Merge branch 'master' into uni2work

Merge pull request #371 from Vlix/patch-1
Small refactor
2024-01-09 02:48:31 +01:00 · 2022-10-03 08:11:46 +08:00 · 2022-10-03 01:01:30 +02:00 · 2022-05-02 12:31:16 +08:00 · 2022-03-13 20:54:14 +08:00 · 2022-03-13 20:49:31 +08:00
307 changed files with 24600 additions and 20990 deletions
--- a/.appveyor.yml
+++ b/.appveyor.yml
@ -0,0 +1,29 @@
 # ~*~ auto-generated by haskell-ci with config : 4fdddfa41dd039e198b8d125a70471f7dd140fa01001d99126af56fb31429ece ~*~
 version: "{build}"
 clone_folder: C:\project
 build: off
 cache:
  - "C:\\SR -> .appveyor.yml"
 environment:
  global:
    STACK_ROOT: "C:\\SR"
  matrix:
    - { BUILD: "ghc-8.6", STACKCMD: "stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps", STACKCFG: "{ resolver: lts-14.27, packages: [ '.' ], extra-deps: [], flags: {} }", STACKURL: "https://www.stackage.org/stack/windows-x86_64" }
    - { BUILD: "ghc-8.8", STACKCMD: "stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps", STACKCFG: "{ resolver: lts-15.1, packages: [ '.' ], extra-deps: [], flags: {} }", STACKURL: "https://www.stackage.org/stack/windows-x86_64" }
 matrix:
  fast_finish: true
 install:
  - set PATH=C:\Program Files\Git\mingw64\bin;%PATH%
  - curl -ostack.zip -L %STACKURL%
  - 7z x stack.zip stack.exe
  - refreshenv
 test_script:
  - echo %STACKCFG% > stack.yaml
  - stack setup > nul
  - echo "" | %STACKCMD%
--- a/.envrc
+++ b/.envrc
@ -0,0 +1 @@
 use flake
--- a/.gitignore
+++ b/.gitignore
@ -12,3 +12,4 @@ benchs/Hash
 *.sublime-workspace
 .cabal-sandbox/
 cabal.sandbox.config
 stack.yaml.lock
--- a/.haskell-ci
+++ b/.haskell-ci
@ -0,0 +1,26 @@
 # compiler supported and their equivalent LTS
 compiler: ghc-8.0 lts-9.21
 compiler: ghc-8.2 lts-11.22
 compiler: ghc-8.4 lts-12.26
 compiler: ghc-8.6 lts-14.27
 compiler: ghc-8.8 lts-15.1
 # options
 # option: alias x=y z=v
 option: gaugedeps extradep=gauge-0.2.1
 option: basementmin extradep=basement-0.0.8 extradep=memory-0.14.18
 # builds
 build: ghc-8.0 basementmin gaugedeps
 build: ghc-8.2 basementmin
 build: ghc-8.4
 build: ghc-8.6 os=linux,osx,windows
 build: ghc-8.8 os=linux,windows
 # packages
 package: '.'
 # extra builds
 hlint: allowed-failure
 weeder: allowed-failure
 coverall: false
--- a/.hlint.yaml
+++ b/.hlint.yaml
@ -0,0 +1,3 @@
 - arguments: [ --cpp-define=ARCH_X86_64
             ]
 - ignore: { name: Use camelCase }
--- a/.travis.yml
+++ b/.travis.yml
@ -1,50 +1,83 @@
-sudo: false
+# ~*~ auto-generated by haskell-ci with config : 4fdddfa41dd039e198b8d125a70471f7dd140fa01001d99126af56fb31429ece ~*~
-env:
+# Caching so the next build will be fast too.
- - CABALVER=1.18 GHCVER=7.8.4
+cache:
- - CABALVER=1.22 GHCVER=7.10.3
+  directories:
- - CABALVER=1.24 GHCVER=8.0.1 RUNTEST=0
+  - $HOME/.ghc
- - CABALVER=head GHCVER=head RUNTEST=0
+  - $HOME/.stack
  - $HOME/.local
-matrix:
+language: generic
 os: linux
 jobs:
  include:
  - { env: BUILD=stack RESOLVER=ghc-8.0, addons: { apt: { packages: [ libgmp-dev ] } } }
  - { env: BUILD=stack RESOLVER=ghc-8.2, addons: { apt: { packages: [ libgmp-dev ] } } }
  - { env: BUILD=stack RESOLVER=ghc-8.4, addons: { apt: { packages: [ libgmp-dev ] } } }
  - { env: BUILD=stack RESOLVER=ghc-8.6, addons: { apt: { packages: [ libgmp-dev ] } } }
  - { env: BUILD=stack RESOLVER=ghc-8.6, addons: { apt: { packages: [ libgmp-dev ] } }, os: osx }
  - { env: BUILD=stack RESOLVER=ghc-8.8, addons: { apt: { packages: [ libgmp-dev ] } } }
  - { env: BUILD=hlint }
  - { env: BUILD=weeder, addons: { apt: { packages: [ libgmp-dev ] } } }
  allow_failures:
-   - env: CABALVER=head GHCVER=head RUNTEST=0
+  - { env: BUILD=hlint }
-
+  - { env: BUILD=weeder, addons: { apt: { packages: [ libgmp-dev ] } } }
 addons:
    apt:
        sources:
         - hvr-ghc
        packages:
         - cabal-install-1.18
         - cabal-install-1.20
         - cabal-install-1.22
         - cabal-install-1.24
         - cabal-install-head
         - ghc-7.8.4
         - ghc-7.10.3
         - ghc-8.0.1
         - ghc-head
 before_install:
 - export PATH=/opt/ghc/$GHCVER/bin:/opt/cabal/$CABALVER/bin:$PATH
 install:
- - cabal --version
+  - export PATH=$HOME/.local/bin:$HOME/.cabal/bin:$PATH
- - echo "$(ghc --version) [$(ghc --print-project-git-commit-id 2> /dev/null || echo '?')]"
+  - mkdir -p ~/.local/bin
- - travis_retry cabal update
+  - |
- - if [ "${RUNTEST}" != "0" ]; then cabal install --only-dependencies --enable-tests; else cabal install --only-dependencies; fi
+    case "$BUILD" in
      stack|weeder)
        if [ `uname` = "Darwin" ]
        then
          travis_retry curl -L https://www.stackage.org/stack/osx-x86_64 | tar xz --strip-components=1 --include '*/stack' -C ~/.local/bin
        else
          travis_retry curl -L https://www.stackage.org/stack/linux-x86_64 | tar xz --wildcards --strip-components=1 -C ~/.local/bin '*/stack'
        fi
      ;;
    cabal)
      ;;
    esac
 script:
- - if [ "${RUNTEST}" != "0" ]; then cabal configure --enable-tests -v2; else cabal configure -v2; fi
+- |
- - cabal build
+  set -ex
- - if [ "${RUNTEST}" != "0" ]; then cabal test; fi;
+  if [ "x${RUNTEST}" = "xfalse" ]; then exit 0; fi
- - cabal check
+  case "$BUILD" in
- - cabal sdist
+    stack)
- - export SRC_TGZ=$(cabal info . | awk '{print $2 ".tar.gz";exit}') ;
+      # create the build stack.yaml
-   cd dist/;
+      case "$RESOLVER" in
-   if [ -f "$SRC_TGZ" ]; then
+      ghc-8.0)
-      cabal install --force-reinstalls "$SRC_TGZ";
+        echo "{ resolver: lts-9.21, packages: [ '.' ], extra-deps: [ basement-0.0.8, memory-0.14.18, gauge-0.2.1 ], flags: {} }" > stack.yaml
-   else
+        stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps
-      echo "expected '$SRC_TGZ' not found";
+        ;;
-      exit 1;
+      ghc-8.2)
-   fi
+        echo "{ resolver: lts-11.22, packages: [ '.' ], extra-deps: [ basement-0.0.8, memory-0.14.18 ], flags: {} }" > stack.yaml
        stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps
        ;;
      ghc-8.4)
        echo "{ resolver: lts-12.26, packages: [ '.' ], extra-deps: [], flags: {} }" > stack.yaml
        stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps
        ;;
      ghc-8.6)
        echo "{ resolver: lts-14.27, packages: [ '.' ], extra-deps: [], flags: {} }" > stack.yaml
        stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps
        ;;
      ghc-8.8)
        echo "{ resolver: lts-15.1, packages: [ '.' ], extra-deps: [], flags: {} }" > stack.yaml
        stack --no-terminal build --install-ghc --coverage --test --bench --no-run-benchmarks --haddock --no-haddock-deps
        ;;
      esac
      ;;
    hlint)
      curl -sL https://raw.github.com/ndmitchell/hlint/master/misc/travis.sh | sh -s . --cpp-define=__GLASGOW_HASKELL__=800 --cpp-define=x86_64_HOST_ARCH=1 --cpp-define=mingw32_HOST_OS=1
      ;;
    weeder)
      stack --no-terminal build --install-ghc --ghc-options="-ddump-to-file -ddump-hi" --test --no-run-tests --bench --no-run-benchmarks
      curl -sL https://raw.github.com/ndmitchell/weeder/master/misc/travis.sh | sh -s .
