26

Coding stuff after taking the hint from my previous question's answer, I ran into an issue with overloading Scene::addObject.

To reiterate the relevant bits and make this self contained, with the least details possible:

  • I have a hierarchy of objects inheriting from Interface of which there are Foos and Bars;
  • I have a Scene which owns these objects;
  • Foos are to be unique_ptrs and Bars are to be shared_ptrs in my main (for reasons explained in the previous question);
  • the main passes them to the Scene instance, which takes ownership.

Minimal code example is this:

#include <memory>
#include <utility>

class Interface
{
public:
  virtual ~Interface() = 0;
};

inline Interface::~Interface() {}

class Foo : public Interface
{
};

class Bar : public Interface
{
};

class Scene
{
public:
  void addObject(std::unique_ptr<Interface> obj);
//  void addObject(std::shared_ptr<Interface> obj);
};

void Scene::addObject(std::unique_ptr<Interface> obj)
{
}

//void Scene::addObject(std::shared_ptr<Interface> obj)
//{
//}

int main(int argc, char** argv)
{
  auto scn = std::make_unique<Scene>();

  auto foo = std::make_unique<Foo>();
  scn->addObject(std::move(foo));

//  auto bar = std::make_shared<Bar>();
//  scn->addObject(bar);
}

Uncommenting the commented lines results in:

error: call of overloaded 'addObject(std::remove_reference<std::unique_ptr<Foo, std::default_delete<Foo> >&>::type)' is ambiguous

   scn->addObject(std::move(foo));

                                ^

main.cpp:27:6: note: candidate: 'void Scene::addObject(std::unique_ptr<Interface>)'

 void Scene::addObject(std::unique_ptr<Interface> obj)

      ^~~~~

main.cpp:31:6: note: candidate: 'void Scene::addObject(std::shared_ptr<Interface>)'

 void Scene::addObject(std::shared_ptr<Interface> obj)

      ^~~~~

Uncommenting the shared and commenting the unique stuff also compiles, so I take it the problem is, like the compiler says, in the overload. However I need the overload as both these types will need to be stored in some kind of collection, and they are indeed kept as pointers to base (possibly all moved into shared_ptrs).

I'm passing both by-value because I want to make clear I'm taking ownership in Scene (and upping the reference counter for the shared_ptrs). Not really clear to me where the issue lies at all, and I couldn't find any example of this elsewhere.

3
  • Converting from std::unique_ptr<Foo> to std::shared_ptr<Scene> is as good as converting to std::unique_ptr<Scene>.
    – felix
    Nov 26, 2018 at 12:49
  • 2
    Nice MCVE, nice question. I'd like to see more of those.
    – YSC
    Nov 26, 2018 at 12:52
  • 1
    For me if class accepts two different kind of pointers for the same base class is a code smell. This means that something bad happens with memory management inside that class. So to fix it I would remove one of the methods. Probably the unique_ptr version is obsolete since there is easy conversion to shared_ptr. Other way to fix the issue is do not use overload (rename at least one of the methods) what should improve readability.
    – Marek R
    Nov 26, 2018 at 13:19

5 Answers 5

18

The problem you are encountering is this constructor of shared_ptr (13), (which is not explicit), is as good a match as a similar "moving derived to base" constructor of unique_ptr (6) (also not explicit).

template< class Y, class Deleter > 
shared_ptr( std::unique_ptr<Y,Deleter>&& r ); // (13)

13) Constructs a shared_ptr which manages the object currently managed by r. The deleter associated with r is stored for future deletion of the managed object. r manages no object after the call.

This overload doesn't participate in overload resolution if std::unique_ptr<Y, Deleter>::pointer is not compatible with T*. If r.get() is a null pointer, this overload is equivalent to the default constructor (1). (since C++17)

template< class U, class E >
unique_ptr( unique_ptr<U, E>&& u ) noexcept; //(6)

6) Constructs a unique_ptr by transferring ownership from u to *this, where u is constructed with a specified deleter (E).

This constructor only participates in overload resolution if all of the following is true:

a) unique_ptr<U, E>::pointer is implicitly convertible to pointer

b) U is not an array type

c) Either Deleter is a reference type and E is the same type as D, or Deleter is not a reference type and E is implicitly convertible to D

In the non polymorphic case, you are constructing a unique_ptr<T> from a unique_ptr<T>&&, which uses the non-template move constructor. There overload resolution prefers the non-template


I'm going to assume that Scene stores shared_ptr<Interface>s. In that case you don't need to overload addObject for unique_ptr, you can just allow the implicit conversion in the call.

