# lazy evaluation in infinte list

Hi I have the following code:

let f n (xs) = if n < 0 then f (n-1) (n:xs) else xs
f (-3) [] !! 1

and I expect it to print -4

But it does not print anything and keeps calculation in background.

What is wrong with my code?

• I'm not sure what you're expecting, but if you follow through how this will evaluate, the recursion only ends when n >= 0, yet you are subtracting 1 from it each time. Hence, infinite recursion. [You are building up an infinite list in xs as you do this, but the evaluation never stops for GHC to "see" this. So this is different from an "actual" infinite list like [1..] where you can quite happily do operations with some elements.] Jan 22, 2019 at 23:59
• Ordinary function application occurs immediately; the evaluation of the recursive call isn't delayed until some later time. Jan 23, 2019 at 13:53

Let's step through the evaluation:

f (-3) []
f (-4) [-3]
f (-5) [-4, -3]
f (-6) [-5, -4, -3]
f (-7) [-6, -5, -4, -3]
...

Considering this, what do you expect f (-3) [] !! 1 to be? The value in the index 1 changes each iteration, so there's no way Haskell can know what it is until it reaches the non-recursive case at n >= 0, which never happens.

If you build the list in the other direction, it will work as you expect:

let f n = if n < 0 then n : f (n - 1) else []

> f (-3) !! 1
-4

So here's a pretend integer type:

data Int2 = ... -- 2 bit signed integers [-2, -1, 0, 1]
deriving (Num, Ord, Eq, ...)

Let's imagine that your function was defined on Int2 values:

f :: Int2 -> [Int2] -> [Int2]
f n (xs) = if n < 0 then f (n-1) (n:xs) else xs

This makes it fairly easy to work out what one evaluation step looks like for f n xs:

f 1 xs = xs
f 0 xs = xs
f (-1) xs = f (-2) (-1 : xs)
f (-2) xs = f 1 (-2 : xs) -- because finite signed arithmetic wraps around

and from there we can work out the full value of f n []:

f 1 [] = []
f 0 [] = []
f (-1) [] = f (-2) [-1] = f 1 [-2, -1] = [-2, -1]
f (-2) [] = f 1 [-2] = [-2]

Each computed a value, but note how it took 3 evaluation steps before we got a list out of f (-1) [].

Now see if you can work out how many steps it would take to compute f (-1) [] if it were defined on 4-bit numbers. 8-bit? 32-bit? 64-bit? What if it were using Integer which has no lower bound?

At no point does laziness help you because there's no partial result, only a recursive call. That's the difference between:

lazyReplicate 0 _ = []
lazyReplicate n x = x : lazyReplicate (n - 1) x

and

strictReplicate n x = helper [] n x where
helper xs 0 _ = xs
helper xs n x = helper (x : xs) n x