45

Given:

int i = 42;
int j = 43;
int k = 44;

By looking at the variables addresses we know that each one takes up 4 bytes (on most platforms).

However, considering:

int i = 42;
int& j = i;
int k = 44;

We will see that variable i indeed takes 4 bytes, but j takes none and k takes again 4 bytes on the stack.

What is happening here? It looks like j is simply non-existent in runtime. And what about a reference I receive as a function argument? That must take some space on the stack...

And while we're at it - why can't I define an array or references?

int&[] arr = new int&[SIZE]; // compiler error! array of references is illegal
  • 6
    How do you know j takes "none"? sizeof()? Or debugger inspection? (If the latter, that could just be optimizations.) – Jim Buck Jul 24 '09 at 20:24
51

everywhere the reference j is encountered, it is replaced with the address of i. So basically the reference content address is resolved at compile time, and there is not need to dereference it like a pointer at run time.

Just to clarify what I mean by the address of i :

void function(int& x)
{
    x = 10;
}

int main()
{
    int i = 5;
    int& j = i;

    function(j);
}

In the above code, j should not take space on the main stack, but the reference x of function will take a place on its stack. That means when calling function with j as an argument, the address of i that will be pushed on the stack of function. The compiler can and should not reserve space on the main stack for j.

For the array part the standards say ::

C++ Standard 8.3.2/4:

There shall be no references to references, no arrays of references, and no pointers to references.

Why arrays of references are illegal?

  • This kind of dodges the question of why j doesn't take up any stack space. If it was just "the address of i" it would take up sizeof(int*) bytes. – jalf Jul 24 '09 at 20:42
  • 3
    It doesn't take up any stack because the compiler knows the address of i. It doesn't need to store it. – Peter Ruderman Jul 24 '09 at 21:04
  • 4
    You can think of a reference variable as being a synonym for another variable. It doesn't require more storage because it isn't a real "thing", just a new name for an existing thing. A reference argument, on the other hand, is essentially a pointer value and requires the memory of a pointer. – Darryl Jul 24 '09 at 21:16
  • 4
    point is it is not simply "the address of i". It is another name for i. In some cases, this "other name" has to be implemented as a pointer, by storing the address of i, which takes up a few bytes, but that's an implementation detail, not part of the concept of a reference. – jalf Jul 25 '09 at 11:52
  • "the reference content address is resolved at compile time" Hold on, I thought that compilers didn't know the memory addresses of variables at compile time : "Local and dynamically allocated variables have addresses that are not known by the compiler when the source file is compiled". So how does this work with references ? – Julien Zakaib Jan 6 '17 at 19:24
41

How does a C++ reference look, memory-wise?

It doesn't. The C++ standard only says how it should behave, not how it should be implemented.

In the general case, compilers usually implement references as pointers. But they generally have more information about what a reference may point to, and use that for optimization.

Remember that the only requirement for a reference is that it behaves as an alias for the referenced object. So if the compiler encounters this code:

int i = 42;
int& j = i;
int k = 44;

what it sees is not "create a pointer to the variable i" (although that is how the compiler may choose to implement it in some cases), but rather "make a note in the symbol table that j is now an alias for i."

The compiler doesn't have to create a new variable for j, it simply has to remember that whenever j is referenced from now on, it should really swap it out and use i instead.

As for creating an array of references, you can't do it because it'd be useless and meaningless.

When you create an array, all elements are default-constructed. What does it mean to default-construct a reference? What does it point to? The entire point in references is that they re initialized to reference another object, after which they can not be reseated.

So if it could be done, you would end up with an array of references to nothing. And you'd be unable to change them to reference something because they'd been initialized already.

  • 4
    +1. In ISO C++, "reference is not an object". As such, it needs not have any memory representation. It's just an alias. – Pavel Minaev Jul 24 '09 at 21:17
  • @Pavel Worth noting though that if the reference is a class member, there's not really any other way to do it than to give it pointer-like storage, otherwise (even if you could full-program optimise it away) your class's size would be unpredictable and this is generally not a permitted thing (consider padding/alignment for counter-examples, though these are deterministic within ABI specifications) – Lightness Races BY-SA 3.0 Aug 15 '18 at 9:43
  • It depends. E.g. if a member reference is always initialized to a field of another member of the same object, the compiler could just treat it as an alias without using storage. – Pavel Minaev Mar 17 '19 at 2:05
11

Sorry for using assembly to explain this but I think this is the best way to understand references.

