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

 #include "pthread_impl.h"

 static int pshared_barrier_wait(pthread_barrier_t *b)
 {
 	int limit = (b->_b_limit & INT_MAX) + 1;
 	int ret = 0;
 	int v, w;

 	if (limit==1) return PTHREAD_BARRIER_SERIAL_THREAD;

 	while ((v=a_cas(&b->_b_lock, 0, limit)))
 		__wait(&b->_b_lock, &b->_b_waiters, v, 0);

 	/* Wait for <limit> threads to get to the barrier */
 	if (++b->_b_count == limit) {
 		a_store(&b->_b_count, 0);
 		ret = PTHREAD_BARRIER_SERIAL_THREAD;
 		if (b->_b_waiters2) __wake(&b->_b_count, -1, 0);
 	} else {
 		a_store(&b->_b_lock, 0);
 		if (b->_b_waiters) __wake(&b->_b_lock, 1, 0);
 		while ((v=b->_b_count)>0)
 			__wait(&b->_b_count, &b->_b_waiters2, v, 0);
 	}

 	__vm_lock();

 	/* Ensure all threads have a vm lock before proceeding */
 	if (a_fetch_add(&b->_b_count, -1)==1-limit) {
 		a_store(&b->_b_count, 0);
 		if (b->_b_waiters2) __wake(&b->_b_count, -1, 0);
 	} else {
 		while ((v=b->_b_count))
 			__wait(&b->_b_count, &b->_b_waiters2, v, 0);
 	}

 	/* Perform a recursive unlock suitable for self-sync'd destruction */
 	do {
 		v = b->_b_lock;
 		w = b->_b_waiters;
 	} while (a_cas(&b->_b_lock, v, v==INT_MIN+1 ? 0 : v-1) != v);

 	/* Wake a thread waiting to reuse or destroy the barrier */
 	if (v==INT_MIN+1 || (v==1 && w))
 		__wake(&b->_b_lock, 1, 0);

 	__vm_unlock();

 	return ret;
 }

 struct instance
 {
 	volatile int count;
 	volatile int last;
 	volatile int waiters;
 	volatile int finished;
 };

 int pthread_barrier_wait(pthread_barrier_t *b)
 {
 	int limit = b->_b_limit;
 	struct instance *inst;

 	/* Trivial case: count was set at 1 */
 	if (!limit) return PTHREAD_BARRIER_SERIAL_THREAD;

 	/* Process-shared barriers require a separate, inefficient wait */
 	if (limit < 0) return pshared_barrier_wait(b);

 	/* Otherwise we need a lock on the barrier object */
 	while (a_swap(&b->_b_lock, 1))
 		__wait(&b->_b_lock, &b->_b_waiters, 1, 1);
 	inst = b->_b_inst;

 	/* First thread to enter the barrier becomes the "instance owner" */
 	if (!inst) {
 		struct instance new_inst = { 0 };
 		int spins = 200;
 		b->_b_inst = inst = &new_inst;
 		a_store(&b->_b_lock, 0);
 		if (b->_b_waiters) __wake(&b->_b_lock, 1, 1);
 		while (spins-- && !inst->finished)
 			a_spin();
 		a_inc(&inst->finished);
 		while (inst->finished == 1)
 			__syscall(SYS_futex,&inst->finished,FUTEX_WAIT|FUTEX_PRIVATE,1,0) != -ENOSYS
 			|| __syscall(SYS_futex,&inst->finished,FUTEX_WAIT,1,0);
 		return PTHREAD_BARRIER_SERIAL_THREAD;
 	}

 	/* Last thread to enter the barrier wakes all non-instance-owners */
 	if (++inst->count == limit) {
 		b->_b_inst = 0;
 		a_store(&b->_b_lock, 0);
 		if (b->_b_waiters) __wake(&b->_b_lock, 1, 1);
 		a_store(&inst->last, 1);
 		if (inst->waiters)
 			__wake(&inst->last, -1, 1);
 	} else {
 		a_store(&b->_b_lock, 0);
 		if (b->_b_waiters) __wake(&b->_b_lock, 1, 1);
 		__wait(&inst->last, &inst->waiters, 0, 1);
 	}

