**Statically speaking**, this is easy to understand:

```
int mtx[3][2] = {{1, 2},
{2, 3},
{3, 4}};
```

Nothing complicated here. 3 rows, 2 columns; data in column one: `1, 2, 3`

; data in column two: `2, 3, 4`

.
We can access the elements via the same construct:

```
for(i = 0; i<3; i++){
for(j = 0; j<2; j++)
printf("%d ", mtx[i][j]);
printf("\n");
}
//output
//1 2
//2 3
//3 4
```

Now let’s look at this in terms of **Pointers**:

The brackets are a very nice construct to help simplify things, but it doesn’t help when we need to work in a dynamic environment, so we need to think of this in terms of pointers. If we want to store a “row” of integers, we need an array:

```
int row[2] = {1,2};
```

And you know what? We can access this just like a pointer.

```
printf("%d, %d\n",*row,*(row+1)); //prints 1, 2
printf("%d, %d\n",row[0],row[1]); //prints 1, 2
```

Now if we don’t know the number of values in a row we can make this array a dynamic length if we have a pointer to int, and we give it some memory:

```
int *row = malloc(X * sizeof(int)); //allow for X number of ints
*row = 1; //row[0] = 1
*(row+1) = 2; //row[1] = 2
…
*(row+(X-1)) = Y; // row[x-1] = Some value y
```

So now we have a dynamic 1 dimensional array; a single row. But we want lots of rows, not just one, and we don’t know how many. That means we need another dynamic 1 dimensional array, each element of that array will be a pointer which points to a row.

```
//we want enough memory to point to X number of rows
//each value stored there is a pointer to an integer
int ** matrix = malloc(X * sizeof(int *));
//conceptually:
(ptr to ptr to int) (pointer to int)
**matrix ------------> *row1 --------> [1][2]
*row2 --------> [2][3]
*row3 --------> [3][4]
```

Now all that’s left to do is to write the code which will perform these dynamic allocations:

```
int i, j, value = 0;
//allocate memory for the pointers to rows
int ** matrix = malloc(Rows * sizeof(int*));
//each row needs a dynamic number of elements
for(i=0; i<Rows; i++){
// so we need memory for the number of items in each row…
// we could call this number of columns as well
*(matrix + i) = malloc(X * sizeof(int));
//While we’re in here, if we have the items we can populate the matrix
for(j=0; j<X; j++)
*(*(matrix+i)+j) = value; // if you deference (matrix + i) you get the row
// if you add the column and deference again, you
// get the actual item to store (not a pointer!)
}
```

One of the most important things to do now is to make sure we free the memory when we’re done. Each level of `malloc()`

should have the same number of `free()`

calls, and the calls should be in a FILO order (reverse of the malloc calls):

```
for(i=0; i<Rows; i++)
free(*(matrix + i));
free(matrix);
//set to NULL to clean up, matrix points to allocated memory now so let’s not use it!
matrix = NULL;
```