    #include <iostream>

    using namespace std;

    int main()
    {
        int i = 10;
        int *ptrToI = &i;
        int &refToI = i;

        cout << "i = " << i << "\n";
        cout << "&i = " << &i << "\n";

        cout << "ptrToI = " << ptrToI << "\n";
        cout << "*ptrToI = " << *ptrToI << "\n";
        cout << "&ptrToI = " << &ptrToI << "\n";

        cout << "refToI = " << refToI << "\n";
        //cout << "*refToI = " << *refToI << "\n";
        cout << "&refToI = " << &refToI << "\n";

        return 0;
    }

Output of this code is like this

    i = 10
    &i = 0xbf9e52f8
    ptrToI = 0xbf9e52f8
    *ptrToI = 10
    &ptrToI = 0xbf9e52f4
    refToI = 10
    &refToI = 0xbf9e52f8

Lets look at the disassembly(I used GDB for this. 8,9 and 10 here are line numbers of code)

8           int i = 10;
0x08048698 <main()+18>: movl   $0xa,-0x10(%ebp)

Here $0xa is the 10(decimal) that we are assigning to i. -0x10(%ebp) here means content of ebp register –16(decimal). -0x10(%ebp) points to the address of i on stack.

9           int *ptrToI = &i;
0x0804869f <main()+25>: lea    -0x10(%ebp),%eax
0x080486a2 <main()+28>: mov    %eax,-0x14(%ebp)

Assign address of i to ptrToI. ptrToI is again on stack located at address -0x14(%ebp), that is ebp – 20(decimal).

10          int &refToI = i;
0x080486a5 <main()+31>: lea    -0x10(%ebp),%eax
0x080486a8 <main()+34>: mov    %eax,-0xc(%ebp)

Now here is the catch! Compare disassembly of line 9 and 10 and you will observer that ,-0x14(%ebp) is replaced by -0xc(%ebp) in line number 10. -0xc(%ebp) is the address of refToI. It is allocated on stack. But you will never be able to get this address from you code because you are not required to know the address.

So; a reference does occupy memory. In this case it is the stack memory since we have allocated it as a local variable. How much memory does it occupy? As much a pointer occupies.

Now lets see how we access the reference and pointers. For simplicity I have shown only part of the assembly snippet

16          cout << "*ptrToI = " << *ptrToI << "\n";
0x08048746 <main()+192>:        mov    -0x14(%ebp),%eax
0x08048749 <main()+195>:        mov    (%eax),%ebx
19          cout << "refToI = " << refToI << "\n";
0x080487b0 <main()+298>:        mov    -0xc(%ebp),%eax
0x080487b3 <main()+301>:        mov    (%eax),%ebx

Now compare the above two lines, you will see striking similarity. -0xc(%ebp) is the actual address of refToI which is never accessible to you. In simple terms, if you think of reference as a normal pointer, then accessing a reference is like fetching the value at address pointed to by the reference. Which means the below two lines of code will give you the same result

cout << "Value if i = " << *ptrToI << "\n";
cout << " Value if i = " << refToI << "\n";

Now compare this

15          cout << "ptrToI = " << ptrToI << "\n";
0x08048713 <main()+141>:        mov    -0x14(%ebp),%ebx
21          cout << "&refToI = " << &refToI << "\n";
0x080487fb <main()+373>:        mov    -0xc(%ebp),%eax

I guess you are able to spot what is happening here. If you ask for &refToI, the contents of -0xc(%ebp) address location are returned and -0xc(%ebp) is where refToi resides and its contents are nothing but address of i.

One last thing, Why is this line commented?

//cout << "*refToI = " << *refToI << "\n";

Because *refToI is not permitted and it will give you a compile time error.

  • Is there any reason for ref to occupy memory instead of aliasing in this particular code? It would be nice to see compiler version and compile options. – artin Oct 7 '19 at 14:53
10

In practice, a reference is equivalent to a pointer, except that the extra constraints on how references are allowed to be used can allow a compiler to "optimize it away" in more cases (depending on how smart the compiler is, its optimization settings, etc etc of course).

8

You can't define an array of references because there is no syntax to initialize them. C++ does not allow uninitialized references. As for your first question, the compiler is under no obligation to allocate space for unnecessary variables. There is no way to have j point to another variable, so it's effectively just an alias for i in the function's scope, and that's how the compiler treats it.

6

Something that is only mentioned in passing elsewhere - how to get the compiler to devote some storage space to a reference:

class HasRef
{
    int &r;

public:
    HasRef(int &n)
        : r(n) { }
};

This denies the compiler the opportunity to simply treat it as a compile-time alias (an alternative name for the same storage).

3

References don't actually exist physically until they need to have a physical manifestation (i.e., as a member of an aggregate).

Having an array of references is illegal probably due to the above. But nothing prevents you from creating an array of structs/classes that have reference members.

I'm sure someone will point out the standard clause that mentions all this.

3

It's not fixed - the compiler has a great freedom in how to implement a reference on a case by case basis. So in your second example it treats j as an alias for i, nothing else needed. When passing a ref parameter it could also use a stack-offset, again no overhead. But in other situations it could use a pointer.

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