So I figured when making function pointers, you do not need the operator & to get the address of the initial function:

#include <stdio.h>

double foo (double x){
    return x*x;

int main () {

    double (*fun1)(double) = &foo;
    double (*fun2)(double) =  foo;


    printf("fun1 = %p \t &foo = %p\n",fun1, &foo);
    printf("fun2 = %p \t  foo = %p\n",fun2,  foo);       

    int a[10];

    printf("  a = %p \n &a = %p  \n",a,&a);

    return 0;


fun1 = 0x4004f4      &foo = 0x4004f4
fun2 = 0x4004f4       foo = 0x4004f4
  a = 0x7fff26804470 
 &a = 0x7fff26804470 

Then I realized this is also true for arrays, meaning that if you have int a[10] both a and &a point to the same location. Why is that with arrays and functions? Is the address saved in a memory location that has the same address as the value(address) being saved in it?

  • I never quite understood why you didn't have to use the address-of operator to take the address of a function. I have always assumed that is just a bit of syntactic sugar. Mar 4, 2012 at 5:48
  • @Bill: Exactly! That's what I always use to think but it seems you don't need to!
    – mmirzadeh
    Mar 4, 2012 at 5:51
  • If the address was saved in the same memory location as itself, there couldn't be the actual function code/array data! You'll practically treat arrays as pointers and functions passed as arguments also as pointers, so you won't need the addressof operator. Basically, the 'value' of a function or an array is nonsense. Only the address makes sense, so you get that when you query the 'value', and also when you query the address.
    – user529758
    Mar 4, 2012 at 6:22

5 Answers 5


Given int a[10], both a and &a yield the same address, yes, but their types are different.

a is of type int[10]. When it is implicitly converted to a pointer type, the pointer is of type int* and points to the initial element of the array. &a is of type int (*)[10] (that is, a pointer to an array of ten integers). Because there can be no padding in an array, they both yield pointers with the same value, but the pointers have different types.

Functions are similar to arrays, but not entirely the same. Your function foo is of type double(double). Whenever foo is used in an expression and is not the operand of the unary & operator, it is implicitly converted to a pointer to itself, which is of type double(*)(double).

So, for all practical purposes, the name of a function and a pointer to the same function are interchangeable. There are some subtleties, all of which I discuss in an answer to "Why do all these crazy function pointer definitions all work? What is really going on?" (That question was asked about C++, but the rules for nonmember functions in C++ are the same as for functions in C.)


No, there's no extra storage dedicated to pointing to the function/array.

With most variables variable_name has a meaning other than getting the address of that variable, so you need to use &variable to get the address.

With a function or array, function_name (by itself, not followed by parentheses) doesn't have any other meaning, so there was no problem with interpreting it as taking the address of the function.

Likewise in reverse: a normal pointer needs to be dereferenced explicitly, but a pointer to a function doesn't (again, because there's no other reasonable interpretation), so given a pointer to a function like:

int (*func)(param_list);

The following are equivalent to each other -- both call whatever function func points at:


  • 2
    There seem's to be a slight different though, for int a[10], (*a)[5] is not a valid call
    – mmirzadeh
    Mar 4, 2012 at 6:02

fun and &fun are exactly the same (except that sizeof(f) is illegal). a and &a are the same up to pointer arithmetic: a + 10 == &a + 1, because 10*sizeof(*a) == sizeof(a) (where sizeof(*a) == sizeof(int)).


Basically, since the function name is "known" to be a function, the & is not strictly necessary. This behavior is the same for arrays. Recall that a function itself is not a variable, so it behaves a little differently than you might expect sometimes. If you have the 2nd edition of K&R, you can check out section 5.11 on pointers to functions, or the reference manual at the end,

Section A7.1 Pointer generation: If the type of an expression or subexpression is "array of T" for some type T, then the value of the expression is a pointer to the first object in the array, and the type of the expression is altered to "pointer to T." This conversion does not take place of the expression is the operand of the unary & operator, ... Similarly, an expression of type "function returning T," except when used as the operand of the & operator, is converted to "pointer to function returning T."

Section A7.4.2 Address Operator: The unary & operator takes the address of its operand.... The result is a pointer to the object or function referred to by the lvalue. If the type of the operand is T, the type of the result is "pointer to T."

As far as I know, this is the same for C99.


printf("fun1 = %p \t &foo = %p\n",fun1, foo);

Here your are calling foo by passing Function Pointer with pass by value and

printf("fun2 = %p \t foo = %p\n",fun2, &foo)

Here you are calling &foo by passing function Pointer with pass by reference

in both case your are calling the printf with function pointer only.

Remember foo itself is function pointer value and `not a variable.

Same happens with array. int arr[10] translates into get continuous block of 10 Integers and address of first element is stored into arr. so arr is also a pointer.

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