/* 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 ch.c * @brief Nil RTOS main source file. * * @addtogroup NIL_KERNEL * @{ */ #include "ch.h" /*===========================================================================*/ /* Module local definitions. */ /*===========================================================================*/ /*===========================================================================*/ /* Module exported variables. */ /*===========================================================================*/ /** * @brief System data structures. */ nil_system_t nil; /*===========================================================================*/ /* Module local variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Module local functions. */ /*===========================================================================*/ /*===========================================================================*/ /* Module interrupt handlers. */ /*===========================================================================*/ /*===========================================================================*/ /* Module exported functions. */ /*===========================================================================*/ #if (CH_DBG_SYSTEM_STATE_CHECK == TRUE) || defined(__DOXYGEN__) /** * @brief Guard code for @p chSysDisable(). * * @notapi */ void _dbg_check_disable(void) { if ((nil.isr_cnt != (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#1"); } } /** * @brief Guard code for @p chSysSuspend(). * * @notapi */ void _dbg_check_suspend(void) { if ((nil.isr_cnt != (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#2"); } } /** * @brief Guard code for @p chSysEnable(). * * @notapi */ void _dbg_check_enable(void) { if ((nil.isr_cnt != (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#3"); } } /** * @brief Guard code for @p chSysLock(). * * @notapi */ void _dbg_check_lock(void) { if ((nil.isr_cnt != (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#4"); } _dbg_enter_lock(); } /** * @brief Guard code for @p chSysUnlock(). * * @notapi */ void _dbg_check_unlock(void) { if ((nil.isr_cnt != (cnt_t)0) || (nil.lock_cnt <= (cnt_t)0)) { chSysHalt("SV#5"); } _dbg_leave_lock(); } /** * @brief Guard code for @p chSysLockFromIsr(). * * @notapi */ void _dbg_check_lock_from_isr(void) { if ((nil.isr_cnt <= (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#6"); } _dbg_enter_lock(); } /** * @brief Guard code for @p chSysUnlockFromIsr(). * * @notapi */ void _dbg_check_unlock_from_isr(void) { if ((nil.isr_cnt <= (cnt_t)0) || (nil.lock_cnt <= (cnt_t)0)) { chSysHalt("SV#7"); } _dbg_leave_lock(); } /** * @brief Guard code for @p CH_IRQ_PROLOGUE(). * * @notapi */ void _dbg_check_enter_isr(void) { port_lock_from_isr(); if ((nil.isr_cnt < (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#8"); } nil.isr_cnt++; port_unlock_from_isr(); } /** * @brief Guard code for @p CH_IRQ_EPILOGUE(). * * @notapi */ void _dbg_check_leave_isr(void) { port_lock_from_isr(); if ((nil.isr_cnt <= (cnt_t)0) || (nil.lock_cnt != (cnt_t)0)) { chSysHalt("SV#9"); } nil.isr_cnt--; port_unlock_from_isr(); } /** * @brief I-class functions context check. * @details Verifies that the system is in an appropriate state for invoking * an I-class API function. A panic is generated if the state is * not compatible. * * @api */ void chDbgCheckClassI(void) { if ((nil.isr_cnt < (cnt_t)0) || (nil.lock_cnt <= (cnt_t)0)) { chSysHalt("SV#10"); } } /** * @brief S-class functions context check. * @details Verifies that the system is in an appropriate state for invoking * an S-class API function. A panic is generated if the state is * not compatible. * * @api */ void chDbgCheckClassS(void) { if ((nil.isr_cnt != (cnt_t)0) || (nil.lock_cnt <= (cnt_t)0)) { chSysHalt("SV#11"); } } #endif /* CH_DBG_SYSTEM_STATE_CHECK == TRUE */ /** * @brief Initializes the kernel. * @details Initializes the kernel structures, the current instructions flow * becomes the idle thread upon return. The idle thread must not * invoke any kernel primitive able to change state to not runnable. * @note This function assumes that the @p nil global variable has been * zeroed by the runtime environment. If this is not the case then * make sure to clear it before calling this function. * * @special */ void chSysInit(void) { thread_t *tp; const thread_config_t *tcp; #if CH_DBG_SYSTEM_STATE_CHECK == TRUE nil.isr_cnt = (cnt_t)0; nil.lock_cnt = (cnt_t)0; #endif /* System initialization hook.