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I have a threaded class from which I would like to occasionally acquire a pointer an instance variable. I would like this access to be guarded by a mutex so that the thread is blocked from accessing this resource until the client is finished with its pointer.

My initial approach to this is to return a pair of objects: one a pointer to the resource and one a shared_ptr to a lock object on the mutex. This shared_ptr holds the only reference to the lock object so the mutex should be unlocked when it goes out of scope. Something like this:

void A::getResource()
{
    Lock* lock = new Lock(&mMutex);
    return pair<Resource*, shared_ptr<Lock> >(
        &mResource, 
        shared_ptr<Lock>(lock));
}

This solution is less than ideal because it requires the client to hold onto the entire pair of objects. Behaviour like this breaks the thread safety:

Resource* r = a.getResource().first;

In addition, my own implementation of this is deadlocking and I'm having difficulty determining why, so there may be other things wrong with it.

What I would like to have is a shared_ptr that contains the lock as an instance variable, binding it with the means to access the resource. This seems like something that should have an established design pattern but having done some research I'm surprised to find it quite hard to come across.

My questions are:

  • Is there a common implementation of this pattern?
  • Are there issues with putting a mutex inside a shared_ptr that I'm overlooking that prevent this pattern from being widespread?
  • Is there a good reason not to implement my own shared_ptr class to implement this pattern?

(NB I'm working on a codebase that uses Qt but unfortunately cannot use boost in this case. However, answers involving boost are still of general interest.)

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Both answers from riv and Jonanthan Wakely are interesting and worth following. I'm going with Riz just because it's nice to have some complete collaboratively edited code in an answer. –  Tim MB Apr 10 '13 at 10:15

2 Answers 2

up vote 4 down vote accepted

I'm not sure if there are any standard implementations, but since I like re-implementing stuff for no reason, here's a version that should work (assuming you don't want to be able to copy such pointers):

template<class T>
class locking_ptr
{
public:
  locking_ptr(T* ptr, mutex* lock)
    : m_ptr(ptr)
    , m_mutex(lock)
  {
    m_mutex->lock();
  }
  ~locking_ptr()
  {
    if (m_mutex)
      m_mutex->unlock();
  }
  locking_ptr(locking_ptr<T>&& ptr)
    : m_ptr(ptr.m_ptr)
    , m_mutex(ptr.m_mutex)
  {
    ptr.m_ptr = nullptr;
    ptr.m_mutex = nullptr;
  }

  T* operator ->()
  {
    return m_ptr;
  }
  T const* operator ->() const
  {
    return m_ptr;
  }
private:
  // disallow copy/assignment
  locking_ptr(locking_ptr<T> const& ptr)
  {
  }
  locking_ptr& operator = (locking_ptr<T> const& ptr)
  {
    return *this;
  }
  T* m_ptr;
  mutex* m_mutex; // whatever implementation you use
};
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+1 this should do it - maybe disable assignment and add a move constructor? –  stijn Apr 8 '13 at 10:23
    
Sure, you could disable assignment by moving the operator = to private section, but it should be safe as long as mutexes support nested locks. Added move constructor. –  riv Apr 8 '13 at 10:25
1  
Why are you you assigning m_mutex = nullptr in your copy constructor? You don't do any sanity checking in your destructor so you will end up calling unlock() on a null pointer. –  Tom Knapen Apr 8 '13 at 10:48
5  
Even in light of the danger of a possible off-topic discussion I don't really want to spark, but "I generally avoid using std libraries" - Ouch! –  Christian Rau Apr 8 '13 at 10:49
3  
Why have you implemented the copy constructor and copy assignment operator? Either make them private and unimplemented, or stop living in 1998 and define them as deleted. –  Jonathan Wakely Apr 8 '13 at 11:22

You're describing a variation of the EXECUTE AROUND POINTER pattern, described by Kevlin Henney in Executing Around Sequences.

I have a prototype implementation at exec_around.h but I can't guarantee it works correctly in all cases as it's a work in progress. It includes a function mutex_around which creates an object and wraps it in a smart pointer that locks and unlocks a mutex when accessed.

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