I have a reference and want to call a function that takes boost::shared_ptr

Question

I have a reference to an object and want to call a function that takes a boost::shared_ptr of this object. If I build a boost::shared_ptr to make the call when my boost::shared_ptr is canceled from the stack than the object is canceled too! This is exactly what happens when I run this code:

double f(boost::shared_ptr<Obj>& object)
{
  ...
}

double g(Obj& object)
{
  boost::shared_ptr<Obj> p(&object);
  double x = f(p);
  ...
}

Is there a way to make it work? How can I create in g() a boost::shared pointer that leaves my object alive at the end? I think I have to connect it to the reference counting machinery of other shared pointers that already point to object... but how?

Even if I make it work do you think this way of doing is bad design? What is the best practice to solve this kind of problems? In my code I have objects and methods that work both with shared pointer and references and I cannot work only with these or those...

Answer 1

A function that takes a shared_ptr is saying something about what it does. It is saying, "I want to potentially claim shared ownership of this object". If this is not true, then it is a poorly written function and shouldn't be taking a shared_ptr at all.

A function which takes a value by non-const reference to an object means that the function can modify the object, but cannot claim ownership. If you don't own something, you also can't give ownership to someone else.

Now, you could perform this trick of using an empty deleter function:

void EmptyDeleter(Obj *) {}

double g(Obj& object)
{
  boost::shared_ptr<Obj> p(&object, EmptyDeleter);
  double x = f(p);
  ...
}

However, you are now lying to f. It doesn't own object; it can't own object. It is very possible that object is a stack object that may disappear any time after f completes. If f were a member of a class, it might store the shared_ptr in a member variable. At which point, it would then have a shared_ptr to a dead object. This is exactly the sort of thing that shared_ptrs are intended to prevent.

The correct answer is for either f to not take its argument by shared_ptr (use non-const reference or non-const pointer if it is modifiable, and const& if it is not modifiable), or for g to take its argument by shared_ptr.

Answer 2

You may create a shared_ptr that doesn't actually free the object. Like this:

struct FictiveDisposer {
    template <class T> void operator ()(T) {}
};

Obj& object = /* ... */;
boost::shared_ptr<Obj> myPtr(&obj, FictiveDisposer ());

// you may use myPtr

However you should use this carefully. If you're sure the function you're calling won't try to "save" your object for later use - there's no problem. Otherwise you must guarantee that the lifetime of the saved shared_ptr to your object won't exceed the actual lifetime of your object.

In simple words: you got the reference to the object. You didn't create it, and you may not affect its lifetime (neither shared_ptr can). Hence there may happen a situation where the object doesn't exist anymore, still it's referenced by shared_ptr. This must be avoided.

Answer 3

You must consider the purpose of f(). Presumably if it takes a shared_ptr, f intends to retain shared ownership of this pointer over time, past its return. Why? What is f() assuming when you pass it a shared_ptr? Once you answer this question you will be able to figure out how to code g().

If for some reason f() does not need to retain shared ownership of the pointer, then if you have control over its interface it could be rewritten to take a Obj* or Obj& instead of a shared_ptr. Any code possessing a shared_ptr could then call f by pulling the pointer out of the shared_ptr or dereferencing it.

Answer 4

It's usually a sign of poor design for a library interface to take a shared_ptr (but there are exceptions). Since the function you're calling expects to take responsibility, or at least partial responsibility, for the object you pass it, and the rest of the code isn't prepared for this, you're only safe solution is to clone the object, e.g.:

double x = f( boost::shared_ptr<Obj>( new Obj( object ) ) );

But you'd really be best off finding out why f requires a shared_ptr, and why g can't take one as an argument.

Answer 5

How can I create in g() a boost::shared pointer that leaves my object alive at the end?

You can give the shared pointer a custom destructor that does nothing:

boost::shared_ptr<Obj> p(&object, [](void*){});

or if your compiler doesn't support lambdas:

void do_nothing(void*) {}
boost::shared_ptr<Obj> p(&object, do_nothing);

Even if I make it work do you think this way of doing is bad design?

Yes: you lose the lifetime management that shared pointers give you, and it is now your responsibility to make sure that the object outlives all of the shared pointers.

What is the best practice to solve this kind of problems?

Decide on an ownership model for all the objects you're using, and stick to it. Shared pointers can be useful when you want to share ownership, but not otherwise. In your case f wants to share ownership, and whatever calls g seems to want exclusive ownership; it would be a good idea to think about why they want that, and whether you can change one to be compatible with the other.

Answer 6

std::shared_ptr<T> is to possible give multiple entities ownership of the referenced object. If an interface expects a std::shared_ptr<T> there are two possibilities:

1. Someone ignorantly used std::shared_ptr<T> in an interface which was meant to receive a T object or a reference or a pointer to a T object. If that is the case the author shall be educated (and if this doesn't work be released from his current duties to pursue a new career) and the interface corrected.
2. Since now all interfaces using a std::shared_ptr<T> are using this to possibly grant shared ownership to the object, it should be obvious that a stack allocated T isn't a suitable argument to such an interface. The only possible argument is a T object whose life-time is maintained vy a std::shared_ptr<T>.

I realize that this doesn't answer the original question but it should be clear that the only viable course of action is: don't ever try to pass an object to a function taking a std::shared_ptr<T> which can't be fully controlled by such a pointer! (the same applies to the boost version of shared pointers).