      ;;
  esac
  set +ex
--- a/CHANGELOG.md
+++ b/CHANGELOG.md
@ -1,3 +1,115 @@
 ## 0.30
 * Fix some C symbol blake2b prefix to be cryptonite_ prefix (fix mixing with other C library)
 * add hmac-lazy
 * Fix compilation with GHC 9.2
 * Drop support for GHC8.0, GHC8.2, GHC8.4, GHC8.6
 ## 0.29
 * advance compilation with gmp breakage due to change upstream
 * Add native EdDSA support
 ## 0.28
 * Add hash constant time capability
 * Prevent possible overflow during hashing by hashing in 4GB chunks
 ## 0.27
 * Optimise AES GCM and CCM
 * Optimise P256R1 implementation
 * Various AES-NI building improvements
 * Add better ECDSA support
 * Add XSalsa derive
 * Implement square roots for ECC binary curve
 * Various tests and benchmarks
 ## 0.26
 * Add Rabin cryptosystem (and variants)
 * Add bcrypt_pbkdf key derivation function
 * Optimize Blowfish implementation
 * Add KMAC (Keccak Message Authentication Code)
 * Add ECDSA sign/verify digest APIs
 * Hash algorithms with runtime output length
 * Update blake2 to latest upstream version
 * RSA-PSS with arbitrary key size
 * SHAKE with output length not divisible by 8
 * Add Read and Data instances for Digest type
 * Improve P256 scalar primitives
 * Fix hash truncation bug in DSA
 * Fix cost parsing for bcrypt
 * Fix ECC failures on arm64
 * Correction to PKCS#1 v1.5 padding
 * Use powModSecInteger when available
 * Drop GHC 7.8 and GHC 7.10 support, refer to pkg-guidelines
 * Optimise GCM mode
 * Add little endian serialization of integer
 ## 0.25
 * Improve digest binary conversion efficiency
 * AES CCM support
 * Add MonadFailure instance for CryptoFailable
 * Various misc improvements on documentation
 * Edwards25519 lowlevel arithmetic support
 * P256 add point negation
 * Improvement in ECC (benchmark, better normalization)
 * Blake2 improvements to context size
 * Use gauge instead of criterion
 * Use haskell-ci for CI scripts
 * Improve Digest memory representation to be 2 less Ints and one less boxing
  moving from `UArray` to `Block`
 ## 0.24
 * Ed25519: generateSecret & Documentation updates
 * Repair tutorial
 * RSA: Allow signing digest directly
 * IV add: fix overflow behavior
 * P256: validate point when decoding
 * Compilation fix with deepseq disabled
 * Improve Curve448 and use decaf for Ed448
 * Compilation flag blake2 sse merged in sse support
 * Process unaligned data better in hashes and AES, on architecture needing alignment
 * Drop support for ghc 7.6
 * Add ability to create random generator Seed from binary data and
  loosen constraint on ChaChaDRG seed from ByteArray to ByteArrayAccess.
 * Add 3 associated types with the HashAlgorithm class, to get
  access to the constant for BlockSize, DigestSize and ContextSize at the type level.
  the related function that this replaced will be deprecated in later release, and
  eventually removed.
 API CHANGES:
 * Improve ECDH safety to return failure for bad inputs (e.g. public point in small order subgroup).
  To go back to previous behavior you can replace `ecdh` by `ecdhRaw`. It's recommended to
  use `ecdh` and handle the error appropriately.
 * Users defining their own HashAlgorithm needs to define the
  HashBlockSize, HashDigest, HashInternalContextSize associated types
 ## 0.23
 * Digest memory usage improvement by using unpinned memory
 * Fix generateBetween to generate within the right bounds
 * Add pure Twofish implementation
 * Fix memory allocation in P256 when using a temp point
 * Consolidate hash benchmark code
 * Add Nat-length Blake2 support (GHC > 8.0)
 * Update tutorial
 ## 0.22
 * Add Argon2 (Password Hashing Competition winner) hash function
 * Update blake2 to latest upstream version
 * Add extra blake2 hashing size
 * Add faster PBKDF2 functions for SHA1/SHA256/SHA512
 * Add SHAKE128 and SHAKE256
 * Cleanup prime generation, and add tests
 * Add Time-based One Time Password (TOTP) and HMAC-based One Time Password (HOTP)
 * Rename Ed448 module name to Curve448, old module name still valid for now
 ## 0.21
 * Drop automated tests with GHC 7.0, GHC 7.4, GHC 7.6. support dropped, but probably still working.
--- a/Crypto/Cipher/AES.hs
+++ b/Crypto/Cipher/AES.hs
@ -14,12 +14,11 @@ module Crypto.Cipher.AES
 import Crypto.Error
 import Crypto.Cipher.Types
 import Crypto.Cipher.Utils
 import Crypto.Cipher.Types.Block
 import Crypto.Cipher.AES.Primitive
 import Crypto.Internal.Imports
 import Data.ByteArray as BA
 -- | AES with 128 bit key
 newtype AES128 = AES128 AES
    deriving (NFData)
@ -47,15 +46,6 @@ instance Cipher AES256 where
    cipherKeySize _ = KeySizeFixed 32
    cipherInit k    = AES256 <$> (initAES =<< validateKeySize (undefined :: AES256) k)
 validateKeySize :: (ByteArrayAccess key, Cipher cipher) => cipher -> key -> CryptoFailable key
 validateKeySize c k = if validKeyLength
                      then CryptoPassed k
                      else CryptoFailed CryptoError_KeySizeInvalid
  where keyLength = BA.length k
        validKeyLength = case cipherKeySize c of
          KeySizeRange low high -> keyLength >= low && keyLength <= high
          KeySizeEnum lengths -> keyLength `elem` lengths
          KeySizeFixed s -> keyLength == s
 #define INSTANCE_BLOCKCIPHER(CSTR) \
 instance BlockCipher CSTR where \
@ -67,6 +57,7 @@ instance BlockCipher CSTR where \
    ; ctrCombine (CSTR aes) (IV iv) = encryptCTR aes (IV iv) \
    ; aeadInit AEAD_GCM (CSTR aes) iv = CryptoPassed $ AEAD (gcmMode aes) (gcmInit aes iv) \
    ; aeadInit AEAD_OCB (CSTR aes) iv = CryptoPassed $ AEAD (ocbMode aes) (ocbInit aes iv) \
    ; aeadInit (AEAD_CCM n m l) (CSTR aes) iv = AEAD (ccmMode aes) <$> ccmInit aes iv n m l \
    ; aeadInit _        _          _  = CryptoFailed CryptoError_AEADModeNotSupported \
    }; \
 instance BlockCipher128 CSTR where \
--- a/Crypto/Cipher/AES/Primitive.hs
+++ b/Crypto/Cipher/AES/Primitive.hs
@ -11,39 +11,46 @@
 --
 module Crypto.Cipher.AES.Primitive
    (
-    -- * block cipher data types
+    -- * Block cipher data types
      AES
    -- * Authenticated encryption block cipher types
    , AESGCM
    , AESOCB
