int main(void) {
    int x[4];
    printf("%p\n", x);
    printf("%p\n", x + 1);
    printf("%p\n", &x);
    printf("%p\n", &x + 1);


$ ./a.out

I expect that the following is the output of the above program. For example:

x        // 0x100
x+1      // 0x104  Because x is an integer array
&x       // 0x100  Address of array
&x+1     // 0x104

But the output of the last statement is different from whast I expected. &x is also the address of the array. So incrementing 1 on this will print the address incremented by 4. But &x+1 gives the address incremented by 10. Why?

  • 3
    It seems that &x+1 gives you the address after the array memory (4*4=16 or 0x100)...
    – alnet
    Nov 18, 2015 at 9:09
  • 30
    This is one of those cases where you clearly see the difference between a pointer and an array. Nov 18, 2015 at 9:15
  • 15
    Important clarification: those addresses are in hex. "Incremented by 4" means a 0x4 increment as well, but "incremented by 0x10" means "incremented by 16," not by 10.
    – kdbanman
    Nov 18, 2015 at 17:36
  • 2
    @LukePark It should actually be of type int (*)[4] Nov 18, 2015 at 21:54
  • 1
    Just a note (unrelated to the question you are asking): Your program has undefined behaviour (at least under C99), because you need to cast the pointers to void * before passing them to printf (because it is a variadic function). See Printing pointers in C.
    – sleske
    Nov 19, 2015 at 10:09

5 Answers 5

x -> Points to the first element of the array.
&x ->Points to the entire array.

Stumbled upon a descriptive explanation here: http://arjunsreedharan.org/post/69303442896/the-difference-between-arr-and-arr-how-to-find

SO link: Why is arr and &arr the same?


In case 4 you get 0x100 + sizeof x and sizeof x is 4 * sizeof int = 4 * 4 = 16 = 0x10.

(On your system, sizeof int is 4).

  • 1
    Added the sizeof int step as it varies from system to system.
    – Bathsheba
    Nov 18, 2015 at 9:17

An easy thumbrule to evaluate this is:

Any pointer on increment points to the next memory location of its base type.

The base type of &x here is int (*p)[4] which is a pointer to array of 4 integers.

So the next pointer of this type will point to 16 bytes away (assuming int to be 4 bytes) from the original array.


Even though x and &x evaluate to the same pointer value, they are different types. Type of x after it decays to a pointer is int* whereas type of &x is int (*)[4].

sizeof(x) is sizeof(int)*4.

Hence the numerical difference between &x and &x + 1 is sizeof(int)*4.

It can be better visualized using a 2D array. Let's say you have:

int array[2][4];

The memory layout for array is:

|   |   |   |   |   |   |   |   |

array[0]        array[1]
|               |
|   |   |   |   |   |   |   |   |

If you use a pointer to such an array,

int (*ptr)[4] = array;

and look at the memory through the pointer, it looks like:

ptr             ptr+1
|               |
|   |   |   |   |   |   |   |   |

As you can see, the difference between ptr and ptr+1 is sizeof(int)*4. That analogy applies to the difference between &x and &x + 1 in your code.


Believe it or not, the behaviour of your program is undefined!

&x + 1 is actually pointing to just beyond the array, as @i486's answer cleverly points out. You don't own that memory. Even attempting to assign a pointer to it is undefined behaviour, let alone attempting to dereference it.

  • 9
    I always thought that this was defined since taking a pointer to one-past the end of an array was defined. I guess it may be different since this isn't an array of int[4]s, it's only one.
    – chbaker0
    Nov 18, 2015 at 11:03
  • 9
    @Bathsheba: Can you cite the standard here? Usually, past the end pointers are well-defined things; why should it not be in this particular case?
    – user1084944
    Nov 18, 2015 at 11:57
  • 5
    @Bathsheba: As Hurkyl mentions, there should be a blurb in the Standard about how "scalar" objects are treated as arrays of size of 1 for the purpose of "past-the-end" pointers. I would expect this to hold in this case (since an array can contain arrays), but the Standard regularly defies my expectations. Nov 18, 2015 at 12:36
  • 6
    @Bathsheba You are not allowed to "look" beyond the array, but IIRC you are explicitly allowed to store that address in a pointer. I think this answer (and others to that question) cover this.
    – TripeHound
    Nov 18, 2015 at 13:59
  • 12
    @Bathsheba C11 6.5.6 p7: "a pointer to an object that is not an element of an array behaves the same as a pointer to the first element of an array of length one". Not even a note - this is main text. (immediately precedes the stuff about one-past-the-end) No UB here. Scalars are exactly the same as arrays for pointer arithmetic purposes. Nov 18, 2015 at 16:19

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