src/third_party/musl/src/thread/pthread_cond_timedwait.c - cobalt - Git at Google

 #include "pthread_impl.h"

 void __pthread_testcancel(void);
 int __pthread_mutex_lock(pthread_mutex_t *);
 int __pthread_mutex_unlock(pthread_mutex_t *);
 int __pthread_setcancelstate(int, int *);

 /*
  * struct waiter
  *
  * Waiter objects have automatic storage on the waiting thread, and
  * are used in building a linked list representing waiters currently
  * waiting on the condition variable or a group of waiters woken
  * together by a broadcast or signal; in the case of signal, this is a
  * degenerate list of one member.
  *
  * Waiter lists attached to the condition variable itself are
  * protected by the lock on the cv. Detached waiter lists are never
  * modified again, but can only be traversed in reverse order, and are
  * protected by the "barrier" locks in each node, which are unlocked
  * in turn to control wake order.
  *
  * Since process-shared cond var semantics do not necessarily allow
  * one thread to see another's automatic storage (they may be in
  * different processes), the waiter list is not used for the
  * process-shared case, but the structure is still used to store data
  * needed by the cancellation cleanup handler.
  */

 struct waiter {
 	struct waiter *prev, *next;
 	volatile int state, barrier;
 	volatile int *notify;
 };

 /* Self-synchronized-destruction-safe lock functions */

 static inline void lock(volatile int *l)
 {
 	if (a_cas(l, 0, 1)) {
 		a_cas(l, 1, 2);
 		do __wait(l, 0, 2, 1);
 		while (a_cas(l, 0, 2));
 	}
 }

 static inline void unlock(volatile int *l)
 {
 	if (a_swap(l, 0)==2)
 		__wake(l, 1, 1);
 }

 static inline void unlock_requeue(volatile int *l, volatile int *r, int w)
 {
 	a_store(l, 0);
 	if (w) __wake(l, 1, 1);
 	else __syscall(SYS_futex, l, FUTEX_REQUEUE|FUTEX_PRIVATE, 0, 1, r) != -ENOSYS
 		|| __syscall(SYS_futex, l, FUTEX_REQUEUE, 0, 1, r);
 }

 enum {
 	WAITING,
 	SIGNALED,
 	LEAVING,
 };

 int __pthread_cond_timedwait(pthread_cond_t *restrict c, pthread_mutex_t *restrict m, const struct timespec *restrict ts)
 {
 	struct waiter node = { 0 };
 	int e, seq, clock = c->_c_clock, cs, shared=0, oldstate, tmp;
 	volatile int *fut;

 	if ((m->_m_type&15) && (m->_m_lock&INT_MAX) != __pthread_self()->tid)
 		return EPERM;

 	if (ts && ts->tv_nsec >= 1000000000UL)
 		return EINVAL;

 	__pthread_testcancel();

 	if (c->_c_shared) {
 		shared = 1;
 		fut = &c->_c_seq;
 		seq = c->_c_seq;
 		a_inc(&c->_c_waiters);
 	} else {
 		lock(&c->_c_lock);

 		seq = node.barrier = 2;
 		fut = &node.barrier;
 		node.state = WAITING;
 		node.next = c->_c_head;
 		c->_c_head = &node;
 		if (!c->_c_tail) c->_c_tail = &node;
 		else node.next->prev = &node;

 		unlock(&c->_c_lock);
 	}

 	__pthread_mutex_unlock(m);

 	__pthread_setcancelstate(PTHREAD_CANCEL_MASKED, &cs);
 	if (cs == PTHREAD_CANCEL_DISABLE) __pthread_setcancelstate(cs, 0);

 	do e = __timedwait_cp(fut, seq, clock, ts, !shared);
 	while (*fut==seq && (!e || e==EINTR));
 	if (e == EINTR) e = 0;

 	if (shared) {
 		/* Suppress cancellation if a signal was potentially
 		 * consumed; this is a legitimate form of spurious
 		 * wake even if not. */
 		if (e == ECANCELED && c->_c_seq != seq) e = 0;
 		if (a_fetch_add(&c->_c_waiters, -1) == -0x7fffffff)
 			__wake(&c->_c_waiters, 1, 0);
 		oldstate = WAITING;
 		goto relock;
 	}

 	oldstate = a_cas(&node.state, WAITING, LEAVING);

 	if (oldstate == WAITING) {
 		/* Access to cv object is valid because this waiter was not
 		 * yet signaled and a new signal/broadcast cannot return
 		 * after seeing a LEAVING waiter without getting notified
 		 * via the futex notify below. */

 		lock(&c->_c_lock);