-    -- * creation
+    -- * Creation
    , initAES
-    -- * misc
+    -- * Miscellanea
    , genCTR
    , genCounter
-    -- * encryption
+    -- * Encryption
    , encryptECB
    , encryptCBC
    , encryptCTR
    , encryptXTS
-    -- * decryption
+    -- * Decryption
    , decryptECB
    , decryptCBC
    , decryptCTR
    , decryptXTS
-    -- * incremental GCM
+    -- * CTR with 32-bit wrapping
    , combineC32
    -- * Incremental GCM
    , gcmMode
    , gcmInit
-    -- * incremental OCB
+    -- * Incremental OCB
    , ocbMode
    , ocbInit
    -- * CCM
    , ccmMode
    , ccmInit
    ) where
 import           Data.Word
@ -73,6 +80,7 @@ instance BlockCipher AES where
    ctrCombine = encryptCTR
    aeadInit AEAD_GCM aes iv = CryptoPassed $ AEAD (gcmMode aes) (gcmInit aes iv)
    aeadInit AEAD_OCB aes iv = CryptoPassed $ AEAD (ocbMode aes) (ocbInit aes iv)
    aeadInit (AEAD_CCM n m l) aes iv = AEAD (ccmMode aes) <$> ccmInit aes iv n m l
    aeadInit _        _   _  = CryptoFailed CryptoError_AEADModeNotSupported
 instance BlockCipher128 AES where
    xtsEncrypt = encryptXTS
@ -96,6 +104,15 @@ ocbMode aes = AEADModeImpl
    , aeadImplFinalize     = ocbFinish aes
    }
 -- | Create an AES AEAD implementation for CCM
 ccmMode :: AES -> AEADModeImpl AESCCM
 ccmMode aes = AEADModeImpl
    { aeadImplAppendHeader = ccmAppendAAD aes
    , aeadImplEncrypt      = ccmEncrypt aes
    , aeadImplDecrypt      = ccmDecrypt aes
    , aeadImplFinalize     = ccmFinish aes
    }
 -- | AES Context (pre-processed key)
 newtype AES = AES ScrubbedBytes
@ -109,12 +126,19 @@ newtype AESGCM = AESGCM ScrubbedBytes
 newtype AESOCB = AESOCB ScrubbedBytes
    deriving (NFData)
 -- | AESCCM State
 newtype AESCCM = AESCCM ScrubbedBytes
    deriving (NFData)
 sizeGCM :: Int
-sizeGCM = 80
+sizeGCM = 320
 sizeOCB :: Int
 sizeOCB = 160
 sizeCCM :: Int
 sizeCCM = 80
 keyToPtr :: AES -> (Ptr AES -> IO a) -> IO a
 keyToPtr (AES b) f = withByteArray b (f . castPtr)
@ -152,6 +176,13 @@ withOCBKeyAndCopySt aes (AESOCB gcmSt) f =
        a     <- withByteArray newSt $ \gcmStPtr -> f (castPtr gcmStPtr) aesPtr
        return (a, AESOCB newSt)
 withCCMKeyAndCopySt :: AES -> AESCCM -> (Ptr AESCCM -> Ptr AES -> IO a) -> IO (a, AESCCM)
 withCCMKeyAndCopySt aes (AESCCM ccmSt) f =
    keyToPtr aes $ \aesPtr -> do
        newSt <- B.copy ccmSt (\_ -> return ())
        a     <- withByteArray newSt $ \ccmStPtr -> f (castPtr ccmStPtr) aesPtr
        return (a, AESCCM newSt)
 -- | Initialize a new context with a key
 --
 -- Key needs to be of length 16, 24 or 32 bytes. Any other values will return failure
@ -289,6 +320,21 @@ decryptXTS :: ByteArray ba
           -> ba         -- ^ output decrypted
 decryptXTS = doXTS c_aes_decrypt_xts
 -- | encrypt/decrypt using Counter mode (32-bit wrapping used in AES-GCM-SIV)
 {-# NOINLINE combineC32 #-}
 combineC32 :: ByteArray ba
           => AES        -- ^ AES Context
           -> IV AES     -- ^ initial vector of AES block size (usually representing a 128 bit integer)
           -> ba         -- ^ plaintext input
           -> ba         -- ^ ciphertext output
 combineC32 ctx iv input
    | len <= 0          = B.empty
    | B.length iv /= 16 = error $ "AES error: IV length must be block size (16). Its length is: " ++ show (B.length iv)
    | otherwise = B.allocAndFreeze len doEncrypt
  where doEncrypt o = withKeyAndIV ctx iv $ \k v -> withByteArray input $ \i ->
                      c_aes_encrypt_c32 (castPtr o) k v i (fromIntegral len)
        len = B.length input
 {-# INLINE doECB #-}
 doECB :: ByteArray ba
      => (Ptr b -> Ptr AES -> CString -> CUInt -> IO ())
@ -447,6 +493,78 @@ ocbFinish ctx ocb taglen = AuthTag $ B.take taglen computeTag
  where computeTag = B.allocAndFreeze 16 $ \t ->
                        withOCBKeyAndCopySt ctx ocb (c_aes_ocb_finish (castPtr t)) >> return ()
 ccmGetM :: CCM_M -> Int
 ccmGetL :: CCM_L -> Int
 ccmGetM m = case m of
  CCM_M4 -> 4
  CCM_M6 -> 6
  CCM_M8 -> 8
  CCM_M10 -> 10
  CCM_M12 -> 12
  CCM_M14 -> 14
  CCM_M16 -> 16
 ccmGetL l = case l of
  CCM_L2 -> 2
  CCM_L3 -> 3
  CCM_L4 -> 4
 -- | initialize a ccm context
 {-# NOINLINE ccmInit #-}
 ccmInit :: ByteArrayAccess iv => AES -> iv -> Int -> CCM_M -> CCM_L -> CryptoFailable AESCCM
 ccmInit ctx iv n m l
    | 15 - li /= B.length iv = CryptoFailed CryptoError_IvSizeInvalid
    | otherwise = unsafeDoIO $ do
          sm <- B.alloc sizeCCM $ \ccmStPtr ->
            withKeyAndIV ctx iv $ \k v ->
            c_aes_ccm_init (castPtr ccmStPtr) k v (fromIntegral $ B.length iv) (fromIntegral n) (fromIntegral mi) (fromIntegral li)
          return $ CryptoPassed (AESCCM sm)
  where
    mi = ccmGetM m
    li = ccmGetL l
 -- | append data which is only going to be authenticated to the CCM context.
 --
 -- needs to happen after initialization and before appending encryption/decryption data.
 {-# NOINLINE ccmAppendAAD #-}
 ccmAppendAAD :: ByteArrayAccess aad => AES -> AESCCM -> aad -> AESCCM
 ccmAppendAAD ctx ccm input = unsafeDoIO $ snd <$> withCCMKeyAndCopySt ctx ccm doAppend
  where doAppend ccmStPtr aesPtr =
            withByteArray input $ \i -> c_aes_ccm_aad ccmStPtr aesPtr i (fromIntegral $ B.length input)
 -- | append data to encrypt and append to the CCM context
 --
 -- the bytearray needs to be a multiple of AES block size, unless it's the last call to this function.
 -- needs to happen after AAD appending, or after initialization if no AAD data.
 {-# NOINLINE ccmEncrypt #-}
 ccmEncrypt :: ByteArray ba => AES -> AESCCM -> ba -> (ba, AESCCM)
 ccmEncrypt ctx ccm input = unsafeDoIO $ withCCMKeyAndCopySt ctx ccm cbcmacAndIv
  where len = B.length input
        cbcmacAndIv ccmStPtr aesPtr =
            B.alloc len $ \o ->
            withByteArray input $ \i ->
            c_aes_ccm_encrypt (castPtr o) ccmStPtr aesPtr i (fromIntegral len)
 -- | append data to decrypt and append to the CCM context
 --
 -- the bytearray needs to be a multiple of AES block size, unless it's the last call to this function.
 -- needs to happen after AAD appending, or after initialization if no AAD data.
