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In the code below, function-pointer and what i considered as "function-reference" seems to have identical semantics:

#include <iostream>
using std::cout;

void func(int a) {
    cout << "Hello" << a << '\n';
}
void func2(int a) {
    cout << "Hi" << a << '\n';
}

int main() {
    void (& f_ref)(int) = func;
    void (* f_ptr)(int) = func;

    // what i expected to be, and is, correct:
    f_ref(1);
    (*f_ptr)(2);

    // what i expected to be, and is not, wrong:
    (*f_ref)(4); // i even added more stars here like (****f_ref)(4)
    f_ptr(3);    // everything just works!

    // all 4 statements above works just fine

    // the only difference i found, as one would expect:
//  f_ref = func2; // ERROR: read-only reference
    f_ptr = func2; // works fine!
    f_ptr(5);

    return 0;
}

I used gcc version 4.7.2 in Fedora/Linux

UPDATE

My questions are:

  1. Why function pointer does not require dereferencing?
  2. Why dereferencing a function reference doesn't result in an error?
  3. Is(Are) there any situation(s) where I must use one over the other?
  4. Why f_ptr = &func; works? Since func should be decayed into a pointer?
    While f_ptr = &&func; doesn't work (implicit conversion from void *)
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8  
Reminds me this image :D (no offense intended, just 4 fun) – LihO Oct 5 '13 at 17:19
up vote 7 down vote accepted

Functions and function references (i.e. id-expressions of those types) decay into function pointers almost immediately, so the expressions func and f_ref actually become function pointers in your case. You can also call (***func)(5) and (******f_ref)(6) if you like.

It may be preferable to use function references in cases where you want the &-operator to work as though it had been applied to the function itself, e.g. &func is the same as &f_ref, but &f_ptr is something else.

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is that an implementation bug? 'coz that goes against our intuitive concepts of "typing", right? I have also seen something like void (*&f)(void) as a parameter to function - * and & used together.. how come? – John Oct 5 '13 at 17:27
    
It's not a bug, just the way the language is defined. In expressions there are basically no functions, there are only ever function pointers; decay takes care of making the "obvious" syntax work (i.e. you can type f(1) rather than the more cumbersome (&f)(1)). – Kerrek SB Oct 5 '13 at 17:29
    
@John: Compare to the way arrays are handled; they can't be passed by value, so in a function prototype, int x[] (and for that matter (int x[10]) is equivalent to int *x; since receiving a C array by value isn't legal, they let array declaration syntax be used as syntactic sugar for receiving a pointer. – ShadowRanger Dec 23 '15 at 15:24

"Why function pointer does not require dereferencing?"

Because the function identifier itself is actually a pointer to the function already:

4.3 Function-to-pointer conversion
§1 An lvalue of function type T can be converted to an rvalue of type “pointer to T.” The result is a pointer to the function.

"Why dereferencing a function reference doesn't result in an error?"

Basically you can look at defining a reference as defining an alias (alternative name). Even in the standard in 8.3.2 References in part addressing creating a reference to an object, you will find:
"a reference can be thought of as a name of an object."

So when you define a reference:

void (& f_ref)(int) = func;

it gives you the ability to use f_ref almost everywhere where it would be possible to use func, which is the reason why:

f_ref(1);
(*f_ref)(4);

works exactly the same way as using the func directly:

func(1);
(*func)(4);
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See here.

The address-of operator acts like you would expect, as it points to a function but cannot be assigned. Functions are converted to function pointers when used as rvalues, which means you can dereference a function pointer any number of times and get the same function pointer back.

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