a pointer to a thread reference object
* @param[in] msg the message code
*
* @iclass
*/
void chThdResumeS(thread_reference_t *trp, msg_t msg) {
if (*trp != NULL) {
thread_t *tp = *trp;
chDbgAssert(tp->state == CH_STATE_SUSPENDED, "not CH_STATE_SUSPENDED");
*trp = NULL;
chSchWakeupS(tp, msg);
}
}
/**
* @brief Wakes up a thread waiting on a thread reference object.
* @note This function must reschedule, it can only be called from thread
* context.
*
* @param[in] trp a pointer to a thread reference object
* @param[in] msg the message code
*
* @api
*/
void chThdResume(thread_reference_t *trp, msg_t msg) {
chSysLock();
chThdResumeS(trp, msg);
chSysUnlock();
}
/**
* @brief Enqueues the caller thread on a threads queue object.
* @details The caller thread is enqueued and put to sleep until it is
* dequeued or the specified timeouts expires.
*
* @param[in] tqp pointer to the threads queue object
* @param[in] timeout the timeout in system ticks, the special values are
* handled as follow:
* - @a TIME_INFINITE the thread enters an infinite sleep
* state.
* - @a TIME_IMMEDIATE the thread is not enqueued and
* the function returns @p MSG_TIMEOUT as if a timeout
* occurred.
* .
* @return The message from @p osalQueueWakeupOneI() or
* @p osalQueueWakeupAllI() functions.
* @retval MSG_TIMEOUT if the thread has not been dequeued within the
* specified timeout or if the function has been
* invoked with @p TIME_IMMEDIATE as timeout
* specification.
*
* @sclass
*/
msg_t chThdEnqueueTimeoutS(threads_queue_t *tqp, systime_t timeout) {
if (TIME_IMMEDIATE == timeout) {
return MSG_TIMEOUT;
}
queue_insert(currp, tqp);
return chSchGoSleepTimeoutS(CH_STATE_QUEUED, timeout);
}
/**
* @brief Dequeues and wakes up one thread from the threads queue object,
* if any.
*
* @param[in] tqp pointer to the threads queue object
* @param[in] msg the message code
*
* @iclass
*/
void chThdDequeueNextI(threads_queue_t *tqp, msg_t msg) {
if (queue_notempty(tqp)) {
chThdDoDequeueNextI(tqp, msg);
}
}
/**
* @brief Dequeues and wakes up all threads from the threads queue object.
*
* @param[in] tqp pointer to the threads queue object
* @param[in] msg the message code
*
* @iclass
*/
void chThdDequeueAllI(threads_queue_t *tqp, msg_t msg) {
while (queue_notempty(tqp)) {
chThdDoDequeueNextI(tqp, msg);
}
}
/** @} */