# Project Euler 14: performance compared to C and memoization

I'm currently working on project euler problem 14.

I solved it using a poorly coded program, without memoization, that took 386 5 seconds to run (see edit).

Here it is:

``````step :: (Integer, Int) -> Integer -> (Integer, Int)
step (i, m) n   | nextValue > m         = (n, nextValue)
| otherwise             = (i, m)
where nextValue = syr n 1

syr :: Integer -> Int -> Int
syr 1 acc   = acc
syr x acc   | even x    = syr (x `div` 2) (acc + 1)
| otherwise = syr (3 * x + 1) (acc + 1)

p14 = foldl step (0, 0) [500000..999999]
``````

My question is about several comments in the thread related to this problem, where were mentionned execution times of <1 s for programs as follow (C code, credits to the project euler forum user ix for the code -- note: I didn't check that the execution time is in fact as mentionned):

``````#include <stdio.h>

int main(int argc, char **argv) {
int longest = 0;
int terms = 0;
int i;
unsigned long j;
for (i = 1; i <= 1000000; i++) {
j = i;
int this_terms = 1;
while (j != 1) {
this_terms++;
if (this_terms > terms) {
terms = this_terms;
longest = i;
}
if (j % 2 == 0) {
j = j / 2;
} else {
j = 3 * j + 1;
}
}
}
printf("longest: %d (%d)\n", longest, terms);
return 0;
}
``````

To me, those programs are kind of the same, when talking about the algorithm.

So I wonder why there is such a big difference? Or is there any fondamental difference between our two algorithms that can justify a x6 factor in performance?

BTW, I'm currently trying to implement this algorithm with memoization, but am kind of lost as to me, it's way easier to implement in an imperative language (and I don't manipulate monads yet so I can't use this paradigm). So if you have any good tutorial that fits a beginner to learn memoization, I'll be glad (the ones I encountered were not detailed enough or out of my league).

Note: I came to declarative paradigm through Prolog and am still in the very early process of discovering Haskell, so I might miss important things.

EDIT: thanks to delnan's help, I compiled the program and it now runs in 5 seconds, so I mainly look for hints on memoization now (even if ideas about the existing x6 gap are still welcome).

-
Well, replacing `ghci` with `ghc -O` should be a no-brainer and is bound to narrow the gap. Regardless of how effective it is, trying it is probably a good idea, if only to answer the notorious "what have you tried?" comment ;) Not to mention that it's easier and faster to try out than bringing memoization in. – delnan Mar 18 '12 at 18:35
@delnan: well my problem is that I'm still new to Haskell and still didn't look at how to compile properly a program. Or to be more precise, I looked and saw that `do` was used and thought I'd go back at it later, when I'll be working on monads. But I'd have made the same comment reading this question, so I feel a bit stupid :p – m09 Mar 18 '12 at 18:38
To get you started, you can probably get away with `main = print p14` and compiling as `ghc -O p14.hs`. – delnan Mar 18 '12 at 18:42
@delnan: Thanks, it now runs in about 5 seconds, so that was definitely the main difference. I suggest you post your comment as an answer so that I can at least upvote it! I'll edit to precise that I'm now looking for answers mainly about memoization. – m09 Mar 18 '12 at 18:46
Well, 5x is still a pretty large difference, and I've got nothing to offer regarding memoization. I suggest you simply update the question with the new runtime, remove the GHCi reference, and carry on asking about memoization and other optimizations. I'd much rather see answers on that some rep :) – delnan Mar 18 '12 at 18:47

After having compiled it with optimisations, there are still several differences to the C programme

• you use `div`, while the C programme uses machine division (which truncates) [but any self-respecting C compiler transforms that into a shift, so that makes it yet faster], that would be `quot` in Haskell; that reduced the run time by some 15% here.
• the C programme uses fixed-width 64-bit (or even 32-bit, but then it's just luck that it gets the correct answer, since some intermediate values exceed 32-bit range) integers, the Haskell programme uses arbitrary precision `Integer`s. If you have 64-bit `Int`s in your GHC (64-bit OS other than Windows), replace `Integer` with `Int`. That reduced the run time by a factor of about 3 here. If you're on a 32-bit system, you're out of luck, GHC doesn't use native 64-bit instructions there, these operations are implemented as C calls, that's still rather slow.

