Here's an alternate ordering of the same list (by hammar's suggestion):

```
-- the integer points along the diagonals of slope -1 on the cartesian plane,
-- organized by x-intercept
-- diagonals = [ (0,0), (1,0), (0,1), (2,0), (1,1), (0,2), ...
diagonals = [ (n-i, i) | n <- [0..], i <- [0..n] ]
-- the multiples of three paired with the squares
paar = [ (3*x, y^2) | (x,y) <- diagonals ]
```

and in action:

```
ghci> take 10 diagonals
[(0,0),(1,0),(0,1),(2,0),(1,1),(0,2),(3,0),(2,1),(1,2),(0,3)]
ghci> take 10 paar
[(0,0),(3,0),(0,1),(6,0),(3,1),(0,4),(9,0),(6,1),(3,4),(0,9)]
ghci> elem (9, 9801) paar
True
```

By using a diagonal path to iterate through all the possible values, we guarantee that we reach each finite point in finite time (though some points are still outside the bounds of memory).

As hammar points out in his comment, though, this isn't sufficient, as it will still take
an infinite amount of time to get a `False`

answer.

However, we have an order on the elements of paar, namely `(3*a,b^2)`

comes before `(3*c,d^2)`

when
`a + b < c + d`

. So to determine whether a given pair `(x,y)`

is in `paar`

, we only have to check
pairs `(p,q)`

while `p/3 + sqrt q <= x/3 + sqrt y`

.

To avoid using `Floating`

numbers, we can use a slightly looser condition, that `p <= x || q <= y`

.
Certainly `p > x && q > y`

implies `p/3 + sqrt q > x/3 + sqrt y`

, so this will still include any possible solutions, and it's guaranteed to terminate.

So we can build this check in

```
-- check only a finite number of elements so we can get a False result as well
isElem (p, q) = elem (p,q) $ takeWhile (\(a,b) -> a <= p || b <= q) paar
```

And use it:

```
ghci> isElem (9,9801)
True
ghci> isElem (9,9802)
False
ghci> isElem (10,9801)
False
```

`paar`

is. What do you want this list to look like? The elem function does indeed work on infinite lists (as long as the answer is`True`

), but the way you generate the list is causing problems. – Dan Burton May 10 '11 at 18:22