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Is the following legal in C++?

As far as I can tell, Reference has a trivial destructor, so it should be legal.
But I thought references can't be rebound legally... can they?

template<class T>
struct Reference
{
    T &r;
    Reference(T &r) : r(r) { }
};

int main()
{
    int x = 5, y = 6;
    Reference<int> r(x);
    new (&r) Reference<int>(y);
}
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3  
Not your downvoter, but I'm going to guess it was a knee jerk reaction to the horror of doing such a thing. Interesting question, though. –  Fred Larson Jan 13 at 21:40
3  
These are definitely cases where the downvote should be undone by a mod or a community manager. It's just not justified. –  user529758 Jan 13 at 21:42
    
@FredLarson: Haha probably. Thanks! :) –  Mehrdad Jan 13 at 21:51
    
Maybe I shouldn't have mentioned the triviality of the destructor at all -- I just realized that I could very well have done r.~Reference<int>() before the placement-new, so whether or not the destructor is trivial doesn't really affect the question... –  Mehrdad Jan 13 at 22:01
    
@Mehrdad, But it did bring up some interesting discussion, which I find very nice. –  chris Jan 14 at 0:21

4 Answers 4

up vote 4 down vote accepted

I think I found the answer in a passage below the "quoted" one that talks about trivial dtor / dtor side effects, namely [basic.life]/7:

If, after the lifetime of an object has ended and before the storage which the object occupied is reused or released, a new object is created at the storage location which the original object occupied, a pointer that pointed to the original object, a reference that referred to the original object, or the name of the original object will automatically refer to the new object and, once the lifetime of the new object has started, can be used to manipulate the new object, if:

  • the storage for the new object exactly overlays the storage location which the original object occupied, and

  • the new object is of the same type as the original object (ignoring the top-level cv-qualifiers), and

  • the type of the original object is not const-qualified, and, if a class type, does not contain any non-static data member whose type is const-qualified or a reference type, and

  • the original object was a most derived object of type T and the new object is a most derived object of type T (that is, they are not base class subobjects).

By reusing the storage, we end the lifetime of original object [basic.life]/1

The lifetime of an object of type T ends when:

  • if T is a class type with a non-trivial destructor, the destructor call starts, or

  • the storage which the object occupies is reused or released.

So I think [basic.life]/7 covers the situation

Reference<int> r(x);
new (&r) Reference<int>(y);

where we end the lifetime of the object denoted by r, and create a new object at the same location.

As Reference<int> is a class type with a reference data member, the requirements of [basic.life]/7 are not fulfilled. That is, r might not even refer to the new object, and we may not use it to "manipulate" this newly created object (I interpret this "manipulate" also as read-only accesses).

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Hmm although I've first read the conditions under which the lifetime ends as either you call the dtor, or you reuse the storage, I now think it's a strict separation: either it has a non-trivial dtor and you call it, or you reuse the storage. The example in [basic.life]/7 is not really helpful, as the dtor is trivial anyway (are you here, @Mehrdad?) –  dyp Jan 15 at 20:15
    
Yeah passage 1 seems to put a strict separation between the two, i didn't see it initially so I thought a lifetime can only end if there's a nontrivial dtor (from the other passage). The answer makes sense and is probably correct... let me think about it a bit more but I'll probably accept it, thanks! +1 –  Mehrdad Jan 15 at 20:20

You aren't rebinding a reference, you're creating a new object in the memory of another one with a placement new. Since the destructor of the old object was never run I think this would be undefined behavior.

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2  
Could you elaborate on the destructor not being run? If it's trivial, is it really UB for it not to run? –  chris Jan 13 at 21:42
4  
It's not automatically UB if a destructor is not run before the storage for an object is re-run, only "any program that depends on the side effects produced by the destructor has undefined behavior" (ISO/IEC 14882:2011 3.8 [basic.life] / 4) which leaves open the possibility for whole classes of programs to omit the call of destructors - even non-trivial ones - and not have UB. –  Charles Bailey Jan 13 at 21:48
    
Yeah I think you missed the point of the question, @CharlesBailey hit the nail on the head. In fact I had no idea that non-trivial destructors could be omitted at will if we didn't depend on their effects... –  Mehrdad Jan 13 at 21:51
1  
@CharlesBailey, thanks for the reference - is the destructor of a reference guaranteed to have no side effects? I can't think of a situation where it would, but my imagination has failed me before. –  Mark Ransom Jan 13 at 22:17
1  
I don't think that references even have destructors. –  Charles Bailey Jan 13 at 23:41

There is no reference being rebound in your example. The first reference (constructed on line two with the name r.r) is bound to the int denoted by x for the entire of its lifetime. This reference's lifetime is ended when the storage for its containing object is re-used by the placement new expression on line three. The replacement object contains a reference which is bound y for its entire lifetime which lasts until the end of its scope - the end of main.

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1  
I wasn't so hooked up on the terminology ("rebinding") than the actual code... so the code is legal/well-defined? –  Mehrdad Jan 13 at 21:54
    
There is nothing wrong with the code, there is no UB at the end of main because Reference has a trivial destructor. Even if it didn't there would still be no UB because you ensure that an object of the correct type exists at the storage for r at the point where the implicit destructor call takes place - the end of main. –  Charles Bailey Jan 13 at 21:56
    
@Mehrdad I would have doubts about amiguities with r :/ ... –  πάντα ῥεῖ Jan 13 at 21:58
1  
Couldn't an optimizing compiler conclude that since the reference is known in that context and can't be rebound and hasn't been destroyed, that it could use the underlying source directly and miss the reconstruction entirely? –  Mark Ransom Jan 13 at 22:56
2  
@MarkRansom: but the "hasn't been destroyed part" would be an incorrect assumption because reusing an object's storage for a different object destroys the original object. This implies that such an optimization would be non-conforming. –  Charles Bailey Jan 13 at 23:40

Probably this does not answer your question, but you can make use of std::reference_wrapper, I think it accomplishes quite the same as your code:

#include <iostream>
#include <functional>
int main()
{
    int x = 5, y = 6;    
    std::reference_wrapper<int> rf(x);
    std::cout << rf << std::endl;
    rf = y;
    std::cout << rf << std::endl;
}
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