 {-# NOINLINE ccmDecrypt #-}
 ccmDecrypt :: ByteArray ba => AES -> AESCCM -> ba -> (ba, AESCCM)
 ccmDecrypt ctx ccm input = unsafeDoIO $ withCCMKeyAndCopySt ctx ccm cbcmacAndIv
  where len = B.length input
        cbcmacAndIv ccmStPtr aesPtr =
            B.alloc len $ \o ->
            withByteArray input $ \i ->
            c_aes_ccm_decrypt (castPtr o) ccmStPtr aesPtr i (fromIntegral len)
 -- | Generate the Tag from CCM context
 {-# NOINLINE ccmFinish #-}
 ccmFinish :: AES -> AESCCM -> Int -> AuthTag
 ccmFinish ctx ccm taglen = AuthTag $ B.take taglen computeTag
  where computeTag = B.allocAndFreeze 16 $ \t ->
                        withCCMKeyAndCopySt ctx ccm (c_aes_ccm_finish (castPtr t)) >> return ()
 ------------------------------------------------------------------------
 foreign import ccall "cryptonite_aes.h cryptonite_aes_initkey"
    c_aes_init :: Ptr AES -> CString -> CUInt -> IO ()
@ -478,6 +596,9 @@ foreign import ccall unsafe "cryptonite_aes.h cryptonite_aes_gen_ctr_cont"
 foreign import ccall "cryptonite_aes.h cryptonite_aes_encrypt_ctr"
    c_aes_encrypt_ctr :: CString -> Ptr AES -> Ptr Word8 -> CString -> CUInt -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_encrypt_c32"
    c_aes_encrypt_c32 :: CString -> Ptr AES -> Ptr Word8 -> CString -> CUInt -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_gcm_init"
    c_aes_gcm_init :: Ptr AESGCM -> Ptr AES -> Ptr Word8 -> CUInt -> IO ()
@ -508,3 +629,17 @@ foreign import ccall "cryptonite_aes.h cryptonite_aes_ocb_decrypt"
 foreign import ccall "cryptonite_aes.h cryptonite_aes_ocb_finish"
    c_aes_ocb_finish :: CString -> Ptr AESOCB -> Ptr AES -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_ccm_init"
    c_aes_ccm_init :: Ptr AESCCM -> Ptr AES -> Ptr Word8 -> CUInt -> CUInt -> CInt -> CInt -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_ccm_aad"
    c_aes_ccm_aad :: Ptr AESCCM -> Ptr AES -> CString -> CUInt -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_ccm_encrypt"
    c_aes_ccm_encrypt :: CString -> Ptr AESCCM -> Ptr AES -> CString -> CUInt -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_ccm_decrypt"
    c_aes_ccm_decrypt :: CString -> Ptr AESCCM -> Ptr AES -> CString -> CUInt -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_ccm_finish"
    c_aes_ccm_finish :: CString -> Ptr AESCCM -> Ptr AES -> IO ()
--- a/Crypto/Cipher/AESGCMSIV.hs
+++ b/Crypto/Cipher/AESGCMSIV.hs
@ -0,0 +1,193 @@
 -- |
 -- Module      : Crypto.Cipher.AESGCMSIV
 -- License     : BSD-style
 -- Maintainer  : Olivier Chéron <olivier.cheron@gmail.com>
 -- Stability   : experimental
 -- Portability : unknown
 --
 -- Implementation of AES-GCM-SIV, an AEAD scheme with nonce misuse resistance
 -- defined in <https://tools.ietf.org/html/rfc8452 RFC 8452>.
 --
 -- To achieve the nonce misuse-resistance property, encryption requires two
 -- passes on the plaintext, hence no streaming API is provided.  This AEAD
 -- operates on complete inputs held in memory.  For simplicity, the
 -- implementation of decryption uses a similar pattern, with performance
 -- penalty compared to an implementation which is able to merge both passes.
 --
 -- The specification allows inputs up to 2^36 bytes but this implementation
 -- requires AAD and plaintext/ciphertext to be both smaller than 2^32 bytes.
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 module Crypto.Cipher.AESGCMSIV
    ( Nonce
    , nonce
    , generateNonce
    , encrypt
    , decrypt
    ) where
 import Data.Bits
 import Data.Word
 import Foreign.C.Types
 import Foreign.C.String
 import Foreign.Ptr (Ptr, plusPtr)
 import Foreign.Storable (peekElemOff, poke, pokeElemOff)
 import           Data.ByteArray
 import qualified Data.ByteArray as B
 import           Data.Memory.Endian (toLE)
 import           Data.Memory.PtrMethods (memXor)
 import Crypto.Cipher.AES.Primitive
 import Crypto.Cipher.Types
 import Crypto.Error
 import Crypto.Internal.Compat (unsafeDoIO)
 import Crypto.Random
 -- 12-byte nonces
 -- | Nonce value for AES-GCM-SIV, always 12 bytes.
 newtype Nonce = Nonce Bytes deriving (Show, Eq, ByteArrayAccess)
 -- | Nonce smart constructor.  Accepts only 12-byte inputs.
 nonce :: ByteArrayAccess iv => iv -> CryptoFailable Nonce
 nonce iv
    | B.length iv == 12 = CryptoPassed (Nonce $ B.convert iv)
    | otherwise         = CryptoFailed CryptoError_IvSizeInvalid
 -- | Generate a random nonce for use with AES-GCM-SIV.
 generateNonce :: MonadRandom m => m Nonce
 generateNonce = Nonce <$> getRandomBytes 12
 -- POLYVAL (mutable context)
 newtype Polyval = Polyval Bytes
 polyvalInit :: ScrubbedBytes -> IO Polyval
 polyvalInit h = Polyval <$> doInit
  where doInit = B.alloc 272 $ \pctx -> B.withByteArray h $ \ph ->
            c_aes_polyval_init pctx ph
 polyvalUpdate :: ByteArrayAccess ba => Polyval -> ba -> IO ()
 polyvalUpdate (Polyval ctx) bs = B.withByteArray ctx $ \pctx ->
    B.withByteArray bs $ \pbs -> c_aes_polyval_update pctx pbs sz
  where sz = fromIntegral (B.length bs)
 polyvalFinalize :: Polyval -> IO ScrubbedBytes
 polyvalFinalize (Polyval ctx) = B.alloc 16 $ \dst ->
    B.withByteArray ctx $ \pctx -> c_aes_polyval_finalize pctx dst
 foreign import ccall unsafe "cryptonite_aes.h cryptonite_aes_polyval_init"
    c_aes_polyval_init :: Ptr Polyval -> CString -> IO ()
 foreign import ccall "cryptonite_aes.h cryptonite_aes_polyval_update"
    c_aes_polyval_update :: Ptr Polyval -> CString -> CUInt -> IO ()
 foreign import ccall unsafe "cryptonite_aes.h cryptonite_aes_polyval_finalize"
    c_aes_polyval_finalize :: Ptr Polyval -> CString -> IO ()
 -- Key Generation
 le32iv :: Word32 -> Nonce -> Bytes
 le32iv n (Nonce iv) = B.allocAndFreeze 16 $ \ptr -> do
    poke ptr (toLE n)
    copyByteArrayToPtr iv (ptr `plusPtr` 4)
 deriveKeys :: BlockCipher128 aes => aes -> Nonce -> (ScrubbedBytes, AES)
 deriveKeys aes iv =
    case cipherKeySize aes of
        KeySizeFixed sz | sz `mod` 8 == 0 ->
            let mak = buildKey [0 .. 1]
                key = buildKey [2 .. fromIntegral (sz `div` 8) + 1]
                mek = throwCryptoError (cipherInit key)
             in (mak, mek)
        _ -> error "AESGCMSIV: invalid cipher"
  where
    idx n = ecbEncrypt aes (le32iv n iv) `takeView` 8
    buildKey = B.concat . map idx
 -- Encryption and decryption
 lengthInvalid :: ByteArrayAccess ba => ba -> Bool
 lengthInvalid bs
    | finiteBitSize len > 32 = len >= 1 `unsafeShiftL` 32
    | otherwise              = False
  where len = B.length bs
 -- | AEAD encryption with the specified key and nonce.  The key must be given
 -- as an initialized 'Crypto.Cipher.AES.AES128' or 'Crypto.Cipher.AES.AES256'
 -- cipher.
 --
 -- Lengths of additional data and plaintext must be less than 2^32 bytes,
 -- otherwise an exception is thrown.
 encrypt :: (BlockCipher128 aes, ByteArrayAccess aad, ByteArray ba)
        => aes -> Nonce -> aad -> ba -> (AuthTag, ba)
 encrypt aes iv aad plaintext
    | lengthInvalid aad = error "AESGCMSIV: aad is too large"
    | lengthInvalid plaintext = error "AESGCMSIV: plaintext is too large"
    | otherwise = (AuthTag tag, ciphertext)
  where
    (mak, mek) = deriveKeys aes iv
    ss = getSs mak aad plaintext
    tag = buildTag mek ss iv
    ciphertext = combineC32 mek (transformTag tag) plaintext
 -- | AEAD decryption with the specified key and nonce.  The key must be given
 -- as an initialized 'Crypto.Cipher.AES.AES128' or 'Crypto.Cipher.AES.AES256'
 -- cipher.
