What you're loking for is what's known as a pairing function, where *(x, y)* maps to a certain integer *N* and vice-versa (the function is one-to-one and onto). Keith's first answer (for finite ranges) is close, but requires you to know the maximum size of the square, in effect adding another parameter to the pairing function. His screenshot in Excel (for infinite ranges) shows how it's done, but I'd like to add some explanation to it.

Given a value *N* that you want to map to a coordinate *(x, y)*:

First, we locate which *layer* it belongs to. A layer is what Keith showed in his **Excel column D**, and goes something like this:

```
1 2 5 10 -> '1 2 3 4
4 3 6 11 -> 2 '2 3 4
9 8 7 12 -> 3 3 '3 4
16 15 14 13 -> 4 4 4 '4
```

You find out what layer *N* belongs to by

```
layer = math.floor(math.sqrt(N - 1)) + 1
```

Given the layer, find the integer corresponding to the *diagonal* (shown above with a ', with values 1, 3, 7, 13 for layers 1, 2, 3, 4; **Column H** in Keith's answer)

```
diagonal = (layer^2) - layer + 1
```

Now that you have the diagonal, we can find the values of *x* and *y* (Keith's **columns I and J**):

```
if (N < diagonal):
x = layer
y = N - ((layer-1)^2) + 1
elif (N == diagonal):
x = layer
y = layer
else:
x = (layer^2) - N + 1
y = layer
```

My formulas look a little different from Keith's, but they're ultimately derived from the same place. I did my calculations independently, then compared them to Keith's, and found that they're pretty much identical.

`(1, sqrt(index))`

- but I doubt this is the case. – Blair Apr 5 '11 at 3:12