/* ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010, 2011,2012,2013,2014 Giovanni Di Sirio. This file is part of ChibiOS/RT. ChibiOS/RT 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/RT 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 . */ /* Concepts and parts of this file have been contributed by Andre R. */ /** * @file cmsis_os.c * @brief CMSIS RTOS module code. * * @addtogroup CMSIS_OS * @{ */ #include "cmsis_os.h" #include /*===========================================================================*/ /* Module local definitions. */ /*===========================================================================*/ /*===========================================================================*/ /* Module exported variables. */ /*===========================================================================*/ int32_t cmsis_os_started; /*===========================================================================*/ /* Module local types. */ /*===========================================================================*/ /*===========================================================================*/ /* Module local variables. */ /*===========================================================================*/ static memory_pool_t sempool; static semaphore_t semaphores[CMSIS_CFG_NUM_SEMAPHORES]; static memory_pool_t timpool; static struct os_timer_cb timers[CMSIS_CFG_NUM_TIMERS]; /*===========================================================================*/ /* Module local functions. */ /*===========================================================================*/ /** * @brief Virtual timers common callback. */ static void timer_cb(void const *arg) { osTimerId timer_id = (osTimerId)arg; timer_id->ptimer(timer_id->argument); if (timer_id->type == osTimerPeriodic) { chSysLockFromISR(); chVTDoSetI(&timer_id->vt, timer_id->millisec, (vtfunc_t)timer_cb, timer_id); chSysUnlockFromISR(); } } /*===========================================================================*/ /* Module exported functions. */ /*===========================================================================*/ /** * @brief Kernel initialization. */ osStatus osKernelInitialize(void) { cmsis_os_started = 0; chSysInit(); chThdSetPriority(HIGHPRIO); chPoolObjectInit(&sempool, sizeof(semaphore_t), chCoreAlloc); chPoolLoadArray(&sempool, semaphores, CMSIS_CFG_NUM_SEMAPHORES); chPoolObjectInit(&timpool, sizeof(virtual_timer_t), chCoreAlloc); chPoolLoadArray(&timpool, timers, CMSIS_CFG_NUM_TIMERS); return osOK; } /** * @brief Kernel start. */ osStatus osKernelStart(void) { cmsis_os_started = 1; chThdSetPriority(NORMALPRIO); return osOK; } /** * @brief Creates a thread. */ osThreadId osThreadCreate(const osThreadDef_t *thread_def, void *argument) { size_t size; size = thread_def->stacksize == 0 ? CMSIS_CFG_DEFAULT_STACK : thread_def->stacksize; return (osThreadId)chThdCreateFromHeap(0, THD_WORKING_AREA_SIZE(size), NORMALPRIO+thread_def->tpriority, (tfunc_t)thread_def->pthread, argument); } /** * @brief Thread termination. * @note The thread is not really terminated but asked to terminate which * is not compliant. */ osStatus osThreadTerminate(osThreadId thread_id) { if (thread_id == osThreadGetId()) { /* Note, no memory will be recovered unless a cleaner thread is implemented using the registry.*/ chThdExit(0); } chThdTerminate(thread_id); chThdWait((thread_t *)thread_id); return osOK; } /** * @brief Change thread priority. * @note This can interfere with the priority inheritance mechanism. */ osStatus osThreadSetPriority(osThreadId thread_id, osPriority newprio) { osPriority oldprio; thread_t * tp = (thread_t *)thread_id; chSysLock(); /* Changing priority.*/ #if CH_CFG_USE_MUTEXES oldprio = (osPriority)tp->p_realprio; if ((tp->p_prio == tp->p_realprio) || ((tprio_t)newprio > tp->p_prio)) tp->p_prio = (tprio_t)newprio; tp->p_realprio = (tprio_t)newprio; #else oldprio = tp->p_prio; tp->p_prio = (tprio_t)newprio; #endif /* The following states need priority queues reordering.