I first posted

```
Prelude> let pairs = [(m, n) | t <- [0..]
, let m = head $ take 1 $ drop t [0..]
, let n = head $ take 1 $ drop (t + 1) [0..]]
```

Which, I believed answered the three conditions set by the professor. But hammar pointed out that if I chose this list as an answer, that is, the list of pairs of the form (t, t+1), then I might as well choose the list

```
repeat [(0,0)]
```

Well, both of these do seem to answer the professor's question, considering there seems to be no mention of the list having to contain *all* combinations of [0..] and [0..].

That aside, hammer helped me see how you can list all combinations, facilitating the evaluation of elem in finite time by building the infinite list from finite lists. Here are two other finite lists - less succinct than Hammar's suggestion of the diagonals - that seem to build all combinations of [0..] and [0..]:

```
edges = concat [concat [[(m,n),(n,m)] | let m = t, n <- take m [0..]] ++ [(t,t)]
| t <- [0..]]
*Main> take 9 edges
[(0,0),(1,0),(0,1),(1,1),(2,0),(0,2),(2,1),(1,2),(2,2)]
```

which construct the edges (t, 0..t) (0..t, t), and

```
oddSpirals size = concat [spiral m size' | m <- n] where
size' = if size < 3 then 3 else if even size then size - 1 else size
n = map (\y -> (fst y * size' + div size' 2, snd y * size' + div size' 2))
[(x, t-x) | let size' = 5, t <- [0..], x <- [0..t]]
spiral seed size = spiral' (size - 1) "-" 1 [seed]
spiral' limit op count result
| count == limit =
let op' = if op == "-" then (-) else (+)
m = foldl (\a b -> a ++ [(op' (fst $ last a) b, snd $ last a)]) result (replicate count 1)
nextOp = if op == "-" then "+" else "-"
nextOp' = if op == "-" then (+) else (-)
n = foldl (\a b -> a ++ [(fst $ last a, nextOp' (snd $ last a) b)]) m (replicate count 1)
n' = foldl (\a b -> a ++ [(nextOp' (fst $ last a) b, snd $ last a)]) n (replicate count 1)
in n'
| otherwise =
let op' = if op == "-" then (-) else (+)
m = foldl (\a b -> a ++ [(op' (fst $ last a) b, snd $ last a)]) result (replicate count 1)
nextOp = if op == "-" then "+" else "-"
nextOp' = if op == "-" then (+) else (-)
n = foldl (\a b -> a ++ [(fst $ last a, nextOp' (snd $ last a) b)]) m (replicate count 1)
in spiral' limit nextOp (count + 1) n
*Main> take 9 $ oddSpirals 3
[(1,1),(0,1),(0,2),(1,2),(2,2),(2,1),(2,0),(1,0),(0,0)]
```

which build clockwise spirals of length 'size' squared, superimposed on hammar's diagonals algorithm.

`t = x + y`

and generate all pairs`(x, y)`

for each`t`

in`[0..]`

. Since there are only a finite number of pairs for each`t`

, this will satsify the requirements. – hammar Mar 23 '13 at 6:32`m`

and`n`

. For a fixed`t`

, what is the highest value`m`

can have? Once you've picked a`t`

and`m`

, you can use`t = m + n`

to calculate`n`

directly. – hammar Mar 23 '13 at 7:43`(m,n)`

meant to hold? Perhaps the problem is to generate all`(m,n)`

pairs where`m`

and`n`

satisfy`helper m n == True`

(i.e., you know what`helper`

is when youmakethe list)? – Andrew Jaffe Mar 23 '13 at 7:56