Hi I have this complex iterations program I wrote in TI Basic to perform a basic iteration on a complex number and then give the magnitude of the result:

``````INPUT “SEED?”, C
INPUT “ITERATIONS?”, N
C→Z
For (I,1,N)
Z^2 + C → Z
DISP Z
DISP “MAGNITUDE”, sqrt ((real(Z)^2 + imag(Z)^2))
PAUSE
END
``````

What I would like to do is make a Haskell version of this to wow my teacher in an assignment. I am still only learning and got this far:

``````fractal ::(RealFloat a) =>
(Complex a) -> (Integer a) -> [Complex a]
fractal c n | n == a = z : fractal (z^2 + c)
| otherwise = error "Finished"
``````

What I don't know how to do is how to make it only iterate `n` times, so I wanted to have it count up `a` and then compare it to `n` to see if it had finished.

-

``````fractal c n = take n \$ iterate (\z -> z^2 + c) c
``````

`Iterate` generates the infinite list of repeated applications. Ex:

``````iterate (2*) 1 == [1, 2, 4, 8, 16, 32, ...]
``````

Regarding the IO, you'll have to do some monadic computations.

``````import Data.Complex

fractal c n = take n \$ iterate (\z -> z^2 + c) c

main :: IO ()
main = do
-- Print and read (you could even omit the type signatures here)
putStr "Seed: "
c <- readLn :: IO (Complex Double)

putStr "Number of iterations: "
n <- readLn :: IO Int

-- Working with each element the result list
forM_ (fractal c n) \$ \current -> do
putStrLn \$ show current
putStrLn \$ "Magnitude: " ++ (show \$ magnitude current)
``````

Since Complex is convertible from and to strings by default, you can use `readLn` to read them from the console (format is `Re :+ Im`).

Edit: Just for fun, one could desugar the monadic syntax and type signatures which would compress the whole programm to this:

``````main =
(putStr "Seed: ") >> readLn >>= \c ->
(putStr "Number of iterations: ") >> readLn >>= \n ->
forM_ (take n \$ iterate (\z -> z^2 + c) c) \$ \current ->
putStrLn \$ show current ++ "\nMagnitude: " ++ (show \$ magnitude current)
``````

Edit #2: Some Links related to plotting and Mandelbrot's sets.

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Thanks, is there any way to perhaps get this drawn on a graph with some crazy colours if the results appear in the mandlebrot set (when magnitude < 2)? –  Jonno_FTW Sep 12 '09 at 13:11
Edited my post - Some very interesting links ;-) –  Dario Sep 12 '09 at 13:37
I am so compiling all this and the fractal plotter and sending my teacher an executable. –  Jonno_FTW Sep 12 '09 at 14:43

Well you can always generate an infinite list of results of repeated applications and take the first `n` of them using `take`. And the `iterate` function is useful for generating an infinite list of results of repeated applications.

-

If you'd like a list of values:

``````fractalList c n = fractalListHelper c c n
where
fractalListHelper z c 0 = []
fractalListHelper z c n = z : fractalListHelper (z^2 + c) c (n-1)
``````

If you only care about the last result:

``````fractal c n = fractalHelper c c n
where
fractalHelper z c 0 = z
fractalHelper z c n = fractalHelper (z^2 + c) c (n-1)
``````

Basically, in both cases you need a helper function to the counting and accumulation. Now I'm sure there's a better/less verbose way to do this, but I'm pretty much a Haskell newbie myself.

Edit: just for kicks, a foldr one-liner:

``````fractalFold c n = foldr (\c z -> z^2 + c) c (take n (repeat c))
``````

(although, the (take n (repeat c)) thing seems kind of unnecessary, there has to be an even better way)

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I think it's better to use `foldl'` instead of `foldr` like `fractalFold c n = foldl' (\z c -> z^2 + c) c (take n (repeat c))`. Because `foldr` is lazy. It means it creates thunks as the length of given list, but return type of `fractalFold` doesn't need to be lazy. –  nonowarn Jan 29 '10 at 3:46