 --
 -- Lengths of additional data and ciphertext must be less than 2^32 bytes,
 -- otherwise an exception is thrown.
 decrypt :: (BlockCipher128 aes, ByteArrayAccess aad, ByteArray ba)
        => aes -> Nonce -> aad -> ba -> AuthTag -> Maybe ba
 decrypt aes iv aad ciphertext (AuthTag tag)
    | lengthInvalid aad = error "AESGCMSIV: aad is too large"
    | lengthInvalid ciphertext = error "AESGCMSIV: ciphertext is too large"
    | tag `constEq` buildTag mek ss iv = Just plaintext
    | otherwise = Nothing
  where
    (mak, mek) = deriveKeys aes iv
    ss = getSs mak aad plaintext
    plaintext = combineC32 mek (transformTag tag) ciphertext
 -- Calculate S_s = POLYVAL(mak, X_1, X_2, ...).
 getSs :: (ByteArrayAccess aad, ByteArrayAccess ba)
      => ScrubbedBytes -> aad -> ba -> ScrubbedBytes
 getSs mak aad plaintext = unsafeDoIO $ do
    ctx <- polyvalInit mak
    polyvalUpdate ctx aad
    polyvalUpdate ctx plaintext
    polyvalUpdate ctx (lb :: Bytes)  -- the "length block"
    polyvalFinalize ctx
  where
    lb = B.allocAndFreeze 16 $ \ptr -> do
            pokeElemOff ptr 0 (toLE64 $ B.length aad)
            pokeElemOff ptr 1 (toLE64 $ B.length plaintext)
    toLE64 x = toLE (fromIntegral x * 8 :: Word64)
 -- XOR the first 12 bytes of S_s with the nonce and clear the most significant
 -- bit of the last byte.
 tagInput :: ScrubbedBytes -> Nonce -> Bytes
 tagInput ss (Nonce iv) =
    B.copyAndFreeze ss $ \ptr ->
    B.withByteArray iv $ \ivPtr -> do
        memXor ptr ptr ivPtr 12
        b <- peekElemOff ptr 15
        pokeElemOff ptr 15 (b .&. (0x7f :: Word8))
 -- Encrypt the result with AES using the message-encryption key to produce the
 -- tag.
 buildTag :: BlockCipher128 aes => aes -> ScrubbedBytes -> Nonce -> Bytes
 buildTag mek ss iv = ecbEncrypt mek (tagInput ss iv)
 -- The initial counter block is the tag with the most significant bit of the
 -- last byte set to one.
 transformTag :: Bytes -> IV AES
 transformTag tag = toIV $ B.copyAndFreeze tag $ \ptr ->
    peekElemOff ptr 15 >>= pokeElemOff ptr 15 . (.|. (0x80 :: Word8))
  where toIV bs = let Just iv = makeIV (bs :: Bytes) in iv
--- a/Crypto/Cipher/Blowfish/Box.hs
+++ b/Crypto/Cipher/Blowfish/Box.hs
@ -5,15 +5,33 @@
 -- Portability : Good
 {-# LANGUAGE MagicHash #-}
 module Crypto.Cipher.Blowfish.Box
-    ( createKeySchedule
+    (   KeySchedule(..)
    ,   createKeySchedule
    ,   copyKeySchedule
    ) where
-import Crypto.Internal.WordArray (mutableArray32FromAddrBE, MutableArray32)
+import           Crypto.Internal.WordArray (MutableArray32,
                                            mutableArray32FromAddrBE,
                                            mutableArrayRead32,
                                            mutableArrayWrite32)
 newtype KeySchedule = KeySchedule MutableArray32
 -- | Copy the state of one key schedule into the other.
 --   The first parameter is the destination and the second the source.
 copyKeySchedule :: KeySchedule -> KeySchedule -> IO ()
 copyKeySchedule (KeySchedule dst) (KeySchedule src) = loop 0
  where
    loop 1042 = return ()
    loop i    = do
        w32 <-mutableArrayRead32 src i
        mutableArrayWrite32 dst i w32
        loop (i + 1)
 -- | Create a key schedule mutable array of the pbox followed by
 -- all the sboxes.
-createKeySchedule :: IO MutableArray32
+createKeySchedule :: IO KeySchedule
-createKeySchedule = mutableArray32FromAddrBE 1042 "\
+createKeySchedule = KeySchedule `fmap` mutableArray32FromAddrBE 1042 "\
    \\x24\x3f\x6a\x88\x85\xa3\x08\xd3\x13\x19\x8a\x2e\x03\x70\x73\x44\
    \\xa4\x09\x38\x22\x29\x9f\x31\xd0\x08\x2e\xfa\x98\xec\x4e\x6c\x89\
    \\x45\x28\x21\xe6\x38\xd0\x13\x77\xbe\x54\x66\xcf\x34\xe9\x0c\x6c\
--- a/Crypto/Cipher/Blowfish/Primitive.hs
+++ b/Crypto/Cipher/Blowfish/Primitive.hs
@ -5,18 +5,24 @@
 -- Portability : Good
 -- Rewritten by Vincent Hanquez (c) 2015
 --              Lars Petersen (c) 2018
 --
 -- Original code:
 --      Crypto.Cipher.Blowfish.Primitive, copyright (c) 2012 Stijn van Drongelen
 --      based on: BlowfishAux.hs (C) 2002 HardCore SoftWare, Doug Hoyte
 --           (as found in Crypto-4.2.4)
-
+{-# LANGUAGE BangPatterns #-}
 module Crypto.Cipher.Blowfish.Primitive
    ( Context
    , initBlowfish
    , encrypt
    , decrypt
-    , eksBlowfish
+    , KeySchedule
    , createKeySchedule
    , freezeKeySchedule
    , expandKey
    , expandKeyWithSalt
    , cipherBlockMutable
    ) where
 import           Control.Monad              (when)
@ -24,178 +30,229 @@ import           Data.Bits
 import           Data.Memory.Endian
 import           Data.Word
 import           Crypto.Cipher.Blowfish.Box
 import           Crypto.Error
 import           Crypto.Internal.ByteArray  (ByteArray, ByteArrayAccess)
 import qualified Crypto.Internal.ByteArray  as B
 import           Crypto.Internal.Compat
 import           Crypto.Internal.Imports
 import           Crypto.Internal.ByteArray (ByteArrayAccess, ByteArray, Bytes)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Internal.Words
 import           Crypto.Internal.WordArray
 import           Crypto.Cipher.Blowfish.Box
-- | variable keyed blowfish state
+newtype Context = Context Array32
 data Context = BF (Int -> Word32) -- p
                  (Int -> Word32) -- sbox0
                  (Int -> Word32) -- sbox1
                  (Int -> Word32) -- sbox2
                  (Int -> Word32) -- sbox2
 instance NFData Context where
-    rnf (BF p a b c d) = p `seq` a `seq` b `seq` c `seq` d `seq` ()
+    rnf a = a `seq` ()
 -- | Encrypt blocks
 --
 -- Input need to be a multiple of 8 bytes
 encrypt :: ByteArray ba => Context -> ba -> ba
 encrypt = cipher
 -- | Decrypt blocks
 --
 -- Input need to be a multiple of 8 bytes
 decrypt :: ByteArray ba => Context -> ba -> ba
 decrypt = cipher . decryptContext
 decryptContext :: Context -> Context
 decryptContext (BF p s0 s1 s2 s3) = BF (\i -> p (17-i)) s0 s1 s2 s3
 cipher :: ByteArray ba => Context -> ba -> ba
 cipher ctx b
    | B.length b == 0         = B.empty
    | B.length b `mod` 8 /= 0 = error "invalid data length"
    | otherwise               = B.mapAsWord64 (coreCrypto ctx) b
 -- | Initialize a new Blowfish context from a key.
 --
 -- key needs to be between 0 and 448 bits.
 initBlowfish :: ByteArrayAccess key => key -> CryptoFailable Context
 initBlowfish key
-    | len > (448 `div` 8) = CryptoFailed CryptoError_KeySizeInvalid
+    | B.length key > (448 `div` 8) = CryptoFailed CryptoError_KeySizeInvalid
-    | otherwise           = CryptoPassed $ makeKeySchedule key (Nothing :: Maybe (Bytes, Int))
+    | otherwise                    = CryptoPassed $ unsafeDoIO $ do
-  where len = B.length key
+        ks <- createKeySchedule
        expandKey ks key
        freezeKeySchedule ks
-- | The BCrypt "expensive key schedule" version of blowfish.
+-- | Get an immutable Blowfish context by freezing a mutable key schedule.
