third_party/fuchsia-sdk/pkg/sync/include/lib/sync/condition.h - fuchsia-benchmarks - Git at Google

 // Copyright 2018 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef LIB_SYNC_CONDITION_H_
 #define LIB_SYNC_CONDITION_H_

 #include <assert.h>
 #include <lib/sync/mutex.h>
 #include <zircon/compiler.h>
 #include <zircon/types.h>

 __BEGIN_CDECLS

 // A condition variable that works with a sync_mutex_t
 typedef struct sync_condition {
   int lock;
   void* head;
   void* tail;

 #ifdef __cplusplus
   sync_condition() : lock(0), head(nullptr), tail(nullptr) {}
 #endif
 } sync_condition_t;

 static_assert(sizeof(((sync_condition_t*)0)->lock) == sizeof(sync_mutex_t),
               "sync_condition lock storage must be the same size as sync_mutex_t");

 #if !defined(__cplusplus)
 #define SYNC_CONDITION_INIT ((sync_condition_t){0})
 #endif

 // Block until |condition| is signaled by sync_condition_signal()/sync_condition_broadcast(), or a
 // spurious wake up occurs.
 //
 // |mutex| must be in a locked state, and will be atomically unlocked for the duration of the wait,
 // then locked again before the function returns.
 void sync_condition_wait(sync_condition_t* condition, sync_mutex_t* mutex);

 // Block until |condition| is signaled by sync_condition_signal()/sync_condition_broadcast(), or a
 // spurious wake up or a timeout occurs.
 //
 // |mutex| must be in a locked state, and will be atomically unlocked for the duration of the wait,
 // then locked again before the function returns.
 //
 // ZX_TIME_INFINITE can be used for |deadline| to wait for an unlimited amount of time.
 //
 // Return value:
 //      ZX_OK if |condition| was signaled or a spurious wake up occurred.
 //      ZX_ERR_TIMED_OUT if the wait timed out.
 zx_status_t sync_condition_timedwait(sync_condition_t* condition, sync_mutex_t* mutex,
                                      zx_time_t deadline);

 // Wake up one thread waiting for |condition|.
 //
 // If the woken thread was waiting on sync_condition_timedwait(), then it is guaranteed
 // to receive a ZX_OK return value even if a race with a timeout occurs. As an example
 // where this makes a difference, consider the following implementation of a multi-producer,
 // multi-consumer queue:
 //
 // Message* MessageQueue::DequeueTimeout(zx_time_t deadline) {
 //    sync_mutex_lock(&mutex_);
 //    for (;;) {
 //        if (!list_.empty()) {
 //            Message* msg = list_.front();
 //            list_.pop_front();
 //            sync_mutex_unlock(&mutex_);
 //            return msg;
 //        }
 //        zx_status_t status = sync_condition_timedwait(&condition_, &mutex_, deadline);
 //        if (status == ZX_ERR_TIMED_OUT) {
 //            // Without the above guarantee, this would be a bug: a race between
 //            // a timeout and a signal() would result in a missed wakeup.
 //            // To fix that, we would need to recheck list_.empty() here, which
 //            // is not obvious and would make the code more complex.
 //            sync_mutex_unlock(&mutex_);
 //            return nullptr;
 //        }
 //    }
 // }
 //
 // void MessageQueue::Enqueue(Message* msg) {
 //     sync_mutex_lock(&mutex_);
 //     list_.push_back(msg);
 //     // Signal just one waiter. Assumes that any possible waiter will dequeue the message.
 //     sync_condition_signal(&condvar_);
 //     sync_mutex_unlock(&mutex_);
 // }
 //
 // Note that pthread does not seem to require this property, and in fact the current upstream
 // implementation of pthread_cond_timedwait() in MUSL does not have it.
 void sync_condition_signal(sync_condition_t* condition);

 // Wake up all threads that are currently waiting for |condition|.
 void sync_condition_broadcast(sync_condition_t* condition);