For the memoisation, you can outsource it to one of the memoisation packages on hackage, the only one that I remember is data-memocombinators, but there are others. Or you can do it yourself, for example keeping a map of previously calculated values - that would work best in the `State` monad,

``````import Control.Monad.State.Strict
import qualified Data.Map as Map
import Data.Map (Map, singleton)

type Memo = Map Integer Int

syr :: Integer -> State Memo Int
syr n = do
mb <- gets (Map.lookup n)
case mb of
Just l -> return l
Nothing -> do
let m = if even n then n `quot` 2 else 3*n+1
l <- syr m
let l' = l+1
modify (Map.insert n l')
return l'

solve :: Integer -> Int -> Integer -> State Memo (Integer,Int)
solve maxi len start
| len > 1000000 = return (maxi,len)
| otherwise = do
l <- syr start
if len < l
then solve start l (start+1)
else solve maxi len (start+1)

p14 :: (Integer,Int)
p14 = evalState (solve 0 0 500000) (singleton 1 1)
``````

but that will probably not gain too much (not even when you've added the necessary strictness). The trouble is that a lookup in a `Map` is not too cheap and an insertion is relatively expensive.

Another method is to keep a mutable array for the lookup. The code becomes more complicated, since you have to choose a reasonable upper bound for the values to cache (should be not much larger than the bound for the starting values) and deal with the parts of the sequences falling outside the memoised range. But an array lookup and write are fast. If you have 64-bit `Int`s, the below code runs pretty fast, here it takes 0.03s for a limit of 1 million, and 0.33s for a limit of 10 million, the corresponding (as closely as I reasonably could) C code runs in 0.018 resp. 0.2s.

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

import System.Environment (getArgs)
import Data.Array.ST
import Data.Array.Base
import Data.Bits
import Data.Int

main :: IO ()
main = do
args <- getArgs
let bd = case args of
_   -> 100000
print \$ collMax bd

next :: Int -> Int
next n
| n .&. 1 == 0  = n `unsafeShiftR` 1
| otherwise     = 3*n + 1

