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I've read in multiple sources that a C++ reference is no more than a pointer with compile time restrictions.

If this is true, how come I am forced to dereference a pointer in order to pass it to a function that expects a parameter?

void FooRef(const int&);
void FooPointer(const int*);

int main()
{
    int* p = new int(5);
    FooPointer(p);
    FooRef(*p); // why do I have to dereference the pointer?

    ...
}

As I understand it, if I were to pass an int to FooRef the compiler would create the pointer (reference) from the address of the variable for me, but if the type is already a pointer then dereferencing it seems pointless. It seems to me like I am dereferencing a pointer, just to let the compiler create another pointer from the dereferenced value which seems senseless to me.
Wouldn't it be simpler / more performant to just copy the pointer instead of just referencing+derferencing the value? (Perhaps this is really what's happening?)

Am I missing something here? and does calling FooRef in such a scenario be slower than calling FooPointer?
And do references and pointers really produce the same code during compilation?

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A reference is IMO much more an alias - another name for an object. It might be implemented by a pointer sometimes (it's not always necessary, the compiler might substitute it for the original name in some cases). –  dyp May 6 '13 at 0:46
4  
the dereference operation here is nothing more than syntactic sugar. You have to write a dereference, but none actually is performed. –  Hal Canary May 6 '13 at 0:48
    
Note you can call FooRef(5); but not FooPointer(&5);. –  dyp May 6 '13 at 0:49
    
Another example: int a = 42; int& b = a; b = 33; might as well be optimized to int a = 42; a = 33; –  dyp May 6 '13 at 0:54
4  
@Acidic: No, the language does not guarantee that. As far as the language specification is concerned, the compiler writers could decide to put a 10 minute sleep in your code whenever you dereference a pointer, and that would be a valid decision. You just have to trust that the compiler authors are not idiots, or check the code output yourself. –  Benjamin Lindley May 6 '13 at 1:27

6 Answers 6

The fact that references can be implemented in terms of pointers under the hood is irrelevant. Many programming concepts can be implemented in terms of other things. You may as well ask why we have while loops when while can be implemented in terms of goto or jmp. The point of different language concepts is to make things easier for the programmer, and references are a language-concept designed for the convenience of the programmer.

You probably are misunderstanding the purpose of references. References give you the positive side of pointers (cheap to pass around), but since they have the same semantics as regular values, they remove a lot of the dangers that come with using pointers: (pointer arithmetic, dangling pointers, etc.) More importantly, a reference is a totally different type than a pointer in the C++ type-system, and it would be madness to allow the two to be interchangeable (that would defeat the purpose of references.)

Reference syntax is designed on purpose to mirror the syntax of regular value semantics - while at the same time providing you with the ability to cheaply pass around memory addresses instead of copying entire values.

Now, turning to your example:

FooRef(*p); // why do I have to dereference the pointer?

You have to dereference the pointer here because FooRef takes a reference to an int, not a reference to an int*. Note that you can also have a reference to a pointer:

void FooPointerRef(const int*&);

A function that takes a reference to a pointer enables you to modify the memory address of the pointer from within the function. In your example, you have to explicitly dereference the pointer to mirror value semantics. Otherwise, someone looking at the function call FooRef(p) is going to think that FooRef either takes a pointer-by-value or a pointer-by-reference - but NOT a (non-pointer) value or a reference.

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My question wasn't about the syntax, but about why I am seemingly dereferencing a value just to have the compiler reference it in the same line. –  Acidic May 6 '13 at 0:56
    
Because what if you wanted a reference to a pointer? –  Charles Salvia May 6 '13 at 0:57
    
But I don't. I want to pass a pointer by value (if a reference really is a pointer) instead of having to dereference it just so that the compiler can create a pointer from the dereferenced value. –  Acidic May 6 '13 at 1:08
    
@Acidic void FooRef(const int&); is designed/intended to have the same calling syntax as void FooRef(int); There's basically no difference for an int (concerning performance), but a big difference for objects of class type. –  dyp May 6 '13 at 1:15
    
@DyP you don't need to teach me the basics or explain to me the purpose of references... –  Acidic May 6 '13 at 1:18

The actual argument for a parameter passed by reference is consistently the same type as the parameter, whether it is obtained by dereferencing a pointer or not, and regardless how passing-by-reference is implemented.

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Your second comment would be the start of a good answer. For the first comment, I did not mean to imply multiple implementations -- only that the consistency of the language in this case was more valuable than worrying about the implementation by the compiler. –  Andy Thomas May 6 '13 at 3:06
    
I don't know what comments those are, because some sociopath has gone through and deleted those and several other of my (and other people's) comments. –  Jim Balter May 6 '13 at 6:02
1  
Disturbing. You had noted that passing-by-reference could only be implemented by passing the address, and corrected the OP's assumption that work was required at runtime when a dereferenced pointer was passed to a reference parameter. –  Andy Thomas May 6 '13 at 13:12

I've read in multiple sources that a C++ reference is no more than a pointer with compile time restrictions.

Don't believe everything you read.

