Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I would like to pass (shared) ownership of an object to a function foo::bar. The thing is I do not care, whether the ownership is exclusive or shared. I see class foo as an interface where I do not want to care about the ownership details. All I care about is that I can secure the lifetime of the passed smart pointer beyond the return of foo::bar.

Now I could write

class foo {
  void bar( std::shared_ptr<blub> );
  void bar( std::unique_ptr<blub> );
};

but this is unelegant in times where we have accumulated several smart pointer variants. And writing an overload for every variant is quite cumbersome, especially if I want to use this scheme multiple times in my code.

Now I also do not want foo to be templated, for the obvious template complexities.

The simplest I can come up with would be a smart pointer wrapper

template <typename T>
class owning_ptr {
  // Sorts out the largest type so we can allocate enough space
  typedef largest<std::shared_ptr<T>, std::unique_ptr<T>, myptr<T>>::type big_type;
  typedef std::aligned_storage <sizeof(big_type), std::alignment_of<big_type>::value>::type buffer_type;
  buffer_type _internal;
  int _type;
};

which is a bit inefficient. Is there a better way to construct the wrapper?

In the end I would really like to have the signature:

class foo {
  void bar( owning_ptr<blub> );
};
share|improve this question
    
are templates an option? –  stefan May 28 '13 at 17:30
    
@stefan for everything except foo. –  abergmeier May 28 '13 at 17:38
    
you only need to use templates for bar ;-) –  stefan May 28 '13 at 17:46
    
@stefan Sure. The question still remains, how does one manage arbitrary owning pointers elegantly. :P –  abergmeier May 28 '13 at 17:57
    
You can construct a std::shared_ptr from a std::unique_ptr anyway (needs a move but that is required anyway). std::shared_ptr can also hold a pointer that is different from the owned pointer so create a shared pointer to your custom pointer (or a copy thereof) and return another constructed from that shared pointer and the raw pointer pointed to your custom owning pointer. The wrapping into a shared pointer can be done an a small wrapper function or for convenience as a conversion operator in your owning pointers. –  John5342 May 28 '13 at 18:50

1 Answer 1

Note: There's an interesting EDIT at the bottom

If you don't want to parameterize or overload on the owning pointer type, you're probably best off taking a shared_ptr<> and forcing a conversion for unique_ptr<>. Any non-template solution I can think of would have at least the same amount of overhead as a shared_ptr, most requiring a polymorphic call, a free-store allocation, or both.

You might be able to automate the conversion from shared_ptr by taking some type of proxy converter, which should allow you to take either a unique_ptr R-value or a shared_ptr without a cast or explicit conversion (other than move()) and extract a usable shared_ptr to store in your instance. Here's an example:

#include <iostream>
#include <memory>
#include <utility>
using namespace std;

// Take an instance of gimme_owned_ptr<T> to save off a shared_ptr<T>
// from either a shared_ptr or unique_ptr.
template<typename T>
struct gimme_owned_ptr {
    // Make the two constructors templates so we can accept
    // any convertible owning pointer:
    template<typename S>
    gimme_owned_ptr( unique_ptr<S> p )
        : p_( shared_ptr<S>( move(p) ) )
    { }
    template<typename S>
    gimme_owned_ptr( shared_ptr<S> p )
        : p_( p )
    { }
    shared_ptr<T> get() const {
        return p_;
    }
private:
    shared_ptr<T> p_;
};

struct Foo {
    void operator()() const { v_call(); }
    virtual ~Foo() { }
private:
    virtual void v_call() const = 0;
};

struct Bar {
    Bar( gimme_owned_ptr<Foo const> const &gop )
        : foo_( gop.get() )
    { }
    void operator()() const { (*foo_)(); }
private:
    shared_ptr<Foo const> foo_;
};

struct Baz : Foo {
private:
    virtual void v_call() const { cout << "Baz()()\n"; }
};

int main() {
    unique_ptr<Baz> upf( new Baz() );
    shared_ptr<Baz> spf( new Baz() );

    Bar upb( move( upf ) );
    Bar spb( spf );

    upb();
    spb();
}

Yes, this solution does use templates, but only for the gimme_owned_ptr utility class template, and only for re-use and conversion. Your own class (Bar in this case) wouldn't need to be a template, nor would you need to re-implement gimme_owned_ptr to use it with another type.

======== EDIT ========

I just checked, and the built-in conversion from unique_ptr to shared_ptr essentially does everything the gimme_owned_ptr class I wrote above. If the class takes a type of shared_ptr<T>, passing a move(unique_ptr<S>) will result in a workable conversion. So, all you really need is to take a shared_ptr and the only thing the user should have to do is call move() on unique_ptrs (which they should be doing anyway). The only reason to use something like gimme_owned_ptr would be to accept a different mixture of pointers or accept them in a different way. (For example, you could make the move() unnecessary by taking a unique_ptr<S>& and calling move() internally, but this is probably a bad idea as it will silently seize ownership.)

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.