4
  • Why it's not ambiguous without polymorphism? Nov 26, 2018 at 12:55
  • @snake_style clarified. Move constructor was a misnomer
    – Caleth
    Nov 26, 2018 at 12:57
  • I mean struct D { }; void func(shared_ptr<D> ptr){} void func(unique_ptr<D> ptr){} int main() { auto p = make_unique<D>(); func(std::move(p)); } Why those ctor don't called here in this sample? Nov 26, 2018 at 13:03
  • @snake_style in that case, you don't have a template constructor selected for unique_ptr, but the non-template move constructor. Overload resolution prefers non-template conversions
    – Caleth
    Nov 26, 2018 at 13:10
5

The other answer explains the ambiguity and a possible solution. Here's another way in case you end up needing both overloads; you can always add another parameter in such cases to break the ambiguity and use tag-dispatching. The boiler-plate code is hidden in private part of Scene:

class Scene
{
    struct unique_tag {};
    struct shared_tag {};
    template<typename T> struct tag_trait;
    // Partial specializations are allowed in class scope!
    template<typename T, typename D> struct tag_trait<std::unique_ptr<T,D>> { using tag = unique_tag; };
    template<typename T>             struct tag_trait<std::shared_ptr<T>>   { using tag = shared_tag; };

  void addObject_internal(std::unique_ptr<Interface> obj, unique_tag);
  void addObject_internal(std::shared_ptr<Interface> obj, shared_tag);

public:
    template<typename T>
    void addObject(T&& obj)
    {
        addObject_internal(std::forward<T>(obj),
            typename tag_trait<std::remove_reference_t<T>>::tag{});
    }
};

Full compilable example is here.

3

You have declared two overloads, one taking std::unique_ptr<Interface> and one taking std::shared_ptr<Interface> but are passing in a parameter of type std::unique_ptr<Foo>. As none of your functions match directly the compiler has to perform a conversion to call your function.

There is one conversion available to std::unique_ptr<Interface> (simple type conversion to unique pointer to base class) and another to std::shared_ptr<Interface> (change to a shared pointer to the base class). These conversions have the same priority so the compiler doesn't know which conversion to use so your functions are ambiguous.

If you pass std::unique_ptr<Interface> or std::shared_ptr<Interface> there is no conversion required so there is no ambiguity.

The solution is to simply remove the unique_ptr overload and always convert to shared_ptr. This assumes that the two overloads have the same behaviour, if they don't renaming one of the methods could be more appropriate.

1

The solution by jrok is already quite good. The following approach allows to reuse code even better:

#include <memory>
#include <utility>
#include <iostream>
#include <type_traits>

namespace internal {
    template <typename S, typename T>
    struct smart_ptr_rebind_trait {};

    template <typename S, typename T, typename D>
    struct smart_ptr_rebind_trait<S,std::unique_ptr<T,D>> { using rebind_t = std::unique_ptr<S>; };

    template <typename S, typename T>
    struct smart_ptr_rebind_trait<S,std::shared_ptr<T>> { using rebind_t = std::shared_ptr<S>; };

}

template <typename S, typename T>
using rebind_smart_ptr_t = typename internal::smart_ptr_rebind_trait<S,std::remove_reference_t<T>>::rebind_t;

class Interface
{
public:
  virtual ~Interface() = 0;
};

inline Interface::~Interface() {}

class Foo : public Interface {};

class Bar : public Interface {};

class Scene
{
  void addObject_internal(std::unique_ptr<Interface> obj) { std::cout << "unique\n"; }

  void addObject_internal(std::shared_ptr<Interface> obj) { std::cout << "shared\n"; }

public:

  template<typename T>
  void addObject(T&& obj) {
    using S = rebind_smart_ptr_t<Interface,T>;
    addObject_internal( S(std::forward<T>(obj)) );
  }   
};

int main(int argc, char** argv)
{
  auto scn = std::make_unique<Scene>();

  auto foo = std::make_unique<Foo>();
  scn->addObject(std::move(foo));

  auto bar = std::make_shared<Bar>();
  scn->addObject(bar); // ok
}

What we do here is to first introduce some helper classes that allow to rebind smart pointers.

0

Foos are to be unique_ptrs and Bars are to be shared_ptrs in my main (for reasons explained in the previous question);

Can you overload in terms of pointer-to-Foo and pointer-to-Bar instead of pointer-to-Interface, since you want to treat them differently ?

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