*/ CH_CFG_SYSTEM_INIT_HOOK(); /* Iterates through the list of defined threads.*/ tp = &nil.threads[0]; tcp = nil_thd_configs; while (tp < &nil.threads[CH_CFG_NUM_THREADS]) { #if CH_DBG_ENABLE_STACK_CHECK tp->stklimit = (stkalign_t *)tcp->wbase; #endif /* Port dependent thread initialization.*/ PORT_SETUP_CONTEXT(tp, tcp->wbase, tcp->wend, tcp->funcp, tcp->arg); /* Initialization hook.*/ CH_CFG_THREAD_EXT_INIT_HOOK(tp); tp++; tcp++; } #if CH_DBG_ENABLE_STACK_CHECK /* The idle thread is a special case because its stack is set up by the runtime environment.*/ tp->stklimit = THD_IDLE_BASE; #endif /* Interrupts partially enabled. It is equivalent to entering the kernel critical zone.*/ chSysSuspend(); #if CH_DBG_SYSTEM_STATE_CHECK == TRUE nil.lock_cnt = (cnt_t)1; #endif /* Heap initialization, if enabled.*/ #if CH_CFG_USE_HEAP == TRUE _heap_init(); #endif /* Port layer initialization last because it depend on some of the initializations performed before.*/ port_init(); /* Runs the highest priority thread, the current one becomes the idle thread.*/ nil.current = nil.next = nil.threads; port_switch(nil.current, tp); chSysUnlock(); } /** * @brief Halts the system. * @details This function is invoked by the operating system when an * unrecoverable error is detected, for example because a programming * error in the application code that triggers an assertion while * in debug mode. * @note Can be invoked from any system state. * * @param[in] reason pointer to an error string * * @special */ void chSysHalt(const char *reason) { port_disable(); #if NIL_DBG_ENABLED nil.dbg_panic_msg = reason; #else (void)reason; #endif CH_CFG_SYSTEM_HALT_HOOK(reason); /* Harmless infinite loop.*/ while (true) { } } /** * @brief Time management handler. * @note This handler has to be invoked by a periodic ISR in order to * reschedule the waiting threads. * * @iclass */ void chSysTimerHandlerI(void) { chDbgCheckClassI(); #if CH_CFG_ST_TIMEDELTA == 0 thread_t *tp = &nil.threads[0]; nil.systime++; do { /* Is the thread in a wait state with timeout?.*/ if (tp->timeout > (systime_t)0) { chDbgAssert(!NIL_THD_IS_READY(tp), "is ready"); /* Did the timer reach zero?*/ if (--tp->timeout == (systime_t)0) { /* Timeout on semaphores requires a special handling because the semaphore counter must be incremented.*/ /*lint -save -e9013 [15.7] There is no else because it is not needed.*/ if (NIL_THD_IS_WTSEM(tp)) { tp->u1.semp->cnt++; } else if (NIL_THD_IS_SUSP(tp)) { *tp->u1.trp = NULL; } /*lint -restore*/ (void) chSchReadyI(tp, MSG_TIMEOUT); } } /* Lock released in order to give a preemption chance on those architectures supporting IRQ preemption.*/ chSysUnlockFromISR(); tp++; chSysLockFromISR(); } while (tp < &nil.threads[CH_CFG_NUM_THREADS]); #else thread_t *tp = &nil.threads[0]; systime_t next = (systime_t)0; chDbgAssert(nil.nexttime == port_timer_get_alarm(), "time mismatch"); do { /* Is the thread in a wait state with timeout?.*/ if (tp->timeout > (systime_t)0) { chDbgAssert(!NIL_THD_IS_READY(tp), "is ready"); chDbgAssert(tp->timeout >= (nil.nexttime - nil.lasttime), "skipped one"); tp->timeout -= nil.nexttime - nil.lasttime; if (tp->timeout == (systime_t)0) { #if CH_CFG_USE_SEMAPHORES == TRUE /* Timeout on semaphores requires a special handling because the semaphore counter must be incremented.