include/private/SkSemaphore.h - skia.git - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkSemaphore_DEFINED
 #define SkSemaphore_DEFINED

 #include "SkTypes.h"
 #include "../private/SkAtomics.h"
 #include "../private/SkOncePtr.h"

 struct SkBaseSemaphore {

     // Increment the counter by 1.
     // This is a specialization for supporting SkMutex.
     void signal() {
         // Since this fetches the value before the add, 0 indicates that this thread is running and
         // no threads are waiting, -1 and below means that threads are waiting, but only signal 1
         // thread to run.
         if (sk_atomic_fetch_add(&fCount, 1, sk_memory_order_release) < 0) {
            this->osSignal(1);
         }
     }

     // Increment the counter N times.
     // Generally it's better to call signal(N) instead of signal() N times.
     void signal(int N);

     // Decrement the counter by 1,
     // then if the counter is <= 0, sleep this thread until the counter is > 0.
     void wait() {
         // Since this fetches the value before the subtract, zero and below means that there are no
         // resources left, so the thread needs to wait.
         if (sk_atomic_fetch_sub(&fCount, 1, sk_memory_order_acquire) <= 0) {
             this->osWait();
         }
     }

     struct OSSemaphore;

     void osSignal(int n);
     void osWait();
     void deleteSemaphore();

     // This implementation follows the general strategy of
     //     'A Lightweight Semaphore with Partial Spinning'
     // found here
     //     http://preshing.com/20150316/semaphores-are-surprisingly-versatile/
     // That article (and entire blog) are very much worth reading.
     //
     // We wrap an OS-provided semaphore with a user-space atomic counter that
     // lets us avoid interacting with the OS semaphore unless strictly required:
     // moving the count from >0 to <=0 or vice-versa, i.e. sleeping or waking threads.
     int                        fCount;
     SkBaseOncePtr<OSSemaphore> fOSSemaphore;
 };

 /**
  * SkSemaphore is a fast mostly-user-space semaphore.
  *
  * A semaphore is logically an atomic integer with a few special properties:
  *   - The integer always starts at 0.
  *   - You can only increment or decrement it, never read or write it.
  *   - Increment is spelled 'signal()'; decrement is spelled 'wait()'.
  *   - If a call to wait() decrements the counter to <= 0,
  *     the calling thread sleeps until another thread signal()s it back above 0.
  */
 class SkSemaphore : SkNoncopyable {
 public:
     // Initializes the counter to 0.
     // (Though all current implementations could start from an arbitrary value.)
     SkSemaphore();
     ~SkSemaphore();

     void wait();

     void signal(int n = 1);

 private:
     SkBaseSemaphore fBaseSemaphore;
 };

 #endif//SkSemaphore_DEFINED
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkSemaphore_DEFINED
	#define SkSemaphore_DEFINED

	#include "SkTypes.h"
	#include "../private/SkAtomics.h"
	#include "../private/SkOncePtr.h"

	struct SkBaseSemaphore {

	// Increment the counter by 1.
	// This is a specialization for supporting SkMutex.
	void signal() {
	// Since this fetches the value before the add, 0 indicates that this thread is running and
	// no threads are waiting, -1 and below means that threads are waiting, but only signal 1
	// thread to run.
	if (sk_atomic_fetch_add(&fCount, 1, sk_memory_order_release) < 0) {
	this->osSignal(1);
	}
	}

	// Increment the counter N times.
	// Generally it's better to call signal(N) instead of signal() N times.
	void signal(int N);

	// Decrement the counter by 1,
	// then if the counter is <= 0, sleep this thread until the counter is > 0.
	void wait() {
	// Since this fetches the value before the subtract, zero and below means that there are no
	// resources left, so the thread needs to wait.
	if (sk_atomic_fetch_sub(&fCount, 1, sk_memory_order_acquire) <= 0) {
	this->osWait();
	}
	}

	struct OSSemaphore;

	void osSignal(int n);
	void osWait();
	void deleteSemaphore();

	// This implementation follows the general strategy of
	// 'A Lightweight Semaphore with Partial Spinning'
	// found here
	// http://preshing.com/20150316/semaphores-are-surprisingly-versatile/
	// That article (and entire blog) are very much worth reading.
	//
	// We wrap an OS-provided semaphore with a user-space atomic counter that
	// lets us avoid interacting with the OS semaphore unless strictly required:
	// moving the count from >0 to <=0 or vice-versa, i.e. sleeping or waking threads.
	int fCount;
	SkBaseOncePtr<OSSemaphore> fOSSemaphore;
	};

	/**
	* SkSemaphore is a fast mostly-user-space semaphore.
	*
	* A semaphore is logically an atomic integer with a few special properties:
	* - The integer always starts at 0.
	* - You can only increment or decrement it, never read or write it.
	* - Increment is spelled 'signal()'; decrement is spelled 'wait()'.
	* - If a call to wait() decrements the counter to <= 0,
	* the calling thread sleeps until another thread signal()s it back above 0.
	*/
	class SkSemaphore : SkNoncopyable {
	public:
	// Initializes the counter to 0.
	// (Though all current implementations could start from an arbitrary value.)
	SkSemaphore();
	~SkSemaphore();

	void wait();

	void signal(int n = 1);

	private:
	SkBaseSemaphore fBaseSemaphore;
	};

	#endif//SkSemaphore_DEFINED