--
+freezeKeySchedule :: KeySchedule -> IO Context
-- Salt must be 128 bits
+freezeKeySchedule (KeySchedule ma) = Context `fmap` mutableArray32Freeze ma
 -- Cost must be between 4 and 31 inclusive
 -- See <https://www.usenix.org/conference/1999-usenix-annual-technical-conference/future-adaptable-password-scheme>
 eksBlowfish :: (ByteArrayAccess salt, ByteArrayAccess password) => Int -> salt -> password -> Context
 eksBlowfish cost salt key
    | B.length salt /= 16 = error "bcrypt salt must be 16 bytes"
    | otherwise           = makeKeySchedule key (Just (salt, cost))
-coreCrypto :: Context -> Word64 -> Word64
+expandKey :: (ByteArrayAccess key) => KeySchedule -> key -> IO ()
-coreCrypto (BF p s0 s1 s2 s3) input = doRound input 0
+expandKey ks@(KeySchedule ma) key = do
    when (B.length key > 0) $ iterKeyStream key 0 0 $ \i l r a0 a1 cont-> do
        mutableArrayWriteXor32 ma i l
        mutableArrayWriteXor32 ma (i + 1) r
        when (i + 2 < 18) (cont a0 a1)
    loop 0 0 0
    where
-    -- transform the input over 16 rounds
+        loop i l r = do
            n <- cipherBlockMutable ks (fromIntegral l `shiftL` 32 .|. fromIntegral r)
            let nl = fromIntegral (n `shiftR` 32)
                nr = fromIntegral (n .&. 0xffffffff)
            mutableArrayWrite32 ma i nl
            mutableArrayWrite32 ma (i + 1) nr
            when (i < 18 + 1024) (loop (i + 2) nl nr)
 expandKeyWithSalt :: (ByteArrayAccess key, ByteArrayAccess salt)
    => KeySchedule
    -> key
    -> salt
    -> IO ()
 expandKeyWithSalt ks key salt
    | B.length salt == 16 = expandKeyWithSalt128 ks key (fromBE $ B.toW64BE salt 0) (fromBE $ B.toW64BE salt 8)
    | otherwise           = expandKeyWithSaltAny ks key salt
 expandKeyWithSaltAny :: (ByteArrayAccess key, ByteArrayAccess salt)
    => KeySchedule         -- ^ The key schedule
    -> key                 -- ^ The key
    -> salt                -- ^ The salt
    -> IO ()
 expandKeyWithSaltAny ks@(KeySchedule ma) key salt = do
    when (B.length key > 0) $ iterKeyStream key 0 0 $ \i l r a0 a1 cont-> do
        mutableArrayWriteXor32 ma i l
        mutableArrayWriteXor32 ma (i + 1) r
        when (i + 2 < 18) (cont a0 a1)
    -- Go through the entire key schedule overwriting the P-Array and S-Boxes
    when (B.length salt > 0) $ iterKeyStream salt 0 0 $ \i l r a0 a1 cont-> do
        let l' = xor l a0
        let r' = xor r a1
        n <- cipherBlockMutable ks (fromIntegral l' `shiftL` 32 .|. fromIntegral r')
        let nl = fromIntegral (n `shiftR` 32)
            nr = fromIntegral (n .&. 0xffffffff)
        mutableArrayWrite32 ma i nl
        mutableArrayWrite32 ma (i + 1) nr
        when (i + 2 < 18 + 1024) (cont nl nr)
 expandKeyWithSalt128 :: ByteArrayAccess ba
    => KeySchedule         -- ^ The key schedule
    -> ba                  -- ^ The key
    -> Word64              -- ^ First word of the salt
    -> Word64              -- ^ Second word of the salt
    -> IO ()
 expandKeyWithSalt128 ks@(KeySchedule ma) key salt1 salt2 = do
    when (B.length key > 0) $ iterKeyStream key 0 0 $ \i l r a0 a1 cont-> do
        mutableArrayWriteXor32 ma i l
        mutableArrayWriteXor32 ma (i + 1) r
        when (i + 2 < 18) (cont a0 a1)
    -- Go through the entire key schedule overwriting the P-Array and S-Boxes
    loop 0 salt1 salt1 salt2
    where
        loop i input slt1 slt2
            | i == 1042   = return ()
            | otherwise = do
                n <- cipherBlockMutable ks input
                let nl = fromIntegral (n `shiftR` 32)
                    nr = fromIntegral (n .&. 0xffffffff)
                mutableArrayWrite32 ma i     nl
                mutableArrayWrite32 ma (i+1) nr
                loop (i+2) (n `xor` slt2) slt2 slt1
 -- | Encrypt blocks
 --
 -- Input need to be a multiple of 8 bytes
 encrypt :: ByteArray ba => Context -> ba -> ba
 encrypt ctx ba
    | B.length ba == 0         = B.empty
    | B.length ba `mod` 8 /= 0 = error "invalid data length"
    | otherwise                = B.mapAsWord64 (cipherBlock ctx False) ba
 -- | Decrypt blocks
 --
 -- Input need to be a multiple of 8 bytes
 decrypt :: ByteArray ba => Context -> ba -> ba
 decrypt ctx ba
    | B.length ba == 0         = B.empty
    | B.length ba `mod` 8 /= 0 = error "invalid data length"
    | otherwise                = B.mapAsWord64 (cipherBlock ctx True) ba
 -- | Encrypt or decrypt a single block of 64 bits.
 --
 -- The inverse argument decides whether to encrypt or decrypt.
 cipherBlock :: Context -> Bool -> Word64 -> Word64
 cipherBlock (Context ar) inverse input = doRound input 0
    where
    -- | Transform the input over 16 rounds
    doRound :: Word64 -> Int -> Word64
-    doRound i roundIndex
+    doRound !i roundIndex
        | roundIndex == 16 =
            let final = (fromIntegral (p 16) `shiftL` 32) .|. fromIntegral (p 17)
             in rotateL (i `xor` final) 32
        | otherwise     =
-            let newr = fromIntegral (i `shiftR` 32) `xor` (p roundIndex)
+            let newr = fromIntegral (i `shiftR` 32) `xor` p roundIndex
-                newi = ((i `shiftL` 32) `xor` (f newr)) .|. (fromIntegral newr)
+                newi = ((i `shiftL` 32) `xor` f newr) .|. fromIntegral newr
             in doRound newi (roundIndex+1)
    -- | The Blowfish Feistel function F
    f   :: Word32 -> Word64
-    f t = let a = s0 (fromIntegral $ (t `shiftR` 24) .&. 0xff)
+    f t = let a = s0 (0xff .&. (t `shiftR` 24))
-              b = s1 (fromIntegral $ (t `shiftR` 16) .&. 0xff)
+              b = s1 (0xff .&. (t `shiftR` 16))
-              c = s2 (fromIntegral $ (t `shiftR` 8) .&. 0xff)
+              c = s2 (0xff .&. (t `shiftR` 8))
-              d = s3 (fromIntegral $ t .&. 0xff)
+              d = s3 (0xff .&.  t)
           in fromIntegral (((a + b) `xor` c) + d) `shiftL` 32
-
+    -- | S-Box arrays, each containing 256 32-bit words
 -- | Create a key schedule for either plain Blowfish or the BCrypt "EKS" version
 -- For the expensive version, the salt and cost factor are supplied. Salt must be
 -- a 128-bit byte array.
 --
 -- The standard case is just a single key expansion with the salt set to zero.
 makeKeySchedule :: (ByteArrayAccess key, ByteArrayAccess salt) => key-> Maybe (salt, Int) -> Context
 makeKeySchedule keyBytes saltCost =
    let v = unsafeDoIO $ do
              mv <- createKeySchedule
              case saltCost of
                  -- Standard blowfish
                  Nothing -> expandKey mv 0 0 keyBytes
                  -- The expensive case
                  Just (s, cost)  -> do
                      let (salt1, salt2) = splitSalt s
                      expandKey mv salt1 salt2 keyBytes
                      forM_ [1..2^cost :: Int] $ \_ -> do
                          expandKey mv 0 0 keyBytes
                          expandKey mv 0 0 s
              mutableArray32Freeze mv
     in BF (\i -> arrayRead32 v i)
           (\i -> arrayRead32 v (s0+i))
           (\i -> arrayRead32 v (s1+i))
           (\i -> arrayRead32 v (s2+i))
           (\i -> arrayRead32 v (s3+i))
  where
        splitSalt s = (fromBE (B.toW64BE s 0), fromBE (B.toW64BE s 8))
        -- Indices of the S-Box arrays, each containing 256 32-bit words
    --   The first 18 words contain the P-Array of subkeys
-        s0 = 18
+    s0, s1, s2, s3 :: Word32 -> Word32
-        s1 = 274
+    s0 i            = arrayRead32 ar (fromIntegral i + 18)
-        s2 = 530
+    s1 i            = arrayRead32 ar (fromIntegral i + 274)
-        s3 = 786
+    s2 i            = arrayRead32 ar (fromIntegral i + 530)
    s3 i            = arrayRead32 ar (fromIntegral i + 786)
    p              :: Int -> Word32
    p i | inverse   = arrayRead32 ar (17 - i)
        | otherwise = arrayRead32 ar i
-expandKey :: ByteArrayAccess ba
+-- | Blowfish encrypt a Word using the current state of the key schedule
-          => MutableArray32      -- ^ The key schedule
+cipherBlockMutable :: KeySchedule -> Word64 -> IO Word64
-          -> Word64              -- ^ First word of the salt
+cipherBlockMutable (KeySchedule ma) input = doRound input 0
          -> Word64              -- ^ Second word of the salt
          -> ba                  -- ^ The key
          -> IO ()
 expandKey mv salt1 salt2 key = do
    when (len > 0) $ forM_ [0..17] $ \i -> do
        let a = B.index key ((i * 4 + 0) `mod` len)
            b = B.index key ((i * 4 + 1) `mod` len)
            c = B.index key ((i * 4 + 2) `mod` len)
            d = B.index key ((i * 4 + 3) `mod` len)
            k = (fromIntegral a `shiftL` 24) .|.
