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void foo ( Bar* bar , void(Bar::*qux)(void) )
{
    if ( bar )
    {
        bar->qux();
    }
}

The problem is:

  1. bar can be deleted after the check by another thread.

  2. I can not add a mutex member to Bar in order to lock it.

Thus I wonder, if I can tell the processor to run this function atomically, and how would I do so? I've spent way to much time on Google, but found no understandable manuals...

P.S. Debian, gcc , Boost NOT allowed, C++11 IS allowed.

share|improve this question
    
please also show the code where bar can be deleted. – user2k5 Sep 13 '12 at 14:05
3  
@user2k5 delete bar; I don't get it, what do you expect to see... – Kolyunya Sep 13 '12 at 14:10
1  
I don't think that running this function atomically will do anything about the possibility that the object might be deleted in another thread... Atomicity in a function primarily assures that it won't be interrupted by something else, and places no restrictions on what might be going on elsewhere. A mutex protecting the object is what is needed to prevent the scenario you describe. – twalberg Sep 13 '12 at 14:31
1  
How can that be? If bar is deleted in another function, then it doesnt matter what you do in this function, unless both use the same mutex. – Brady Sep 13 '12 at 14:38
1  
@Kolyunya Running function A atomically makes absolutely no guarantees about what function B running in another thread on another core is doing with data, even data that A might be using. It only guarantees that function A won't be interrupted. Atomicity is not the same thing as mutual exclusion. – twalberg Sep 13 '12 at 14:44
up vote 2 down vote accepted

The concept of atomic methods doesnt exist in C++ like it does in Java, where you can define a method as synchronized. The closest you can get to that in C++ would be to create a ScopedMutex class as follows:

class ScopedMutex {
public:
    ScopedMutex(pthread_mutex *m) : theMutex_(m) {pthread_mutex_lock(theMutex_);}
    ~ScopedMutex() { pthread_mutex_unlock(theMutex_); }
    // Add appropriate copy constructors and operator=() to disallow mutex copy
    // Or consider passing in a reference
private:
    pthread_mutex *theMutex_;
};

Then use it like this in your function:

void foo ( Bar* bar , void(Bar::*qux)(void) )
{
    ScopedMutex m(&aMutex); // This mutex must be defined/initialized elsewhere

    if ( bar )
    {
        bar->qux();
    }

    // The ScopedMutex goes out of scope when the function does,
    // thus releasing the lock
}

But this wont do you any good unless you use the same mutex in every other method that uses the bar object.

Scoped Mutex are especially useful when you have a function with complicated logic where there are several return statements, so you dont have to manually unlock the mutex it will be unlocked when the function goes out of scope.

share|improve this answer
    
-1, Your lock is copyable, but it should not be. Using pthread_mutex & theMutex_; (Reference instead of pointer) will solve the problem – nogard Sep 20 '12 at 8:24
    
@nogard, I updated the answer with suggestions to avoid said copy. Although its technically possible to copy the mutex and it should be avoided, I cant imagine anyone ever wanting to copy a scoped mutex. What would be the use case to do so? – Brady Sep 20 '12 at 8:37
    
there is no use case for scoped mutex, that's why it must be explicitly disabled. However copying of locks make sence for other types of locks (shared_lock). See here: boost.org/doc/libs/1_51_0/doc/html/thread/synchronization.html – nogard Sep 20 '12 at 8:43
    
It seems you didn't upgrade the answer. I removed -1 anyway – nogard Sep 20 '12 at 8:45
1  
@nogard, Ugg, sorry, Im trying to do too many things at once, too many context switches isnt only bad for computers :) – Brady Sep 20 '12 at 10:04

You probably want to use a smart pointer with shared ownership semantics (e.g. shared_ptr, intrusive_ptr) to make sure the object stays alive as long as you refer to it.

share|improve this answer
    
no boost allowed... – Kolyunya Sep 13 '12 at 14:17
    
Ok, but how does it work? I bet it uses some atomic-mechanisms inside? – Kolyunya Sep 13 '12 at 14:30
    
They normally use atomic integer increment and decrement to update the reference counter in a thread-safe manner. – Maxim Egorushkin Sep 13 '12 at 14:33
    
Ok, thank you for an answer! – Kolyunya Sep 13 '12 at 14:36

You want to temporarily share ownership of the object, in order to prevent another thread from deleting it. This is a job for shared_ptr, using weak_ptr to allow deletion when we don't need to access it:

void foo ( std::weak_ptr<Bar> weak_bar , void(Bar::*qux)(void) ) 
{
    if (std::shared_ptr<Bar> bar = weak_bar.lock())
    {
        // We now share ownership of the object - it won't be deleted
        bar->qux();
    }

    // We have released ownership - it can now be deleted
}

Of course, you still need synchronisation if multiple threads need to access the object; this only solves the problem of deletion specified in the question.

share|improve this answer

Sorry, but no. C++ doesn't have anything to support that. You don't necessarily need to add the mutex to Bar, but to avoid it, you'll probably need a wrapper around Bar, or something on that order.

share|improve this answer
    
Sad... very sad... I probably would derive Bar from BarBase, which will have a mutex. Is this a correct solution? – Kolyunya Sep 13 '12 at 14:08
    
@Kolyunya: If you can add a base class to Bar, then why on earth can't you add a member? That would be much less weird. – Mike Seymour Sep 13 '12 at 14:12
    
@Kolyunya I don't see how adding a mutex to Bar will help at all. When and how would it be used? If it's a member of the Bar class, it will be destructed together with the instance so still can't be used in e.g. foo. – Joachim Pileborg Sep 13 '12 at 14:12
    
@JoachimPileborg foo will lock the mutex and another thread will try to lock it too before deleting bar. It's that easy. – Kolyunya Sep 13 '12 at 14:16
    
@MikeSeymour, the whole 'story' is about designing an observer pattern. It's more use-able to derive listener from Listener than to add a mutex member to each listener – Kolyunya Sep 13 '12 at 14:19

I too have a requirement for executing 2 functions atomically in Thread-1.

Main Thread:

   CMythread* pThread = GetThreadFromPool();
   //allocate work to thread
   pThread->ResumeThread();

Thread-1:

 AddtoThreadPool(this);
 SuspendThread(); //sleep infinitely unless awakened by Main Thread

Problem: Main Thread can resume the thread in the pool before it is suspended and Thread-1 (pool thread) can suspend itself infinitely.

Solution: 1. Execute the 2 functions in the Thread-1 atomically. No amount of protection will work. 2. Periodically check the thread pool to resume a suspended thread that was allocated work.

Thanks for your answers.

Ajay

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