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This is my attempt at a FIFO queue:

type Queue a = [a] -> [a]

empty :: Queue a
empty = id

remove :: Int -> Queue a -> ([a], Queue a)
remove n queue = (take n (queue []), (\x -> drop n (queue x)));

add :: [a] -> Queue a -> Queue a
add elems queue = (\x -> queue (elems ++ x))

empty creates an empty queue, remove takes the first n elements of the queue and returns the rest of the queue as the second element of the tuple, and add adds the list elems to the queue.

Will this add/remove 1 element in O(1) time and n elements in O(n) time?

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Maybe it's me, but I don't understand how your code works. Could you add type signatures? What is the type of queue? –  efie Jul 13 '12 at 13:27
Why? (++) is not an O(1) operation, it's O(n), laziness notwithstanding. –  n.m. Jul 13 '12 at 13:28
@efie: I've added type signatures. –  Clinton Jul 13 '12 at 13:38
Unfortunately, remove may take up to O(N) time. If a queue was created with N add operations, remove will need to evaluate N ++ operations to find the first element. –  comingstorm Jul 13 '12 at 18:03
remove is not only ineffective on difference lists, it's also not particularly Haskell-idiomatic and often more cumbersome than the faster alternative: build up the FIFO completely in one place in your program (the "source") apply toList to it just once (i.e. $ []) and pass the result as a whole to the "consumer" function. Thanks to lazyness, this does not cause any need to finish the buildup process before you can start reading from the other end. The readout will automatically "wait" for the source to yield each element. Ideal behaviour for a FIFO, for many problems! –  leftaroundabout Jul 13 '12 at 21:22

2 Answers 2

up vote 6 down vote accepted

What you have implemented effectively amounts to difference lists. (See: dlist.)

Difference lists allow for cheap appends, but unfortunately your removal will take linear time. It becomes more clear if we rewrite your code slightly:

type Queue a = [a] -> [a]

empty :: Queue a
empty = id

toList :: Queue a -> [a]
toList q = q []

fromList :: [a] -> Queue a
fromList = (++)

remove :: Int -> Queue a -> ([a], Queue a)
remove n q = (xs, fromList ys)
    (xs, ys) = splitAt n (toList q)

add :: [a] -> Queue a -> Queue a
add xs q = (++ xs) . q

Note that I have made the conversion to and from lists a bit more explicit than it was in your code. You clearly see that the core of your removal code gets bracketed between toList and fromList.

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What do you mean by linear time? Do you mean time proportional to the length of the queue? Because using your code I can remove from queues of infinite length in finite time. –  Clinton Jul 13 '12 at 14:01
Doesn't this add function adds elements to the start of the queue not the end? –  is7s Jul 13 '12 at 14:02
@is7s Ah, you're right. So does the OP's code, doesn't it. I'll modify the code. :) –  Stefan Holdermans Jul 13 '12 at 14:06
@Clinton going from a difference list to a list takes time linear in the number of elements, doesn't it? –  Stefan Holdermans Jul 13 '12 at 14:08
@dblhelix: Yes, I'm not sure how that relates though. –  Clinton Jul 13 '12 at 14:13

Well, sidestepping your question somewhat, the classic purely functional implementation of a FIFO queue is as a pair of lists, one for the "front" and one for the "back." You enqueue elements by adding them as the head of the back list, and dequeue by taking the head of the front list; if the front list is empty, you "rotate" the queue by reversing the back list and swapping that with the empty front list. In code:

import Control.Monad
import Data.List
import Data.Maybe

data FIFO a = FIFO [a] [a]
              deriving Show

empty :: FIFO a
empty = FIFO [] []

isEmpty :: FIFO a -> Bool
isEmpty (FIFO [] []) = True
isEmpty _ = False

enqueue :: a -> FIFO a -> FIFO a
enqueue x (FIFO front back) = FIFO front (x:back)

-- | Remove the head off the queue.  My type's different from yours
-- because I use Maybe to handle the case where somebody tries to
-- dequeue off an empty FIFO.
dequeue :: FIFO a -> Maybe (a, FIFO a)
dequeue queue = case queue of
                  FIFO [] [] -> Nothing
                  FIFO (x:f) b -> Just (x, FIFO f b)
                  otherwise -> dequeue (rotate queue)
    where rotate (FIFO [] back) = FIFO (reverse back) []

-- | Elements exit the queue in the order they appear in the list.
fromList :: [a] -> FIFO a
fromList xs = FIFO xs []

-- | Elements appear in the result list in the order they exit the queue.
toList :: FIFO a -> [a]
toList = unfoldr dequeue

That's the classic implementation. Now your operations can be written in terms of that:

-- | Enqueue multiple elements.  Elements exit the queue in the order
-- they appear in xs.
add :: [a] -> FIFO a -> FIFO a
add xs q = foldl' (flip enqueue) q xs

To write remove in terms of dequeue, you need to handle all of those intermediate FIFOs from the (a, FIFO a) result of dequeue. One way to do that is to use the State monad:

import Control.Monad.State

-- | Remove n elements from the queue.  My result type is different
-- from yours, again, because I handle the empty FIFO case.  If you
-- try to remove too many elements, you get a bunch of Nothings at
-- the end of your list.
remove :: Int -> FIFO a -> ([Maybe a], FIFO a)
remove n q = runState (removeM n) q

-- | State monad action to dequeue n elements from the state queue.
removeM :: Int -> State (FIFO a) [Maybe a]
removeM n = replicateM n dequeueM

-- | State monad action to dequeue an element from the state queue.
dequeueM :: State (FIFO a) (Maybe a)
dequeueM = do q <- get
              case dequeue q of
                Just (x, q') -> put q' >> return (Just x)
                Nothing -> return Nothing
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