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I have a doubt related to Singleton and multithread programming in C++ Following you can see an example code of a Singleton class with a variable named shared.

I create 1000 threads that modify (+1) that variable of my Singleton global instance. The final value of shared is 1000 but I would expect this value to be under 1000 since I am not protecting this variable for concurrency.

Is the code really thread safe because the class is Singleton or it just happened to be lucky and the value is 1000 but it can perfectly be less than 1000?

#include <iostream>
using namespace std;

class Singleton {
private:
    Singleton() {shared = 0;};
    static Singleton * _instance;
    int shared;

public:
    static Singleton* Instance();
    void increaseShared () { shared++; };
    int getSharedValue () { return shared; };
};

// Global static pointer used to ensure a single instance of the class.
Singleton* Singleton::_instance = NULL;

Singleton * Singleton::Instance() {
    if (!_instance) { 
        _instance = new Singleton;
    }

    return _instance;
}

void * myThreadCode (void * param) {
    Singleton * theInstance;
    theInstance = Singleton::Instance();
    theInstance->increaseShared();

    return NULL;
}

int main(int argc, const char * argv[]) {
    pthread_t threads[1000];
    Singleton * theInstance = Singleton::Instance();

    for (int i=0; i<1000; i++) {
        pthread_create(&threads[i], NULL, &myThreadCode, NULL);
    }

    cout << "The shared value is: " << theInstance->getSharedValue() << endl;

    return 0;
}
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We've edited your question so that it is easier to read. –  user7116 Jul 17 '12 at 1:41

2 Answers 2

Is the code really thread safe because the class is Singleton or it just happened to be lucky and the value is 1000 but it can perfectly be less than 1000?

You got lucky...

In reality, the most likely issue with what you're observing has to-do with the fact that the time it takes to increment the value of your singleton on your specific machine is less than the time it takes the operating system to allocate the resources to launch an individual pthread. Thus you never ended up with a scenario where two threads contend for the unprotected resources of the singleton.

A much better test would have been to launch all of your pthreads first, have them block on a barrier or condition variable, and then perform the increment on the singleton once the barrier's condition of all the threads being "active" is met ... at that point you would have been much more likely to have seen the sorts of data-races that occur with non-atomic operations like an increment operation.

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yep, thanks, I just synchronized the threads at the end of the main (that i was missing) and sleep for a bit in the thread code to simulate a bit of work and buhala... shared < 1000 –  Jorge Jul 17 '12 at 1:48
    
yeah, if you have more processing (data allocation, i/o, display) in increaseShared then race condition would be even more visible. –  zodi Jul 18 '12 at 8:32

If you implement your Singleton like this, the singleton creation will be thread safe:

Singleton & Singleton::Instance() {
    static Singleton instance;
    return instance;
}

Since the instance can never be null, and no memory to manager, a reference is returned instead of a pointer.

The increment operation can be made atomic by using platform specific operations (g++ provides built-ins, e.g. __sync_fetch_and_add), or C++11 atomic from STL, or Boost.Atomic, or with mutex guards.

std::atomic<int> shared;

void increaseShared () { ++shared; };
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1  
No it won't be. There's no guarantee that post-increment is atomic. –  Slavik81 Jul 17 '12 at 2:20
    
@Slavik81: I was only considering the singleton creation, thanks for pointing out the variable increment operation. –  jxh Jul 17 '12 at 2:29
    
There is absolutely no reason to return a pointer when 1/ there is no memory to manage and 2/ it cannot be null => in this case, a reference would be much better. –  Matthieu M. Jul 17 '12 at 7:24
    
@MatthieuM.: You're right. I was \maintaining the original interface, which can be important in a large existing project. I'll update the answer. –  jxh Jul 17 '12 at 13:04

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