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I work with a codebase that was partially implemented by someone who was in love with overly complex solutions to simple problems (e.g. template classes with two parameters that were only ever instantiated for one pair of types). One thing she did was to create objects in a smart pointer, and then have the object store a weak pointer to itself.

class MyClass {
    //...
    boost::weak_ptr<MyClass> m_self;
    //...
};

boost::shared_ptr<MyClass>
Factory::Factory::Factory::CreateMyClass() {
    boost::shared_ptr<MyClass> obj(new MyClass(...));
    boost::weak_ptr<MyClass> p(obj);
    obj->storeSelfPointer(p);
    return obj;
}

The class then proceeds to use m_self by locking it and passing around the resulting shared pointer.

For the life of me, I cannot fathom what she was trying to accomplish. Is there some pattern or idea that would explain this implementation? It looks to me like this is completely pointless and I'd like to refactor it away.

EDIT: I should mention that none of the places that use the resulting smart pointer obtained from locking m_self actually retain the smart pointer.

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5  
didn't know about std::shared_from_this I guess –  Ben Voigt Jun 26 '14 at 0:31
    
It's c++98, newer stuff is not used –  James Davidoff Jun 26 '14 at 0:39
2  
Well ok, it's a C++98 version of enable_shared_from_this –  Ben Voigt Jun 26 '14 at 0:40
1  
could you please elaborate on the " template classes with two parameters that were only ever instantiated for one pair of types". and also the Factory::Factory::Factory::? this is interesting –  Cheers and hth. - Alf Jun 26 '14 at 0:55
    
template <class T, class U> class Foo; class Bar; class Biz; Foo is only ever used as Foo<Bar, Biz>; totally pointless generalization of the behavior. –  James Davidoff Jun 26 '14 at 1:00

1 Answer 1

up vote 15 down vote accepted

A possible use of this "design" could be to use m_self.lock() to generate shared pointers from this.

If you remove this weak pointer member, the reference count hold by the generated shared pointer from this would be incorrect.

It achieves the same than std::enable_shared_from_this, interestingly enough, cppreference.com mentions this design :

A common implementation for enable_shared_from_this is to hold a weak reference (such as std::weak_ptr) to this. The constructors of std::shared_ptr detect the presence of an enable_shared_from_this base and assign the newly created std::shared_ptr to the internally stored weak reference

And the C++ standard, section § 20.8.2.4 10 , mention the same possible implementation :

The shared_ptr constructors that create unique pointers can detect the presence of an enable_shared_- from_this base and assign the newly created shared_ptr to its __weak_this member


Possible Refactoring :

  • If you are using C++11, you can remove the std::weak_ptr member, and publicly inherits from std::enable_shared_from_this<T>. You should retrieve a shared pointer from this by calling shared_from_this().

  • If you are not using C++11 but can use boost, use boost::enable_shared_from_this, see the boost documentation. You should retrieve a shared pointer from this by calling shared_from_this().

  • If you are not using C++11, and can't use boost, you can bring the proposed implementation of the standard to your code base, it is short enough :

Code : (copied from § 20.8.2.4 - 11, remove leading underscores, and you probably want to rename it)

template<class T> class enable_shared_from_this {
    private:
     weak_ptr<T> __weak_this;
    protected:
     constexpr enable_shared_from_this() : __weak_this() { }
     enable_shared_from_this(enable_shared_from_this const &) { }
     enable_shared_from_this& operator=(enable_shared_from_this const &) { return *this; }
     ~enable_shared_from_this() { }
    public:
     shared_ptr<T> shared_from_this() { return shared_ptr<T>(__weak_this); }
     shared_ptr<T const> shared_from_this() const { return shared_ptr<T const>(__weak_this); }
};

And use shared_from_this() to make a shared pointer. If you do copy this code, note that constructing shared pointers from this by other means would not work. The shared pointers constructors need to be modified (as explain by the standard quote above).

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1  
That's not official documentation –  Ben Voigt Jun 26 '14 at 0:41
1  
True. Actually the standard shows the exact same possible implementation. –  quantdev Jun 26 '14 at 0:44
    
Yup I was trying to confirm that, but PDF search wasn't working. I see it now. –  Ben Voigt Jun 26 '14 at 0:45
    
The note accompanying that example is kinda important...how would the library shared_ptr know the existence of your enable_shared_from_this clone let alone access its __weak_this? –  T.C. Jun 26 '14 at 1:10
    
@T.C. : Yes, you would not have the features exposed in the standard, but by using shared_from_this(), the OP would keep its current behavior. Creating shared_pointer from this by other means would still not work without modifying shared_pointer ctors, Ill edit.. –  quantdev Jun 26 '14 at 1:19

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