undefined
.
CIS 5520 students should be able to access this code through
github. Eventually, the
completed version will be available.
In class exercise: SecretCode
> module SecretCode where
Remember that you can execute the definitions in this module by loading it into ghci. In the terminal, you can use the command
stack ghci SecretCode.hs
to automatically start ghci and load the module.
OK, we're going to write a Haskell program to encode and decode text files using a secret code.
We'll call it the Brown Fox code. Here's how it works:
- Replace each letter according to the following correspondence:
"abcdefghijklmnopqrstuvwxyz"
to "thequickbrownfxjmpsvlazydg"
But leave any non-letter characters alone.
- Then reverse the order of the lines in the file.
> import Data.Char
> import Data.Maybe
> import Test.HUnit
> import System.FilePath -- library for manipulating FilePaths.
First, we make a lookup list (aka association list) containing each pair of corresponding letters:
> code :: [(Char,Char)]
> code = zip ['a' .. 'z'] cypher ++ zip ['A' .. 'Z'] (map toUpper cypher)
> where
> cypher :: String
> cypher = "thequickbrownfxjmpsvlazydg"
Now, how can we use this lookup list?
Association lists seem like they are probably a pretty common idiom, so let's check Hoogle to see if there is a function to look things up in them automatically...
What type would such a function have? In our case, we want something like:
[(Char,Char)] -> Char -> Char
That is, the function should take a list that maps Char
s to Char
s and a
specific Char
, and it should return the corresponding Char
from the list
(if it is present). The first hit on
Hoogle
for this type is the standard library function lookup
:
lookup :: Eq a => a -> [(a,b)] -> Maybe b
Ignoring the Eq a
part for now (we'll talk about it next week), this
type makes a lot of sense. It's a bit more general than what we
searched for, allowing the function to be called with different types
for the "keys" and "values" of the association list to take on
different, and lookup
also returns a Maybe
type because the thing
we're looking up might not be in the list.
(Recall that a Maybe a
is either Just v
for some v of type a
, or
Nothing.)
So, we can use lookup
to encode a particular character. If we don't have a mapping for a
character in our code, (i.e. for punctuation) we should leave it alone.
> -- >>> encodeChar 'a'
> -- 't'
> -- >>> encodeChar '.'
> -- '.
> encodeChar :: Char -> Char
> encodeChar c = undefined
> testEncodeChar = runTestTT $ TestList [ encodeChar 'a' ~?= 't',
> encodeChar '.' ~?= '.']
We'll next need a way to encode a whole line of text. Of course, remembering
that String
s are just lists of Char
s, there is a perfect higher-order
function in HigherOrder
that we can use:
> -- >>> encodeLine "abc defgh"
> -- "the quick"
> encodeLine :: String -> String
> encodeLine = undefined
> testEncodeLine = runTestTT $ TestList [encodeLine "abc defgh" ~?= "the quick"]
Finally, we need a function to encode a whole file. Remember, we want to
reverse the order of the lines (so that the last line is first, and so on),
then swap the letters in each. The
reverse
function in the standard library will come in handy.
However, we also need a way to break a file into
lines - we could do this manually by folding over the String
and checking
for newlines, but this seems like a commonly used function, let's check
Hoogle
instead. Indeed, we find a function of type
String -> [String]
in the standard library to do just this. Furthermore, its counterpart of type
[String] -> String
So...
> encodeContent :: String -> String
> encodeContent = undefined
> testEncodeContent = runTestTT $
> encodeContent "abc\n defgh\n" ~?= " quick\nthe\n"
Don't forget that the . operator is function composition. That is:
(f . g) x = f (g x)
See if you can simplify your definition of encodeContent
using this
operator.
OK, now let's construct an IO action that actually reads in a file from disk, encodes it, and writes it back out. We can look at the Haskell Prelude to find functions for reading and writing files.
readFile :: FilePath -> IO String
writeFile :: FilePath -> String -> IO ()
Your function should read from the file 'f', but shouldn't overwrite the file
with the encoded version. In Haskell, FilePath
s can be manipulated with
functions in the System.FilePath
library.
For example, we can use the replaceExtension
function to create a new file
name for output.
> encodeFile :: FilePath -> IO ()
> encodeFile f =
> if takeExtension f == "code"
> then putStrLn "Cannot encode .code files"
> else do
> let outFilePath = replaceExtension f "code"
> undefined
Finally, let's put it all together into a "main" function that reads in a file name from the standard input stream and swizzles it:
> main :: IO ()
> main = do putStrLn "What file shall I encode?"
> fn <- getLine
> encodeFile fn
> putStrLn "All done!"