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Is the following singleton implementation data-race free?

static std::atomic<Tp *> m_instance;
...

static Tp &
instance()
{
    if (!m_instance.load(std::memory_order_relaxed))
    {
        std::lock_guard<std::mutex> lock(m_mutex);
        if (!m_instance.load(std::memory_order_acquire))
        {
            Tp * i = new Tp;
            m_instance.store(i, std::memory_order_release);    
        }    
    }

    return * m_instance.load(std::memory_order_relaxed);
}

Is the std::memory_model_acquire of the load operation superfluous? Is it possible to further relax both load and store operations by switching them to std::memory_order_relaxed? In that case, is the acquire/release semantic of std::mutex enough to guarantee its correctness, or a further std::atomic_thread_fence(std::memory_order_release) is also required to ensure that the writes to memory of the constructor happen before the relaxed store? Yet, is the use of fence equivalent to have the store with memory_order_release?

EDIT: Thanks to the answer of John, I came up with the following implementation that should be data-race free. Even though the inner load could be non-atomic at all, I decided to leave a relaxed load in that it does not affect the performance. In comparison to always have an outer load with the acquire memory order, the thread_local machinery improves the performance of accessing the instance of about an order of magnitude.

static Tp &
instance()
{
    static thread_local Tp *instance;

    if (!instance && 
        !(instance = m_instance.load(std::memory_order_acquire)))
    {
        std::lock_guard<std::mutex> lock(m_mutex);
        if (!(instance = m_instance.load(std::memory_order_relaxed)))
        {
            instance = new Tp; 
            m_instance.store(instance, std::memory_order_release);    
        }    
    }
    return *instance;
}
share|improve this question
15  
I see one bug, your code is not singleton-free. –  Cat Plus Plus May 22 '11 at 12:09
    
If you don't know how to implement a Singleton safely, then you probably shouldn't be using one. –  Puppy May 22 '11 at 12:15
24  
Upvoted. C++11 <atomic> is a new header with new terminology. Asking how to use it to safely implement double checked locking is an excellent question that I imagine many people will be asking. –  Howard Hinnant May 22 '11 at 14:19
2  
@Matthew Gilman: that paper specifically refers to [15] ISO/IEC 14882: 1998 –  MSalters May 26 '11 at 9:39
4  
In my opinion, the entire notion of double-checked locking as such is rubbish. The only safe (and not totally convoluted, unintellegible) way to achieve what double-checked locking tries to do is create a singleton from the main thread before any other threads are created. Trivial to do, no complicated voodoo needed, considerably less overhead, and guaranteed to work. –  Damon Dec 13 '11 at 12:54

4 Answers 4

up vote 17 down vote accepted

That implementation is not race-free. The atomic store of the singleton, while it uses release semantics, will only synchronize with the matching acquire operation—that is, the load operation that is already guarded by the mutex.

It's possible that the outer relaxed load would read a non-null pointer before the locking thread finished initializing the singleton.

The acquire that is guarded by the lock, on the other hand, is redundant. It will synchronize with any store with release semantics on another thread, but at that point (thanks to the mutex) the only thread that can possibly store is the current thread. That load doesn't even need to be atomic—no stores can happen from another thread.

See Anthony Williams' series on C++0x multithreading.

share|improve this answer
    
A possible fix could be to make the outer load with memory_order_acquire and the inner with memory_order_relaxed. What do you think about this? –  Nicola Bonelli May 22 '11 at 14:23
    
That should make it race-free. But the inner load doesn't need to be atomic at all, in any sense. No reordering can happen to make the inner load happen before the mutex is locked, and once the mutex is locked there's no way to get "part" of another value back, even if Tp is bigger than a hardware word. –  John Calsbeek May 22 '11 at 21:44
    
Great link. Anthony Williams does a great job explaining the what and why of the memory ordering used. –  deft_code May 23 '11 at 16:06

I think this a great question and John Calsbeek has the correct answer.

However, just to be clear a lazy singleton is best implemented using the classic Meyers singleton. It has garanteed correct semantics in C++11.

§ 6.7.4

... If control enters the declaration concurrently while the variable is being initialized, the concurrent execution shall wait for completion of the initialization. ...

The Meyer's singleton is preferred in that the compiler can aggressively optimize the concurrent code. The compiler would be more restricted if it had to preserve the semantics of a std::mutex. Furthermore, the Meyer's singleton is 2 lines and virtually impossible to get wrong.

Here is a classic example of a Meyer's singleton. Simple, elegant, and broken in c++03. But simple, elegant, and powerful in c++11.

class Foo
{
public:
   static Foo& instance( void )
   {
      static Foo s_instance;
      return s_instance;
   }
};
share|improve this answer
    
I hate down votes without explanations. –  deft_code May 23 '11 at 22:10
1  
The downvoter (not me) may not be aware of C++11's new guarantee of thread-safety for static local variables. Mind adding a standard citation? –  ildjarn May 24 '11 at 1:17
    
I thought I had provided an explanation. This question is only tangentially about singletons, and the Meyer's singleton isn't particularly robust, even if it is thread-safe now. However, I'll remove my downvote since you did flesh out the bit that does pertain to the actual question. –  Dennis Zickefoose May 25 '11 at 21:39
1  
i think it should be noted that MS still not support this C++11 feature even in Visual Studio 2013 –  javapowered Feb 12 at 8:59
    
I can confirm that VS2013 does NOT support C++11 thread-safe construction of function local statics. –  Vinnie Falco Jul 16 at 17:43

See also call_once. Where you'd previously use a singleton to do something, but not actually use the returned object for anything, call_once may be the better solution. For a regular singleton you could do call_once to set a (global?) variable and then return that variable...

Simplified for brevity:

template< class Function, class... Args>
void call_once( std::once_flag& flag, Function&& f, Args&& args...);
  • Exactly one execution of exactly one of the functions, passed as f to the invocations in the group (same flag object), is performed.

  • No invocation in the group returns before the abovementioned execution of the selected function is completed successfully

share|improve this answer

Yes, your first solution is safe (I disagree with the accepted answer). Using memory_order_release for the store of m_instance means that no writes in the thread doing the store can be reordered after the store. That means if an atomic load of m_instance is seen as non-NULL (in any thread), it is pointing to a fully constructed object.

The only problem I see in this code is that it is possible for the first memory_order_relaxed load to miss that m_instance has been set by another thread. However, this is not a problem because the mutex and memory_order_acquire load will ensure that the store from the other thread will now be seen in this thread, and you won't reinitialize m_instance. Thus, you did a mutex lock when it wasn't strictly necessary.

share|improve this answer
1  
You do need memory_order_acquire unless you know everything about how the caller is going to use the returned pointer. The first problem is that memory_order_relaxed allows your code to (in effect) read a field like p->a before you read p - the compiler can do it by speculate-p-then-verify. The hardware can do it if the local cache for p->a is old but the cache for p is not. Also, the constructor of Tp might have side-effects and unless you use memory_order_acquire the caller is not guaranteed to see those side-effects - or worse, the caller could see only half of those side-effects. –  Bjarke H. Roune May 9 '13 at 20:36
1  
To add to the previous comment, it is true that memory_order_release imposes an order on all the prior writes in the thread that executes the memory_order_release store. However, other threads are not guaranteed to see that order. What pairing release to an acquire does is to transfer the happens-before relation from the storing thread to the reading thread. With memory_order_relaxed, that transfer of ordering is not guaranteed to happen, so the reading thread is not guaranteed to see a fully constructed object if it only synchronizes with memory_order_relaxed. –  Bjarke H. Roune May 9 '13 at 20:43

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