2

I know this question has probably been asked in many different ways, but I'm adding my own because this is still unclear for me.

Consider this code:

long double q = 1.2;
long double &p = q;
cout << sizeof(p) << endl;`

long double is 12 bytes on my machine, and the output of the code is as expected 12 because as the standard says:

When applied to a reference or a reference type, the result is the size of the referenced type. (ISO C++ $5.3.3/2)

But as you most likely all know, references implementation is free, and thus, as the standard says again:

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

So it seems that tomorrow I can come up with my own reference implementation that takes 200 bytes and make sure that the sizeof operator returns the right object size (instead of returning what would be the true implementation size of my reference)

So my question is actually extremely simple:

Can we rely on the sizeof operator to return the real memory occupation of a class when it contains, specifically, reference members?

  • 6
    You do realize that there's a big difference between taking the sizeof of a variable that happens to be a reference, and taking the sizeof a type that has a non-static data member that is a reference, right? – Nicol Bolas Jan 29 '16 at 15:03
  • 2
    I don't even understand the question. Are you asking whether you can rely on sizeof telling you the correct size of something? Yes. Of course you can. – Jonathan Wakely Jan 29 '16 at 15:04
  • You do reaize that to do So it seems that tomorrow i can come up with my own reference implementation that takes 200 bytes and make sure that the sizeof operator returns the right object size. you would have to make your own compiler right? – NathanOliver Jan 29 '16 at 15:05
  • 2
    Read Nicol's comment above. If you have struct S { long double& d; }; then sizeof(S) != sizeof(long double) on most platforms. The compiler does not get confused, it's not stupid. It doesn't implement sizeof(S) by adding together the result of applying sizeof to each member, so that it would get sizeof(S::d) which would be the size of the referenced type, not the storage needed for the reference. – Jonathan Wakely Jan 29 '16 at 15:08
  • 2
    Don't use std::endl unless you need the extra stuff that it does. '\n' starts a new line. – Pete Becker Jan 29 '16 at 15:11
6

Compare and contrast:

struct container {
  long double& dbl;
};

std::cout << sizeof(container::dbl) << '\n';
std::cout << sizeof(container)      << '\n';

(Live on ideone)

One line tells you the size of a referred-to object. The other tells you the size of the structure containing the reference.

That behaviour is not by chance. It's defined by the standard and yes, you can rely on it.

There seems to be an assumption behind this question that the behaviour of the sizeof operator with a reference or reference type is somehow arbitrary and conventional. That is not the case; it falls out of the same logic that generally applies to references.

If I have

long double dbl;

then any use of dbl in its scope is an lvalue, which is to say a reference. That is necessary in order for it to be possible to assign a value to dbl. So the type of dbl (as revealed, for example, by decltype(dbl)) is long double&, not long double.

It would be ridiculous for sizeof(dbl) to return the size of the reference itself rather than the size of the referenced object.

Once you put the reference into a structure, you have a completely different beast. As part of an object, the reference occupies space, which cannot be optimized away unless the entire object containing it can be optimized away.

  • ok, pretty clear, so indeed as Nicol has pointed first, i was confused between size of a class/struct type vs size of a reference variable. Upvoted (+ Nicol's) – Romain227 Jan 29 '16 at 15:20
  • Well, i thought i got it perfectly but actually no : why do we actually have to make this distinction? between sizeof( a class containing a ref) and sizeof(a ref)? – Romain227 Jan 29 '16 at 16:26
  • This is what i understand from everything I read : in the case of a ref variable (see my example), the compiler would be easily able to make it completely disappear (thus printing the variable q directly), however, in some other (more complex than mine) cases, it might have to to keep track of it, thus having to really create a reference – Romain227 Jan 29 '16 at 16:27
  • Because of these two cases, I guess people concluded "well, let's s agree to make sizeof(reference) return the size of the referenced object. If my explanation is correct, does this mean that in the case of a struct containing a ref (your example), the reference member IS SYSTEMATICALLY CREATED? without the optim' i mentioned ? (make the variable disappear and point directly to the ref object)? This is the only explanation i see as to why both sizeof are different – Romain227 Jan 29 '16 at 16:27
  • 1
    @Romain227: It took me a long time to really understand C++ references, too, and that was part of my struggle to accept C++ as a valid model. Probably my ill-informed rants are still kicking around to embarrass me. A variable declared as a reference is not different from a variable declared as a value. If I declared double d, &rd=d, both d and rd are of type double&; if they are used in a context which requires a value, the conversion will be automatic. But they are not different things. Putting a reference in a struct, however, is different. – rici Jan 29 '16 at 17:00
0

If you question if you can rely on sizeof of the following type:

struct A
{
   int& r;
};

Then yes - you can rely on sizeof in structs containing references.

E.g. this code is safe:

   char* buffer = new char[sizeof(A)];
   int value;
   A* valueRef = new (buffer) A{value};

You have enough bytes in buffer to store A object.

0
struct S {
    long double& d;
};

static_assert(sizeof(S::d) == sizeof(long double));
static_assert(sizeof(S) != sizeof(S::d));  // true on most platforms

The compiler is smart enough to know the size of S, it doesn't get confused and think it is sizeof(S::d) because that would be stupid.

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