                (fromIntegral b `shiftL` 16) .|.
                (fromIntegral c `shiftL`  8) .|.
                (fromIntegral d)
        mutableArrayWriteXor32 mv i k
    prepare mv
    return ()
    where
-        len = B.length key
+    -- | Transform the input over 16 rounds
-
+    doRound !i roundIndex
        -- | Go through the entire key schedule overwriting the P-Array and S-Boxes
        prepare mctx = loop 0 salt1 salt1 salt2
          where loop i input slt1 slt2
                  | i == 1042   = return ()
                  | otherwise = do
                      ninput <- coreCryptoMutable input
                      let (nl, nr) = w64to32 ninput
                      mutableArrayWrite32 mctx i     nl
                      mutableArrayWrite32 mctx (i+1) nr
                      loop (i+2) (ninput `xor` slt2) slt2 slt1
                -- | Blowfish encrypt a Word using the current state of the key schedule
                coreCryptoMutable :: Word64 -> IO Word64
                coreCryptoMutable input = doRound input 0
                  where doRound i roundIndex
        | roundIndex == 16 = do
-                              pVal1 <- mutableArrayRead32 mctx 16
+            pVal1 <- mutableArrayRead32 ma 16
-                              pVal2 <- mutableArrayRead32 mctx 17
+            pVal2 <- mutableArrayRead32 ma 17
            let final = (fromIntegral pVal1 `shiftL` 32) .|. fromIntegral pVal2
            return $ rotateL (i `xor` final) 32
        | otherwise     = do
-                              pVal <- mutableArrayRead32 mctx roundIndex
+            pVal <- mutableArrayRead32 ma roundIndex
            let newr = fromIntegral (i `shiftR` 32) `xor` pVal
            newr' <- f newr
-                              let newi = ((i `shiftL` 32) `xor` newr') .|. (fromIntegral newr)
+            let newi = ((i `shiftL` 32) `xor` newr') .|. fromIntegral newr
            doRound newi (roundIndex+1)
-                -- The Blowfish Feistel function F
+    -- | The Blowfish Feistel function F
    f   :: Word32 -> IO Word64
-                f t = do a <- mutableArrayRead32 mctx (s0 + fromIntegral ((t `shiftR` 24) .&. 0xff))
+    f t = do
-                         b <- mutableArrayRead32 mctx (s1 + fromIntegral ((t `shiftR` 16) .&. 0xff))
+        a <- s0 (0xff .&. (t `shiftR` 24))
-                         c <- mutableArrayRead32 mctx (s2 + fromIntegral ((t `shiftR` 8) .&. 0xff))
+        b <- s1 (0xff .&. (t `shiftR` 16))
-                         d <- mutableArrayRead32 mctx (s3 + fromIntegral (t .&. 0xff))
+        c <- s2 (0xff .&. (t `shiftR` 8))
        d <- s3 (0xff .&.  t)
        return (fromIntegral (((a + b) `xor` c) + d) `shiftL` 32)
-                  where s0 = 18
+
-                        s1 = 274
+    -- | S-Box arrays, each containing 256 32-bit words
-                        s2 = 530
+    --   The first 18 words contain the P-Array of subkeys
-                        s3 = 786
+    s0, s1, s2, s3 :: Word32 -> IO Word32
    s0 i = mutableArrayRead32 ma (fromIntegral i + 18)
    s1 i = mutableArrayRead32 ma (fromIntegral i + 274)
    s2 i = mutableArrayRead32 ma (fromIntegral i + 530)
    s3 i = mutableArrayRead32 ma (fromIntegral i + 786)
 iterKeyStream :: (ByteArrayAccess x)
    => x
    -> Word32
    -> Word32
    -> (Int -> Word32 -> Word32 -> Word32 -> Word32 -> (Word32 -> Word32 -> IO ()) -> IO ())
    -> IO ()
 iterKeyStream x a0 a1 g = f 0 0 a0 a1
    where
        len          = B.length x
        -- Avoiding the modulo operation when interating over the ring
        -- buffer is assumed to be more efficient here. All other
        -- implementations do this, too. The branch prediction shall prefer
        -- the branch with the increment.
        n j          = if j + 1 >= len then 0 else j + 1
        f i j0 b0 b1 = g i l r b0 b1 (f (i + 2) j8)
            where
                j1 = n j0
                j2 = n j1
                j3 = n j2
                j4 = n j3
                j5 = n j4
                j6 = n j5
                j7 = n j6
                j8 = n j7
                x0 = fromIntegral (B.index x j0)
                x1 = fromIntegral (B.index x j1)
                x2 = fromIntegral (B.index x j2)
                x3 = fromIntegral (B.index x j3)
                x4 = fromIntegral (B.index x j4)
                x5 = fromIntegral (B.index x j5)
                x6 = fromIntegral (B.index x j6)
                x7 = fromIntegral (B.index x j7)
                l  = shiftL x0 24 .|. shiftL x1 16 .|. shiftL x2 8 .|. x3
                r  = shiftL x4 24 .|. shiftL x5 16 .|. shiftL x6 8 .|. x7
 {-# INLINE iterKeyStream #-}
 -- Benchmarking shows that GHC considers this function too big to inline
 -- although forcing inlining causes an actual improvement.
 -- It is assumed that all function calls (especially the continuation)
 -- collapse into a tight loop after inlining.
--- a/Crypto/Cipher/CAST5.hs
+++ b/Crypto/Cipher/CAST5.hs
@ -0,0 +1,43 @@
 -- |
 -- Module      : Crypto.Cipher.CAST5
 -- License     : BSD-style
 -- Maintainer  : Olivier Chéron <olivier.cheron@gmail.com>
 -- Stability   : stable
 -- Portability : good
 --
 module Crypto.Cipher.CAST5
    ( CAST5
    ) where
 import           Crypto.Error
 import           Crypto.Cipher.Types
 import           Crypto.Cipher.CAST5.Primitive
 import           Crypto.Internal.ByteArray (ByteArrayAccess)
 import qualified Crypto.Internal.ByteArray as B
 -- | CAST5 block cipher (also known as CAST-128).  Key is between
 -- 40 and 128 bits.
