Using dynamic programming in Haskell? [Warning: ProjectEuler 31 solution inside]

In solving projecteuler.net's problem #31 [SPOILERS AHEAD] (counting the number of ways to make 2£ with the British coins), I wanted to use dynamic programming. I started with OCaml, and wrote the short and very efficient following programming:

``````open Num

let make_dyn_table amount coins =
let t = Array.make_matrix (Array.length coins) (amount+1) (Int 1) in
for i = 1 to (Array.length t) - 1 do
for j = 0 to amount do
if j < coins.(i) then
t.(i).(j) <- t.(i-1).(j)
else
t.(i).(j) <- t.(i-1).(j) +/ t.(i).(j - coins.(i))
done
done;
t

let _ =
let t = make_dyn_table 200 [|1;2;5;10;20;50;100;200|] in
let last_row = Array.length t - 1 in
let last_col = Array.length t.(last_row) - 1 in
Printf.printf "%s\n" (string_of_num (t.(last_row).(last_col)))
``````

This executes in ~8ms on my laptop. If I increase the amount from 200 pence to one million, the program still finds an answer in less than two seconds.

I translated the program to Haskell (which was definitely not fun in itself), and though it terminates with the right answer for 200 pence, if I increase that number to 10000, my laptop comes to a screeching halt (lots of thrashing). Here's the code:

``````import Data.Array

createDynTable :: Int -> Array Int Int -> Array (Int, Int) Int
createDynTable amount coins =
let numCoins = (snd . bounds) coins
t = array ((0, 0), (numCoins, amount))
[((i, j), 1) | i <- [0 .. numCoins], j <- [0 .. amount]]
in t

populateDynTable :: Array (Int, Int) Int -> Array Int Int -> Array (Int, Int) Int
populateDynTable t coins =
go t 1 0
where go t i j
| i > maxX = t
| j > maxY = go t (i+1) 0
| j < coins ! i = go (t // [((i, j), t ! (i-1, j))]) i (j+1)
| otherwise = go (t // [((i, j), t!(i-1,j) + t!(i, j - coins!i))]) i (j+1)
((_, _), (maxX, maxY)) = bounds t

changeCombinations amount coins =
let coinsArray = listArray (0, length coins - 1) coins
dynTable = createDynTable amount coinsArray
dynTable' = populateDynTable dynTable coinsArray
((_, _), (i, j)) = bounds dynTable
in
dynTable' ! (i, j)

main =
print \$ changeCombinations 200 [1,2,5,10,20,50,100,200]
``````

I'd love to hear from somebody who knows Haskell well why the performance of this solution is so bad.

-
FWIW, if I were writing this from scratch in Haskell, I would have done something much closer to @augustss's answer than Daniel's. – luqui Dec 14 '12 at 17:48

Haskell is pure. The purity means that values are immutable, and thus in the step

``````j < coins ! i = go (t // [((i, j), t ! (i-1, j))]) i (j+1)
``````

you create an entire new array for each entry you update. That's already very expensive for a small amount like £2, but it becomes utterly obscene for an amount of £100.

Furthermore, the arrays are boxed, that means they contain pointers to the entries, which worsens locality, uses more storage, and allows thunks to be built up that are also slower to evaluate when they finally are forced.

The used algorithm depends on a mutable data structure for its efficiency, but the mutability is confined to the computation, so we can use what is intended to allow safely shielded computations with temporarily mutable data, the `ST` state transformer monad family, and the associated [unboxed, for efficiency] arrays.

Give me half an hour or so to translate the algorithm into code using `STUArray`s, and you'll get a Haskell version that is not too ugly, and ought to perform comparably to the O'Caml version (some more or less constant factor is expected for the difference, whether it's larger or smaller than 1, I don't know).

Here it is:

``````module Main (main) where

import System.Environment (getArgs)

import Data.Array.ST
import Data.Array.Unboxed

standardCoins :: [Int]
standardCoins = [1,2,5,10,20,50,100,200]

changeCombinations :: Int -> [Int] -> Int
changeCombinations amount coins = runST \$ do
let coinBound = length coins - 1
coinsArray :: UArray Int Int
coinsArray = listArray (0, coinBound) coins
table <- newArray((0,0),(coinBound, amount)) 1 :: ST s (STUArray s (Int,Int) Int)
let go i j
| i > coinBound = readArray table (coinBound,amount)
| j > amount   = go (i+1) 0
| j < coinsArray ! i = do
writeArray table (i,j) v
go i (j+1)
| otherwise = do
w <- readArray table (i, j - coinsArray!i)
writeArray table (i,j) (v+w)
go i (j+1)
go 1 0

main :: IO ()
main = do
args <- getArgs
let amount = case args of
_   -> 200
print \$ changeCombinations amount standardCoins
``````

runs in not too shabby time,

``````\$ time ./mutArr
73682

real    0m0.002s
user    0m0.000s
sys     0m0.001s
\$ time ./mutArr 1000000
986687212143813985

real    0m0.439s
user    0m0.128s
sys     0m0.310s
``````

and uses checked array accesses, using unchecked accesses, the time could be somewhat reduced.

