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I need convert this code to Haskell. Please help me. I would be very grateful for your help.

#lang scheme

(define (lab1 currentList counter result) 
    (let countdown ((i (- (length currentList) 1))) 
      (if (= i 0) 
          (display result) 
          (begin 
            (if (list? (list-ref currentList i))  
                (if (> (+ 1 counter) result) 
                    (begin
                      (set! counter (+ 1 counter))
                      (set! result (+ 1 result))
                      (countdown(- i 1))) 
                    (begin
                      (set! counter (+ 1 counter))
                      (countdown(- i 1)))) 
                (begin
                  (set! counter 0)
                  (countdown(- i 1)))))))) 

I think I need to use something like:

data PolarBear a = P a | B [PolarBear a] 

task :: [PolarBear a] -> Int 
task [] = 0 
task ((P _):ps) = task ps 
task ((B p):ps) | null p = 1 + task ps 
                | otherwise = task ps + (task p) 

main = task $ [B [ P 1, B [], B [ P 2, B [ P 3, B [], B []]]]]

?

11
  • What does your code do?
    – sshine
    Dec 7, 2015 at 11:17
  • @SimonShine Need to do without the use of standard functions: "For a given list to determine the maximum number of consecutive lists."
    – x3kt0
    Dec 7, 2015 at 11:22
  • IIUC, the list? check dynamically tests whether something is a list. This has no clear counterpart in a statically typed language, unless there's a giant sum type around like data Value = VCons ... | VNil | VInt ... | ..... Anyway, this looks too broad for SO.
    – chi
    Dec 7, 2015 at 11:24
  • 2
    I would first rewrite that in Scheme (or Lisp), as it looks like it's already been converted from an assignment-based, non-list-processing language. (If you have list of lists - [[a]] - in Haskell, the number you're looking for is the length of the list. If you don't have a list of lists, the number is zero.)
    – molbdnilo
    Dec 7, 2015 at 15:22
  • Yes, this looks like a way to count elements in a a list where some but not all elements are themselves lists. Haskell doesn't allow for lists of heterogeneous types.
    – WorBlux
    Dec 7, 2015 at 20:50

2 Answers 2

3

As molbdnilo indicated, that's a really wretched excuse for Scheme code. To really get a feel for translating Scheme to Haskell, you should first make versions of counter and result that are bound in the countdown named let and updated on each pass without using set!.

(define (lab1 currentList counter0 result0) 
    (let countdown
         ((i (- (length currentList) 1))
         (counter counter0)
         (result result0)) 
      (if (= i 0) 
          (display result) 
          (if (list? (list-ref currentList i))  
              (if (> (+ 1 counter) result) 
                 (countdown (- i 1) (+ 1 counter) (+ 1 result))
                 (countdown (- i 1) (+ 1 counter) result))
              (countdown (- i 1) 0 result))))) 

Once you've done that, you can expand the named let out into a local recursive function. Remember that

(let loop ((x x0)) body)

is basically the same as

(letrec ((loop (lambda (x) body)))
        (loop x0))

Once you've done that, the translation to Haskell should be pretty much immediate. It will be really bad Haskell code, because Haskell's !! is every bit as horribly inefficient as Scheme's list-ref (Will Ness shows how to do it much better), but it will faithfully reproduce the original code's behavior and (terrible) performance.

1
  • that's not me, that's foldr! :)
    – Will Ness
    Dec 11, 2015 at 15:56
2

The thing to notice in your code is that it processes the input list from back to front, passing the info along in the same direction (in two variables). This is the same as what foldr does, when the combining function is strict in its second argument.

The pair which is the second argument to the combining function emulates the updatable "environment" for the two vars in Scheme.

I'm leaving spaces to be filled, since it's a homework.

lab1 ... = ... $ 
    foldr (\x (counter,result)-> 
       if (listP x) 
       then (if counter >= result 
             then (counter+1,result+1) 
             else (counter+1,result)) 
       else (0,result)) (....,....) currentlist

assuming a datatype to which there exists a listP predicate returning a Boolean result. Like e.g.

data NestedList a = Atom a | List [NestedList a] 

with

listP (Atom _) = ... 
listP (...) = ...

If you need to present an explicitly recursive code, you need to write down the definition for foldr, and fuse it with the definition for the combining function above (let's call it g), turning

foldr g ... = ...

into

foldr_g ... = ...

then just renaming the foldr_g to your liking. The postprocessing step can go into a separate, "interface" function. Like so,

foldr_g z [] = z
foldr_g z (x:xs) = -- g x (foldr_g z xs)
                      g x r
                        where
                        r = foldr_g z xs

g x (counter, result) 
  | listP x = if counter >= result then ... else ...
  | otherwise = ....

Actually inline the definition of g into the foldr_g by interchanging the code lines and smashing the two definitions together, as

foldr_g z [] = z
foldr_g z (x:xs)   -- g x (foldr_g z xs)
                   -- g x r
  | listP x = if counter >= result then ... else ...
  | otherwise = ....
                   --   where
                   --   r = foldr_g z xs
 where
    (counter, result) = foldr_g z xs

and we call it as

lab1 currentList counter result =
  ... (foldr_g (...,...) currentlist)

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