# What is a good way to generate a infinite list of all integers in Haskell

I wrote the following function in haskell, as it will enumerate every integer:

``````integers = (0:)\$ concat \$ zipWith (\x y -> [x,y]) [1..] (map negate [1..])
``````

I wonder if there are better ways to do it, it does seem a bit too complicated.

Also, I wonder are there standard implementations to list all elements in the integer lattice of dimension \$k\$.

-

``````integers = 0 : concat [[x,(-x)] | x <- [1..]]
``````

(or, alternatively, as in @DanielWagner's solution in the comment below that works better I think)

-
Why `concat` when you're already in a list comprehension? `integers = 0 : [y | x <- [1..], y <- [x,-x]]`. –  Daniel Wagner Mar 17 '12 at 15:38
@DanielWagner: True, I missed that solution :) –  Riccardo Mar 17 '12 at 15:49
``````map fun [0 .. ]
where
fun n
| even n = n `quot` 2
| otherwise = (1 - n) `quot` 2
``````

There aren't any standard implementations to list all points in ℤk. Not even for `k == 1`, really. But with any enumeration of ℤ and a cartesian product of two lists that outputs any pair at a finite index even if the lists are infinite (some possible implementations here), you can roll your own.

``````integers :: [Integer]
integers = -- whatever is your favourite implementation

-- get all pairs at finite index, even for infinite input lists
--
cartesian :: [a] -> [b] -> [(a,b)]
cartesian xs ys = ???

-- enumDim k enumerates the points in ℤ^k, to avoid type problems, the points
-- are represented as lists of coordinates, not tuples
enumDim :: Int -> [[Integer]]
enumDim k
| k < 0     = error "Can't handle negative dimensions"
| k == 0    = [[]]
| otherwise = map (uncurry (:)) \$ cartesian integers (enumDim (k-1))
-- alternative:
{-
| k == 1    = map return integers
| otherwise = map (uncurry (++)) \$ cartesian (enumDim h) (enumDim (k-h))
where
h = k `quot` 2
-}
``````
-
``````import Control.Applicative

integers = 0 : zipWith (*) ([1..] <* "mu") (cycle [1,-1])
``````

Of course you can take the path of the non-monk as well:

``````integers = 0 : [y | x <- [1..], y <- [x,-x]]
``````

But then you won't understand the true meaning of mu.

-

We have had many short solutions. Here is a systematic one, with tuples of integers as well.

``````-- interleave lists
interleave :: [a] -> [a] -> [a]
interleave [] ys = ys
interleave xs [] = xs
interleave (x:xs) (y:ys) = x : y : interleave xs ys

-- positive integers
positiveIntegers = 1 : [k + 1 | k <- positiveIntegers]

-- negative integers
negativeIntegers = map negate positiveIntegers

-- integers
integers = 0 : interleave positiveIntegers negativeIntegers

-- enumeration of the cartesian product of two lists
prod :: [a] -> [b] -> [(a,b)]
prod [] ys = []
prod xs [] = []
prod (x:xs) (y:ys) = (x,y) : interleave (interleave xys yxs) (prod xs ys)
where xys = map (\y -> (x,y)) ys
yxs = map (\x -> (x,y)) xs

-- the k-fold power of a list
power :: Int -> [a] -> [[a]]
power 0 xs = [[]]
power k xs = map (\(y,ys) -> y:ys) (prod xs (power (k-1) xs))

-- the millionth quadruple is [62501,0,0,1]
``````[0..] ++ [ -x | x <- [1..] ]
That doesn't enumerate all integers, because for `n<0` there doesn't exist a `k` such that `n == l!!k`. –  leftaroundabout Jun 24 at 14:43