include/private/SkSemaphore.h - skia - 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 "include/core/SkTypes.h"
 #include "include/private/SkOnce.h"
 #include "include/private/SkThreadAnnotations.h"
 #include <algorithm>
 #include <atomic>

 class SkSemaphore {
 public:
     constexpr SkSemaphore(int count = 0) : fCount(count), fOSSemaphore(nullptr) {}

     // Cleanup the underlying OS semaphore.
     SK_SPI ~SkSemaphore();

     // Increment the counter n times.
     // Generally it's better to call signal(n) instead of signal() n times.
     void signal(int n = 1);

     // Decrement the counter by 1,
     // then if the counter is < 0, sleep this thread until the counter is >= 0.
     void wait();

     // If the counter is positive, decrement it by 1 and return true, otherwise return false.
     SK_SPI bool try_wait();

 private:
     // 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.
     struct OSSemaphore;

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

     std::atomic<int> fCount;
     SkOnce           fOSSemaphoreOnce;
     OSSemaphore*     fOSSemaphore;
 };

 inline void SkSemaphore::signal(int n) {
     int prev = fCount.fetch_add(n, std::memory_order_release);

     // We only want to call the OS semaphore when our logical count crosses
     // from <0 to >=0 (when we need to wake sleeping threads).
     //
     // This is easiest to think about with specific examples of prev and n.
     // If n == 5 and prev == -3, there are 3 threads sleeping and we signal
     // std::min(-(-3), 5) == 3 times on the OS semaphore, leaving the count at 2.
     //
     // If prev >= 0, no threads are waiting, std::min(-prev, n) is always <= 0,
     // so we don't call the OS semaphore, leaving the count at (prev + n).
     int toSignal = std::min(-prev, n);
     if (toSignal > 0) {
         this->osSignal(toSignal);
     }
 }

 inline void SkSemaphore::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 (fCount.fetch_sub(1, std::memory_order_acquire) <= 0) {
         SK_POTENTIALLY_BLOCKING_REGION_BEGIN;
         this->osWait();
         SK_POTENTIALLY_BLOCKING_REGION_END;
     }
 }

 #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 "include/core/SkTypes.h"
	#include "include/private/SkOnce.h"
	#include "include/private/SkThreadAnnotations.h"
	#include <algorithm>
	#include <atomic>

	class SkSemaphore {
	public:
	constexpr SkSemaphore(int count = 0) : fCount(count), fOSSemaphore(nullptr) {}

	// Cleanup the underlying OS semaphore.
	SK_SPI ~SkSemaphore();

	// Increment the counter n times.
	// Generally it's better to call signal(n) instead of signal() n times.
	void signal(int n = 1);

	// Decrement the counter by 1,
	// then if the counter is < 0, sleep this thread until the counter is >= 0.
	void wait();

	// If the counter is positive, decrement it by 1 and return true, otherwise return false.
	SK_SPI bool try_wait();

	private:
	// 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.
	struct OSSemaphore;

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

	std::atomic<int> fCount;
	SkOnce fOSSemaphoreOnce;
	OSSemaphore* fOSSemaphore;
	};

	inline void SkSemaphore::signal(int n) {
	int prev = fCount.fetch_add(n, std::memory_order_release);

	// We only want to call the OS semaphore when our logical count crosses
	// from <0 to >=0 (when we need to wake sleeping threads).
	//
	// This is easiest to think about with specific examples of prev and n.
	// If n == 5 and prev == -3, there are 3 threads sleeping and we signal
	// std::min(-(-3), 5) == 3 times on the OS semaphore, leaving the count at 2.
	//
	// If prev >= 0, no threads are waiting, std::min(-prev, n) is always <= 0,
	// so we don't call the OS semaphore, leaving the count at (prev + n).
	int toSignal = std::min(-prev, n);
	if (toSignal > 0) {
	this->osSignal(toSignal);
	}
	}

	inline void SkSemaphore::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 (fCount.fetch_sub(1, std::memory_order_acquire) <= 0) {
	SK_POTENTIALLY_BLOCKING_REGION_BEGIN;
	this->osWait();
	SK_POTENTIALLY_BLOCKING_REGION_END;
	}
	}

	#endif//SkSemaphore_DEFINED