*/ if (NIL_THD_IS_WTSEM(tp)) { tp->u1.semp->cnt++; } else { #endif if (NIL_THD_IS_SUSP(tp)) { *tp->u1.trp = NULL; } #if CH_CFG_USE_SEMAPHORES == TRUE } #endif (void) chSchReadyI(tp, MSG_TIMEOUT); } else { if (tp->timeout <= (systime_t)(next - (systime_t)1)) { next = tp->timeout; } } } /* Lock released in order to give a preemption chance on those architectures supporting IRQ preemption.*/ chSysUnlockFromISR(); tp++; chSysLockFromISR(); } while (tp < &nil.threads[CH_CFG_NUM_THREADS]); nil.lasttime = nil.nexttime; if (next > (systime_t)0) { nil.nexttime += next; port_timer_set_alarm(nil.nexttime); } else { /* No tick event needed.*/ port_timer_stop_alarm(); } #endif } /** * @brief Unconditionally enters the kernel lock state. * @note Can be called without previous knowledge of the current lock state. * The final state is "s-locked". * * @special */ void chSysUnconditionalLock(void) { if (port_irq_enabled(port_get_irq_status())) { chSysLock(); } } /** * @brief Unconditionally leaves the kernel lock state. * @note Can be called without previous knowledge of the current lock state. * The final state is "normal". * * @special */ void chSysUnconditionalUnlock(void) { if (!port_irq_enabled(port_get_irq_status())) { chSysUnlock(); } } /** * @brief Returns the execution status and enters a critical zone. * @details This functions enters into a critical zone and can be called * from any context. Because its flexibility it is less efficient * than @p chSysLock() which is preferable when the calling context * is known. * @post The system is in a critical zone. * * @return The previous system status, the encoding of this * status word is architecture-dependent and opaque. * * @xclass */ syssts_t chSysGetStatusAndLockX(void) { syssts_t sts = port_get_irq_status(); if (port_irq_enabled(sts)) { if (port_is_isr_context()) { chSysLockFromISR(); } else { chSysLock(); } } return sts; } /** * @brief Restores the specified execution status and leaves a critical zone. * @note A call to @p chSchRescheduleS() is automatically performed * if exiting the critical zone and if not in ISR context. * * @param[in] sts the system status to be restored. * * @xclass */ void chSysRestoreStatusX(syssts_t sts) { if (port_irq_enabled(sts)) { if (port_is_isr_context()) { chSysUnlockFromISR(); } else { chSchRescheduleS(); chSysUnlock(); } } } #if (PORT_SUPPORTS_RT == TRUE) || defined(__DOXYGEN__) /** * @brief Realtime window test. * @details This function verifies if the current realtime counter value * lies within the specified range or not. The test takes care * of the realtime counter wrapping to zero on overflow. * @note When start==end then the function returns always true because the * whole time range is specified. * @note This function is only available if the port layer supports the * option @p PORT_SUPPORTS_RT. * * @param[in] cnt the counter value to be tested * @param[in] start the start of the time window (inclusive) * @param[in] end the end of the time window (non inclusive) * @retval true current time within the specified time window. * @retval false current time not within the specified time window. * * @xclass */ bool chSysIsCounterWithinX(rtcnt_t cnt, rtcnt_t start, rtcnt_t end) { return (bool)((cnt - start) < (end - start)); } /** * @brief Polled delay. * @note The real delay is always few cycles in excess of the specified * value. * @note This function is only available if the port layer supports the * option @p PORT_SUPPORTS_RT. * * @param[in] cycles number of cycles * * @xclass */ void chSysPolledDelayX(rtcnt_t cycles) { rtcnt_t start = chSysGetRealtimeCounterX(); rtcnt_t end = start + cycles; while (chSysIsCounterWithinX(chSysGetRealtimeCounterX(), start, end)) { } } #endif /* PORT_SUPPORTS_RT == TRUE */ /** * @brief Makes the specified thread ready for execution. * * @param[in] tp pointer to the @p thread_t object * @param[in] msg the wakeup message * * @return The same reference passed as parameter. */ thread_t *chSchReadyI(thread_t *tp, msg_t msg) { chDbgCheckClassI(); chDbgCheck((tp >= nil.threads) && (tp < &nil.threads[CH_CFG_NUM_THREADS])); chDbgAssert(!NIL_THD_IS_READY(tp), "already ready"); chDbgAssert(nil.next <= nil.current, "priority ordering"); tp->u1.msg = msg; tp->state = NIL_STATE_READY; tp->timeout = (systime_t)0; if (tp < nil.next) { nil.next = tp; } return tp; } /** * @brief Evaluates if preemption is required. * @details The decision is taken by comparing the relative priorities and * depending on the state of the round robin timeout counter. * @note Not a user function, it is meant to be invoked by the scheduler * itself or from within the port layer. * * @retval true if there is a thread that must go in running state * immediately. * @retval false if preemption is not required. * * @special */ bool chSchIsPreemptionRequired(void) { return chSchIsRescRequiredI(); } /** * @brief Switches to the first thread on the runnable queue. * @note Not a user function, it is meant to be invoked by the scheduler * itself or from within the port layer. * * @special */ void chSchDoReschedule(void) { thread_t *otp = nil.current; nil.current = nil.next; if (otp == &nil.threads[CH_CFG_NUM_THREADS]) { CH_CFG_IDLE_LEAVE_HOOK(); } port_switch(nil.next, otp); } /** * @brief Reschedules if needed. * * @sclass */ void chSchRescheduleS(void) { chDbgCheckClassS(); if (chSchIsRescRequiredI()) { chSchDoReschedule(); } } /** * @brief Puts the current thread to sleep into the specified state with * timeout specification. * @details The thread goes into a sleeping state, if it is not awakened * explicitly within the specified system time then it is forcibly * awakened with a @p NIL_MSG_TMO low level message. * * @param[in] newstate the new thread state or a semaphore pointer * @param[in] timeout the number of ticks before the operation timeouts. * the following special values are allowed: * - @a TIME_INFINITE no timeout. * . * @return The wakeup message. * @retval NIL_MSG_TMO if a timeout occurred. * * @sclass */ msg_t chSchGoSleepTimeoutS(tstate_t newstate, systime_t timeout) { thread_t *ntp, *otp = nil.current; chDbgCheckClassS(); chDbgAssert(otp != &nil.threads[CH_CFG_NUM_THREADS], "idle cannot sleep"); /* Storing the wait object for the current thread.*/ otp->state = newstate; #if CH_CFG_ST_TIMEDELTA > 0 if (timeout != TIME_INFINITE) { systime_t abstime; /* TIMEDELTA makes sure to have enough time to reprogram the timer before the free-running timer counter reaches the selected timeout.*/ if (timeout < (systime_t)CH_CFG_ST_TIMEDELTA) { timeout = (systime_t)CH_CFG_ST_TIMEDELTA; } /* Absolute time of the timeout event.*/ abstime = chVTGetSystemTimeX() + timeout; if (nil.lasttime == nil.nexttime) { /* Special case, first thread asking for a timeout.*/ port_timer_start_alarm(abstime); nil.nexttime = abstime; } else { /* Special case, there are already other threads with a timeout activated, evaluating the order.*/ if (chVTIsTimeWithinX(abstime, nil.lasttime, nil.nexttime)) { port_timer_set_alarm(abstime); nil.nexttime = abstime; } } /* Timeout settings.*/ otp->timeout = abstime - nil.lasttime; } #else /* Timeout settings.*/ otp->timeout = timeout; #endif /* Scanning the whole threads array.*/ ntp = nil.threads; while (true) { /* Is this thread ready to execute?*/ if (NIL_THD_IS_READY(ntp)) { nil.current = nil.next = ntp; if (ntp == &nil.threads[CH_CFG_NUM_THREADS]) { CH_CFG_IDLE_ENTER_HOOK(); } port_switch(ntp, otp); return nil.current->u1.msg; } /* Points to the next thread in lowering priority order.