## tl;dr - add type signature, use `ByteString`

and turn on -O3

But first of all - as others have said before - you are not comparing the same things, while your c code uses a lot of mutability and the weak type system of c. And I believe also the writing to a file is more unsafe than the haskell equivalent. You have the benefit of type-checking/type-inference of haskell.

Also note that without any type signature your code is polymorphic - i.e. you could use the same code with `Float`

or `Double`

, `Word8`

or `Int`

if you desired to do so. Here lies the first trap - for integral numbers GHC defaults to `Integer`

, an arbitrary precision integral number, equivalent to "bigint", which is usually slower by orders of magnitude.

Therefore adding a type signature, increases the speed tremendously.

(for exercise and learning) I did some comparison and implementation using unboxed types (ub-mandel), a typed version (mandel) and the op's untyped version (ut-mandel), as well as the c version (c-mandel).

measuring these programs you get the following (on a modern laptop using linux)

```
★ time ./c-mandel
./c-mandel 0,46s user 0,00s system 99% cpu 0,467 total
★ time stack exec -- ut-mandel
stack exec -- ut-mandel 9,33s user 0,09s system 99% cpu 9,432 total
★ time stack exec -- mandel
stack exec -- mandel 1,70s user 0,04s system 99% cpu 1,749 total
★ time stack exec -- ub-mandel
stack exec -- ub-mandel 1,25s user 0,08s system 98% cpu 1,343 total
```

Obviously the c code beats all implementations - but just adding the type signature brings a speedup by a factor of 5.49. Though doing the migration to unboxed types (which I have to admit was a first time) brings another 36 % speedup (note: this speedup is at the cost of the readability of the code).

But still this can be improved switching from the `String`

version to `ByteString`

gets us even further.

```
★ time stack exec -- ub-mandel-bytestring
stack exec -- ub-mandel-bytestring 0,84s user 0,04s system 98% cpu 0,890 total
```

## Lessons learned

- turn on type signatures
- turn on
`-O3`

- use
`Bytestring`

- if your code is still not fast enough - invest an hour and move to unboxed types
- if you still have energy, go read on reading llvm output and what the compiler does, a starting point would be neil mitchell's blog article

**Note:** all these calculations were done without the use of parallel computations, which I think could be done a lot more easily in haskell than in C. But this is a task I leave to someone else, or take a look at gh: simonmar/parconc-examples for a version that runs parallel on the gpu.

For completeness' sake the unboxed, bytestring version:

`Main.hs`

```
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE MagicHash #-}
module Main where
import Control.Monad
import Data.ByteString.Char8 as C
import System.IO (withFile, IOMode(WriteMode), Handle)
import GHC.Prim
import GHC.Exts (Int(..), Double(..))
import qualified Data.Vector.Unboxed as U
import qualified MandelV as MV
savePgm :: Int -> Int -> Int -> U.Vector Int -> String -> IO ()
savePgm w h orbits v filename =
withFile filename WriteMode $ \f -> do
hPutStrLn f "P2"
hPutStrLn f $ C.pack $ show w ++ " " ++ show h
hPutStrLn f (C.pack $ show orbits)
U.imapM_ (elm f) v
where
elm :: Handle -> Int -> Int -> IO ()
elm f ix e =
if rem ix w == 0
then hPutStrLn f $ C.pack $ show e
else hPutStr f $ C.pack $ show e ++ " "
main :: IO ()
main = do
let w = 2560# :: Int#
h = 1600# :: Int#
x1 = -2.0## :: Double#
y1 = -1.5## :: Double#
x2 = 1.0## :: Double#
y2 = 1.5## :: Double#
filename = "test_hs.pgm"
orbits = 63# :: Int#
radius = 2.0## :: Double#
v = MV.mandelbrot orbits radius x1 y1 x2 y2 w h :: U.Vector Int
savePgm (I# w) (I# h) (I# orbits) v filename
```

`MandelV.hs`

```
{-# LANGUAGE MagicHash #-}
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE UnboxedTuples #-}
module MandelV where
import GHC.Prim
import GHC.Exts
import qualified Data.Vector.Unboxed as U
orbits :: Int# -> Double# -> Double# -> Double# -> Int#
orbits limit radius a b =
go 0# 0.0## 0.0##
where
r2 = radius *## radius
go :: Int# -> Double# -> Double# -> Int#
go !n !x !y
| unsafeCoerce# (n ==# limit) = n
| unsafeCoerce# (x2 +## y2 >=## r2) = n
| otherwise = go (n +# 1#) (x2 -## y2 +## a) (2.0## *## x *## y +## b)
where
x2 = x *## x
y2 = y *## y
mandelbrot :: Int# -> Double# -> Double# -> Double# -> Double# -> Double# -> Int# -> Int# -> U.Vector Int
mandelbrot limit radius x1 y1 x2 y2 w h = U.generate (I# (w *# h)) f
where
mx = (x2 -## x1) /## int2Double# (w -# 1#)
my = (y2 -## y1) /## int2Double# (h -# 1#)
f :: Int -> Int
f (I# ix) = I# (orbits limit radius x y)
where (# j,i #) = quotRemInt# ix w
x = mx *## (x1 +## int2Double# i)
y = my *## (y1 +## int2Double# j)
```

relevant portions of

`mandel.cabal`

```
executable ub-mandel
main-is: Main.hs
other-modules: MandelV
-- other-extensions:
build-depends: base >=4.8 && <4.9
, vector >=0.11 && <0.12
, ghc-prim
, bytestring
hs-source-dirs: unboxed
default-language: Haskell2010
ghc-options: -O3
```

`orbits :: Int -> Double -> Double -> Double -> Int`

– Dan Jun 20 '16 at 20:22`Integers`

– cdk Jun 20 '16 at 21:07`-O3`

to the ghc compiler? This is a program you really want to optimize; with that, I'm down to 3x slowdown. The way you are doing the printing could also have some influence. – ejgallego Jun 20 '16 at 22:12