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Basically I've a class A and a class B : public A.

And I'd like to cast a std::shared_ptr<std::vector<A*> to a std::shared_ptr<std::vector<B*>

The problem is std::vector<B> doesn't inherit from std::vector<A>, and the smart_ptr neither. So I do a horrible cast:

  std::shared_ptr<VectorA> vector_a = * ((std::shared_ptr<VectorA>*)&vector_b);

The code compiles and runs there, but it is safe? http://liveworkspace.org/code/3dQTz1$0

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  • 5
    Short answer: No. It's basically a reinterpret cast of the shared pointer, so who knows what it would do.
    – Dave S
    Feb 5, 2013 at 21:46
  • 1
    At least use reinterpret_cast, not C style cast here. And no, this is not defined by the standard (this doesn't mean it won't work, it's just not guaranteed). Feb 5, 2013 at 21:51
  • Also, a vector of non-smart pointers is also just waiting to leak (and probably is). use vector<shared_ptr<A>> or something, as then you won't leak (if needing polymorphic behavior) or just vector<A> if you don't. Feb 5, 2013 at 22:00
  • @Kevin : true, sorry about that. I've simplified my code; I'm not using a std::vector but a custom template class. Feb 5, 2013 at 22:05

4 Answers 4

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This is a horrible solution. When you cast a vector of objects of one type to the other you can expect all kind of incorrect/undefined behaviour.

You should use vector of std::shared_ptr<A> from the beginning and initialize them with pointers to objects of type B there.

If it is not possible you can create a new vector holding std::weak_ptr<A> to avoid managing these objects twice.

3

Don't do that.

Consider that a vector of (pointers to) B is not a vector of (pointers to) A, or to be more precise, is not a universally valid substitution for a vector of (pointers to) A; thus, there is a good reason why you cannot perform such a conversion.

Although it is true that all you have in a vector of B is indeed a set of objects which are (also( instances of A, consider the following algorithm:

void f(vector<A>& v)
{
    A a;
    v.push_back(a);
}

Now imagine you invoke f() with a vector of B. That would be an attempt to add an instance of a class that is not B to a collection which is supposed to contain only elements of type B.

The solution here is to make the code which accepts only a vector<A> flexible enough to work also on a vector<B>. In other words, you need to make it a template. For instance, your template could accept as arguments only vectors of a type which is derived from A. This is quite easy to enforce with some SFINAE techniques and type traits such as std::is_base_of.

2

Strictly speaking the dereferencing operations should succeed. Both vectors are pointer containers, so casting one to another, whilst unacceptable for production code, will still use the same dimensions and alignment.

C++ provides rich abstractions to avoid these shenanigans though, it would be better to populate the vector of derived objects as pointers to the base class.

2

You can still cast the elements:

A* a = vector_b->at (42);

gives you what you want.

Now, if you have written functions taking shared_ptr<vector<A*>> as arguments, then you have multiple solutions to take you out of this situation:

  • use shared_ptr<A*[]> instead of shared_ptr<vector<A*>> (it works as you'd like to)
  • take A** as arguments (and use vector_b->data ()) : it does not ties you to shared pointers.
  • Better: take iterators which dereference as [smart] pointers to A (recall that operator-> chains)
  • use std::vector<std::shared_ptr<A>> (wastes resources)

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