*/ ntp++; chDbgAssert(ntp <= &nil.threads[CH_CFG_NUM_THREADS], "pointer out of range"); } } /** * @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 number of ticks before the operation timeouts, * the following special values are allowed: * - @a TIME_INFINITE no timeout. * . * @return The wake up message. * * @sclass */ msg_t chThdSuspendTimeoutS(thread_reference_t *trp, systime_t timeout) { chDbgAssert(*trp == NULL, "not NULL"); *trp = nil.current; nil.current->u1.trp = trp; return chSchGoSleepTimeoutS(NIL_STATE_SUSP, 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_reference_t tr = *trp; chDbgAssert(NIL_THD_IS_SUSP(tr), "not suspended"); *trp = NULL; (void) chSchReadyI(tr, msg); } } /** * @brief Suspends the invoking thread for the specified time. * * @param[in] timeout the delay in system ticks * * @api */ void chThdSleep(systime_t timeout) { chSysLock(); chThdSleepS(timeout); chSysUnlock(); } /** * @brief Suspends the invoking thread until the system time arrives to the * specified value. * * @param[in] abstime absolute system time * * @api */ void chThdSleepUntil(systime_t abstime) { chSysLock(); chThdSleepUntilS(abstime); chSysUnlock(); } #if (CH_CFG_USE_SEMAPHORES == TRUE) || defined(__DOXYGEN__) /** * @brief Performs a wait operation on a semaphore with timeout specification. * * @param[in] sp pointer to a @p semaphore_t structure * @param[in] timeout the number of ticks before the operation timeouts, * the following special values are allowed: * - @a TIME_IMMEDIATE immediate timeout. * - @a TIME_INFINITE no timeout. * . * @return A message specifying how the invoking thread has been * released from the semaphore. * @retval NIL_MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval NIL_MSG_RST if the semaphore has been reset using @p chSemReset(). * @retval NIL_MSG_TMO if the semaphore has not been signaled or reset within * the specified timeout. * * @api */ msg_t chSemWaitTimeout(semaphore_t *sp, systime_t timeout) { msg_t msg; chSysLock(); msg = chSemWaitTimeoutS(sp, timeout); chSysUnlock(); return msg; } /** * @brief Performs a wait operation on a semaphore with timeout specification. * * @param[in] sp pointer to a @p semaphore_t structure * @param[in] timeout the number of ticks before the operation timeouts, * the following special values are allowed: * - @a TIME_IMMEDIATE immediate timeout. * - @a TIME_INFINITE no timeout. * . * @return A message specifying how the invoking thread has been * released from the semaphore. * @retval NIL_MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval NIL_MSG_RST if the semaphore has been reset using @p chSemReset(). * @retval NIL_MSG_TMO if the semaphore has not been signaled or reset within * the specified timeout. * * @sclass */ msg_t chSemWaitTimeoutS(semaphore_t *sp, systime_t timeout) { chDbgCheckClassS(); chDbgCheck(sp != NULL); /* Note, the semaphore counter is a volatile variable so accesses are manually optimized.*/ cnt_t cnt = sp->cnt; if (cnt <= (cnt_t)0) { if (TIME_IMMEDIATE == timeout) { return MSG_TIMEOUT; } sp->cnt = cnt - (cnt_t)1; nil.current->u1.semp = sp; return chSchGoSleepTimeoutS(NIL_STATE_WTSEM, timeout); } sp->cnt = cnt - (cnt_t)1; return MSG_OK; } /** * @brief Performs a signal operation on a semaphore. * @post This function does not reschedule so a call to a rescheduling * function must be performed before unlocking the kernel. Note that * interrupt handlers always reschedule on exit so an explicit * reschedule must not be performed in ISRs. * * @param[in] sp pointer to a @p semaphore_t structure * * @api */ void chSemSignal(semaphore_t *sp) { chSysLock(); chSemSignalI(sp); chSchRescheduleS(); chSysUnlock(); } /** * @brief Performs a signal operation on a semaphore. * @post This function does not reschedule so a call to a rescheduling * function must be performed before unlocking the kernel. Note that * interrupt handlers always reschedule on exit so an explicit * reschedule must not be performed in ISRs. * * @param[in] sp pointer to a @p semaphore_t structure * * @iclass */ void chSemSignalI(semaphore_t *sp) { chDbgCheckClassI(); chDbgCheck(sp != NULL); if (++sp->cnt <= (cnt_t)0) { thread_reference_t tr = nil.threads; while (true) { /* Is this thread waiting on this semaphore?