 	/* Last thread to exit the barrier wakes the instance owner */
 	if (a_fetch_add(&inst->count,-1)==1 && a_fetch_add(&inst->finished,1))
 		__wake(&inst->finished, 1, 1);

 	return 0;
 }
	#include "pthread_impl.h"

	static int pshared_barrier_wait(pthread_barrier_t *b)
	{
	int limit = (b->_b_limit & INT_MAX) + 1;
	int ret = 0;
	int v, w;

	if (limit==1) return PTHREAD_BARRIER_SERIAL_THREAD;

	while ((v=a_cas(&b->_b_lock, 0, limit)))
	__wait(&b->_b_lock, &b->_b_waiters, v, 0);

	/* Wait for <limit> threads to get to the barrier */
	if (++b->_b_count == limit) {
	a_store(&b->_b_count, 0);
	ret = PTHREAD_BARRIER_SERIAL_THREAD;
	if (b->_b_waiters2) __wake(&b->_b_count, -1, 0);
	} else {
	a_store(&b->_b_lock, 0);
	if (b->_b_waiters) __wake(&b->_b_lock, 1, 0);
	while ((v=b->_b_count)>0)
	__wait(&b->_b_count, &b->_b_waiters2, v, 0);
	}

	__vm_lock();

	/* Ensure all threads have a vm lock before proceeding */
	if (a_fetch_add(&b->_b_count, -1)==1-limit) {
	a_store(&b->_b_count, 0);
	if (b->_b_waiters2) __wake(&b->_b_count, -1, 0);
	} else {
	while ((v=b->_b_count))
	__wait(&b->_b_count, &b->_b_waiters2, v, 0);
	}

	/* Perform a recursive unlock suitable for self-sync'd destruction */
	do {
	v = b->_b_lock;
	w = b->_b_waiters;
	} while (a_cas(&b->_b_lock, v, v==INT_MIN+1 ? 0 : v-1) != v);

	/* Wake a thread waiting to reuse or destroy the barrier */
	if (v==INT_MIN+1 \|\| (v==1 && w))
	__wake(&b->_b_lock, 1, 0);

	__vm_unlock();

	return ret;
	}

	struct instance
	{
	volatile int count;
	volatile int last;
	volatile int waiters;
	volatile int finished;
	};

	int pthread_barrier_wait(pthread_barrier_t *b)
	{
	int limit = b->_b_limit;
	struct instance *inst;

	/* Trivial case: count was set at 1 */
	if (!limit) return PTHREAD_BARRIER_SERIAL_THREAD;

	/* Process-shared barriers require a separate, inefficient wait */
	if (limit < 0) return pshared_barrier_wait(b);

	/* Otherwise we need a lock on the barrier object */
	while (a_swap(&b->_b_lock, 1))
	__wait(&b->_b_lock, &b->_b_waiters, 1, 1);
	inst = b->_b_inst;

	/* First thread to enter the barrier becomes the "instance owner" */
	if (!inst) {
	struct instance new_inst = { 0 };
	int spins = 200;
	b->_b_inst = inst = &new_inst;
	a_store(&b->_b_lock, 0);
	if (b->_b_waiters) __wake(&b->_b_lock, 1, 1);
	while (spins-- && !inst->finished)
	a_spin();
	a_inc(&inst->finished);
	while (inst->finished == 1)
	__syscall(SYS_futex,&inst->finished,FUTEX_WAIT\|FUTEX_PRIVATE,1,0) != -ENOSYS
	\|\| __syscall(SYS_futex,&inst->finished,FUTEX_WAIT,1,0);
	return PTHREAD_BARRIER_SERIAL_THREAD;
	}

	/* Last thread to enter the barrier wakes all non-instance-owners */
	if (++inst->count == limit) {
	b->_b_inst = 0;
	a_store(&b->_b_lock, 0);
	if (b->_b_waiters) __wake(&b->_b_lock, 1, 1);
	a_store(&inst->last, 1);
	if (inst->waiters)
	__wake(&inst->last, -1, 1);
	} else {
	a_store(&b->_b_lock, 0);
	if (b->_b_waiters) __wake(&b->_b_lock, 1, 1);
	__wait(&inst->last, &inst->waiters, 0, 1);
	}

	/* Last thread to exit the barrier wakes the instance owner */
	if (a_fetch_add(&inst->count,-1)==1 && a_fetch_add(&inst->finished,1))
	__wake(&inst->finished, 1, 1);

	return 0;
	}