/*
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 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 must always be performed
* in lock-reverse order. This restriction both improves the
* performance and is required for an efficient implementation
* of the priority inheritance mechanism.
* Operating under this restriction also ensures that deadlocks
* are no possible.
*
* Recursive mode
* By default mutexes are not recursive, this mean that it is not
* possible to take a mutex already owned by the same thread.
* It is possible to enable the recursive behavior by enabling the
* option @p CH_CFG_USE_MUTEXES_RECURSIVE.
*
* 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_CFG_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_t structure.
* @{
*/
#include "ch.h"
#if (CH_CFG_USE_MUTEXES == TRUE) || defined(__DOXYGEN__)
/*===========================================================================*/
/* Module exported variables. */
/*===========================================================================*/
/*===========================================================================*/
/* Module local types. */
/*===========================================================================*/
/*===========================================================================*/
/* Module local variables. */
/*===========================================================================*/
/*===========================================================================*/
/* Module local functions. */
/*===========================================================================*/
/*===========================================================================*/
/* Module exported functions. */
/*===========================================================================*/
/**
* @brief Initializes s @p mutex_t structure.
*
* @param[out] mp pointer to a @p mutex_t structure
*
* @init
*/
void chMtxObjectInit(mutex_t *mp) {
chDbgCheck(mp != NULL);
queue_init(&mp->queue);
mp->owner = NULL;
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)0;
#endif
}
/**
* @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_t structure
*
* @api
*/
void chMtxLock(mutex_t *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_t structure
*
* @sclass
*/
void chMtxLockS(mutex_t *mp) {
thread_t *ctp = currp;
chDbgCheckClassS();
chDbgCheck(mp != NULL);
/* Is the mutex already locked? */
if (mp->owner != NULL) {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt >= (cnt_t)1, "counter is not positive");
/* If the mutex is already owned by this thread, the counter is increased
and there is no need of more actions.*/
if (mp->owner == ctp) {
mp->cnt++;
}
else {
#endif
/* 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_t *tp = mp->owner;
/* Does the running thread have higher priority than the mutex
owning thread? */
while (tp->prio < ctp->prio) {
/* Make priority of thread tp match the running thread's priority.*/
tp->prio = ctp->prio;
/* The following states need priority queues reordering.*/
switch (tp->state) {
case CH_STATE_WTMTX:
/* Re-enqueues the mutex owner with its new priority.*/
queue_prio_insert(queue_dequeue(tp), &tp->u.wtmtxp->queue);
tp = tp->u.wtmtxp->owner;
/*lint -e{9042} [16.1] Continues the while.*/
continue;
#if (CH_CFG_USE_CONDVARS == TRUE) || \
((CH_CFG_USE_SEMAPHORES == TRUE) && \
(CH_CFG_USE_SEMAPHORES_PRIORITY == TRUE)) || \
((CH_CFG_USE_MESSAGES == TRUE) && \
(CH_CFG_USE_MESSAGES_PRIORITY == TRUE))
#if CH_CFG_USE_CONDVARS == TRUE
case CH_STATE_WTCOND:
#endif
#if (CH_CFG_USE_SEMAPHORES == TRUE) && \
(CH_CFG_USE_SEMAPHORES_PRIORITY == TRUE)
case CH_STATE_WTSEM:
#endif
#if (CH_CFG_USE_MESSAGES == TRUE) && (CH_CFG_USE_MESSAGES_PRIORITY == TRUE)
case CH_STATE_SNDMSGQ:
#endif
/* Re-enqueues tp with its new priority on the queue.*/
queue_prio_insert(queue_dequeue(tp), &tp->u.wtmtxp->queue);
break;
#endif
case CH_STATE_READY:
#if CH_DBG_ENABLE_ASSERTS == TRUE
/* Prevents an assertion in chSchReadyI().*/
tp->state = CH_STATE_CURRENT;
#endif
/* Re-enqueues tp with its new priority on the ready list.*/
(void) chSchReadyI(queue_dequeue(tp));
break;
default:
/* Nothing to do for other states.*/
break;
}
break;
}
/* Sleep on the mutex.*/
queue_prio_insert(ctp, &mp->queue);
ctp->u.wtmtxp = mp;
chSchGoSleepS(CH_STATE_WTMTX);
/* It is assumed that the thread performing the unlock operation assigns
the mutex to this thread.*/
chDbgAssert(mp->owner == ctp, "not owner");
chDbgAssert(ctp->mtxlist == mp, "not owned");
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt == (cnt_t)1, "counter is not one");
}
#endif
}
else {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt == (cnt_t)0, "counter is not zero");
mp->cnt++;
#endif
/* It was not owned, inserted in the owned mutexes list.*/
mp->owner = ctp;
mp->next = ctp->mtxlist;
ctp->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_t structure
* @return The operation status.
