It's up to you to turn the a[1][1] into a linear address. In other words, we have to take `a[1][1]`

and figure out how far that is from the beginning of `a`

. We start by figuring the size of a row -- in this case, 2 ints. So, (working in ints, for the moment) the beginning of row 0 is at offset 0 from a, row 1 at offset 2, and (if there were more rows) so on. We then add on the offset within that row. Finally, we scale that by the size of a single item.

From there, we have a couple of possibilities. One is that we just need a fixed position -- we're going to get `a[1][1]`

, no matter what. The other is that we're really looking at `a[i][j]`

, where `i`

and `j`

happen to be 1 at the moment, but could be other sizes.

For the first, we can use the fact that the assembler can do some math to compute the address for us.

```
// one row down times 2 ints per row + offset of 1 into last row, all times size of int
movl a + (1 * 2 + 1)*4, eax
```

In the second case, let's assume we have `i`

in `esi`

and `j`

in `ebx`

. In this case, we have to do the math ourselves (sorry, for the moment I'm going to use Intel syntax -- I'm just a lot more accustomed to it):

```
shl esi, 1 ; i * 2
add esi, ebx ; i * 2 + j
shl esi, 2 ;(i * 2 + j) * 4
mov eax, a[esi]
```

The x86 can actually combine some operations like this that are common for addressing, so you don't have to execute them as separate instructions as I have above, so we could pretty easily reduce that to:

```
shl esi, 1
mov eax, a[esi][ebx]
```

That last may require a bit of explanation -- at least with MASM (and probably with gas, I'd guess) the assembler knows that since you're loading a value into `eax`

that you're working in 4-byte quantities, so it automatically scales the offset by 4.