/*
ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010,
2011 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 .
*/
/**
* @file chmtx.c
* @brief Mutexes code.
*
* @addtogroup mutexes
* @details Mutexes related APIs and services.
*
* Operation mode
* A mutex is a threads synchronization object that can be in two
* distinct states:
* - Not owned (unlocked).
* - Owned by a thread (locked).
* .
* Operations defined for mutexes:
* - Lock: The mutex is checked, if the mutex is not owned by
* some other thread then it is associated to the locking thread
* else the thread is queued on the mutex in a list ordered by
* priority.
* - Unlock: The mutex is released by the owner and the highest
* priority thread waiting in the queue, if any, is resumed and made
* owner of the mutex.
* .
* Constraints
* In ChibiOS/RT the Unlock operations are always performed in
* lock-reverse order. The unlock API does not even have a parameter,
* the mutex to unlock is selected from an internal, per-thread, stack
* of owned mutexes. This both improves the performance and is
* required for an efficient implementation of the priority
* inheritance mechanism.
*
* The priority inversion problem
* The mutexes in ChibiOS/RT implements the full priority
* inheritance mechanism in order handle the priority inversion
* problem.
* When a thread is queued on a mutex, any thread, directly or
* indirectly, holding the mutex gains the same priority of the
* waiting thread (if their priority was not already equal or higher).
* The mechanism works with any number of nested mutexes and any
* number of involved threads. The algorithm complexity (worst case)
* is N with N equal to the number of nested mutexes.
* @pre In order to use the mutex APIs the @p CH_USE_MUTEXES option
* must be enabled in @p chconf.h.
* @post Enabling mutexes requires 5-12 (depending on the architecture)
* extra bytes in the @p Thread structure.
* @{
*/
#include "ch.h"
#if CH_USE_MUTEXES || defined(__DOXYGEN__)
/**
* @brief Initializes s @p Mutex structure.
*
* @param[out] mp pointer to a @p Mutex structure
*
* @init
*/
void chMtxInit(Mutex *mp) {
chDbgCheck(mp != NULL, "chMtxInit");
queue_init(&mp->m_queue);
mp->m_owner = NULL;
}
/**
* @brief Locks the specified mutex.
* @post The mutex is locked and inserted in the per-thread stack of owned
* mutexes.
*
* @param[in] mp pointer to the @p Mutex structure
*
* @api
*/
void chMtxLock(Mutex *mp) {
chSysLock();
chMtxLockS(mp);
chSysUnlock();
}
/**
* @brief Locks the specified mutex.
* @post The mutex is locked and inserted in the per-thread stack of owned
* mutexes.
*
* @param[in] mp pointer to the @p Mutex structure
*
* @sclass
*/
void chMtxLockS(Mutex *mp) {
Thread *ctp = currp;
chDbgCheckClassS();
chDbgCheck(mp != NULL, "chMtxLockS");
/* Ia the mutex already locked? */
if (mp->m_owner != NULL) {
/* Priority inheritance protocol; explores the thread-mutex dependencies
boosting the priority of all the affected threads to equal the priority
of the running thread requesting the mutex.*/
Thread *tp = mp->m_owner;
/* Does the running thread have higher priority than the mutex
ownning thread? */
while (tp->p_prio < ctp->p_prio) {
/* Make priority of thread tp match the running thread's priority.*/
tp->p_prio = ctp->p_prio;