*/ switch (tp->p_state) { #if CH_CFG_USE_MUTEXES | \ CH_CFG_USE_CONDVARS | \ (CH_CFG_USE_SEMAPHORES && CH_CFG_USE_SEMAPHORES_PRIORITY) | \ (CH_CFG_USE_MESSAGES && CH_CFG_USE_MESSAGES_PRIORITY) #if CH_CFG_USE_MUTEXES case CH_STATE_WTMTX: #endif #if CH_CFG_USE_CONDVARS case CH_STATE_WTCOND: #endif #if CH_CFG_USE_SEMAPHORES && CH_CFG_USE_SEMAPHORES_PRIORITY case CH_STATE_WTSEM: #endif #if CH_CFG_USE_MESSAGES && CH_CFG_USE_MESSAGES_PRIORITY case CH_STATE_SNDMSGQ: #endif /* Re-enqueues tp with its new priority on the queue.*/ queue_prio_insert(queue_dequeue(tp), (threads_queue_t *)tp->p_u.wtobjp); break; #endif case CH_STATE_READY: #if CH_DBG_ENABLE_ASSERTS /* Prevents an assertion in chSchReadyI().*/ tp->p_state = CH_STATE_CURRENT; #endif /* Re-enqueues tp with its new priority on the ready list.*/ chSchReadyI(queue_dequeue(tp)); break; } /* Rescheduling.*/ chSchRescheduleS(); chSysUnlock(); return oldprio; } /** * @brief Create a timer. */ osTimerId osTimerCreate(const osTimerDef_t *timer_def, os_timer_type type, void *argument) { osTimerId timer = chPoolAlloc(&timpool); chVTObjectInit(&timer->vt); timer->ptimer = timer_def->ptimer; timer->type = type; timer->argument = argument; return timer; } /** * @brief Start a timer. */ osStatus osTimerStart(osTimerId timer_id, uint32_t millisec) { if (millisec == 0) return osErrorValue; timer_id->millisec = millisec; chVTSet(&timer_id->vt, millisec, (vtfunc_t)timer_cb, timer_id); return osOK; } /** * @brief Stop a timer. */ osStatus osTimerStop(osTimerId timer_id) { chVTReset(&timer_id->vt); return osOK; } /** * @brief Delete a timer. */ osStatus osTimerDelete(osTimerId timer_id) { chVTReset(&timer_id->vt); chPoolFree(&timpool, (void *)timer_id); return osOK; } /** * @brief Send signals. */ int32_t osSignalSet(osThreadId thread_id, int32_t signals) { int32_t oldsignals; syssts_t sts = chSysGetStatusAndLockX(); oldsignals = (int32_t)thread_id->p_epending; chEvtSignalI((thread_t *)thread_id, (eventmask_t)signals); chSysRestoreStatusX(sts); return oldsignals; } /** * @brief Clear signals. */ int32_t osSignalClear(osThreadId thread_id, int32_t signals) { eventmask_t m; chSysLock(); m = thread_id->p_epending & (eventmask_t)signals; thread_id->p_epending &= ~(eventmask_t)signals; chSysUnlock(); return (int32_t)m; } /** * @brief Wait for signals. */ osEvent osSignalWait(int32_t signals, uint32_t millisec) { osEvent event; if (signals == 0) event.value.signals = (uint32_t)chEvtWaitAnyTimeout((eventmask_t)signals, (systime_t)millisec); else event.value.signals = (uint32_t)chEvtWaitAllTimeout((eventmask_t)signals, (systime_t)millisec); /* Type of event.*/ if (event.value.signals == 0) event.status = osEventTimeout; else event.status = osEventSignal; return event; } /** * @brief Create a semaphore. * @note @p semaphore_def is not used. * @note Can involve memory allocation. */ osSemaphoreId osSemaphoreCreate(const osSemaphoreDef_t *semaphore_def, int32_t count) { (void)semaphore_def; semaphore_t *sem = chPoolAlloc(&sempool); chSemObjectInit(sem, (cnt_t)count); return sem; } /** * @brief Wait on a semaphore. */ int32_t osSemaphoreWait(osSemaphoreId semaphore_id, uint32_t millisec) { msg_t msg = chSemWaitTimeout((semaphore_t *)semaphore_id, (systime_t)millisec); switch (msg) { case MSG_OK: return osOK; case MSG_TIMEOUT: return osErrorTimeoutResource; } return osErrorResource; } /** * @brief Release a semaphore. */ osStatus osSemaphoreRelease(osSemaphoreId semaphore_id) { syssts_t sts = chSysGetStatusAndLockX(); chSemSignalI((semaphore_t *)semaphore_id); chSysRestoreStatusX(sts); return osOK; } /** * @brief Deletes a semaphore. * @note After deletion there could be references in the system to a * non-existent semaphore. */ osStatus osSemaphoreDelete(osSemaphoreId semaphore_id) { chSemReset((semaphore_t *)semaphore_id, 0); chPoolFree(&sempool, (void *)semaphore_id); return osOK; } /** * @brief Create a mutex. * @note @p mutex_def is not used. * @note Can involve memory allocation. */ osMutexId osMutexCreate(const osMutexDef_t *mutex_def) { (void)mutex_def; binary_semaphore_t *mtx = chPoolAlloc(&sempool); chBSemObjectInit(mtx, false); return mtx; } /** * @brief Wait on a mutex. */ osStatus osMutexWait(osMutexId mutex_id, uint32_t millisec) { msg_t msg = chBSemWaitTimeout((binary_semaphore_t *)mutex_id, (systime_t)millisec); switch (msg) { case MSG_OK: return osOK; case MSG_TIMEOUT: return osErrorTimeoutResource; } return osErrorResource; } /** * @brief Release a mutex. */ osStatus osMutexRelease(osMutexId mutex_id) { syssts_t sts = chSysGetStatusAndLockX(); chBSemSignalI((binary_semaphore_t *)mutex_id); chSysRestoreStatusX(sts); return osOK; } /** * @brief Deletes a mutex. * @note After deletion there could be references in the system to a * non-existent semaphore. */ osStatus osMutexDelete(osMutexId mutex_id) { chSemReset((semaphore_t *)mutex_id, 0); chPoolFree(&sempool, (void *)mutex_id); return osOK; } /** * @brief Create a memory pool. * @note The pool is not really created because it is allocated statically, * this function just re-initializes it. */ osPoolId osPoolCreate(const osPoolDef_t *pool_def) { chPoolObjectInit(pool_def->pool, (size_t)pool_def->item_sz, NULL); chPoolLoadArray(pool_def->pool, pool_def->items, (size_t)pool_def->pool_sz); return (osPoolId)pool_def->pool; } /** * @brief Allocate an object. */ void *osPoolAlloc(osPoolId pool_id) { void *object; syssts_t sts = chSysGetStatusAndLockX(); object = chPoolAllocI((memory_pool_t *)pool_id); chSysRestoreStatusX(sts); return object; } /** * @brief Allocate an object clearing it. */ void *osPoolCAlloc(osPoolId pool_id) { void *object; object = chPoolAllocI((memory_pool_t *)pool_id); memset(object, 0, pool_id->mp_object_size); return object; } /** * @brief Free an object. */ osStatus osPoolFree(osPoolId pool_id, void *block) { syssts_t sts = chSysGetStatusAndLockX(); chPoolFreeI((memory_pool_t *)pool_id, block); chSysRestoreStatusX(sts); return osOK; } /** * @brief Create a message queue. * @note The queue is not really created because it is allocated statically, * this function just re-initializes it. */ osMessageQId osMessageCreate(const osMessageQDef_t *queue_def, osThreadId thread_id) { /* Ignoring this parameter for now.*/ (void)thread_id; if (queue_def->item_sz > sizeof (msg_t)) return NULL; chMBObjectInit(queue_def->mailbox, queue_def->items, (size_t)queue_def->queue_sz); return osOK; } /** * @brief Put a message in the queue. */ osStatus osMessagePut(osMessageQId queue_id, uint32_t info, uint32_t millisec) { msg_t msg; if (port_is_isr_context()) { /* Waiting makes no sense in ISRs so any value except "immediate" makes no sense.*/ if (millisec != 0) return osErrorValue; chSysLockFromISR(); msg = chMBPostI((mailbox_t *)queue_id, (msg_t)info); chSysUnlockFromISR(); } else msg = chMBPost((mailbox_t *)queue_id, (msg_t)info, (systime_t)millisec); return msg == MSG_OK ? osOK : osEventTimeout; } /** * @brief Get a message from the queue. */ osEvent osMessageGet(osMessageQId queue_id, uint32_t millisec) { msg_t msg; osEvent event; event.def.message_id = queue_id; if (port_is_isr_context()) { /* Waiting makes no sense in ISRs so any value except "immediate" makes no sense.*/ if (millisec != 0) { event.status = osErrorValue; return event; } chSysLockFromISR(); msg = chMBFetchI((mailbox_t *)queue_id, (msg_t*)&event.value.v); chSysUnlockFromISR(); } else { msg = chMBFetch((mailbox_t *)queue_id, (msg_t*)&event.value.v, (systime_t)millisec); } /* Returned event type.*/ event.status = msg == MSG_OK ? osEventMessage : osEventTimeout; return event; } /** @} */