I wonder which parts of the standard specify that in the following code segment:

#include <memory>

class A { };

class B : public A { };

int main()
    std::unique_ptr<B> bptr = std::make_unique<B>(); // (a)
    std::unique_ptr<A> aptr = std::move(bptr);       // (b)
    std::unique_ptr<A> &aptr_r = bptr;               // (c)
    std::unique_ptr<A> &&aptr_rr = std::move(bptr);  // (d)
    return 0;

(d) compiles and (c) does not. Please include the relevant parts of the standard in your answer or refer to them appropriately. Just for reference, Ubuntu clang version 3.6.2-1 (tags/RELEASE_362/final) (based on LLVM 3.6.2) gives me

error: non-const lvalue reference to type 'unique_ptr<A>' cannot
       bind to a value of unrelated type 'unique_ptr<B>'
       std::unique_ptr<A> &aptr_r = bptr;
                           ^        ~~~~

and gcc (Ubuntu 5.2.1-22ubuntu2) 5.2.1 20151010 gives me

error: invalid initialization of reference of type ‘std::unique_ptr<A>&’
       from expression of type ‘std::unique_ptr<B>’
       std::unique_ptr<A> &aptr_r = bptr;


To make my question more clear, let me add

class C { };

std::unique_ptr<C> cptr = std::make_unique<C>(); // (e)
std::unique_ptr<A> &&aptr_rr2 = std::move(cptr); // (f)

What is keeping (f) from compiling when (d) does? Obviously A and C are unrelated, but where is that detected when the std::unique_ptr constructor used to construct the temporary for both (d) and (f) is

template<class U, class E>
unique_ptr(unique_ptr<U, E> &&u);
  • 2
    Not really unique_ptr-specific.
    – chris
    Jan 22, 2016 at 16:18
  • 4
    (c) doesn't compile because aptr_r and bptr are of different types, and thus aptr_ cannot be a become reference of the bptr. It is like this : int x = 0; float & y = x;. But (d) compiles because a temporary object of the target type, is created out of the expression std::move(bptr).. and the temporary object binds to the rvalue reference. Note that once you create this rvalue-reference, bptr becomes null, as it has been moved.
    – Nawaz
    Jan 22, 2016 at 16:23

1 Answer 1


The key difference between your cases lies in the fact that rvalue references can bind indirectly (via a temporary), while non-const lvalue references cannot. In both (c) and (d), the initializer is not similar or convertible to the type referred to as determined in [dcl.init.ref]/(5.1), therefore [dcl.init.ref]/(5.2) must apply - immediately ruling out (c):

Otherwise, the reference shall be an lvalue reference to a non-volatile const type (i.e., cv1 shall be const), or the reference shall be an rvalue reference.

Note also that unique_ptr<A> and unique_ptr<B> are distinct, unrelated types, regardless of how A and B are related.

You can observe that rule with scalars, too:

int&& i = 0.f; // Ok
int& i = 0.f; // Not ok

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