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Consider some function:

template<typename F>
void foo(F f) {
  std::unique_ptr<int> p = f();
  // do some stuff with p
}

Because unique_ptr decrees a default template argument, default_delete, for D, any function object passed to foo that returns a unique_ptr with a non-default deleter fails to compile. For example,

int x = 3;
foo([&x](){
    // use empty deleter
    return std::unique_ptr<int>(&x, [](int*){});
});

However, I could see this being potentially useful, and I don't see a direct reason why it shouldn't be possible. Is there a common approach for addressing this?

Edit

The easy fix would be to define foo instead to use the following:

  std::unique_ptr<int, std::function<void(int*)>> p = f();

But I'm wondering why this couldn't have been incorporated into the interface for unique_ptr? Is there a reason the class interface couldn't provide this generic attribute? Are there approaches for "wrapping" this kind of thing into a new definition?

For example,

template<typename T>
using Generic_unique_ptr =
  std::unique_ptr<
    T,
    std::function< void(typename std::unique_ptr<T>::element_type*) >
  >;

But this seems dangerous because it exposes the potential to do something like the follwing,

Generic_unique_ptr<int> p(new int());

which would leave the deleter uninitialized and exhibit undefined behavior. Perhaps some way to provide an instance of std::default_delete<T> as the default deleter?

share|improve this question
    
@TemplateRex I'm not sure they're the same. How can the deleter type be deduced from template argument F? –  jwalk Aug 23 '13 at 10:06

2 Answers 2

up vote 3 down vote accepted

If all you want to do is use the pointer in a function, you can just use the auto keyword; the compiler will deduce the type of unique_ptr which has been used and thus automatically do the right thing:

template <typename F>
void foo(F f)
{
    auto p = f();
    p->bar();
}

Now, from your comment, we know that this is not all you want, but you want to be able to store the unique_ptr in your class to work with it later. This creates a set of completely different problems:

  1. unique_ptr<T, D1> and unique_ptr<T, D2> are different types. Thus we need to know what unique_ptr<T, D> will be returned by your functor F
  2. Even if we knew the return type of F in advance, our class can still only store unique_ptr<T, D1> and not unique_ptr<T, D2>.

The easiest way around this (that I can think of, there might be better ways) is type erasure.

We create ourselves a base class that exposes the pointer managed by the unique_ptr:

template <typename T>
struct wrapper
{
    virtual ~wrapper() {}
    virtual T const * get() const = 0;
    virtual T * get() = 0;
};

From that class inherits our actual storage class, which deduces the type of unique_ptr:

template <typename T, typename F>
struct storage
    : wrapper<T>
{
    storage(F f) { p_ = f(); }
    T const * get() const { return p_.get(); }
    T * get() { return p_.get(); }

    private:
        typename std::result_of<F()>::type p_;
};

In the class you actually care about, you can now store a pointer to our base class and use polymorphism to access the underlying object, in this case the unique_ptr. Assume we moved the classes above into namespace detail to hide them from the user:

template <typename T>
class some_class
{
    public:
        template <typename F>
        void store(F f)
        {
            storage_.reset(new detail::storage<T, F>(f));
        }

        T const * get() const { return storage_->get(); }
        T * get() { return storage_->get(); }

    private:
        std::unique_ptr<detail::wrapper<T>> storage_;
};

You can find a fully working example here.

share|improve this answer
    
That is fantastic! I have been guilty of not giving that keyword much attention, but it solves this problem brilliantly! –  jwalk Aug 23 '13 at 10:23
    
That's awesome. I tried doing something similar and failed miserably. –  jwalk Aug 23 '13 at 11:20
    
@jwalk updated my answer. –  nijansen Aug 23 '13 at 11:24

But I'm wondering why this couldn't have been incorporated into the interface for unique_ptr?

Because to do so would force all of std::function's overhead onto everyone. unique_ptr is intended to be useful for pretty much any case of single ownership of a pointer. You pay for what you use; not everyone who uses a custom deleter needs that deleter to be generic. This way, they don't have to pay for it.

Also, the current methodology allows it to handle non-pointer resources, as the deleter can specify exactly what type gets stored in the unique_ptr.

If you want to provide this generic deleter construct, you could create a class that (privately) inherits from unique_ptr and replicates its interface, minus the constructor that doesn't take a deleter instance. That way, the user is forced to pass a deleter function in.

share|improve this answer
    
Thanks for the direct answer. I'll look into this. –  jwalk Aug 23 '13 at 10:26
    
+1 for why, -1 for saying someone should inherit from std::unique_ptr: why inherit from a type in std, when a member variable does just as well? –  Yakk Aug 23 '13 at 13:39
    
@Yakk: Because it isn't "just as well". It's much easier to export an interface from an inherited class than a member class. –  Nicol Bolas Aug 23 '13 at 14:52
    
@NicolBolas other than inherited constructors, how exactly? And in this case, a simple single argument perfect forwarding constructor is only marginally more bulky than using an inherited constructor. –  Yakk Aug 23 '13 at 14:55
    
@Yakk: Because you can use using syntax to forward more than just constructors. There's more to unique_ptr's interface than just the constructor. –  Nicol Bolas Aug 23 '13 at 22:12

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