# Print Diamond Pattern using Haskell

I need to write a Haskell program that will generate a diamond output recursively. Here is some sample output for given input

input : 1
output :

`````` *
* *
*
``````

input : 2
output :

``````    *
* *
*
*     *
* *   * *
*     *
*
* *
*
``````

input : 3
output :

``````             *
* *
*
*     *
* *   * *
*     *
*
* *
*

*                 *
* *               * *
*                 *
*     *           *     *
* *   * *         * *   * *
*     *           *     *
*                 *
* *               * *
*                 *
*
* *
*
*     *
* *   * *
*     *
*
* *
*
``````

I wrote following functions:

``````next 0 = [1,0,1]
next n = map (+3^n) (next (n-1)) ++ next (n-1) ++ map (+3^n) (next (n-1))
lpad n = map (++"*") (zipWith (\$) (map (take)(next (n-1))) ((repeat(repeat ' '))))
pretty n = putStrLn \$ intercalate "\n" \$ lpad n
``````

which gives following outputs:

pretty 1

`````` *
*
*
``````

pretty 2

``````    *
*
*
*
*
*
*
*
*
``````

Can anyone help me with the remaining halves? Thanks in advance.

-
This was asked in an exam in PUCSD. (Pune university computer science department). – user1892530 Dec 10 '12 at 18:33
Its me Master . – user1892530 Dec 10 '12 at 18:36

For `n==0`, `next n` describes the whole picture up to mirroring. This is not the case anymore for greater `n`. So, in a first step, we change the `next` function to output a symmetric picture:

``````mmap = map . map

next :: Int -> [[Int]]
next 0 = [[1],[0,2],[1]]
next n = sn ++ map (\a -> a ++ map (+2*3^n) a) nn ++ sn
where
nn = next (n - 1)
sn = mmap (+3^n) nn
``````

Now, `next n` describes the positions of all stars. To print them, we first compute the relative distances.

``````diffs :: [Int] -> [Int]
diffs (x:xs) = x: diffs' x (xs)
where
diffs' x (y:ys) = y - x - 1 : diffs' y ys
diffs' _ [] = []
diffs [] = []

lpad = map (concatMap \$ \n -> replicate n ' ' ++ "*") . map diffs . next'
``````

Applied to one line, `diffs` returns the list of the number of spaces we need to put before each star and `lpad` generates the picture from that. Print it as before:

``````pretty :: Int -> IO ()
pretty n = putStrLn \$ unlines \$ lpad n
``````
-
This is a good solution to the problem as asked, and deserves more upvotes! – AndrewC Dec 9 '12 at 16:15

I liked the task, so I wrote an alternative solution.

We could build it up, a bit like you would with a pretty printer. Look into the pretty package to take these ideas and use them properly, but let's stick to plain old `[String]` for this.

First let's make a blank grid

``````blank :: Int -> [String]
blank n = replicate (3^n) \$ replicate (3^n) ' '
``````

Then let's define a diamond.

``````diamond :: Int -> [String]
diamond 0 = ["*"]
diamond n = let
o = diamond (n-1)
x = blank (n-1) in
joinMatrix [[x,o,x]
,[o,x,o]
,[x,o,x]]
``````

But how can we join this matrix of `[String]` together? First get all the `String`s that should be concatenated together next to each other instead of under each other using `transpose`, then `concat` them all:

``````joinLine :: [[String]] -> [String]
joinLine = map concat.transpose
``````

To do that to a whole matrix we need to join the lines on each row, then concat all the lines together into one list of lines:

``````joinMatrix :: [[[String]]] -> [String]
joinMatrix = concat.map joinLine
``````

helper functions for printing:

``````put = mapM_ putStrLn
d n = put \$ diamond n
``````

You could argue that the numerical solution is more efficient, and it is, but `d 4` is the largest that fits on my screen and isn't slow. You could also argue that this solution is clearer.

``````*Main> d 0
*
*Main> d 1
*
* *
*
*Main>  d 2
*
* *
*
*     *
* *   * *
*     *
*
* *
*
``````

(It works for higher n too, but they would make this post unnecessarily long on the page.)

-
Don't forget to vote for cebewee's good answer! – AndrewC Dec 9 '12 at 16:16
Thanks :) I very much like how in your approach, you only need to encode the diamond once, whereas in my approach, there are two diamonds: Once in `next 0`, and once in `next n`. – Lars Noschinski Dec 10 '12 at 9:28

This is derived from AndrewC's solution. The space blocks are recursively generated and I prefer to use operators to make the code clearer:

``````diamond
= putStr
. unlines
. fst
. (iterate f (["*"], [" "]) !!)
where
f (d, e)
= (  e + d + e
++  d + e + d
++  e + d + e
,  e + e + e
++  e + e + e
++  e + e + e
)

(+) = zipWith (++)
``````

A generalization. If we would like to have this:

``````             +
- -
+
-     -
+ +   + +
-     -
+
- -
+
-                 -
+ +               + +
-                 -
+     +           +     +
- -   - -         - -   - -
+     +           +     +
-                 -
+ +               + +
-                 -
+
- -
+
-     -
+ +   + +
-     -
+
- -
+
``````

then the solution is `star 3` where

``````star
= putStr
. unlines
. (\(d, p, e) -> d)
. (iterate f (["-"], ["+"], [" "]) !!)
where
f (d, p, e)
= (  e + p + e
++  d + e + d
++  e + p + e
,  e + d + e
++  p + e + p
++  e + d + e
,  e + e + e
++  e + e + e
++  e + e + e
)

(+) = zipWith (++)
``````
-
I agree, infixes are great here. Though many programmers would not much like the shadowing of `+`, perhaps something like `%` would be better (default fixity `infixl 9` would in this case be equivalent to +'s `infixl 6`; and redeclaring it `infixr 6` (or `infixr 4`, for that matter) would actually make it a bit more efficient). – leftaroundabout Jan 12 '13 at 11:47
`%` is used in `Data.Ratio`. I don't mind shadowing for small examples like this. – Péter Diviánszky Jan 20 '13 at 9:18