48

I have an 8x8 matrix, like this:

char matrix[8][8];

Also, I have an array of 64 elements, like this:

char array[64];

Then I have drawn the matrix as a table, and filled the cells with numbers, each number being incremented from left to right, top to bottom.

If I have, say, indexes 3 (column) and 4 (row) into the matrix, I know that it corresponds to the element at position 35 in the array, as it can be seen in the table that I've drawn. I believe there is some sort of formula to translate the 2 indexes of the matrix into a single index of the array, but I can't figure out what it is.

Any ideas?

2
  • 3
    arr[i*cols+j] for equivalent matrix[i][j] indexing, assuming you want row-major ordering, and cols is your defined row width in columns (in your example's case, 8).
    – WhozCraig
    Dec 23 '12 at 23:39
  • I've tried all kinds of simple calculations like multiplying row * column * 8, dividing, etc. but it doesn't work. I'm not very good at math. Dec 23 '12 at 23:40
96

The way most languages store multi-dimensional arrays is by doing a conversion like the following:

If matrix has size, n (rows) by m (columns), and we're using "row-major ordering" (where we count along the rows first) then:

matrix[ i ][ j ] = array[ i*m + j ].

Here i goes from 0 to (n-1) and j from 0 to (m-1).

So it's just like a number system of base 'm'. Note that the size of the last dimension (here the number of rows) doesn't matter.


For a conceptual understanding, think of a (3x5) matrix with 'i' as the row number, and 'j' as the column number. If you start numbering from i,j = (0,0) --> 0. For 'row-major' ordering (like this), the layout looks like:

           |-------- 5 ---------|
  Row      ______________________   _ _
   0      |0    1    2    3    4 |   |
   1      |5    6    7    8    9 |   3
   2      |10   11   12   13   14|  _|_
          |______________________|
Column     0    1    2    3    4 

As you move along the row (i.e. increase the column number), you just start counting up, so the Array indices are 0,1,2.... When you get to the second row, you already have 5 entries, so you start with indices 1*5 + 0,1,2.... On the third row, you have 2*5 entries already, thus the indices are 2*5 + 0,1,2....

For higher dimension, this idea generalizes, i.e. for a 3D matrix L by N by M:

matrix[ i ][ j ][ k ] = array[ i*(N*M) + j*M + k ]

and so on.


For a really good explanation, see: http://www.cplusplus.com/doc/tutorial/arrays/; or for some more technical aspects: http://en.wikipedia.org/wiki/Row-major_order

6
  • 2
    I can't believe it was so simple... Very informative, thank you. Dec 23 '12 at 23:53
  • I'm pretty sure the current description is correct (as also described by @user1480848's answer below --- and corresponding edit on Mar 4, 2014). Please leave a comment if you don't think so - instead of editing the answer directly. Nov 4 '15 at 2:51
  • 1
    @DilithiumMatrix shouldn't the formula be j + (i * n) and not i + (j * n) as you suggest? Consider coordinates 2,3, which should return 13 using your matrix: 3 + (2 * 5) = 13. If we used your formula instead, we would get 2 + (3 * 5) = 17. Am I missing something?
    – Mohamad
    Nov 21 '15 at 1:13
  • 1
    @Mohamad absolutely, thanks! That's also what user1480848 described below... I think I must have rolled back to the wrong edit. Should be fixed now. I hope. Nov 21 '15 at 15:50
  • And just to be sure because it's not always the same convetion, by 'n' you mean number of rows and 'm' the number of columns, right?
    – TMOTTM
    Sep 29 '20 at 16:07
12

For row-major ordering, I believe the statement matrix[ i ][ j ] = array[ i*n + j ] is wrong.

The offset should be offset = (row * NUMCOLS) + column.

Your statement results to be row * NUMROWS + column, which is wrong.

The links you provided give a correct explanation.

2
  • Are you responding to zhermes' answer? If so you should probably just edit his/her post with your correction. Mar 4 '14 at 11:23
  • He is correct, you are probably setting up the (raw)array column major way in your head :)
    – arapEST
    Jan 6 at 7:46
7

Something like this?

//columns = amount of columns, x = column, y = row
var calculateIndex = function(columns, x, y){
    return y * columns + x;
};

The example below converts an index back to x and y coordinates.

//i = index, x = amount of columns, y = amount of rows
var calculateCoordinates = function(index, columns, rows){
    //for each row
    for(var i=0; i<rows; i++){
        //check if the index parameter is in the row
        if(index < (columns * i) + columns && index >= columns * i){
            //return x, y
            return [index - columns * i, i];
        }
    }
    return null;
};
4
  • Perhaps you could you explain a little of how this relates to (and answers) the OP's original question?
    – Stewart_R
    Nov 23 '14 at 2:11
  • I should read a little better. It actually does the exact opposite as what the OP has asked for. This converts 35,8,8 to 3,4. Nov 23 '14 at 2:27
  • Now it illustrates both conversions :) Nov 23 '14 at 3:02
  • Although I had to swap row and columns for my use but this is exactly what I was looking for.
    – Nitij
    Jan 24 '16 at 8:27

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.