I m a newbie to Haskell. I am pretty good with Imperative languages but not with functional. Haskell is my first as a functional language.

I am trying to figure out, how to get the index of the smallest element in the list where the minimum element is defined by me.

Let me explain by examples.

For example :

Function signature minList :: x -> [x]

let x = 2
let list = [2,3,5,4,6,5,2,1,7,9,2] 

minList x list --output 1 <- is index

This should return 1. Because the at list[1] is 3. It returns 1 because 3 is the smallest element after x (=2).

let x = 1
let list = [3,5,4,6,5,2,1,7,9,2] 
minList x list -- output 9 <- is index

It should return 9 because at list[9] is 2 and 2 is the smallest element after 1. x = 1 which is defined by me.

What I have tried so far.

minListIndex :: (Ord a, Num  a) => a -> [a] -> a
minListIndex x [] = 0
minListIndex x (y:ys) 
            | x > y =  length ys
            | otherwise = m
            where m = minListIndex x ys

When I load the file I get this error

• Couldn't match expected type ‘a’ with actual type ‘Int’
      ‘a’ is a rigid type variable bound by
        the type signature for:
          minListIndex :: forall a. (Ord a, Num a) => a -> [a] -> a
        at myFile.hs:36:17
    • In the expression: 1 + length ys
      In an equation for ‘minListIndex’:
          minListIndex x (y : ys)
            | x > y = 1 + length ys
            | otherwise = 1 + m
                m = minListIndex x ys
    • Relevant bindings include
        m :: a (bound at myFile.hs:41:19)
        ys :: [a] (bound at myFile.hs:38:19)
        y :: a (bound at myFile.hs:38:17)
        x :: a (bound at myFile.hs:38:14)
        minListIndex :: a -> [a] -> a (bound at myFile.hs:37:1)

When I modify the function like this

minListIndex :: (Ord a, Num  a) => a -> [a] -> a
minListIndex x [] = 0
minListIndex x (y:ys) 
            | x > y =  2 -- <- modified...
            | otherwise = 3 -- <- modifiedd
            where m = minListIndex x ys

I load the file again then it compiles and runs but ofc the output is not desired.

What is the problem with

| x > y =  length ys
| otherwise = m


In short: Basically, I want to find the index of the smallest element but higher than the x which is defined by me in parameter/function signature.

Thanks for the help in advance!

  • Can you explain the reasoning behind the line x > y = length ys? Why if the first element of the list is smaller than x should it return the length of the rest of the list? Dec 12, 2018 at 18:56
  • 1
    It also is a bit "odd" that you "define the smallest element" yourself. If that is the case, then this basically "collapses" to a findIndex. Dec 12, 2018 at 18:58
  • @WillemVanOnsem Thanks for answering. I was just testing length ys and It failed. Regarding findIndex, I don't want to import any library. :(
    – Phoenix404
    Dec 12, 2018 at 18:59
  • Based on the examples, it looks like you basically want to find the index of the smallest element after the given element? Dec 12, 2018 at 19:01
  • yes, exactly....
    – Phoenix404
    Dec 12, 2018 at 19:01

4 Answers 4

minListIndex :: (Ord a, Num  a) => a -> [a] -> a

The problem is that you are trying to return result of generic type a but it is actually index in a list.

Suppose you are trying to evaluate your function for a list of doubles. In this case compiler should instantiate function's type to Double -> [Double] -> Double which is nonsense.

Actually compiler notices that you are returning something that is derived from list's length and warns you that it is not possible to match generic type a with concrete Int.

length ys returns Int, so you can try this instead:

minListIndex :: Ord a => a -> [a] -> Int

Regarding your original problem, seems that you can't solve it with plain recursion. Consider defining helper recursive function with accumulator. In your case it can be a pair (min_value_so_far, its_index).

  • This helped me to understand. Is it way to cast the returning value of length to Integer or a?
    – Phoenix404
    Dec 12, 2018 at 19:04
  • 1
    This must not be possible. Otherwise it will allow you to write unsafe code. Dec 12, 2018 at 19:11

First off, I'd separate the index type from the list element type altogether. There's no apparent reason for them to be the same. I will use the BangPatterns extension to avoid a space leak without too much notation; enable that by adding {-# language BangPatterns #-} to the very top of the file. I will also import Data.Word to get access to the Word64 type.

There are two stages: first, find the index of the given element (if it's present) and the rest of the list beyond that point. Then, find the index of the minimum of the tail.

-- Find the 0-based index of the first occurrence
-- of the given element in the list, and
-- the rest of the list after that element.
findGiven :: Eq a => a -> [a] -> Maybe (Word64, [a])
findGiven given = go 0 where
  go !_k [] = Nothing --not found
  go !k (x:xs)
    | given == xs = Just (k, xs)
    | otherwise = go (k+1) xs

-- Find the minimum (and its index) of the elements of the
-- list greater than the given one.
findMinWithIndexOver :: Ord a => a -> [a] -> Maybe (Word64, a)
findMinWithIndexOver given = go 0 Nothing where
  go !_k acc [] = acc
  go !k acc (x : xs)
    | x <= given = go (k + 1) acc xs
    | otherwise
    = case acc of
        Nothing -> go (k + 1) (Just (k, x)) xs
        Just (ix_min, curr_min)
          | x < ix_min = go (k + 1) (Just (k, x)) xs
          | otherwise = go (k + 1) acc xs

You can now put these functions together to construct the one you seek. If you want a general Num result rather than a Word64 one, you can use fromIntegral at the very end. Why use Word64? Unlike Int or Word, it's (practically) guaranteed not to overflow in any reasonable amount of time. It's likely substantially faster than using something like Integer or Natural directly.

