# Project Euler #4 using Haskell

I hope this works by just pasting and running it with "runghc euler4.hs 1000". Since I am having a hard time learning Haskell, can someone perhaps tell me how I could improve here? Especially all those "fromIntegral" are a mess.

``````module Main where
import System.Environment

main :: IO ()
main = do
args <- getArgs
let
hBound = read (args !! 0)::Int
squarePal = pal hBound
lBound = floor \$ fromIntegral squarePal /
(fromIntegral hBound / fromIntegral squarePal)
euler = maximum \$ takeWhile (>squarePal) [ x | y <- [lBound..hBound],
z <- [y..hBound],
let x = y * z,
let s = show x,
s == reverse s ]
putStrLn \$ show euler

pal :: Int -> Int
pal n
| show pow == reverse (show pow) = n
| otherwise = pal (n-1)
where
pow = n^2
``````
-
See if codereview.stackexchange.com will field this question. – Robert Harvey Aug 20 '12 at 19:32
Don't really think this question merited closing, though he could have formulated his question better. But a bunch of questions like these come in every week and aren't closed normally. – identity Aug 20 '12 at 19:41

If what you want is integer division, you should use `div` instead of converting back and forth to `Integral` in order to use ordinary `/`.

``````module Main where
import System.Environment

main :: IO ()
main = do
(arg:_) <- getArgs
let
hBound = read arg :: Int
squarePal = pal hBound
lBound = squarePal * squarePal `div` hBound
euler = maximum \$ takeWhile (>squarePal) [ x | y <- [lBound..hBound],
z <- [y..hBound],
let x = y * z,
let s = show x,
s == reverse s ]
print euler

pal :: Int -> Int
pal n
| show pow == reverse (show pow) = n
| otherwise = pal (n - 1)
where
pow = n * n
``````

(I've re-written the `lbound` expression, that used two `/`, and fixed some styling issues highlighted by `hlint`.)

-
Thanks a lot. For answering even a few questions and reopening the question. – marcus Aug 23 '12 at 8:36

Okay, couple of things:

First, it might be better to pass in a lower bound and an upper bound for this question, it makes it a little bit more expandable.

If you're only going to use the first two (one in your previous case) arguments from the CL, we can handle this with pattern matching easily and avoid yucky statements like `(args !! 0)`:

``````(arg0:arg1:_) <- getArgs
``````

Let's convert these to `Int`s:

``````let [a, b] = map (\x -> read x :: Int) [arg0,arg1]
``````

Now we can reference `a` and `b`, our upper and lower bounds. Next, let's make a function that runs through all of the numbers between an upper and lower bound and gets a list of their products:

``````products a b = [x*y | x <- [a..b], y <- [x..b]]
``````

We do not have to run over each number twice, so we start `x` at our current `y` to get all of the different products.

from here, we'll want to make a method that filters out non-palindromes in some data set:

``````palindromes xs = filter palindrome xs
where palindrome x = show x == reverse \$ show x
``````

finally, in our main function:

``````print . maximum . palindromes \$ products a b
``````

Here's the full code if you would like to review it:

``````import System.Environment
main = do
(arg0:arg1:_) <- getArgs
let [a, b] = map (\x -> read x :: Int) [arg0,arg1]
print . maximum . palindromes \$ products a b

products a b = [x*y | x <- [a..b], y <- [x..b]]

palindromes = filter palindrome
where palindrome x = (show x) == (reverse \$ show x)
``````
-
Thanks, I have to take closer look at this one. Not really getting it immediately. – marcus Aug 23 '12 at 8:44