Using lists to model nondeterminism is problematic if the inputs can take infinitely many values. For example

```
pairs = [ (a,b) | a <- [0..], b <- [0..] ]
```

This will return `[(0,1),(0,2),(0,3),...]`

and never get around to showing you any pair whose first element is not `0`

.

Using the Cantor pairing function to collapse a list of lists into a single list can get around this problem. For example, we can define a bind-like operator that orders its outputs more intelligently by

```
(>>>=) :: [a] -> (a -> [b]) -> [b]
as >>>= f = cantor (map f as)
cantor :: [[a]] -> [a]
cantor xs = go 1 xs
where
go _ [] = []
go n xs = hs ++ go (n+1) ts
where
ys = filter (not.null) xs
hs = take n $ map head ys
ts = mapN n tail ys
mapN :: Int -> (a -> a) -> [a] -> [a]
mapN _ _ [] = []
mapN n f xs@(h:t)
| n <= 0 = xs
| otherwise = f h : mapN (n-1) f t
```

If we now wrap this up as a monad, we can enumerate all possible pairs

```
newtype Select a = Select { runSelect :: [a] }
instance Monad Select where
return a = Select [a]
Select as >>= f = Select $ as >>>= (runSelect . f)
pairs = runSelect $ do
a <- Select [0..]
b <- Select [0..]
return (a,b)
```

This results in

```
>> take 15 pairs
[(0,0),(0,1),(1,0),(0,2),(1,1),(2,0),(0,3),(1,2),(2,1),(3,0),(0,4),(1,3),(2,2),(3,1),(4,0)]
```

which is a much more desirable result. However, if we were to ask for triples instead, the ordering on the outputs isn't as "nice" and it's not even clear to me that all outputs are eventually included --

```
>> take 15 triples
[(0,0,0),(0,0,1),(1,0,0),(0,1,0),(1,0,1),(2,0,0),(0,0,2),(1,1,0),(2,0,1),(3,0,0),(0,1,1),(1,0,2),(2,1,0),(3,0,1),(4,0,0)]
```

Note that `(2,0,1)`

appears before `(0,1,1)`

in the ordering -- my intuition says that a good solution to this problem will order the outputs according to some notion of "size", which could be an explicit input to the algorithm, or could be given implicitly (as in this example, where the "size" of an input is its position in the input lists). When combining inputs, the "size" of a combination should be some function (probably the sum) of the size of the inputs.

Is there an elegant solution to this problem that I am missing?