  • @WillNess, I think I fixed it.
    – dfeuer
    Dec 13, 2018 at 19:22
  • looks like it. everything is inlined, eliminated, fused; every elem, findIndex, length, span, dropWhile, filter, minimum... and it might as well be written in C. :( :/ :S :L :) .... Wanting a "smart compiler" is frowned upon, but really, should it be? Still? /ranting/ --- anyway, you've one last optimization to add. it might be possible sometimes to bail out early if we hit a successor minimal element by pure chance, with a discrete index type (and it is discrete). :) (Kind of radix sort--style short-circuiting... Or is it integer sorting?)
    – Will Ness
    Dec 13, 2018 at 19:45
  • err, it's the element type that must be Enum, not index, d'oh.
    – Will Ness
    Dec 13, 2018 at 20:26
  • @WillNess, I can fuse the addition in as well if you like, by having findMinWithIndexOver take an initial counter value. I could start off with a zip [0...], and maybe I should. The real trouble is the need to deal with the two "not found" cases (i.e., when the given element isn't in the list or when there's nothing greater than it following it). dropWhile and filter will both want to throw away the length information. Using length itself is a waste of time and may also create a space leak. I agree this solution is ugly and C-like, but I don't know how to fix it efficiently.
    – dfeuer
    Dec 13, 2018 at 21:05
  • /chuckle re:addition/ I understand that it's the price we have to pay more often than we'd liked to. BTW is the code in my answer really that much less efficient? I've implemented the early bail out now, too.
    – Will Ness
    Dec 13, 2018 at 21:21

It is not clear for me what do you want exactly. Based on examples I guess it is: find the index of the smallest element higher than x which appears after x. In that case, This solution is plain Prelude. No imports

minList :: Ord a => a -> [a] -> Int
minList x l = snd . minimum . filter (\a -> x < fst a) . dropWhile (\a -> x /= fst a) $ zip l [0..]

The logic is:

  • create the list of pairs, [(elem, index)] using zip l [0..]
  • drop elements until you find the input x using dropWhile (\a -> x /= fst a)
  • discards elements less than x using filter (\a -> x < fst a)
  • find the minimum of the resulting list. Tuples are ordered using lexicographic order so it fits your problem
  • take the index using snd
  • This solution seems to work for me. But I have small doubt that in which cases a function has to have a signature? Like in your solution, it doesn't have the signature.
    – Phoenix404
    Dec 13, 2018 at 9:50
  • almost always, the compiler can infer the type for you. Nevertheless, it is a bad practice to not specify the signature. I'm editing the answer to add the signature ;)
    – lsmor
    Dec 13, 2018 at 10:09

Your function can be constructed out of ready-made parts as

import Data.Maybe (listToMaybe)
import Data.List  (sortBy)
import Data.Ord   (comparing)

foo :: (Ord a, Enum b) => a -> [a] -> Maybe b
foo x = fmap fst . listToMaybe . take 1 
                 . dropWhile ((<= x) . snd) 
                 . sortBy (comparing snd) 
                 . dropWhile ((/= x) . snd)
                 . zip [toEnum 0..] 

This Maybe finds the index of the next smallest element in the list above the given element, situated after the given element, in the input list. As you've requested.

You can use any Enum type of your choosing as the index.

Now you can implement this higher-level executable specs as direct recursion, using an efficient Map data structure to hold your sorted elements above x seen so far to find the next smallest, etc.

Correctness first, efficiency later!

Efficiency update: dropping after the sort drops them sorted, so there's a wasted effort there; indeed it should be replaced with the filtering (as seen in the answer by Luis Morillo) before the sort. And if our element type is in Integral (so it is a properly discrete type, unlike just an Enum, thanks to @dfeuer for pointing this out!), there's one more opportunity for an opportunistic optimization: if we hit on a succ minimal element by pure chance, there's no further chance of improvement, and so we should bail out at that point right there:

bar :: (Integral a, Enum b) => a -> [a] -> Maybe b
bar x = fmap fst . either Just (listToMaybe . take 1 
                                . sortBy (comparing snd))
                 . findOrFilter ((== succ x).snd) ((> x).snd)
                 . dropWhile ((/= x) . snd)
                 . zip [toEnum 0..] 

findOrFilter :: (a -> Bool) -> (a -> Bool) -> [a] -> Either a [a]
findOrFilter t p = go 
   where  go []                 = Right []
          go (x:xs) | t x       = Left   x
                    | otherwise = fmap ([x | p x] ++) $ go xs


> foo 5 [2,3,5,4,6,5,2,1,7,9,2] :: Maybe Int
Just 4
> foo 2 [2,3,5,4,6,5,2,1,7,9,2] :: Maybe Int
Just 1
> foo 1 [3,5,4,6,5,2,1,7,9,2] :: Maybe Int
Just 9
  • Unfortunately, there are Enum instances for Float, Double, and Ratio a, for which your short-cut approach will fall apart. Yes, that's because Enum is extremely broken, but there you go. Perhaps you should use Integral instead?
    – dfeuer
    Dec 13, 2018 at 22:14
  • (on the second thought, I'll just put Integral in as you said. thanks for the suggestion!)
    – Will Ness
    Dec 13, 2018 at 22:32

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