GCC内置原子性操作

先简单看一篇关于GCC原子性操作的概念东西吧，见
http://blog.csdn.net/summerhust/article/details/7406683

gcc内置原子操作函数

再来看一看陈硕老师封装的原子类，很简单，拿来直接用了。(PS:我去掉了namespace)
下面是线程安全的

// Use of this source code is governed by a BSD-style license// that can be found in the License file.//// Author: Shuo Chen (chenshuo at chenshuo dot com)#ifndef MUDUO_BASE_ATOMIC_H#define MUDUO_BASE_ATOMIC_H#include <boost/noncopyable.hpp>#include <stdint.h>template<typename T>class AtomicIntegerT : boost::noncopyable{ public:  AtomicIntegerT()    : value_(0)  {  }  // uncomment if you need copying and assignment  //  // AtomicIntegerT(const AtomicIntegerT& that)  //   : value_(that.get())  // {}  //  // AtomicIntegerT& operator=(const AtomicIntegerT& that)  // {  //   getAndSet(that.get());  //   return *this;  // }  T get()  {    //if is 0 ,then 0 retrun value,原子性操作，线程安全的    return __sync_val_compare_and_swap(&value_, 0, 0);  }  T getAndAdd(T x)  {    //返回的是没有修改的value的值    return __sync_fetch_and_add(&value_, x);  }  T addAndGet(T x)  {  //+x不会引起race condition，因为是局部变量    return getAndAdd(x) + x;  }  T incrementAndGet()  {    return addAndGet(1);  }  T decrementAndGet()  {    return addAndGet(-1);  }  void add(T x)  {    getAndAdd(x);  }  void increment()  {    incrementAndGet();  }  void decrement()  {    decrementAndGet();  }  T getAndSet(T newValue)  {    return __sync_lock_test_and_set(&value_, newValue);  } private:    /*volatile变量    C和C++中的volatile并不是用来解决多线程竞争问题的?    而是用来修饰一些因为程序不可控因素导致变化的变量，比如访问底层硬件设备的变量，    以提醒编译器不要对该变量的访问擅自进行优化    */  volatile T value_;};typedef detail::AtomicIntegerT<int32_t> AtomicInt32;typedef detail::AtomicIntegerT<int64_t> AtomicInt64;#endif  // MUDUO_BASE_ATOMIC_H

附带上的测试程序

#include <muduo/base/Atomic.h>#include <assert.h>int main(){  {  AtomicInt64 a0;  assert(a0.get() == 0);  assert(a0.getAndAdd(1) == 0);  assert(a0.get() == 1);  assert(a0.addAndGet(2) == 3);  assert(a0.get() == 3);  assert(a0.incrementAndGet() == 4);  assert(a0.get() == 4);  a0.increment();  assert(a0.get() == 5);  assert(a0.addAndGet(-3) == 2);  assert(a0.getAndSet(100) == 2);  assert(a0.get() == 100);  }  {  AtomicInt32 a1;  assert(a1.get() == 0);  assert(a1.getAndAdd(1) == 0);  assert(a1.get() == 1);  assert(a1.addAndGet(2) == 3);  assert(a1.get() == 3);  assert(a1.incrementAndGet() == 4);  assert(a1.get() == 4);  a1.increment();  assert(a1.get() == 5);  assert(a1.addAndGet(-3) == 2);  assert(a1.getAndSet(100) == 2);  assert(a1.get() == 100);  }}