A Solution Using a Parsing Library
Since you'll probably have a number of people responding with code that parses strings of
map (map read . words) . lines $ contents), I'll skip that and introduce one of the parsing libraries. If you were to do this task for real work you'd probably use such a library that parses
ByteString (instead of
String, which means your IO reads everything into a linked list of individual characters).
import qualified Data.ByteString as B
First, I imported the Attoparsec and bytestring libraries. You can see these libraries and their documentation on hackage and install them using the
main = do
(fname:_) <- getArgs
parsed <- parseX fname
main is basically unchanged.
parseX :: FilePath -> IO (Int, Int, [Int], [[Int]])
parseX fname = do
bs <- B.readFile fname
let res = parseOnly parseDrozzy bs
-- We spew the error messages right here
either (error . show) return res
parseX (renamed from parse to avoid name collision) uses the bytestring library's readfile, which reads in the file packed, in contiguous bytes, instead of into cells of a linked list. After parsing I use a little shorthand to return the result if the parser returned
Right result or print an error if the parser returned a value of
-- Helper functions, more basic than you might think, but lets ignore it
sint = skipSpace >> int
int = liftM floor number
parseDrozzy :: Parser (Int, Int, [Int], [[Int]])
parseDrozzy = do
m <- sint
n <- sint
ks <- manyTill sint endOfLine
arr <- count m (count n sint)
The real work then happens in
parseDrozzy. We get our
Int values using the above helper. In most Haskell parsing libraries we must explicitly handle whitespace - so I skip the newline after
n to get to our
ks is just all the int values before the next newline. Now we can actually use the previously specified number of rows and columns to get our array.
Technically speaking, that final bit
arr <- count m (count n sint) doesn't follow your format. It will grab
n ints even if it means going to the next line. We could copy Python's behavior (not verifying the number of values in a row) using
count m (manyTill sint endOfLine) or we could check for each end of line more explicitly and return an error if we are short on elements.
From Lists to a Matrix
Lists of lists are not 2 dimensional arrays - the space and performance characteristics are completely different. Let's pack our list into a real matrix using Data.Array.Repa (
import Data.Array.Repa). This will allow us to access the elements of the array efficiently as well as perform operations on the entire matrix, optionally spreading the work among all the available CPUs.
Repa defines the dimensions of your array using a slightly odd syntax. If your row and column lengths are in variables
Z :. n :. m is much like the C declaration
int arr[m][n]. For the one dimensional example,
ks, we have:
fromList (Z :. (length ks)) ks
Which changes our type from
Array DIM1 Int.
For the two dimensional array we have:
let matrix = fromList (Z :. m :. n) (concat arr)
And change our type from
Array DIM2 Int.
So there you have it. A parsing of your file format into an efficient Haskell data structure using production-oriented libraries.