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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> );
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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_;
    shared_ptr<T> p_;

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

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

struct Baz : Foo {
    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 );


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.)

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