/* The following states need priority queues reordering.*/
switch (tp->p_state) {
case THD_STATE_WTMTX:
/* Re-enqueues the mutex owner with its new priority.*/
prio_insert(dequeue(tp), (ThreadsQueue *)tp->p_u.wtobjp);
tp = ((Mutex *)tp->p_u.wtobjp)->m_owner;
continue;
#if CH_USE_CONDVARS | \
(CH_USE_SEMAPHORES && CH_USE_SEMAPHORES_PRIORITY) | \
(CH_USE_MESSAGES && CH_USE_MESSAGES_PRIORITY)
#if CH_USE_CONDVARS
case THD_STATE_WTCOND:
#endif
#if CH_USE_SEMAPHORES && CH_USE_SEMAPHORES_PRIORITY
case THD_STATE_WTSEM:
#endif
#if CH_USE_MESSAGES && CH_USE_MESSAGES_PRIORITY
case THD_STATE_SNDMSGQ:
#endif
/* Re-enqueues tp with its new priority on the queue.*/
prio_insert(dequeue(tp), (ThreadsQueue *)tp->p_u.wtobjp);
break;
#endif
case THD_STATE_READY:
#if CH_DBG_ENABLE_ASSERTS
/* Prevents an assertion in chSchReadyI().*/
tp->p_state = THD_STATE_CURRENT;
#endif
/* Re-enqueues tp with its new priority on the ready list.*/
chSchReadyI(dequeue(tp));
break;
}
break;
}
/* Sleep on the mutex.*/
prio_insert(ctp, &mp->m_queue);
ctp->p_u.wtobjp = mp;
chSchGoSleepS(THD_STATE_WTMTX);
/* It is assumed that the thread performing the unlock operation assigns
the mutex to this thread.*/
chDbgAssert(mp->m_owner == ctp, "chMtxLockS(), #1", "not owner");
chDbgAssert(ctp->p_mtxlist == mp, "chMtxLockS(), #2", "not owned");
}
else {
/* It was not owned, inserted in the owned mutexes list.*/
mp->m_owner = ctp;
mp->m_next = ctp->p_mtxlist;
ctp->p_mtxlist = mp;
}
}
/**
* @brief Tries to lock a mutex.
* @details This function attempts to lock a mutex, if the mutex is already
* locked by another thread then the function exits without waiting.
* @post The mutex is locked and inserted in the per-thread stack of owned
* mutexes.
* @note This function does not have any overhead related to the
* priority inheritance mechanism because it does not try to
* enter a sleep state.
*
* @param[in] mp pointer to the @p Mutex structure
* @return The operation status.
* @retval TRUE if the mutex has been successfully acquired
* @retval FALSE if the lock attempt failed.
*
* @api
*/
bool_t chMtxTryLock(Mutex *mp) {
bool_t b;
chSysLock();
b = chMtxTryLockS(mp);
chSysUnlock();
return b;
}
/**
* @brief Tries to lock a mutex.
* @details This function attempts to lock a mutex, if the mutex is already
* taken by another thread then the function exits without waiting.
* @post The mutex is locked and inserted in the per-thread stack of owned
* mutexes.
* @note This function does not have any overhead related to the
* priority inheritance mechanism because it does not try to
* enter a sleep state.
*
* @param[in] mp pointer to the @p Mutex structure
* @return The operation status.
* @retval TRUE if the mutex has been successfully acquired
* @retval FALSE if the lock attempt failed.
*
* @sclass
*/
bool_t chMtxTryLockS(Mutex *mp) {
chDbgCheckClassS();
chDbgCheck(mp != NULL, "chMtxTryLockS");
if (mp->m_owner != NULL)
return FALSE;
mp->m_owner = currp;
mp->m_next = currp->p_mtxlist;
currp->p_mtxlist = mp;
return TRUE;
}
/**
* @brief Unlocks the next owned mutex in reverse lock order.
* @pre The invoking thread must have at least one owned mutex.
* @post The mutex is unlocked and removed from the per-thread stack of
* owned mutexes.
*
* @return A pointer to the unlocked mutex.