*/ if (tr->u1.semp == sp) { chDbgAssert(NIL_THD_IS_WTSEM(tr), "not waiting"); (void) chSchReadyI(tr, MSG_OK); return; } tr++; chDbgAssert(tr < &nil.threads[CH_CFG_NUM_THREADS], "pointer out of range"); } } } /** * @brief Performs a reset operation on the semaphore. * @post After invoking this function all the threads waiting on the * semaphore, if any, are released and the semaphore counter is set * to the specified, non negative, value. * @post This function does not reschedule so a call to a rescheduling * function must be performed before unlocking the kernel. Note that * interrupt handlers always reschedule on exit so an explicit * reschedule must not be performed in ISRs. * * @param[in] sp pointer to a @p semaphore_t structure * @param[in] n the new value of the semaphore counter. The value must * be non-negative. * * @api */ void chSemReset(semaphore_t *sp, cnt_t n) { chSysLock(); chSemResetI(sp, n); chSchRescheduleS(); chSysUnlock(); } /** * @brief Performs a reset operation on the semaphore. * @post After invoking this function all the threads waiting on the * semaphore, if any, are released and the semaphore counter is set * to the specified, non negative, value. * @post This function does not reschedule so a call to a rescheduling * function must be performed before unlocking the kernel. Note that * interrupt handlers always reschedule on exit so an explicit * reschedule must not be performed in ISRs. * * @param[in] sp pointer to a @p semaphore_t structure * @param[in] n the new value of the semaphore counter. The value must * be non-negative. * * @iclass */ void chSemResetI(semaphore_t *sp, cnt_t n) { thread_t *tp; cnt_t cnt; chDbgCheckClassI(); chDbgCheck((sp != NULL) && (n >= (cnt_t)0)); cnt = sp->cnt; sp->cnt = n; tp = nil.threads; while (cnt < (cnt_t)0) { chDbgAssert(tp < &nil.threads[CH_CFG_NUM_THREADS], "pointer out of range"); /* Is this thread waiting on this semaphore?*/ if (tp->u1.semp == sp) { chDbgAssert(NIL_THD_IS_WTSEM(tp), "not waiting"); cnt++; (void) chSchReadyI(tp, MSG_RESET); } tp++; } } #endif /* CH_CFG_USE_SEMAPHORES == TRUE */ #if (CH_CFG_USE_EVENTS == TRUE) || defined(__DOXYGEN__) /** * @brief Adds a set of event flags directly to the specified @p thread_t. * * @param[in] tp the thread to be signaled * @param[in] mask the event flags set to be ORed * * @api */ void chEvtSignal(thread_t *tp, eventmask_t mask) { chSysLock(); chEvtSignalI(tp, mask); chSchRescheduleS(); chSysUnlock(); } /** * @brief Adds a set of event flags directly to the specified @p thread_t. * @post This function does not reschedule so a call to a rescheduling * function must be performed before unlocking the kernel. Note that * interrupt handlers always reschedule on exit so an explicit * reschedule must not be performed in ISRs. * * @param[in] tp the thread to be signaled * @param[in] mask the event flags set to be ORed * * @iclass */ void chEvtSignalI(thread_t *tp, eventmask_t mask) { chDbgCheckClassI(); chDbgCheck(tp != NULL); tp->epmask |= mask; if (NIL_THD_IS_WTOREVT(tp) && ((tp->epmask & tp->u1.ewmask) != (eventmask_t)0)) { (void) chSchReadyI(tp, MSG_OK); } } /** * @brief Waits for any of the specified events. * @details The function waits for any event among those specified in * @p mask to become pending then the events are cleared and * returned. * * @param[in] mask mask of the event flags that the function should wait * for, @p ALL_EVENTS enables all the events * @param[in] timeout the number of ticks before the operation timeouts, * the following special values are allowed: * - @a TIME_IMMEDIATE immediate timeout. * - @a TIME_INFINITE no timeout. * . * @return The mask of the served and cleared events. * @retval 0 if the operation has timed out. * * @api */ eventmask_t chEvtWaitAnyTimeout(eventmask_t mask, systime_t timeout) { thread_t *ctp = nil.current; eventmask_t m; chSysLock(); if ((m = (ctp->epmask & mask)) == (eventmask_t)0) { if (TIME_IMMEDIATE == timeout) { chSysUnlock(); return (eventmask_t)0; } ctp->u1.ewmask = mask; if (chSchGoSleepTimeoutS(NIL_STATE_WTOREVT, timeout) < MSG_OK) { chSysUnlock(); return (eventmask_t)0; } m = ctp->epmask & mask; } ctp->epmask &= ~m; chSysUnlock(); return m; } #endif /* CH_CFG_USE_EVENTS == TRUE */ /** @} */