## Make a `Key`

type, and use smart constructors

The main source of boilerplate seems to be the repeated checks that `r`

is invertible, and calculation of its inverse. It makes sense to split your operations (eg `encipher`

) into two steps: first *check*, then *actually encipher*. This way, you can write the checking part just once.

One way to achieve this is by defining a new type `CaesarKey`

which is guaranteed to contain *only* valid keys. We can guarantee this invariant using smart constructors, as follows:

```
{-# LANGUAGE RecordWildCards #-} -- for the Key{..} syntax below
-- invariant: r and q are inverses mod 26.
-- To ensure this invariant, we only export the 'caesarKey' smart constructor,
-- and not the underlying 'Key' constructor
data CaesarKey = Key { r :: Integer, s :: Integer, q :: Integer }
caesarKey :: Integer -> Integer -> Maybe CaesarKey
caesarKey r s = Key r s <$> invertMod r 26
-- ciphers
encipher :: CaesarKey -> Integer -> Integer
encipher Key{..} p = mod (r * p + s) 26
decipher :: CaesarKey -> Integer -> Integer
decipher Key{..} c = mod (q * (c - s)) 26
encipherString :: CaesarKey -> String -> String
encipherString key = digitsToText . map (encipher key) . textToDigits
decipherString :: CaesarKey -> String -> String
decipherString key = digitsToText . map (decipher key) . textToDigits
```

## Define `invert`

on keys

Now we may take advantage of Daniel's observation that `decipher`

is just `encipher`

, but defined on a different key (namely the "inverse key"). So let's define an operation for inverting keys:

```
-- turns a key suitable for encoding into one suitable for decoding, and vice versa.
-- @invert (invert key) = key@
invert :: CaesarKey -> CaesarKey
invert (Key r s q) = Key q ((26-q)*s) r
```

and now we could throw out the `decipher`

and `decipherString`

functions as they are unnecessary (i.e. it's preferable to use `invert`

instead).

## Make an `allKeys`

function

Conceptually, we can split up `bruteForceCaesarDecipher`

into two tasks: first, generate all possible keys; second, decode the text with each key. Let's implement this in code:

```
allKeys :: [CaesarKey]
allKeys = catMaybes $ caesarKey <$> [1,3..25] <*> [1,3..25]
bruteForceCaesar :: String -> [String]
bruteForceCaesar str = [encipherString key str | key <- allKeys]
```

Besides giving easier-to-understand code (in my opinion), splitting the code up in this way has the advantage that we only build the list of keys *once*, rather than having to rebuild the keys for every string we want to decode.

Note also a few other small changes:

The complete code is here.

`Math.NumberTheory.GCD.extendedGCD`

,`Math.NumberTheory.Moduli.invertMod`

. – Daniel Fischer Apr 2 '12 at 1:17