*
* @api
*/
Mutex *chMtxUnlock(void) {
Thread *ctp = currp;
Mutex *ump, *mp;
chSysLock();
chDbgAssert(ctp->p_mtxlist != NULL,
"chMtxUnlock(), #1",
"owned mutexes list empty");
chDbgAssert(ctp->p_mtxlist->m_owner == ctp,
"chMtxUnlock(), #2",
"ownership failure");
/* Removes the top Mutex from the Threads's owned mutexes list and matk it
as not owned.*/
ump = ctp->p_mtxlist;
ctp->p_mtxlist = ump->m_next;
/* If a thread is waiting on the mutex then the fun part begins.*/
if (chMtxQueueNotEmptyS(ump)) {
Thread *tp;
/* Recalculates the optimal thread priority by scanning the owned
mutexes list.*/
tprio_t newprio = ctp->p_realprio;
mp = ctp->p_mtxlist;
while (mp != NULL) {
/* If the highest priority thread waiting in the mutexes list has a
greater priority than the current thread base priority then the final
priority will have at least that priority.*/
if (chMtxQueueNotEmptyS(mp) && (mp->m_queue.p_next->p_prio > newprio))
newprio = mp->m_queue.p_next->p_prio;
mp = mp->m_next;
}
/* Assigns to the current thread the highest priority among all the
waiting threads.*/
ctp->p_prio = newprio;
/* Awakens the highest priority thread waiting for the unlocked mutex and
assigns the mutex to it.*/
tp = fifo_remove(&ump->m_queue);
ump->m_owner = tp;
ump->m_next = tp->p_mtxlist;
tp->p_mtxlist = ump;
chSchWakeupS(tp, RDY_OK);
}
else
ump->m_owner = NULL;
chSysUnlock();
return ump;
}
/**
* @brief Unlocks the next owned mutex in reverse lock order.
* @pre The invoking thread must have at least one owned mutex.
* @post The mutex is unlocked and removed from the per-thread stack of
* owned mutexes.
* @post This function does not reschedule so a call to a rescheduling
* function must be performed before unlocking the kernel.
*
* @return A pointer to the unlocked mutex.
*
* @sclass
*/
Mutex *chMtxUnlockS(void) {
Thread *ctp = currp;
Mutex *ump, *mp;
chDbgCheckClassS();
chDbgAssert(ctp->p_mtxlist != NULL,
"chMtxUnlockS(), #1",
"owned mutexes list empty");
chDbgAssert(ctp->p_mtxlist->m_owner == ctp,
"chMtxUnlockS(), #2",
"ownership failure");
/* Removes the top Mutex from the owned mutexes list and marks it as not
owned.*/
ump = ctp->p_mtxlist;
ctp->p_mtxlist = ump->m_next;
/* If a thread is waiting on the mutex then the fun part begins.*/
if (chMtxQueueNotEmptyS(ump)) {
Thread *tp;
/* Recalculates the optimal thread priority by scanning the owned
mutexes list.*/
tprio_t newprio = ctp->p_realprio;
mp = ctp->p_mtxlist;
while (mp != NULL) {
/* If the highest priority thread waiting in the mutexes list has a
greater priority than the current thread base priority then the final
priority will have at least that priority.*/
if (chMtxQueueNotEmptyS(mp) && (mp->m_queue.p_next->p_prio > newprio))
newprio = mp->m_queue.p_next->p_prio;
mp = mp->m_next;
}
ctp->p_prio = newprio;
/* Awakens the highest priority thread waiting for the unlocked mutex and
assigns the mutex to it.*/
tp = fifo_remove(&ump->m_queue);
ump->m_owner = tp;
ump->m_next = tp->p_mtxlist;
tp->p_mtxlist = ump;
chSchReadyI(tp);
}
else
ump->m_owner = NULL;
return ump;
}
/**
* @brief Unlocks all the mutexes owned by the invoking thread.
* @post The stack of owned mutexes is emptied and all the found
* mutexes are unlocked.
* @note This function is MUCH MORE efficient than releasing the
* mutexes one by one and not just because the call overhead,
* this function does not have any overhead related to the priority
* inheritance mechanism.
*
* @api
*/
void chMtxUnlockAll(void) {
Thread *ctp = currp;
chSysLock();
if (ctp->p_mtxlist != NULL) {
do {
Mutex *ump = ctp->p_mtxlist;
ctp->p_mtxlist = ump->m_next;
if (chMtxQueueNotEmptyS(ump)) {
Thread *tp = fifo_remove(&ump->m_queue);
ump->m_owner = tp;
ump->m_next = tp->p_mtxlist;
tp->p_mtxlist = ump;
chSchReadyI(tp);
}
else
ump->m_owner = NULL;
} while (ctp->p_mtxlist != NULL);
ctp->p_prio = ctp->p_realprio;
chSchRescheduleS();
}
chSysUnlock();
}
#endif /* CH_USE_MUTEXES */
/** @} */