Haskell version(1.03s):

module Main where
  import qualified Data.Text as T
  import qualified Data.Text.IO as TIO
  import Control.Monad
  import Control.Applicative ((<$>))
  import Data.Vector.Unboxed (Vector,(!))
  import qualified Data.Vector.Unboxed as V

  solve :: Vector Int -> Int
  solve ar =
    V.foldl' go 0 ar' where
      ar' = V.zip ar (V.postscanr' max 0 ar)
      go sr (p,m) = sr + m - p

  main = do
    t <- fmap (read . T.unpack) TIO.getLine -- With Data.Text, the example finishes 15% faster.
    T.unlines . map (T.pack . show . solve . V.fromList . map (read . T.unpack) . T.words)
      <$> replicateM t (TIO.getLine >> TIO.getLine) >>= TIO.putStr

F# version(0.17s):

open System

let solve (ar : uint64[]) =
    let ar' = 
        let t = Array.scanBack max ar 0UL |> fun x -> Array.take (x.Length-1) x
        Array.zip ar t

    let go sr (p,m) = sr + m - p
    Array.fold go 0UL ar'

let getIntLine() =
    Console.In.ReadLine().Split [|' '|]
    |> Array.choose (fun x -> if x <> "" then uint64 x |> Some else None)    

let getInt() = getIntLine().[0]

let t = getInt()
for i=1 to int t do
    getInt() |> ignore
    let ar = getIntLine()
    printfn "%i" (solve ar)

The above two programs are the solutions for the Stock Maximize problem and times are for the first test case of the Run Code button.

For some reason the F# version is roughly 6x faster, but I am pretty sure that if I replaced the slow library functions with imperative loops that I could speed it up by at least 3 times and more likely 10x.

Could the Haskell version be similarly improved?

I am doing the above for learning purposes and in general I am finding it difficult to figure out how to write efficient Haskell code.

  • 1
    Just for the record, what are you measuring? The execution of the whole program (from command line) or the runtime of the body (using something not shown in the snippet)? Commented May 30, 2016 at 13:25
  • 2
    I would have imagined that for purely functional code, Haskell would be ahead of F# at least. In the current 4.0 version, F# does not even have fold, scan and zip inlined. I would imagine that for roughly similar, purely functional code Haskell should exceed F# due to the optimizations afforded to it by its purity. Commented May 30, 2016 at 13:26
  • 3
    I would profile the IO code and actual calculation separately. Your input code currently converts from Text to String (with T.unpack) and then uses "read" which is known to be very slow.
    – shang
    Commented May 30, 2016 at 13:27
  • 7
    Why does the Haskell version use replicateM to read everything and start computing only after that? The F# version does not do that. Can't you move solve so that it is called (and its result printed) inside the replicateM? Right now, it seems you are dealing with large lists / Text strings which are not present in F#.
    – chi
    Commented May 30, 2016 at 13:37
  • 3
    @MarkoGrdinic fyi, most people look away from wall of text questions. you will get better responses if you keep the question short and to the point. Commented May 30, 2016 at 14:35

3 Answers 3


If you switch to ByteString and stick with plain Haskell lists (instead of vectors) you will get a more efficient solution. You may also rewrite the solve function with a single left fold and bypass zip and right scan (1). Overall, on my machine, I get 20 times performance improvement compared to your Haskell solution (2).

Below Haskell code performs faster than the F# code:

import Data.List (unfoldr)
import Control.Applicative ((<$>))
import Control.Monad (replicateM_)
import Data.ByteString (ByteString)
import qualified Data.ByteString as B
import qualified Data.ByteString.Char8 as C

parse :: ByteString -> [Int]
parse = unfoldr $ C.readInt . C.dropWhile (== ' ')

solve :: [Int] -> Int
solve xs = foldl go (const 0) xs minBound
    where go f x s = if s < x then f x else s - x + f s

main = do
    [n] <- parse <$> B.getLine
    replicateM_ n $ B.getLine >> B.getLine >>= print . solve . parse

1. See edits for an earlier version of this answer which implements solve using zip and scanr.
2. HackerRank website shows even a larger performance improvement.

