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.

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;
    // 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?


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::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();

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(); }

        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
        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(); }

        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

Your Answer


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.