I would be very impressed in a CPU that provided array lookup semantics in its assembly language. Or rather, I would be annoyed if it meant something more important had been sacrificed.

The general way to do array lookup in assembly is by doing the calculation yourself to turn the two indexes for a 2D array into a single index for a 1D array, and adjust for the element size. For example (pseudo-code):

```
ax = cx * major_dimension
ax = ax + dx
ax = ax * element_size
ax = peek[base+ax]
```

where `major_dimension`

is one of the dimensions of the 2D array (which dimension you use depends entirely on how the data is laid out in memory), `element_size`

is the size of each element, `base`

is the start of the array and cx/dx are the indexes you're using to access the array.

For example, if you have a 3-by-4 (`a[0-2][0-3]`

) array at memory location `0x0700`

and these are 32-bit integers:

```
+--------+--------+--------+--------+
0x0700: | a[0,0] | a[0,1] | a[0,2] | a[0,3] |
+--------+--------+--------+--------+
0x0710: | a[1,0] | a[1,1] | a[1,2] | a[1,3] |
+--------+--------+--------+--------+
0x0720: | a[2,0] | a[2,1] | a[2,2] | a[2,3] |
+--------+--------+--------+--------+
```

To find array element `a[n,m]`

, you calculate the major index multiplied by four plus the minor index, scale it to the correct element size (4 bytes) then add the base. To find element `a[2,1]`

```
addr = base + (n * 4 + m) * 4
= 0x0700 + (2 * 4 + 1) * 4
= 0x0700 + (8 + 1) * 4
= 0x0700 + (9 ) * 4
= 0x0700 + 36
= 0x0700 + 0x24
= 0x0724
```

Then that's the address you use for looking up the 1D array.

And, based on the comment that:

```
ar db 3dup(3dup(0))
mov ar[bx][si],al
```

would work, that's not quite right (`ar[bx][si]`

is masm-specific syntax equivalent to `ar[bx+si]`

).

All that does is a simple addition of the `ar`

address with the `bx`

and `si`

registers. It does *not* scale the `bx`

or `si`

register to take into account the major dimension and it does *not* scale the `bx+si`

value for the element size. So it will only work as-is for a 2D array of *bytes* where the major dimension is 1, which I'm pretty sure would make it a 1D array :-)

To work for any case, you would first need to multiply `bx`

or `si`

(depending on which is being used for the major dimension) by the major dimension then both `bx`

and `si`

by the element size.