int* myPointer = new int[100];

// ...

int firstValue = *(myPointer + 0);
int secondValue = myPointer[1];

Is there any functional difference between *(myPointer + index) and myPointer[index]? Which is considered better practice?

  • 26
    You forgot: int thirdValue = 2[myPointer]; Which crazily also works. – Martin York Jan 7 '11 at 8:41
  • 2
    @Martin Really? Huh. Learn something new every day, I guess. – Maxpm Jan 7 '11 at 14:36
  • 3
    @Maxpm - Array subscripting is commutative in C – jww Jun 3 '13 at 0:42
  • 1
    There is no difference. array[index] and index[array] are just syntax sugar for *(array + index). – Braden Best Aug 17 '16 at 6:00

Functionally, they are identical.

Semantically, the pointer dereference says "Here's a thing, but I really care about the thing X spaces over", while the array access says "Here's a bunch of things, I care about the Xth one."

In most cases, I would prefer the array form.

  • 3
    Someone voted this down? I wish people would comment, and tell me what is wrong with my answer. – Mike Caron Jan 8 '11 at 4:58
  • 1
    Wasn't me, but in this case it's not the Xth but the X+1th. – Marcus Borkenhagen Jan 12 '11 at 22:17
  • 7
    @Fritschy: Well, as programmers, I assume we count from 0 ;) – Mike Caron Jan 14 '11 at 7:40
  • 3
    Let's not start a flame war, shall we :) – Marcus Borkenhagen Jan 14 '11 at 7:51
  • 2
    +1 for the semantics, great summary. I'm often tempted to use *(p + offset) whenever I have a pointer, for some idea of consistency (vs 'actual' arrays), but in practical terms I find p[offset] looks better and more intuitive in most cases, relegating the + form to 'offset from this other thing'. – underscore_d Jan 16 '16 at 11:40

There is no difference between

*(array+10); //and

but guess what? since + is commutative

 *(10 + array); //is all the same
 10[array]; //! it's true try it !
  • 1
    This is true because + is commutative. Operation + is also associative, but this isn't important here. – rcode Mar 4 '18 at 20:13

No, they are functionally equivalent.

First, index is scaled up to the type size then added to the myPointer base, then the value is extracted from that memory location.

The "better practice" is the more readable one, which is usually, but not necessarily always, the myPointer[index] variant.

That's because you're usually interested in an element of the array, not the memory location to dereference.


There is no functional difference I know of but the form myPointer[1] is ultimately more readable and far less likely to incur coding errors.


The form *(myPointer + 1) does not allow for changing the type of pointer to an object and therefore getting access to the overloaded [] operator.

Also debugging is far harder

 int *ints[10];
 int myint = ints[10]; 

is easier to pickup visually than

 int *ints;
 int myint = *(ints + 10); 

also the compiler can insert range checking to catch the error at compile time.


  • But when you need the address, the form ints + 10 is better than &ints[10]. – ruslik Jan 7 '11 at 9:39
  • If you need the address you don't care about overloaded operator[], and avoiding it is safer. – Lorenzo Gatti Dec 11 '13 at 16:23

More readable and more maintainable code is better code.

As for functional part... There is no difference. Both times you are "playing with memory".


There is no functional difference. The decision to use either form is usually made depending on the context in which you are using it. Now in this example, the array form is simpler to use and read and hence is the obvious choice. However, suppose you were processing a character array, say, consuming the words in a sentence. Given a pointer to the array you might find it easier to use the second form as in the code snippet below:

int parse_line(char* line) 
    char* p = line;
         // consume

Edit 1 : Decade old question. but still I think this answer will help knowing the compiler's perspective on processing array indexing

For the compiler they both are the same!

code 1


int main()

    int myArr[5] = {1, 2, 3, 4, 5};
    int value = myArr[0];


code 2


int main()

    int myArr[5] = {1, 2, 3, 4, 5};
    int value = *(myArr + 0);


These files if compiled with gcc -S flag, will produce the assembly code file with .s extension I compared both the .s files with kdiff3 and comparison shows they produced the same asm code.

Here is the proof


Actually , When an Array 'a' is initialized a pointer to its first memory location ie.. a[0] is returned which is nothing but a ;

So if you do 'a+1' it is actually a pointer to a[1]

if you do 'a+2' it is actually a pointer to a[2]

if you do 'a+3' it is actually a pointer to a[3] so on ,

so if you do *(a+1) you will get value of a[1] and similar for other values also. if you do *(a) you actually get a[0], So i think its pretty clear now how it works..

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.