  • 2
    I understand that String functions are supposed to be slow, but are Text functions supposed to be slow as well? Commented May 30, 2016 at 14:04
  • 1
    @MarkoGrdinic with ascii only text, my guess is that ByteString.Char8 performs faster than Text; but rely on your own benchmarks. Commented May 30, 2016 at 14:11
  • 4
    You can make this about five times as fast - 0.02 rather than 0.1 - if you revert to using unboxed vectors for the main solve function, now that the problem is well-analysed sprunge.us/PUYW
    – Michael
    Commented May 30, 2016 at 19:41
  • 2
    Realize that in the normal type of foldl :: Foldable t => (b -> a -> b) -> b -> t a -> b, "b" could be the type "c -> d", in which case the type would be (with extraneous parens removed) Foldable t => ((c ->d) -> a -> c ->d) -> (c -> d) -> t a -> c -> d, which matches the shape of the arguments he is passing. In other words, his accumulator is a function that is changed as he runs down the list, starting as a (const 0). Commented May 31, 2016 at 18:12
  • 1
    @גלעדברקן There was a different question a few days ago to which Behzad wrote the answer in a similar style and I spent a long time analyzing the usage of lambda as an accumulator. Personally, I do think it is confusing and it would make more sense to use tuples instead to accumulate extra values. Understanding it also requires understanding the basics of lambda calculus. Commented Jun 1, 2016 at 6:20

If I wanted to do that quickly in F# I would avoid all of the higher-order functions inside solve and just write a C-style imperative loop:

let solve (ar : uint64[]) =
  let mutable sr, m = 0UL, 0UL
  for i in ar.Length-1 .. -1 .. 0 do
    let p = ar.[i]
    m <- max p m
    sr <- sr + m - p

According to my measurements, this is 11x faster than your F#.

Then the performance is limited by the IO layer (unicode parsing) and string splitting. This can be optimised by reading into a byte buffer and writing the lexer by hand:

let buf = Array.create 65536 0uy
let mutable idx = 0
let mutable length = 0

  use stream = System.Console.OpenStandardInput()
  let rec read m =
    let c =
      if idx < length then
        idx <- idx + 1
        length <- stream.Read(buf, 0, buf.Length)
        idx <- 1
    if length > 0 && '0'B <= c && c <= '9'B then
      read (10UL * m + uint64(c - '0'B))
  let read() = read 0UL
  for _ in 1UL .. read() do
    Array.init (read() |> int) (fun _ -> read())
    |> solve
    |> System.Console.WriteLine
  • 15
    As soon as I saw a question featuring the words F# and Haskell, I began to scan the page for Dr. Harrop's response! Commented May 30, 2016 at 19:32
  • 4
    @Michael: My program takes ~0.000001s to run on this machine so HackerRank is measuring JIT compile time + run time for F# vs just run time for Haskell.
    – J D
    Commented May 30, 2016 at 21:13
  • 8
    Not sure how "write it like C" is a legitimate response. Of course it will be faster, but the whole point of using F# or Haskell is so I don't have to write like C. Commented May 31, 2016 at 14:15
  • 7
    @3noch: As Yaron Minsky famously said "don't be puritanical about purity".
    – J D
    Commented May 31, 2016 at 16:47
  • 3
    @3noch: Sure, that's the whole point of F# or Haskell, but asking a question "How can I make it faster" about reasonably fast code is inevitably asking "How can I make it more like C". How's that not a legitimate response?
    – scrwtp
    Commented Jun 1, 2016 at 7:43

Just for the record, the F# version is also not optimal. I don't think it really matters at this point, but if people wanted to compare the performance, then it is worth noting that it can be made faster.

I have not tried very hard (you can certainly make it even faster by using restricted mutation, which would not be against the nature of F#), but simple change to use Seq instead of Array in the right places (to avoid allocating temporary arrays) makes the code about 2x to 3x faster:

let solve (ar : uint64[]) =
    let ar' = Seq.zip ar (Array.scanBack max ar 0UL)    
    let go sr (p,m) = sr + m - p
    Seq.fold go 0UL ar'

If you use Seq.zip, you can also drop the take call (because Seq.zip truncates the sequence automatically). Measured using #time using the following snippet:

let rnd = Random()
let inp = Array.init 100000 (fun _ -> uint64 (rnd.Next()))
for a in 0 .. 10 do ignore (solve inp) // Measure this line

I get around 150ms for the original code and something between 50-75ms using the new version.

  • 3
    @JonHarrop I was hoping you'll join the game :-). Don't worry about the downvotes, the whole question will probably get deleted soon because it "does not fit the Q&A format" or something. Commented May 31, 2016 at 1:27
  • 4
    @AdamCopley: In all fairness no it shouldn't.
    – user541686
    Commented May 31, 2016 at 7:33
  • 4
    The op has asked for a review of his working code with regard to performance considerations, and how to write more efficient Haskell code. They key being it is working code. How is this not a review request? Commented May 31, 2016 at 7:36
  • 3
    @AdamCopley OP has asked about performance differences between Haskell and F#. Sample snippets of code in each language, proposed to be more or less equivalent, were provided. In benchmarking the sample code is critical, so obviously the samples will need to be discussed, tweaked, or replaced. But the question is not about the code and is not a request for code review. It would be totally off topic there.
    – Yitz
    Commented May 31, 2016 at 10:35
  • 3
    If an asker of a question asks how a snippet of working code can be improved, that to me is a review request, plain and simple, no arguments. Commented May 31, 2016 at 11:37

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