Remember that an array in C is a contiguous area of memory. An array of five arrays are just the same, it's just a chunk of contiguous memory.

Now for simplicity's sake lets take a smaller matrix, like e.g.

```
int a[2][2];
```

In memory it's laid out like this:

+---------+---------+---------+---------+
| a[0][0] | a[0][1] | a[1][0] | a[1][1] |
+---------+---------+---------+---------+

Lets take a corresponding array:

```
int b[4];
```

which is laid out like

+------+------+------+------+
| b[0] | b[1] | b[2] | b[3] |
+------+------+------+------+

In memory, the matrix and the array looks very much like each other, don't they? They basically *are* the same, it's just the semantics and what the language (and compiler) allows that differs.

What you need to do is figure out some way to map the indexes of the matrix to the indexes of the array. So `a[0][0]`

corresponds to `b[0]`

, `a[0][1]`

corresponds to `b[1]`

, `a[1][0]`

corresponds to `b[2]`

, `a[1][1]`

corresponds to `b[3]`

.

So how to get from e.g. `a[0][1]`

`b[1]`

? That's seems to be very simple, just add the row and column indexes together and you have the result.

But how to get from `a[1][0]`

to `b[2]`

? That's a little harder, but still easy if you think a little. The matrix is an array of *two* arrays, and two multiplied by one (the row index) is equal to two.

Finally the last one, `a[1][1]`

to `b[3]`

. Combining the two formulas above, we multiply the row index by the size and add the column index: `1 * 2 + 1`

.

Generalizing it, if you have an array of `I`

rows, and looping over it using the indexes `i`

for the rows and `j`

for the columns then the corresponding index in a plain array is `i * I + j`

.

In code its something like

```
int a[I][J] = { ... }; // Initialization, doesn't matter exactly what
int b[I * J] = { 0 }; // Initialize all to zero
// Loop over rows
for (int i = 0; i < I; ++i)
{
// Loop over columns
for (int j = 0; j < J; ++j)
{
b[i * I + j] = a[i][j];
}
}
```

For your specific use-case you might want to initialize the array `b`

a little differently (to distinguish "unused" elements in the array from actual zeroes), and of course add a check for the matrix value.

I realize this might not be *exactly* what you're after, but the loop shown above could be *one* solution. And it's also a solution that allows you to go back and forth between the matrix and the array. If you have the array index you can calculate the matrix indexes, and if you have the matrix indexes you can calculate the array index.

For a solution where you don't map between the matrix and the array like I do, but just insert the values at the next "available" position in the array, then the other two answers will show you how.

`b`

array and increment it each time an element is added.e.g.`b[bi++] = a[k][l]`

`b[k]`

is wrong. You need to access`b`

using an independent index (not one of the indexes that you are using in order to access`a`

).