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Is that a wrong assumption? –  Acidic May 6 '13 at 0:56
    
Its a dangerous assumption. –  JonnyRo May 6 '13 at 1:07
2  
@Acidic It's not an assumption, it's a falsehood ... or a misunderstanding of what you read. Conceptually, references and pointers are quite different things. The fact that, in most implementations, the code generated for calling foo(int*) and foo(int&) both pass an address is another matter. –  Jim Balter May 6 '13 at 1:22
    
@JimBalter again, my question was never about the conceptual differences. My question was about the possible performance difference between the two. –  Acidic May 6 '13 at 1:24
1  
@Acidic You stated that "a C++ reference is no more than a pointer" -- again, that's false and conceptually confused. You deeply misunderstand the language, the concepts, and the nature of compilers. Compiler writers try to generate as efficient code as the language specification allows. That's the answer to your question. –  Jim Balter May 6 '13 at 1:28

Pointers in C++ are distinct data types. If C++ would have coerced an X* pointer to an X& reference, then how should the following code behave?

int x=5;
void* px = (void*)&x;
void*& prx = px;

Besides, things will be very weird - since what you want is silence dereference, passing NULL will result in segmentation in the caller code, but the caller will have no syntactic way to see it.

And what will you get in return to this confusion? Some more confusion between implementation details and language abstractions. nothing more.

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Well there are plenty of answers here, just see for yourself:

#include <cstdio>

int main(void) 
{
    int p = 5;
    int *p_ptr = &p;
    int &p_ref = p;


    printf("Address of p     = %x\n", &p);
    printf("Address of p_ref = %x\n", &p_ref);
    printf("Value   of p_ptr = %x\n", p_ptr);
    printf("Address of p_ptr = %x\n", &p_ptr);
    return 0;
}

Output:

Address of p     = 16fd80
Address of p_ref = 16fd80
Value   of p_ptr = 16fd80
Address of p_ptr = 16fd88

So, as far as references are concerned--a reference has the same address as the object being referenced. A pointer's value is the address of the object being pointed to (or referenced), while still having its own separate address.

Of course, what is produced: (cl /FA reftest.cpp)

_TEXT   SEGMENT
p$ = 32                         ; all our variables
p_ptr$ = 40
p_ref$ = 48
main    PROC
; ... snip ...
mov DWORD PTR p$[rsp], 5        ; p = 5

lea rax, QWORD PTR p$[rsp]      ; p_ptr = &p
mov QWORD PTR p_ptr$[rsp], rax

lea rax, QWORD PTR p$[rsp]      ; p_ref = p
mov QWORD PTR p_ref$[rsp], rax

Looks the same to me. However consider this: (cl /O2 /FA reftest.cpp)

_TEXT   SEGMENT
p$ = 48
p_ptr$ = 56
main    PROC     ; notice p_ref is gone
; ... snip ...

The best part about references is that they are easy to optimize out of code. A reference can only ever refer to one object during its lifetime, a pointer could reference many different objects during its lifetime, and the compiler must be wary of that fact.

(Note: This is obviously just the assembly resulting from Microsoft's compiler, while the results may vary from compiler to compiler, I suspect most compiler's can pull this one off)

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1  
"So maybe references could be hypothetically an extra instruction or two" -- No, absolutely not. A reference to a value must reference that value ... the extra work the OP fears cannot be done, else it would be a reference to a copy. –  Jim Balter May 6 '13 at 1:53
    
I'm going to edit that out, you are absolutely right. The more I think about it, the more I realize just how ridiculous it sounds. Following the memory address, to get the value's memory address... IIRC (my assembly's rusty), getting the address of an object doesn't make sense in the first place, because the only way to access the object is with its memory address. –  void ptr May 6 '13 at 2:08
    
Note that, even in C, int* q; int* p = &*q; doesn't do any extra work ... it can't. It's semantically identical to p = q; –  Jim Balter May 6 '13 at 2:12

It would certainly create some interesting confusing cases:

int a(int& x)   {    return x + 1;    }
int b(int& x)   {    return x + 2;    }

// now for the fun part, 'b' has another valid overload
int b(int* x)   {    return *x + 3;   }


int  myInt = 1;
int* p = &myInt; // get a pointer to myInt

cout << a(p);    // calls int a(int&) by your rule.  Syntax error in real C++
cout << b(p);    // calls int b(int*), by your rule and real C++.
                 // Isn't that confusing?

cout << a(*p);   // valid, always calls int a(int&)
cout << b(*p);   // valid.  Always calls b(int&)
                 // This isn't confusing, in real C++ or with your rule

It would be confusing if you had to constantly remember whether or not to dereference.

The other reason for it is that it simplifies the specification. The compiler is allowed to assume that a reference ALWAYS refers to a valid object. It gets to make optimizations based on that assumption. The way it keeps that guarantee is by making it illegal to deference the null pointer. If you didn't have to dereference p in the example above, then it couldn't get those guarantees.

References and Pointers have very similar behavior except for the following:

  • Pointers can point to null, while references cannot refer to null
  • References can refer to values which do not have addresses (such as values stored in registers). Pointers must always be stored in memory, which can be slower.

Could they have written C++ where you can automatically convert from pointer to reference? Sure. There is no real technical reason why they couldn't have. But the authors of the language decided that it provided more problems than solutions.

There is an old adage, "A language is not complete when you've put everything you can think of into it. A language is complete when you've taken everything out that you possibly can." Many will argue C++ has too much baggage to have held true to this adage, but it still tries whenever it can.

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