Ah, I just learned that your O'Caml code uses arbitrary precision integers, so using `Int` in Haskell puts O'Caml at an unfair disadvantage. The changes necessary to calculate the results with arbitrary precision `Integer`s are minmal,

``````\$ diff mutArr.hs mutArrIgr.hs
12c12
< changeCombinations :: Int -> [Int] -> Int
---
> changeCombinations :: Int -> [Int] -> Integer
17c17
<     table <- newArray((0,0),(coinBound, amount)) 1 :: ST s (STUArray s (Int,Int) Int)
---
>     table <- newArray((0,0),(coinBound, amount)) 1 :: ST s (STArray s (Int,Int) Integer)
28c28
<                 writeArray table (i,j) (v+w)
---
>                 writeArray table (i,j) \$! (v+w)
``````

only two type signatures needed to be adapted - the array necessarily becomes boxed, so we need to make sure we're not writing thunks to the array in line 28, and

``````\$ time ./mutArrIgr
73682

real    0m0.002s
user    0m0.000s
sys     0m0.002s
\$ time ./mutArrIgr 1000000
99341140660285639188927260001

real    0m1.314s
user    0m1.157s
sys     0m0.156s
``````

the computation with the large result that overflowed for `Int`s takes noticeably longer, but as expected comparable to the O'Caml.

Spending some time understanding the O'Caml, I can offer a closer, a bit shorter, and arguably nicer translation:

``````module Main (main) where

import System.Environment (getArgs)

import Data.Array.ST
import Data.Array.Unboxed

standardCoins :: [Int]
standardCoins = [1,2,5,10,20,50,100,200]

changeCombinations :: Int -> [Int] -> Integer
changeCombinations amount coins = runST \$ do
let coinBound = length coins - 1
coinsArray :: UArray Int Int
coinsArray = listArray (0, coinBound) coins
table <- newArray((0,0),(coinBound, amount)) 1 :: ST s (STArray s (Int,Int) Integer)
forM_ [1 .. coinBound] \$ \i ->
forM_ [0 .. amount] \$ \j ->
if j < coinsArray!i
then do
writeArray table (i,j) v
else do
w <- readArray table (i, j - coinsArray!i)
writeArray table (i,j) \$! (v+w)

main :: IO ()
main = do
args <- getArgs
let amount = case args of
_   -> 200
print \$ changeCombinations amount standardCoins
``````

``````\$ time ./mutArrIgrM 1000000
99341140660285639188927260001

real    0m1.440s
user    0m1.273s
sys     0m0.164s
``````
-
Pretty impressive, give me a few minutes to study this. – gnuvince Dec 14 '12 at 2:18
Don't forget the update, I found out that the O'Caml version computes with arbitrary precision integers, so we don't want to avoid that for Haskell. – Daniel Fischer Dec 14 '12 at 2:28
Thanks for the update with the big ints. As for the State monad, am I correct in understanding that under the hood, the array is actually being modified in place, but the effect of this mutation cannot be observed? – gnuvince Dec 14 '12 at 2:33
Yes, the array is modified in place, but while it is mutable, it cannot be accessed from outside the computation. Having taken a closer look at the algorithm (actually thinking about it, not blindly translating), I have a somewhat nicer and shorter translation of the O'Caml, updating now. – Daniel Fischer Dec 14 '12 at 2:44
@gnuvince: note that the ST monad is different from the State monad, although they serve similar purposes. ST supports true mutability, State is just about threading parameters. – Ben Millwood Dec 14 '12 at 3:58

You could take advantage of Haskell being lazy and not schedule the array filling yourself, but instead relying on lazy evaluation to do it in the right order. (For large inputs you'll need to increase the stack size.)

``````import Data.Array

createDynTable :: Integer -> Array Int Integer -> Array (Int, Integer) Integer
createDynTable amount coins =
let numCoins = (snd . bounds) coins
t = array ((0, 0), (numCoins, amount))
[((i, j), go i j) | i <- [0 .. numCoins], j <- [0 .. amount]]
go i j | i == 0        = 1
| j < coins ! i = t ! (i-1, j)
| otherwise     = t ! (i-1, j) + t ! (i, j - coins!i)
in t

changeCombinations amount coins =
let coinsArray = listArray (0, length coins - 1) coins
dynTable = createDynTable amount coinsArray
((_, _), (i, j)) = bounds dynTable
in
dynTable ! (i, j)

main =
print \$ changeCombinations 200 [1,2,5,10,20,50,100,200]
``````
-