* @retval true if the mutex has been successfully acquired
* @retval false if the lock attempt failed.
*
* @api
*/
bool chMtxTryLock(mutex_t *mp) {
bool 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_t structure
* @return The operation status.
* @retval true if the mutex has been successfully acquired
* @retval false if the lock attempt failed.
*
* @sclass
*/
bool chMtxTryLockS(mutex_t *mp) {
chDbgCheckClassS();
chDbgCheck(mp != NULL);
if (mp->owner != NULL) {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt >= (cnt_t)1, "counter is not positive");
if (mp->owner == currp) {
mp->cnt++;
return true;
}
#endif
return false;
}
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt == (cnt_t)0, "counter is not zero");
mp->cnt++;
#endif
mp->owner = currp;
mp->next = currp->mtxlist;
currp->mtxlist = mp;
return true;
}
/**
* @brief Unlocks the specified mutex.
* @note Mutexes must be unlocked in reverse lock order. Violating this
* rules will result in a panic if assertions are enabled.
* @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.
*
* @param[in] mp pointer to the @p mutex_t structure
*
* @api
*/
void chMtxUnlock(mutex_t *mp) {
thread_t *ctp = currp;
mutex_t *lmp;
chDbgCheck(mp != NULL);
chSysLock();
chDbgAssert(ctp->mtxlist != NULL, "owned mutexes list empty");
chDbgAssert(ctp->mtxlist->owner == ctp, "ownership failure");
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt >= (cnt_t)1, "counter is not positive");
if (--mp->cnt == (cnt_t)0) {
#endif
chDbgAssert(ctp->mtxlist == mp, "not next in list");
/* Removes the top mutex from the thread's owned mutexes list and marks
it as not owned. Note, it is assumed to be the same mutex passed as
parameter of this function.*/
ctp->mtxlist = mp->next;
/* If a thread is waiting on the mutex then the fun part begins.*/
if (chMtxQueueNotEmptyS(mp)) {
thread_t *tp;
/* Recalculates the optimal thread priority by scanning the owned
mutexes list.*/
tprio_t newprio = ctp->realprio;
lmp = ctp->mtxlist;
while (lmp != 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(lmp) &&
(lmp->queue.next->prio > newprio)) {
newprio = lmp->queue.next->prio;
}
lmp = lmp->next;
}
/* Assigns to the current thread the highest priority among all the
waiting threads.*/
ctp->prio = newprio;
/* Awakens the highest priority thread waiting for the unlocked mutex and
assigns the mutex to it.*/
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)1;
#endif
tp = queue_fifo_remove(&mp->queue);
mp->owner = tp;
mp->next = tp->mtxlist;
tp->mtxlist = mp;
/* Note, not using chSchWakeupS() becuase that function expects the
current thread to have the higher or equal priority than the ones
in the ready list. This is not necessarily true here because we
just changed priority.*/
(void) chSchReadyI(tp);
chSchRescheduleS();
}
else {
mp->owner = NULL;
}
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
}
#endif
chSysUnlock();
}
/**
* @brief Unlocks the specified mutex.
