Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I can't sleep! :)

I've written small program building double linked list in Haskell. The basic language's property to make it was lazy evaluation (see the bunch of code below). And my question is can I do the same in a pure functional language with eager evaluation or not? In any case, what properties eager functional language must have to be able to build such structure (impurity?)?

import Data.List

data DLList a = DLNull |
    DLNode { prev :: DLList a
           , x :: a
           , next :: DLList a
           }
  deriving (Show)

walkDLList :: (DLList a -> DLList a) -> DLList a -> [a]
walkDLList _ DLNull = []
walkDLList f n@(DLNode _ x _)  = x : walkDLList f (f n)

-- Returns first and last items.
makeDLList :: [a] -> (DLList a, DLList a)
makeDLList xs = let (first, last) = step DLNull xs in (first, last)
  where
    step prev [] = (DLNull, prev)
                         -- Here I use laziness. 'next' is not built yet, it's a thunk.
    step prev (x : xs) = let this = DLNode prev x next 
                             (next, last) = step this xs
                         in (this, last)

testList :: [Int] -> IO ()
testList l = let
    (first, last) = makeDLList l
    byNext = walkDLList next first
    byPrev = walkDLList prev last
  in do
    putStrLn $ "Testing: " ++ show l
    print byNext
    print byPrev

main = do
  testList []
  testList [1, 2, 3, 4]
share|improve this question
    
check out this code. :) It returns just the head node, and is exceptionally simple. –  Will Ness Feb 14 '12 at 22:51

3 Answers 3

A doubly-linked list can be implemented in a purely functional way in an eager language as a zipper on a singly-linked list. See, for example, Rosetta Code > Doubly-linked list > OCaml > Functional.

share|improve this answer
    
I think the point of doubly-linked list is that it does not allocate new storage on traversal, unlike the code you linked to, Dan. In it, prev(next alist) is not the same storage as alist, unlike the usual C, say, implementation, and also the Haskell code from the question above where after let (alist,zlist)=makeDLList xs we have prev(next alist)==alist and next(prev zlist)==zlist where == means "the same actual storage", or in Lisp-parlance "eq-equivalent" (for non-empty xs of course). –  Will Ness Feb 14 '12 at 20:14
    
@WillNess regarding "not allocat[ing] new storage on traversal", that is an implementation detail, and comes at a cost. You cannot "insert" into an immutable doubly-linked list (in the style given by OP) without making a copy of the entire list. Well, you can usually get away with less copying due to laziness, but the point is the new doubly-linked list cannot share any nodes with the old doubly-linked list. The immutable zipper implementation allows more sharing, though at the cost of more storage required for traversal (but not much more, again due to the ability to share). –  Dan Burton Feb 14 '12 at 22:38
    
@WillNess n.b. Haskell makes no guarantees about eq-ness. GHC's parallel garbage collector takes advantage of this, and can actually remove sharing that you might expect to be there. This is rare, and barely affects performance, though, and due to immutable data, it will never affect your results. –  Dan Burton Feb 14 '12 at 22:41
    
I'd expect it that if the same name is used twice, (a pointer to) the same value would be used in each place: in let {this = DLNode prev x next ; (next, last) = step this xs}, this is this, right? Isn't it what laziness means? One name - one (pointer to an) entity, not? You're quite right about whole-list copy on inserts. Maybe zipper is better in some situations, and DL-list in others. Still they're different. –  Will Ness Feb 14 '12 at 23:29
    
also, if GHC would remove sharing from two uses of same variable, how would it impact the various corecursive definitions which rely on it, like e.g. fibs = 0:scanl (+) 1 fibs? Would it even work, or suffer a drastic loss of efficiency? –  Will Ness Feb 15 '12 at 8:01

As long as a language has something like closures, lambdas etc. you can always simulate lazyness. You could rewrite that code even in Java (without mutating variables etc), you just need to wrap every "lazy" operation in something like

interface Thunk<A> {
   A eval();  
}

Of course this would look terrible, but it is possible.

share|improve this answer
3  
You need something updatable to get the effect of lazy evaluation (evaluate at most once), otherwise you'll be emulating call-by-name. –  augustss Feb 14 '12 at 15:39
    
So, augustus, your point is that it's not enough just closures and lambdas? –  demi Feb 14 '12 at 16:48
2  
I think he just refers to that the result of eval needs to be cached, so the thunk is not recomputed should eval be run multiple times. –  danr Feb 14 '12 at 17:22

In the non-backtracking subset of Prolog, which can be seen as explicitly set-once eager pure functional language, you can build the doubly-linked lists easily. It's the referential transparency that makes it hard in Haskell, for it forbids the Prolog's explicit setting of the named, explicitly not-yet-set logical variables, and instead forces Haskell to achieve same effect in the warped way of "tying the knot". I think.

Plus, there really isn't much difference between Haskell's guarded recursion under lazy evaluation vs. Prolog's open-ended lists built in tail-recursion modulo cons fashion. IMO. Here's for instance an example of lazy lists in Prolog. The memoized shared storage is used as universal access mediator, so the results of previous calculations can be arranged to be cached.

Come to think of it, you can use C in a restrictive manner as an eager pure functional language, if you never reset any variable nor any pointer once it is set. You still have null pointers, just as Prolog has variables, so it is too, explicitly set-once. And of course you can build doubly-linked lists with it.

So the only question that remains is, do you admit such set-once languages as pure?

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.