 		if (c->_c_head == &node) c->_c_head = node.next;
 		else if (node.prev) node.prev->next = node.next;
 		if (c->_c_tail == &node) c->_c_tail = node.prev;
 		else if (node.next) node.next->prev = node.prev;

 		unlock(&c->_c_lock);

 		if (node.notify) {
 			if (a_fetch_add(node.notify, -1)==1)
 				__wake(node.notify, 1, 1);
 		}
 	} else {
 		/* Lock barrier first to control wake order. */
 		lock(&node.barrier);
 	}

 relock:
 	/* Errors locking the mutex override any existing error or
 	 * cancellation, since the caller must see them to know the
 	 * state of the mutex. */
 	if ((tmp = pthread_mutex_lock(m))) e = tmp;

 	if (oldstate == WAITING) goto done;

 	if (!node.next) a_inc(&m->_m_waiters);

 	/* Unlock the barrier that's holding back the next waiter, and
 	 * either wake it or requeue it to the mutex. */
 	if (node.prev)
 		unlock_requeue(&node.prev->barrier, &m->_m_lock, m->_m_type & 128);
 	else
 		a_dec(&m->_m_waiters);

 	/* Since a signal was consumed, cancellation is not permitted. */
 	if (e == ECANCELED) e = 0;

 done:
 	__pthread_setcancelstate(cs, 0);

 	if (e == ECANCELED) {
 		__pthread_testcancel();
 		__pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, 0);
 	}

 	return e;
 }

 int __private_cond_signal(pthread_cond_t *c, int n)
 {
 	struct waiter *p, *first=0;
 	volatile int ref = 0;
 	int cur;

 	lock(&c->_c_lock);
 	for (p=c->_c_tail; n && p; p=p->prev) {
 		if (a_cas(&p->state, WAITING, SIGNALED) != WAITING) {
 			ref++;
 			p->notify = &ref;
 		} else {
 			n--;
 			if (!first) first=p;
 		}
 	}
 	/* Split the list, leaving any remainder on the cv. */
 	if (p) {
 		if (p->next) p->next->prev = 0;
 		p->next = 0;
 	} else {
 		c->_c_head = 0;
 	}
 	c->_c_tail = p;
 	unlock(&c->_c_lock);

 	/* Wait for any waiters in the LEAVING state to remove
 	 * themselves from the list before returning or allowing
 	 * signaled threads to proceed. */
 	while ((cur = ref)) __wait(&ref, 0, cur, 1);

 	/* Allow first signaled waiter, if any, to proceed. */
 	if (first) unlock(&first->barrier);

 	return 0;
 }

 weak_alias(__pthread_cond_timedwait, pthread_cond_timedwait);
	#include "pthread_impl.h"

	void __pthread_testcancel(void);
	int __pthread_mutex_lock(pthread_mutex_t *);
	int __pthread_mutex_unlock(pthread_mutex_t *);
	int __pthread_setcancelstate(int, int *);

	/*
	* struct waiter
	*
	* Waiter objects have automatic storage on the waiting thread, and
	* are used in building a linked list representing waiters currently
	* waiting on the condition variable or a group of waiters woken
	* together by a broadcast or signal; in the case of signal, this is a
	* degenerate list of one member.
	*
	* Waiter lists attached to the condition variable itself are
	* protected by the lock on the cv. Detached waiter lists are never
	* modified again, but can only be traversed in reverse order, and are
	* protected by the "barrier" locks in each node, which are unlocked
	* in turn to control wake order.
	*
	* Since process-shared cond var semantics do not necessarily allow
	* one thread to see another's automatic storage (they may be in
	* different processes), the waiter list is not used for the
	* process-shared case, but the structure is still used to store data
	* needed by the cancellation cleanup handler.
	*/

	struct waiter {
	struct waiter prev, next;
	volatile int state, barrier;
	volatile int *notify;
	};

	/* Self-synchronized-destruction-safe lock functions */

	static inline void lock(volatile int *l)
	{
	if (a_cas(l, 0, 1)) {
	a_cas(l, 1, 2);
	do __wait(l, 0, 2, 1);
	while (a_cas(l, 0, 2));
	}
	}

	static inline void unlock(volatile int *l)
	{
	if (a_swap(l, 0)==2)
	__wake(l, 1, 1);
	}

	static inline void unlock_requeue(volatile int l, volatile int r, int w)
	{
	a_store(l, 0);
	if (w) __wake(l, 1, 1);
	else __syscall(SYS_futex, l, FUTEX_REQUEUE\|FUTEX_PRIVATE, 0, 1, r) != -ENOSYS
	\|\| __syscall(SYS_futex, l, FUTEX_REQUEUE, 0, 1, r);
	}

	enum {
	WAITING,
	SIGNALED,
	LEAVING,
	};

	int __pthread_cond_timedwait(pthread_cond_t restrict c, pthread_mutex_t restrict m, const struct timespec *restrict ts)
	{
	struct waiter node = { 0 };
	int e, seq, clock = c->_c_clock, cs, shared=0, oldstate, tmp;
	volatile int *fut;

	if ((m->_m_type&15) && (m->_m_lock&INT_MAX) != __pthread_self()->tid)
	return EPERM;

	if (ts && ts->tv_nsec >= 1000000000UL)
	return EINVAL;

