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From this question, and consequently, from the Standard (ISO C++-03):

It is unspecified whether or not a reference requires storage (3.7).

In some answers in that thread, it's said that references have, internally, the same structure of a pointer, thus, having the same size of it (32/64 bits).

What I'm struggling to grasp is: how would a reference come not to require storage?

Any sample code exemplifying this would be greatly appreciated.

Edit: From @JohannesSchaub-litb comment, is there anything like, if I'm not using a const &, or if I'm using a const & with default value, it requires allocation? It seems to me, somehow, that there should be no allocations for references at all -- except, of course, when there are explicit allocations involved, like:

A& new_reference(*(new A())); // Only A() instance would be allocated,
                              // not the new_reference itself

Is there any case like this?

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They can be optimized out by the compiler, for example. Or a weird architecture may use a different way of storing them. In some cases they don't have to be stored at all; int a = 0; int& b = a; even storing b here is a waste of memory. Note that references are not objects and shouldn't be thought of as such. –  user142019 Feb 10 '13 at 16:13
A reference is just an alias. I believe for the compiler it is just a matter of allowing different names for the same variable. –  Andy Prowl Feb 10 '13 at 16:13
You know that *(new A()) kills a kitten, right? –  fredoverflow Feb 10 '13 at 18:00

2 Answers 2

up vote 5 down vote accepted

Take something simple:

int foo() {
  int  x = 5;
  int& r = x;
  r = 10;
  return x;

The implementation may use a pointer to x behind the scenes to implement that reference, but there's no reason it has to. It could just as well translate the code to the equivalent form of:

int foo() {
  int x = 10
  return x;

Then no pointers are needed whatsoever. The compiler can just bake it right into the executable that r is the same as x, without storing and dereferencing a pointer that points at x.

The point is, whether the reference requires any storage is an implementation detail that you shouldn't need to care about.

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what's the normative use of the rule he quoted? Can you show an example that would break if references required storage? –  Johannes Schaub - litb Feb 10 '13 at 16:18
@JohannesSchaub-litb Why does there have to be such an example? It says it is unspecified whether they require storage, not that they must not require storage. –  Joseph Mansfield Feb 10 '13 at 16:21
using storage is not part of the observable behavior of an implementation, so there doesn't need to be a rule granting the non-usage. There is no normative rule that says "Whether or not functions require storage is unspecified.", even though C++ says in a note that functions may use storage in the way objects do. –  Johannes Schaub - litb Feb 10 '13 at 16:31
In your example, an implementation may use no storage for x either. It can just erase the whole body of foo. –  Johannes Schaub - litb Feb 10 '13 at 16:33
From @JohannesSchaub-litb comment, is there anything like, if I'm not using a const &, or if I'm using a const & with default value, it requires allocation? From your example it seems somehow that there should be no allocations at all -- except, of course, when you're explicitly allocating something. Is there any case like this? I'll add this to the question. –  Rubens Feb 10 '13 at 16:38

I believe the key point to understanding is that reference types are not object types.

An object type is a (possibly cv-qualified) type that is not a function type, not a reference type, and not a void type (§3.9[basic.types]/8)

Objects require storage ("An object is a region of storage." -- §1.8[intro.object]/1)

Moreover, C++ programs operate on objects: "The constructs in a C++ program create, destroy, refer to, access, and manipulate objects." -- same paragraph

So, when the compiler encounters a reference in the program, it is up to the compiler whether it has to synthesize an object (typically of a pointer type), and, therefore, use some storage, or find some other way to implement the desired semantics in terms of object model (which may involve no storage).

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