collMax :: Int -> (Int,Int16)
collMax upper = runST \$ do
arr <- newArray (0,upper) 0 :: ST s (STUArray s Int Int16)
let go l m
| upper < m = go (l+1) \$ next m
| otherwise = do
case l' of
0 -> do
l'' <- go 1 \$ next m
unsafeWrite arr m (l'' + 1)
return (l+l'')
_ -> return (l+l'-1)
collect mi ml i
| upper < i = return (mi, ml)
| otherwise = do
l <- go 1 i
if l > ml
then collect i l (i+1)
else collect mi ml (i+1)
unsafeWrite arr 1 1
collect 1 1 2
``````
-
`unsigned long` isn't necessarily 64-bit. I think `Word` should always be the same as `unsigned long` with GHC. – ehird Mar 18 '12 at 19:00
@Daniel Fischer: sadly I'm on a windows machine right now, so the `Int` type is not sufficient. The `quot` modification doesn't help here, execution time is the same. Thanks for your answer though, you were definitely right about `Integer`s. – m09 Mar 18 '12 at 19:16
@ehird Correct, `unsigned long` isn't necessarily 64 bits. But if the programme worked, it is on the author's machine. Ah, dang, it need not be, but that's just luck if it's 32 bits. – Daniel Fischer Mar 18 '12 at 19:18
@DanielFischer: thanks for the expansion on your answer, the part added is indeed a very instesting read. – m09 Dec 19 '12 at 9:03

Well, the C program uses `unsigned long`, but `Integer` can store arbitrarily large integers (it's a bignum). If you import `Data.Word`, then you can use `Word`, which is a machine-word-sized unsigned integer.

After replacing `Integer` with `Word`, and using `ghc -O2` and `gcc -O3`, the C program runs in 0.72 seconds, while the Haskell programs runs in 1.92 seconds. 2.6x isn't bad. However, `ghc -O2` doesn't always help, and this is one of the programs on which it doesn't! Using just `-O`, as you did, brings the runtime down to 1.90 seconds.

I tried replacing `div` with `quot` (which uses the same type of division as C; they only differ on negative inputs), but strangely it actually made the Haskell program run slightly slower for me.

You should be able to speed up the `syr` function with the help of this previous Stack Overflow question I answered about the same Project Euler problem.

-
Well, even without modifications suggested in your other answer, your `Word` modification did the job: down to 1s now. It was definitely an `Integer` overhead problem. Thanks! – m09 Mar 18 '12 at 19:14
@Mog Note that with 32-bit `Word`s, you have overflow, and it's sheer luck that you get the correct answer. – Daniel Fischer Mar 18 '12 at 19:22
@Mog: If you're on a 32-bit platform, try using `Word64`; it may have less overhead than `Integer`. – ehird Mar 18 '12 at 19:27
@Mog The largest number that occurs in one of the sequences is 56991483520, from the starting value 704511. It's just luck that none of the overflows leads to a longer sequence or that the one with the longest sequence doesn't overflow. – Daniel Fischer Mar 18 '12 at 19:52
@Daniel Fischer: well I don't plan on using windows for too long as it tends to provoke brain damage on me if I stay exposed. I'll get a fedora running soon enough and won't be bothered anymore by those pesky 32 bit `Int`s : d – m09 Mar 18 '12 at 19:58

On my current system (32-bit Core2Duo) your Haskell code, including all the optimizations given in the answers, takes `0.8s` to compile and `1.2s` to run.

You could transfer the run-time to compile-time, and reduce the run-time to nearly zero.

``````module Euler14 where

import Data.Word

terms :: Word -> Word
terms n = countTerms n 0
where
countTerms 1 acc             = acc + 1
countTerms n acc | even n    = countTerms (n `div` 2) (acc + 1)
| otherwise = countTerms (3 * n + 1) (acc + 1)

longestT :: Word -> Word -> (Word, Word)
longestT mi mx = find mi mx (0, 0)
where
find mi mx (ct,cn) | mi == mx  = if ct > terms mi then (ct,cn) else (terms mi, mi)
| otherwise = find (mi + 1) mx
(if ct > terms mi then (ct,cn) else (terms mi, mi))

longest :: Word -> Word -> ExpQ
longest mi mx = return \$ TupE [LitE (IntegerL (fromIntegral a)),
LitE (IntegerL (fromIntegral b))]
where
(a,b) = longestT mi mx
``````

and

``````{-# LANGUAGE TemplateHaskell #-}
import Euler14

main = print \$(longest 500000 999999)
``````

On my system it takes `2.3s` to compile this but the run-time goes down to `0.003s`. Compile Time Function Execution (CTFE) is something you can't do in C/C++. The only other programming language that I know of that supports CTFE is the D programming language. And just to be complete, the C code takes `0.1s` to compile and `0.7s` to run.

-
In many cases, you can avoid having to write wrappers like `longest` yourself and instead use `lift` from `Language.Haskell.TH.Syntax` to construct a literal expression from the result of your calculation. (Annoyingly though, there is no `Lift` instance for `Word`, so some tweaks are needed to make that work in this case). – hammar Apr 3 '12 at 21:31
@hammar Thanks for the tip. I'm new to Template Haskell :-) – Arlen Apr 3 '12 at 21:43
fun stuff, thanks :) – m09 Apr 4 '12 at 8:07