	__pthread_testcancel();

	if (c->_c_shared) {
	shared = 1;
	fut = &c->_c_seq;
	seq = c->_c_seq;
	a_inc(&c->_c_waiters);
	} else {
	lock(&c->_c_lock);

	seq = node.barrier = 2;
	fut = &node.barrier;
	node.state = WAITING;
	node.next = c->_c_head;
	c->_c_head = &node;
	if (!c->_c_tail) c->_c_tail = &node;
	else node.next->prev = &node;

	unlock(&c->_c_lock);
	}

	__pthread_mutex_unlock(m);

	__pthread_setcancelstate(PTHREAD_CANCEL_MASKED, &cs);
	if (cs == PTHREAD_CANCEL_DISABLE) __pthread_setcancelstate(cs, 0);

	do e = __timedwait_cp(fut, seq, clock, ts, !shared);
	while (*fut==seq && (!e \|\| e==EINTR));
	if (e == EINTR) e = 0;

	if (shared) {
	/* Suppress cancellation if a signal was potentially
	* consumed; this is a legitimate form of spurious
	* wake even if not. */
	if (e == ECANCELED && c->_c_seq != seq) e = 0;
	if (a_fetch_add(&c->_c_waiters, -1) == -0x7fffffff)
	__wake(&c->_c_waiters, 1, 0);
	oldstate = WAITING;
	goto relock;
	}

	oldstate = a_cas(&node.state, WAITING, LEAVING);

	if (oldstate == WAITING) {
	/* Access to cv object is valid because this waiter was not
	* yet signaled and a new signal/broadcast cannot return
	* after seeing a LEAVING waiter without getting notified
	* via the futex notify below. */

	lock(&c->_c_lock);

	if (c->_c_head == &node) c->_c_head = node.next;
	else if (node.prev) node.prev->next = node.next;
	if (c->_c_tail == &node) c->_c_tail = node.prev;
	else if (node.next) node.next->prev = node.prev;

	unlock(&c->_c_lock);

	if (node.notify) {
	if (a_fetch_add(node.notify, -1)==1)
	__wake(node.notify, 1, 1);
	}
	} else {
	/* Lock barrier first to control wake order. */
	lock(&node.barrier);
	}

	relock:
	/* Errors locking the mutex override any existing error or
	* cancellation, since the caller must see them to know the
	* state of the mutex. */
	if ((tmp = pthread_mutex_lock(m))) e = tmp;

	if (oldstate == WAITING) goto done;

	if (!node.next) a_inc(&m->_m_waiters);

	/* Unlock the barrier that's holding back the next waiter, and
	* either wake it or requeue it to the mutex. */
	if (node.prev)
	unlock_requeue(&node.prev->barrier, &m->_m_lock, m->_m_type & 128);
	else
	a_dec(&m->_m_waiters);

	/* Since a signal was consumed, cancellation is not permitted. */
	if (e == ECANCELED) e = 0;

	done:
	__pthread_setcancelstate(cs, 0);

	if (e == ECANCELED) {
	__pthread_testcancel();
	__pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, 0);
	}

	return e;
	}

	int __private_cond_signal(pthread_cond_t *c, int n)
	{
	struct waiter p, first=0;
	volatile int ref = 0;
	int cur;

	lock(&c->_c_lock);
	for (p=c->_c_tail; n && p; p=p->prev) {
	if (a_cas(&p->state, WAITING, SIGNALED) != WAITING) {
	ref++;
	p->notify = &ref;
	} else {
	n--;
	if (!first) first=p;
	}
	}
	/* Split the list, leaving any remainder on the cv. */
	if (p) {
	if (p->next) p->next->prev = 0;
	p->next = 0;
	} else {
	c->_c_head = 0;
	}
	c->_c_tail = p;
	unlock(&c->_c_lock);

	/* Wait for any waiters in the LEAVING state to remove
	* themselves from the list before returning or allowing
	* signaled threads to proceed. */
	while ((cur = ref)) __wait(&ref, 0, cur, 1);

	/* Allow first signaled waiter, if any, to proceed. */
	if (first) unlock(&first->barrier);

	return 0;
	}

	weak_alias(__pthread_cond_timedwait, pthread_cond_timedwait);