 __END_CDECLS

 #endif  // LIB_SYNC_CONDITION_H_
	// Copyright 2018 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef LIB_SYNC_CONDITION_H_
	#define LIB_SYNC_CONDITION_H_

	#include <assert.h>
	#include <lib/sync/mutex.h>
	#include <zircon/compiler.h>
	#include <zircon/types.h>

	__BEGIN_CDECLS

	// A condition variable that works with a sync_mutex_t
	typedef struct sync_condition {
	int lock;
	void* head;
	void* tail;

	#ifdef __cplusplus
	sync_condition() : lock(0), head(nullptr), tail(nullptr) {}
	#endif
	} sync_condition_t;

	static_assert(sizeof(((sync_condition_t*)0)->lock) == sizeof(sync_mutex_t),
	"sync_condition lock storage must be the same size as sync_mutex_t");

	#if !defined(__cplusplus)
	#define SYNC_CONDITION_INIT ((sync_condition_t){0})
	#endif

	// Block until \|condition\| is signaled by sync_condition_signal()/sync_condition_broadcast(), or a
	// spurious wake up occurs.
	//
	// \|mutex\| must be in a locked state, and will be atomically unlocked for the duration of the wait,
	// then locked again before the function returns.
	void sync_condition_wait(sync_condition_t* condition, sync_mutex_t* mutex);

	// Block until \|condition\| is signaled by sync_condition_signal()/sync_condition_broadcast(), or a
	// spurious wake up or a timeout occurs.
	//
	// \|mutex\| must be in a locked state, and will be atomically unlocked for the duration of the wait,
	// then locked again before the function returns.
	//
	// ZX_TIME_INFINITE can be used for \|deadline\| to wait for an unlimited amount of time.
	//
	// Return value:
	// ZX_OK if \|condition\| was signaled or a spurious wake up occurred.
	// ZX_ERR_TIMED_OUT if the wait timed out.
	zx_status_t sync_condition_timedwait(sync_condition_t* condition, sync_mutex_t* mutex,
	zx_time_t deadline);

	// Wake up one thread waiting for \|condition\|.
	//
	// If the woken thread was waiting on sync_condition_timedwait(), then it is guaranteed
	// to receive a ZX_OK return value even if a race with a timeout occurs. As an example
	// where this makes a difference, consider the following implementation of a multi-producer,
	// multi-consumer queue:
	//
	// Message* MessageQueue::DequeueTimeout(zx_time_t deadline) {
	// sync_mutex_lock(&mutex_);
	// for (;;) {
	// if (!list_.empty()) {
	// Message* msg = list_.front();
	// list_.pop_front();
	// sync_mutex_unlock(&mutex_);
	// return msg;
	// }
	// zx_status_t status = sync_condition_timedwait(&condition_, &mutex_, deadline);
	// if (status == ZX_ERR_TIMED_OUT) {
	// // Without the above guarantee, this would be a bug: a race between
	// // a timeout and a signal() would result in a missed wakeup.
	// // To fix that, we would need to recheck list_.empty() here, which
	// // is not obvious and would make the code more complex.
	// sync_mutex_unlock(&mutex_);
	// return nullptr;
	// }
	// }
	// }
	//
	// void MessageQueue::Enqueue(Message* msg) {
	// sync_mutex_lock(&mutex_);
	// list_.push_back(msg);
	// // Signal just one waiter. Assumes that any possible waiter will dequeue the message.
	// sync_condition_signal(&condvar_);
	// sync_mutex_unlock(&mutex_);
	// }
	//
	// Note that pthread does not seem to require this property, and in fact the current upstream
	// implementation of pthread_cond_timedwait() in MUSL does not have it.
	void sync_condition_signal(sync_condition_t* condition);

	// Wake up all threads that are currently waiting for \|condition\|.
	void sync_condition_broadcast(sync_condition_t* condition);

	__END_CDECLS

	#endif // LIB_SYNC_CONDITION_H_