# Efficient heaps in purely functional languages

As an exercise in Haskell, I'm trying to implement heapsort. The heap is usually implemented as an array in imperative languages, but this would be hugely inefficient in purely functional languages. So I've looked at binary heaps, but everything I found so far describes them from an imperative viewpoint and the algorithms presented are hard to translate to a functional setting. How to efficiently implement a heap in a purely functional language such as Haskell?

Edit: By efficient I mean it should still be in O(n*log n), but it doesn't have to beat a C program. Also, I'd like to use purely functional programming. What else would be the point of doing it in Haskell?

-

There are a number of Haskell heap implementations in an appendix to Okasaki's Purely Functional Data Structures. (The source code can be downloaded at the link. The book itself is well worth reading.) None of them are binary heaps, per se, but the "leftist" heap is very similar. It has O(log n) insertion, removal, and merge operations. There are also more complicated data structures like skew heaps, binomial heaps, and splay heaps which have better performance.

-
Thanks, that's exactly what I was looking for. In fact, I ordered the book 2 days ago, but I don't have it yet. Maybe I should just have waited. ;) – Kim Stebel Jun 1 '09 at 7:23

Here is a page containing an ML version of HeapSort. It's quite detailed and should provide a good starting point.

http://flint.cs.yale.edu/cs428/coq/doc/Reference-Manual021.html

-

Just like in efficient Quicksort algorithms written in Haskell, you need to use monads (state transformers) to do stuff in-place.

-
-1: Nobody has ever managed to write an efficient quicksort in Haskell. – Jon Harrop May 23 '10 at 16:34

You could also use the `ST` monad, which allows you to write imperative code but expose a purely functional interface safely.

-
Yes, the ST monad gives you the necessary "mutable state". It provides individual mutable variables (a bit like `ref` in F#) as well as mutable arrays, which are of particular interest for sorting in place. – Christian Klauser May 31 '09 at 20:25

Arrays in Haskell aren't as hugely inefficient as you might think, but typical practice in Haskell would probably be to implement this using ordinary data types, like this:

``````data Heap a = Empty | Heap a (Heap a) (Heap a)
fromList :: Ord a => [a] -> Heap a
toSortedList :: Ord a => Heap a -> [a]
heapSort = toSortedList . fromList
``````

If I were solving this problem, I might start by stuffing the list elements into an array, making it easier to index them for heap creation.

``````import Data.Array
fromList xs = heapify 0 where
size = length xs
elems = listArray (0, size - 1) xs :: Array Int a
heapify n = ...
``````

If you're using a binary max heap, you might want to keep track of the size of the heap as you remove elements so you can find the bottom right element in O(log N) time. You could also take a look at other types of heaps that aren't typically implemented using arrays, like binomial heaps and fibonacci heaps.

A final note on array performance: in Haskell there's a tradeoff between using static arrays and using mutable arrays. With static arrays, you have to create new copies of the arrays when you change the elements. With mutable arrays, the garbage collector has a hard time keeping different generations of objects separated. Try implementing the heapsort using an STArray and see how you like it.

-
Note that the O(n) cost of each array write was a bug fixed in GHC 6.12. – Jon Harrop Dec 25 '10 at 11:57

As an exercise in Haskell, I implemented an imperative heapsort with the ST Monad.

``````{-# LANGUAGE ScopedTypeVariables #-}

import Data.Array.ST (STArray)

heapSort :: forall a. Ord a => [a] -> [a]
heapSort list = runST \$ do
let n = length list
heap <- newListArray (1, n) list :: ST s (STArray s Int a)
heapSizeRef <- newSTRef n
let
heapifyDown pos = do
let children = filter (<= heapSize) [pos*2, pos*2+1]
childrenVals <- forM children \$ \i -> do
return (childVal, i)
let (minChildVal, minChildIdx) = minimum childrenVals
if null children || val < minChildVal
then return ()
else do
writeArray heap pos minChildVal
writeArray heap minChildIdx val
heapifyDown minChildIdx
lastParent = n `div` 2
forM_ [lastParent,lastParent-1..1] heapifyDown
forM [n,n-1..1] \$ \i -> do
writeArray heap 1 val
writeSTRef heapSizeRef (i-1)
heapifyDown 1
``````

btw I contest that if it's not purely functional then there is no point in doing so in Haskell. I think my toy implementation is much nicer than what one would achieve in C++ with templates, passing around stuff to the inner functions.

-

Jon Fairbairn posted a functional heapsort to the Haskell Cafe mailing list back in 1997:

I reproduce it below, reformatted to fit this space. I've also slightly simplified the code of merge_heap.

I'm surprised treefold isn't in the standard prelude since it's so useful. Translated from the version I wrote in Ponder in October 1992 -- Jon Fairbairn

``````module Treefold where

-- treefold (*) z [a,b,c,d,e,f] = (((a*b)*(c*d))*(e*f))
treefold f zero [] = zero
treefold f zero [x] = x
treefold f zero (a:b:l) = treefold f zero (f a b : pairfold l)
where
pairfold (x:y:rest) = f x y : pairfold rest
pairfold l = l -- here l will have fewer than 2 elements

module Heapsort where
import Treefold

data Heap a = Nil | Node a [Heap a]
heapify x = Node x []

heapsort :: Ord a => [a] -> [a]
heapsort = flatten_heap . merge_heaps . map heapify
where
merge_heaps :: Ord a => [Heap a] -> Heap a
merge_heaps = treefold merge_heap Nil

flatten_heap Nil = []
flatten_heap (Node x heaps) = x:flatten_heap (merge_heaps heaps)

merge_heap heap Nil = heap
merge_heap node_a@(Node a heaps_a) node_b@(Node b heaps_b)
| a < b = Node a (node_b: heaps_a)
| otherwise = Node b (node_a: heaps_b)
``````
-

And here is a Fibonacci Heap in Haskell:

https://github.com/liuxinyu95/AlgoXY/blob/algoxy/datastruct/heap/other-heaps/src/FibonacciHeap.hs

Here are the pdf file for some other k-ary heaps based on Okasaki's work.