/* ChibiOS - Copyright (C) 2006..2018 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 rt/src/chsem.c * @brief Semaphores code. * * @addtogroup semaphores * @details Semaphores related APIs and services. *

Operation mode

* Semaphores are a flexible synchronization primitive, ChibiOS/RT * implements semaphores in their "counting semaphores" variant as * defined by Edsger Dijkstra plus several enhancements like: * - Wait operation with timeout. * - Reset operation. * - Atomic wait+signal operation. * - Return message from the wait operation (OK, RESET, TIMEOUT). * . * The binary semaphores variant can be easily implemented using * counting semaphores.
* Operations defined for semaphores: * - Signal: The semaphore counter is increased and if the * result is non-positive then a waiting thread is removed from * the semaphore queue and made ready for execution. * - Wait: The semaphore counter is decreased and if the result * becomes negative the thread is queued in the semaphore and * suspended. * - Reset: The semaphore counter is reset to a non-negative * value and all the threads in the queue are released. * . * Semaphores can be used as guards for mutual exclusion zones * (note that mutexes are recommended for this kind of use) but * also have other uses, queues guards and counters for example.
* Semaphores usually use a FIFO queuing strategy but it is possible * to make them order threads by priority by enabling * @p CH_CFG_USE_SEMAPHORES_PRIORITY in @p chconf.h. * @pre In order to use the semaphore APIs the @p CH_CFG_USE_SEMAPHORES * option must be enabled in @p chconf.h. * @{ */ #include "ch.h" #if (CH_CFG_USE_SEMAPHORES == TRUE) || defined(__DOXYGEN__) /*===========================================================================*/ /* Module exported variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Module local types. */ /*===========================================================================*/ /*===========================================================================*/ /* Module local variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Module local functions. */ /*===========================================================================*/ #if CH_CFG_USE_SEMAPHORES_PRIORITY == TRUE #define sem_insert(tp, qp) queue_prio_insert(tp, qp) #else #define sem_insert(tp, qp) queue_insert(tp, qp) #endif /*===========================================================================*/ /* Module exported functions. */ /*===========================================================================*/ /** * @brief Initializes a semaphore with the specified counter value. * * @param[out] sp pointer to a @p semaphore_t structure * @param[in] n initial value of the semaphore counter. Must be * non-negative. * * @init */ void chSemObjectInit(semaphore_t *sp, cnt_t n) { chDbgCheck((sp != NULL) && (n >= (cnt_t)0)); queue_init(&sp->queue); sp->cnt = n; } /** * @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. * * @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. * @param[in] msg message to be sent * * @api */ void chSemResetWithMessage(semaphore_t *sp, cnt_t n, msg_t msg) { chSysLock(); chSemResetWithMessageI(sp, n, msg); 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. * @param[in] msg message to be sent * * @iclass */ void chSemResetWithMessageI(semaphore_t *sp, cnt_t n, msg_t msg) { chDbgCheckClassI(); chDbgCheck((sp != NULL) && (n >= (cnt_t)0)); chDbgAssert(((sp->cnt >= (cnt_t)0) && queue_isempty(&sp->queue)) || ((sp->cnt < (cnt_t)0) && queue_notempty(&sp->queue)), "inconsistent semaphore"); sp->cnt = n; while (queue_notempty(&sp->queue)) { chSchReadyI(queue_lifo_remove(&sp->queue))->u.rdymsg = msg; } } /** * @brief Performs a wait operation on a semaphore. * * @param[in] sp pointer to a @p semaphore_t structure * @return A message specifying how the invoking thread has been * released from the semaphore. * @retval MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval MSG_RESET if the semaphore has been reset using @p chSemReset(). * * @api */ msg_t chSemWait(semaphore_t *sp) { msg_t msg; chSysLock(); msg = chSemWaitS(sp); chSysUnlock(); return msg; } /** * @brief Performs a wait operation on a semaphore. * * @param[in] sp pointer to a @p semaphore_t structure * @return A message specifying how the invoking thread has been * released from the semaphore. * @retval MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval MSG_RESET if the semaphore has been reset using @p chSemReset(). * * @sclass */ msg_t chSemWaitS(semaphore_t *sp) { chDbgCheckClassS(); chDbgCheck(sp != NULL); chDbgAssert(((sp->cnt >= (cnt_t)0) && queue_isempty(&sp->queue)) || ((sp->cnt < (cnt_t)0) && queue_notempty(&sp->queue)), "inconsistent semaphore"); if (--sp->cnt < (cnt_t)0) { currp->u.wtsemp = sp; sem_insert(currp, &sp->queue); chSchGoSleepS(CH_STATE_WTSEM); return currp->u.rdymsg; } return MSG_OK; } /** * @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 MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval MSG_RESET if the semaphore has been reset using @p chSemReset(). * @retval MSG_TIMEOUT if the semaphore has not been signaled or reset within * the specified timeout. * * @api */ msg_t chSemWaitTimeout(semaphore_t *sp, sysinterval_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 MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval MSG_RESET if the semaphore has been reset using @p chSemReset(). * @retval MSG_TIMEOUT if the semaphore has not been signaled or reset within * the specified timeout. * * @sclass */ msg_t chSemWaitTimeoutS(semaphore_t *sp, sysinterval_t timeout) { chDbgCheckClassS(); chDbgCheck(sp != NULL); chDbgAssert(((sp->cnt >= (cnt_t)0) && queue_isempty(&sp->queue)) || ((sp->cnt < (cnt_t)0) && queue_notempty(&sp->queue)), "inconsistent semaphore"); if (--sp->cnt < (cnt_t)0) { if (TIME_IMMEDIATE == timeout) { sp->cnt++; return MSG_TIMEOUT; } currp->u.wtsemp = sp; sem_insert(currp, &sp->queue); return chSchGoSleepTimeoutS(CH_STATE_WTSEM, timeout); } return MSG_OK; } /** * @brief Performs a signal operation on a semaphore. * * @param[in] sp pointer to a @p semaphore_t structure * * @api */ void chSemSignal(semaphore_t *sp) { chDbgCheck(sp != NULL); chSysLock(); chDbgAssert(((sp->cnt >= (cnt_t)0) && queue_isempty(&sp->queue)) || ((sp->cnt < (cnt_t)0) && queue_notempty(&sp->queue)), "inconsistent semaphore"); if (++sp->cnt <= (cnt_t)0) { chSchWakeupS(queue_fifo_remove(&sp->queue), MSG_OK); } 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); chDbgAssert(((sp->cnt >= (cnt_t)0) && queue_isempty(&sp->queue)) || ((sp->cnt < (cnt_t)0) && queue_notempty(&sp->queue)), "inconsistent semaphore"); if (++sp->cnt <= (cnt_t)0) { /* Note, it is done this way in order to allow a tail call on chSchReadyI().*/ thread_t *tp = queue_fifo_remove(&sp->queue); tp->u.rdymsg = MSG_OK; (void) chSchReadyI(tp); } } /** * @brief Adds the specified value to the semaphore counter. * @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 value to be added to the semaphore counter. The value * must be positive. * * @iclass */ void chSemAddCounterI(semaphore_t *sp, cnt_t n) { chDbgCheckClassI(); chDbgCheck((sp != NULL) && (n > (cnt_t)0)); chDbgAssert(((sp->cnt >= (cnt_t)0) && queue_isempty(&sp->queue)) || ((sp->cnt < (cnt_t)0) && queue_notempty(&sp->queue)), "inconsistent semaphore"); while (n > (cnt_t)0) { if (++sp->cnt <= (cnt_t)0) { chSchReadyI(queue_fifo_remove(&sp->queue))->u.rdymsg = MSG_OK; } n--; } } /** * @brief Performs atomic signal and wait operations on two semaphores. * * @param[in] sps pointer to a @p semaphore_t structure to be signaled * @param[in] spw pointer to a @p semaphore_t structure to wait on * @return A message specifying how the invoking thread has been * released from the semaphore. * @retval MSG_OK if the thread has not stopped on the semaphore or the * semaphore has been signaled. * @retval MSG_RESET if the semaphore has been reset using @p chSemReset(). * * @api */ msg_t chSemSignalWait(semaphore_t *sps, semaphore_t *spw) { msg_t msg; chDbgCheck((sps != NULL) && (spw != NULL)); chSysLock(); chDbgAssert(((sps->cnt >= (cnt_t)0) && queue_isempty(&sps->queue)) || ((sps->cnt < (cnt_t)0) && queue_notempty(&sps->queue)), "inconsistent semaphore"); chDbgAssert(((spw->cnt >= (cnt_t)0) && queue_isempty(&spw->queue)) || ((spw->cnt < (cnt_t)0) && queue_notempty(&spw->queue)), "inconsistent semaphore"); if (++sps->cnt <= (cnt_t)0) { chSchReadyI(queue_fifo_remove(&sps->queue))->u.rdymsg = MSG_OK; } if (--spw->cnt < (cnt_t)0) { thread_t *ctp = currp; sem_insert(ctp, &spw->queue); ctp->u.wtsemp = spw; chSchGoSleepS(CH_STATE_WTSEM); msg = ctp->u.rdymsg; } else { chSchRescheduleS(); msg = MSG_OK; } chSysUnlock(); return msg; } #endif /* CH_CFG_USE_SEMAPHORES == TRUE */ /** @} */