* @note Mutexes must be unlocked in reverse lock order. Violating this
* rules will result in a panic if assertions are enabled.
* @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.
*
* @param[in] mp pointer to the @p mutex_t structure
*
* @sclass
*/
void chMtxUnlockS(mutex_t *mp) {
thread_t *ctp = currp;
mutex_t *lmp;
chDbgCheckClassS();
chDbgCheck(mp != NULL);
chDbgAssert(ctp->mtxlist != NULL, "owned mutexes list empty");
chDbgAssert(ctp->mtxlist->owner == ctp, "ownership failure");
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
chDbgAssert(mp->cnt >= (cnt_t)1, "counter is not positive");
if (--mp->cnt == (cnt_t)0) {
#endif
chDbgAssert(ctp->mtxlist == mp, "not next in list");
/* Removes the top mutex from the thread's owned mutexes list and marks
it as not owned. Note, it is assumed to be the same mutex passed as
parameter of this function.*/
ctp->mtxlist = mp->next;
/* If a thread is waiting on the mutex then the fun part begins.*/
if (chMtxQueueNotEmptyS(mp)) {
thread_t *tp;
/* Recalculates the optimal thread priority by scanning the owned
mutexes list.*/
tprio_t newprio = ctp->realprio;
lmp = ctp->mtxlist;
while (lmp != 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(lmp) &&
(lmp->queue.next->prio > newprio)) {
newprio = lmp->queue.next->prio;
}
lmp = lmp->next;
}
/* Assigns to the current thread the highest priority among all the
waiting threads.*/
ctp->prio = newprio;
/* Awakens the highest priority thread waiting for the unlocked mutex and
assigns the mutex to it.*/
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)1;
#endif
tp = queue_fifo_remove(&mp->queue);
mp->owner = tp;
mp->next = tp->mtxlist;
tp->mtxlist = mp;
(void) chSchReadyI(tp);
}
else {
mp->owner = NULL;
}
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
}
#endif
}
/**
* @brief Unlocks all mutexes owned by the invoking thread.
* @post The stack of owned mutexes is emptied and all the found
* mutexes are unlocked.
* @post This function does not reschedule so a call to a rescheduling
* function must be performed before unlocking the kernel.
* @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.
*
* @sclass
*/
void chMtxUnlockAllS(void) {
thread_t *ctp = currp;
while (ctp->mtxlist != NULL) {
mutex_t *mp = ctp->mtxlist;
ctp->mtxlist = mp->next;
if (chMtxQueueNotEmptyS(mp)) {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)1;
#endif
thread_t *tp = queue_fifo_remove(&mp->queue);
mp->owner = tp;
mp->next = tp->mtxlist;
tp->mtxlist = mp;
(void) chSchReadyI(tp);
}
else {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)0;
#endif
mp->owner = NULL;
}
}
ctp->prio = ctp->realprio;
}
/**
* @brief Unlocks all 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_t *ctp = currp;
chSysLock();
if (ctp->mtxlist != NULL) {
do {
mutex_t *mp = ctp->mtxlist;
ctp->mtxlist = mp->next;
if (chMtxQueueNotEmptyS(mp)) {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)1;
#endif
thread_t *tp = queue_fifo_remove(&mp->queue);
mp->owner = tp;
mp->next = tp->mtxlist;
tp->mtxlist = mp;
(void) chSchReadyI(tp);
}
else {
#if CH_CFG_USE_MUTEXES_RECURSIVE == TRUE
mp->cnt = (cnt_t)0;
#endif
mp->owner = NULL;
}
} while (ctp->mtxlist != NULL);
ctp->prio = ctp->realprio;
chSchRescheduleS();
}
chSysUnlock();
}
#endif /* CH_CFG_USE_MUTEXES == TRUE */
/** @} */