{-# LANGUAGE ScopedTypeVariables #-}

{-|
Description: Encryption of bytestrings using a type level nonce for determinism
License: BSD3

Given a strict 'ByteString' we compute a cryptographic hash of the associated
namespace (carried as a phantom type of kind 'Symbol').
The payload is then encrypted using the symmetric cipher in CBC mode using the
hashed namespace as an initialization vector (IV).

The probability of detecting a namespace mismatch is thus the density of valid
payloads within all 'ByteString's of the correct length.
-}
module Data.CryptoID.ByteString
  ( CryptoID(..)
  , CryptoIDKey
  , genKey, readKeyFile
  , encrypt
  , decrypt
  , CryptoIDError(..)
  , CryptoCipher, CryptoHash
  ) where

import Data.CryptoID

import Data.Binary
import Data.Binary.Put
import Data.Binary.Get

import Data.ByteString (ByteString)
import qualified Data.ByteString.Char8 as ByteString.Char

import qualified Data.ByteString.Lazy as Lazy (ByteString)

import Data.List (sortOn)
import Data.Ord (Down(..))

import Data.ByteArray (ByteArrayAccess)
import qualified Data.ByteArray as ByteArray

import Data.Foldable (asum)
import Control.Monad.Catch (MonadThrow(..))
import Control.Monad.IO.Class
import Control.Monad
import Control.Exception
import System.IO.Error

import Data.Typeable
import GHC.TypeLits

import Crypto.Cipher.Types
import Crypto.Cipher.Blowfish (Blowfish)
import Crypto.Hash (hash, Digest)
import Crypto.Hash.Algorithms (SHAKE128)
import Crypto.Error

import Crypto.Random.Entropy

import System.Directory
import System.FilePath


-- | The symmetric cipher 'BlockCipher' this module uses 
type CryptoCipher = Blowfish
-- | The cryptographic 'HashAlgorithm' this module uses
--
-- We expect the block size of 'CryptoCipher' to be exactly the size of the
-- 'Digest' generated by 'CryptoHash' (since a 'Digest' is used as an 'IV').
--
-- Violation of this expectation causes runtime errors.
type CryptoHash   = SHAKE128 64
  

-- | This newtype ensures only keys of the correct length can be created
--
-- Use 'genKey' to securely generate keys.
--
-- Use the 'Binary' instance to save and restore values of 'CryptoIDKey' across
-- executions.
newtype CryptoIDKey = CryptoIDKey { keyMaterial :: ByteString }
  deriving (Typeable, ByteArrayAccess)

-- | Does not actually show any key material
instance Show CryptoIDKey where
  show = show . typeOf

instance Binary CryptoIDKey where
  put = putByteString . keyMaterial
  get = CryptoIDKey <$> getKey (cipherKeySize cipher)
    where
      cipher :: CryptoCipher
      cipher = undefined

      -- Try key sizes from large to small ('Get' commits to the first branch
      -- that parses)
      getKey (KeySizeFixed n) = getByteString n
      getKey (KeySizeEnum ns) = asum [ getKey $ KeySizeFixed n | n <- sortOn Down ns ]
      getKey (KeySizeRange min max) = getKey $ KeySizeEnum [min .. max]


-- | Error cases that can be encountered during 'encrypt' and 'decrypt'
data CryptoIDError
  = AlgorithmError CryptoError
    -- ^ One of the underlying cryptographic algorithms
    --   ('CryptoHash' or 'CryptoCipher') failed.
  | NamespaceHashIsWrongLength ByteString
    -- ^ The length of the digest produced by 'CryptoHash' does
    --   not match the block size of 'CryptoCipher'.
    --
    -- The offending digest is included.
    --
    -- This error should not occur and is included primarily
    -- for sake of totality.
  | CiphertextConversionFailed
    -- ^ The produced 'ByteString' is the wrong length for conversion into a
    --   ciphertext.
  | DeserializationError (Lazy.ByteString, ByteOffset, String)
    -- ^ The plaintext obtained by decrypting a ciphertext with the given
    --   'CryptoIDKey' in the context of the @namespace@ could not be
    --   deserialized into a value of the expected @payload@-type.
    --
    -- This is expected behaviour if the @namespace@ or @payload@-type does not
    -- match the ones used during 'encrypt'ion or if the 'ciphertext' was
    -- tempered with.
  | InvalidNamespaceDetected
    -- ^ We have determined that, allthough deserializion succeded, the
    --   ciphertext was likely modified during transit or created using a
    --   different namespace.
  deriving (Show, Eq)

instance Exception CryptoIDError

-- | Securely generate a new key using system entropy
--
-- When 'CryptoCipher' accepts keys of varying lengths this function generates a
-- key of the largest accepted size.
genKey :: MonadIO m => m CryptoIDKey
genKey = CryptoIDKey <$> liftIO (getEntropy keySize)
  where
    keySize' = cipherKeySize (undefined :: CryptoCipher)

    keySize
      | KeySizeFixed n <- keySize' = n
      | KeySizeEnum ns <- keySize' = maximum ns
      | KeySizeRange _ max <- keySize' = max

-- | Try to read a 'CryptoIDKey' from a file.
--   If the file does not exist, securely generate a key (using 'genKey') and
--   save it to the file. 
readKeyFile :: MonadIO m => FilePath -> m CryptoIDKey
readKeyFile keyFile = liftIO $ decodeFile keyFile `catch` generateInstead
  where
    generateInstead e
      | isDoesNotExistError e = do
          createDirectoryIfMissing True $ takeDirectory keyFile
          key <- genKey
          encodeFile keyFile key
          return key
      | otherwise = throw e

  
-- | Use 'CryptoHash' to generate a 'Digest' of the Symbol passed as proxy type
namespace' :: forall proxy namespace m.
              ( KnownSymbol namespace, MonadThrow m
              ) => proxy namespace -> m (IV CryptoCipher)
namespace' p = case makeIV namespaceHash of
                 Nothing -> throwM . NamespaceHashIsWrongLength $ ByteArray.convert namespaceHash
                 Just iv -> return iv
  where
    namespaceHash :: Digest CryptoHash
    namespaceHash = hash . ByteString.Char.pack $ symbolVal p

-- | Wrap failure of one of the cryptographic algorithms as a 'CryptoIDError'
cryptoFailable :: MonadThrow m => CryptoFailable a -> m a
cryptoFailable = either (throwM . AlgorithmError) return . eitherCryptoError

-- | Encrypt a serialized value
encrypt :: forall m namespace.
           ( KnownSymbol namespace
           , MonadThrow m
           ) => CryptoIDKey -> ByteString -> m (CryptoID namespace ByteString)
encrypt (keyMaterial -> key) plaintext = do
  cipher <- cryptoFailable (cipherInit key :: CryptoFailable CryptoCipher)
  namespace <- namespace' (Proxy :: Proxy namespace)
  when (ByteArray.length plaintext `mod` blockSize cipher /= 0) $
    throwM CiphertextConversionFailed
  return . CryptoID $ cbcEncrypt cipher namespace plaintext


-- | Decrypt a serialized value
decrypt :: forall m namespace.
           ( KnownSymbol namespace
           , MonadThrow m
           ) => CryptoIDKey -> CryptoID namespace ByteString -> m ByteString
decrypt (keyMaterial -> key) CryptoID{..} = do
  cipher <- cryptoFailable (cipherInit key :: CryptoFailable CryptoCipher)
  namespace <- namespace' (Proxy :: Proxy namespace)
  return $ cbcDecrypt cipher namespace ciphertext