This appears to be directly related to the set theory argument proving that the set of integer pairs are in one-to-one correspondence with the set of integers (*denumerable*). The argument involves a so-called Cantor pairing function.

So, out of curiosity, let's see if we can get a `diagonalize`

function that way.
Define the infinite list of Cantor pairs recursively in Haskell:

```
auxCantorPairList :: (Integer, Integer) -> [(Integer, Integer)]
auxCantorPairList (x,y) =
let nextPair = if (x > 0) then (x-1,y+1) else (x+y+1, 0)
in (x,y) : auxCantorPairList nextPair
cantorPairList :: [(Integer, Integer)]
cantorPairList = auxCantorPairList (0,0)
```

And try that inside ghci:

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

We can number the pairs, and for example extract the *numbers* for those pairs which have a zero x coordinate:

```
λ>
λ> xs = [1..]
λ> take 5 $ map fst $ filter (\(n,(x,y)) -> (x==0)) $ zip xs cantorPairList
[1,3,6,10,15]
λ>
```

We recognize this is the top row from the OP's result in the text of the question.
Similarly for the next two rows:

```
λ>
λ> makeRow xs row = map fst $ filter (\(n,(x,y)) -> (x==row)) $ zip xs cantorPairList
λ> take 5 $ makeRow xs 1
[2,5,9,14,20]
λ>
λ> take 5 $ makeRow xs 2
[4,8,13,19,26]
λ>
```

From there, we can write our first draft of a `diagonalize`

function:

```
λ>
λ> printAsLines xs = mapM_ (putStrLn . show) xs
λ> diagonalize xs = takeWhile (not . null) $ map (makeRow xs) [0..]
λ>
λ> printAsLines $ diagonalize [1..19]
[1,3,6,10,15]
[2,5,9,14]
[4,8,13,19]
[7,12,18]
[11,17]
[16]
λ>
```

## EDIT: performance update

For a list of 1 million items, the runtime is 18 sec, and 145 seconds for 4 millions items. As mentioned by Redu, this seems like O(n√n) complexity.

Distributing the pairs among the various target sublists is inefficient, as most filter operations fail.

To improve performance, we can use a Data.Map structure for the target sublists.

```
{-# LANGUAGE ExplicitForAll #-}
{-# LANGUAGE ScopedTypeVariables #-}
import qualified Data.List as L
import qualified Data.Map as M
type MIL a = M.Map Integer [a]
buildCantorMap :: forall a. [a] -> MIL a
buildCantorMap xs =
let ts = zip xs cantorPairList -- triplets (a,(x,y))
m0 = (M.fromList [])::MIL a
redOp m (n,(x,y)) = let afn as = case as of
Nothing -> Just [n]
Just jas -> Just (n:jas)
in M.alter afn x m
m1r = L.foldl' redOp m0 ts
in
fmap reverse m1r
diagonalize :: [a] -> [[a]]
diagonalize xs = let cm = buildCantorMap xs
in map snd $ M.toAscList cm
```

With that second version, performance appears to be much better: 568 msec for the 1 million items list, 2669 msec for the 4 millions item list. So it is close to the O(n*Log(n)) complexity we could have hoped for.

`foldr`

you may do like`unfoldr (Just . combWith comb)`

for infinite lists. Alas as i have mentioned under my answer`combWith`

is O(n) thus accepted answer using`splitAt`

is significantly more efficient. – Redu Apr 17 '20 at 16:35