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

`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`

).