# Representing a two-dimensional array assignment as a pointer math?

I have an array ex:

``````int array[3][5];
``````

If I want to assign a value to an element in that array, it's simple... ex:

``````array[1][2] = 8;
``````

However, I want to represent it in a pointer math, would this be correct?

``````**(array + 5 * 1 + 2) = 8;
``````

In both cases it's looking for the 7th position... I'm just not sure if I need to include the 2nd * outside of (code)

``````**(code)
``````

EDIT: Just a bit of a follow up. Thank you to everyone who was helping me with this. The confusion that I had came from a mistake in instructor's notes, and after I presented the information you've provided he realized the mistake and agrees that

``````*(*(array+row)+col)
``````

or

``````*(*array+MAX_COL*row+col)
``````

is the accurate pointer math representation for a two-dimensional array.

The **(array+MAX_COL*row+col) is like array[MAX_COL*row+col], which is used in single dimensional array implementation of multidimensional array, just like @James Kanze mentioned in one of the replies to this post (the second one is faster than the first one).

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Possible duplicate: stackoverflow.com/questions/13554244/… –  antonijn Mar 15 '13 at 8:44
That question was for C... I'm not sure it'd be the same for my situation. –  B.K. Mar 15 '13 at 8:45
What you are doing is the same as in C. Go ahead and use the question referenced to by @Antonijn. –  fredrik Mar 15 '13 at 8:47
Well, my code looks a bit different from what everyone else is using there... is my version correct of using **(array + MAX_COL * row + col)? –  B.K. Mar 15 '13 at 8:49
*(*(a+1)+2) = 8; what you do will point at a a[7][0] location which is undefined and wrong. in general *(*(array + row)+column). –  Koushik Mar 15 '13 at 9:03

`array[1][2]` equals `*( *(array + 1) + 2)`.

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First thing you need to know is that two dimensional arrays aren't pointers to pointers. They're contiguous in memory, so you can represent them by a pointer to `T` (`T` is the base type):

``````int arr[3][5];
int *p = &arr[0][0];

int array_1_2 = *(p + 5 * 1 + 2);
``````
-

An example to demonstrate pointer Arithmetic operations synonymous to accessing an Array.

``````#include<stdio.h>

int main()
{
int array[3][5] = {0};
array[2][3] = 5;
printf( "%d\n",array[2][3]);
printf( "%d\n",*(*(array+2)+3) );
return 0;
}
``````
-

There are a couple of wrong assumptions in you question: for example, `array[1][2]` isn't looking at the 7th position; it's looking at the third position in the second array element of `array`. The type of `array` is array[3] of array[5] of `int`; when it converts to a pointer, the resulting type is a pointer to array[5] of `int`, not a pointer to `int`. So ```array + 5 * 1 + 2)``` refers to the eighth element of an array with only 5 elements; i.e. 35 * sizeof(int) beyond the start of `array` (and the expression still has type pointer to array[5] of `int`).

As a general rule, if you want to simulate access into a multidimensional array, you should declare a single dimensional array:

``````int array[columns * rows];
``````

If you do this, then `*(array + i * columns + j)` will effectively perform a 2 dimensional indexing.

-

An alternate representation would be

``````*(array[1]+5)=8
``````

Let me explain simple analogous code.

``````int *p[5];
``````

Here `p` is a pointer that points to the address of first element and `p` is equivalent to `&p[0]`.

To understand this take an example

``````#include<iostream.h>
void main()
{
int *p[2];
int a=0,b=1;
p[0]=&a;p[1]=&b;
cout<<*p<<endl<<&a<<endl;
cout<<*(p+1)<<endl<<&b<<endl;
cout<<p<<endl<<p+1<<endl;
cout<<**p<<endl<<**(p+1);
}
``````

The output of the above code is

``````0x8fbdfff0
0x8fbdfff0
0x8fbdffee
0x8fbdffee
0x8fbdfff2
0x8fbdfff4
0
1
``````

In our case `int array[3][5]` is equivalent to `int *p1[5]` `int *p2[5]` `int *p3[5]`. where `p1`,`p2`,`p3` represent pointers point to the first element of first second and third row respectively.

So in effect we can consider `array[3]` as a pointer and `array[1]`equivalent to `p1` similarly array[2] and 3 Hence to get the value of `array[1][2]` we can use `*(array[1]+2)` or ((array+1)+2) or considering it is implemented in row major form `*(array+1)` is equivalent to `array+1*5` and you get
`*(array+1*5+2)`

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Hmm, it appears *(*array + 5*1+2) works too. –  B.K. Mar 15 '13 at 12:57

With the following array:

``````const int ROWS = 3;
const int COLS = 5;
int arr[ROWS][COLS];
``````

although `arr` points to the memory, where the first element resides, its type is not `int*` thus incrementing this pointer won't move you to the second `int`. So this line:

``````arr[1][2] = 8;
``````

can be replaced by:

``````*((int*)arr + 1*COLS + 2) = 8;
``````

or you can use the fact, that this array resides within the continuous block of memory, size of which is equal to `ROWS * COLS * sizeof(int)`, therefore you can simply retrieve the pointer to the first element and use it for this purpose:

``````int* pFirstEle = &arr[0][0];
*(pFirstEle + 1*COLS + 2) = 8;
``````

But note that this is wrong:

``````**(arr + 1*COLS + 2) = 8;
``````
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First, the type of `arr` is actually `int[3][5]`; `arr` is not a pointer. And converting it to a pointer, then advancing 1, will point to the second element. The type of the elements is, of course, `int[3]`, and not `int`. –  James Kanze Mar 15 '13 at 9:32
@JamesKanze: What I meant was that `int[3][5]` behaves like `int (*)[5]` when treated as a pointer and by second element I meant the second integer of course, not second row. Anyway I edited my answer. –  LihO Mar 15 '13 at 9:58