 newtype CAST5 = CAST5 Key
 instance Cipher CAST5 where
    cipherName    _ = "CAST5"
    cipherKeySize _ = KeySizeRange 5 16
    cipherInit      = initCAST5
 instance BlockCipher CAST5 where
    blockSize _ = 8
    ecbEncrypt (CAST5 k) = B.mapAsWord64 (encrypt k)
    ecbDecrypt (CAST5 k) = B.mapAsWord64 (decrypt k)
 initCAST5 :: ByteArrayAccess key => key -> CryptoFailable CAST5
 initCAST5 bs
    | len <   5 = CryptoFailed CryptoError_KeySizeInvalid
    | len <  16 = CryptoPassed (CAST5 $ buildKey short padded)
    | len == 16 = CryptoPassed (CAST5 $ buildKey False bs)
    | otherwise = CryptoFailed CryptoError_KeySizeInvalid
  where
    len   = B.length bs
    short = len <= 10
    padded :: B.Bytes
    padded = B.convert bs `B.append` B.replicate (16 - len) 0
--- a/Crypto/Cipher/CAST5/Primitive.hs
+++ b/Crypto/Cipher/CAST5/Primitive.hs
@ -0,0 +1,573 @@
 {-# LANGUAGE MagicHash #-}
 -----------------------------------------------------------------------------
 -- |
 -- Module      :  Crypto.Cipher.CAST5.Primitive
 -- License     :  BSD-style
 --
 -- Haskell implementation of the CAST-128 Encryption Algorithm
 --
 -----------------------------------------------------------------------------
 module Crypto.Cipher.CAST5.Primitive
    ( encrypt
    , decrypt
    , Key()
    , buildKey
    ) where
 import Control.Monad (void, (>=>))
 import Data.Bits
 import Data.Memory.Endian
 import Data.Word
 import           Crypto.Internal.ByteArray (ByteArrayAccess)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Internal.WordArray
 -- Data Types
 data P = P {-# UNPACK #-} !Word32 -- left word
           {-# UNPACK #-} !Word32 -- right word
 data Q = Q {-# UNPACK #-} !Word32 {-# UNPACK #-} !Word32
           {-# UNPACK #-} !Word32 {-# UNPACK #-} !Word32
 -- | All subkeys for 12 or 16 rounds
 data Key = K12 {-# UNPACK #-} !Array32 -- [ km1, kr1, km2, kr2, ..., km12, kr12 ]
         | K16 {-# UNPACK #-} !Array32 -- [ km1, kr1, km2, kr2, ..., km16, kr16 ]
 -- Big-endian Transformations
 decomp64 :: Word64 -> P
 decomp64 x = P (fromIntegral (x `shiftR` 32)) (fromIntegral x)
 comp64 :: P -> Word64
 comp64 (P l r) = (fromIntegral l `shiftL` 32) .|. fromIntegral r
 decomp32 :: Word32 -> (Word8, Word8, Word8, Word8)
 decomp32 x =
    let a = fromIntegral (x `shiftR` 24)
        b = fromIntegral (x `shiftR` 16)
        c = fromIntegral (x `shiftR`  8)
        d = fromIntegral x
    in (a, b, c, d)
 -- Encryption
 -- | Encrypts a block using the specified key
 encrypt :: Key -> Word64 -> Word64
 encrypt k = comp64 . cast_enc k . decomp64
 cast_enc :: Key -> P -> P
 cast_enc (K12 a) (P l0 r0) = P r12 r11
  where
    r1  = type1 a 0  l0  r0
    r2  = type2 a 2  r0  r1
    r3  = type3 a 4  r1  r2
    r4  = type1 a 6  r2  r3
    r5  = type2 a 8  r3  r4
    r6  = type3 a 10 r4  r5
    r7  = type1 a 12 r5  r6
    r8  = type2 a 14 r6  r7
    r9  = type3 a 16 r7  r8
    r10 = type1 a 18 r8  r9
    r11 = type2 a 20 r9  r10
    r12 = type3 a 22 r10 r11
 cast_enc (K16 a) p = P r16 r15
  where
    P r12 r11 = cast_enc (K12 a) p
    r13 = type1 a 24 r11 r12
    r14 = type2 a 26 r12 r13
    r15 = type3 a 28 r13 r14
    r16 = type1 a 30 r14 r15
 -- Decryption
 -- | Decrypts a block using the specified key
 decrypt :: Key -> Word64 -> Word64
 decrypt k = comp64 . cast_dec k . decomp64
 cast_dec :: Key -> P -> P
 cast_dec (K12 a) (P r12 r11) = P l0 r0
  where
    r10 = type3 a 22 r12 r11
    r9  = type2 a 20 r11 r10
    r8  = type1 a 18 r10 r9
    r7  = type3 a 16 r9  r8
    r6  = type2 a 14 r8  r7
    r5  = type1 a 12 r7  r6
    r4  = type3 a 10 r6  r5
    r3  = type2 a 8  r5  r4
    r2  = type1 a 6  r4  r3
    r1  = type3 a 4  r3  r2
    r0  = type2 a 2  r2  r1
    l0  = type1 a 0  r1  r0
 cast_dec (K16 a) (P r16 r15) = cast_dec (K12 a) (P r12 r11)
  where
    r14 = type1 a 30 r16 r15
    r13 = type3 a 28 r15 r14
    r12 = type2 a 26 r14 r13
    r11 = type1 a 24 r13 r12
 -- Non-Identical Rounds
 type1 :: Array32 -> Int -> Word32 -> Word32 -> Word32
 type1 arr idx l r =
    let km = arrayRead32 arr idx
        kr = arrayRead32 arr (idx + 1)
        j = (km + r) `rotateL` fromIntegral kr
        (ja, jb, jc, jd) = decomp32 j
     in l `xor` (((sbox_s1 ja `xor` sbox_s2 jb) - sbox_s3 jc) + sbox_s4 jd)
 type2 :: Array32 -> Int -> Word32 -> Word32 -> Word32
 type2 arr idx l r =
    let km = arrayRead32 arr idx
        kr = arrayRead32 arr (idx + 1)
        j = (km `xor` r) `rotateL` fromIntegral kr
        (ja, jb, jc, jd) = decomp32 j
     in l `xor` (((sbox_s1 ja - sbox_s2 jb) + sbox_s3 jc) `xor` sbox_s4 jd)
 type3 :: Array32 -> Int -> Word32 -> Word32 -> Word32
 type3 arr idx l r =
    let km = arrayRead32 arr idx
        kr = arrayRead32 arr (idx + 1)
        j = (km - r) `rotateL` fromIntegral kr
        (ja, jb, jc, jd) = decomp32 j
     in l `xor` (((sbox_s1 ja + sbox_s2 jb) `xor` sbox_s3 jc) - sbox_s4 jd)
 -- Key Schedule
 -- | Precompute "masking" and "rotation" subkeys
 buildKey :: ByteArrayAccess key
         => Bool -- ^ @True@ for short keys that only need 12 rounds
         -> key  -- ^ Input key padded to 16 bytes
         -> Key  -- ^ Output data structure
 buildKey isShort key =
    let P x0123 x4567 = decomp64 (fromBE $ B.toW64BE key 0)
        P x89AB xCDEF = decomp64 (fromBE $ B.toW64BE key 8)
     in keySchedule isShort (Q x0123 x4567 x89AB xCDEF)
 keySchedule :: Bool -> Q -> Key
 keySchedule isShort x
    | isShort   = K12 $ allocArray32AndFreeze 24 $ \ma ->
        void (steps123 ma 0 x >>= skip4 >>= steps123 ma 1)
    | otherwise = K16 $ allocArray32AndFreeze 32 $ \ma ->
        void (steps123 ma 0 x >>= step4 ma 24 >>= steps123 ma 1 >>= step4 ma 25)
  where
    sbox_s56785 a b c d e = sbox_s5 a `xor` sbox_s6 b `xor` sbox_s7 c `xor` sbox_s8 d `xor` sbox_s5 e
    sbox_s56786 a b c d e = sbox_s5 a `xor` sbox_s6 b `xor` sbox_s7 c `xor` sbox_s8 d `xor` sbox_s6 e
    sbox_s56787 a b c d e = sbox_s5 a `xor` sbox_s6 b `xor` sbox_s7 c `xor` sbox_s8 d `xor` sbox_s7 e
    sbox_s56788 a b c d e = sbox_s5 a `xor` sbox_s6 b `xor` sbox_s7 c `xor` sbox_s8 d `xor` sbox_s8 e
    steps123 ma off = step1 ma off >=> step2 ma (off + 8) >=> step3 ma (off + 16)
    step1 :: MutableArray32 -> Int -> Q -> IO Q
    step1 ma off (Q x0123 x4567 x89AB xCDEF) = do
        let (x8, x9, xA, xB) = decomp32 x89AB
            (xC, xD, xE, xF) = decomp32 xCDEF
            z0123 = x0123 `xor` sbox_s56787 xD xF xC xE x8
            z4567 = x89AB `xor` sbox_s56788 z0 z2 z1 z3 xA
            z89AB = xCDEF `xor` sbox_s56785 z7 z6 z5 z4 x9
            zCDEF = x4567 `xor` sbox_s56786 zA z9 zB z8 xB
            (z0, z1, z2, z3) = decomp32 z0123
            (z4, z5, z6, z7) = decomp32 z4567
            (z8, z9, zA, zB) = decomp32 z89AB
            (zC, zD, zE, zF) = decomp32 zCDEF
        mutableArrayWrite32 ma (off + 0) $ sbox_s56785 z8 z9 z7 z6 z2
        mutableArrayWrite32 ma (off + 2) $ sbox_s56786 zA zB z5 z4 z6
        mutableArrayWrite32 ma (off + 4) $ sbox_s56787 zC zD z3 z2 z9
        mutableArrayWrite32 ma (off + 6) $ sbox_s56788 zE zF z1 z0 zC
        return (Q z0123 z4567 z89AB zCDEF)
    step2 :: MutableArray32 -> Int -> Q -> IO Q
    step2 ma off (Q z0123 z4567 z89AB zCDEF) = do
        let (z0, z1, z2, z3) = decomp32 z0123
            (z4, z5, z6, z7) = decomp32 z4567
            x0123 = z89AB `xor` sbox_s56787 z5 z7 z4 z6 z0
            x4567 = z0123 `xor` sbox_s56788 x0 x2 x1 x3 z2
            x89AB = z4567 `xor` sbox_s56785 x7 x6 x5 x4 z1
            xCDEF = zCDEF `xor` sbox_s56786 xA x9 xB x8 z3
            (x0, x1, x2, x3) = decomp32 x0123
            (x4, x5, x6, x7) = decomp32 x4567
            (x8, x9, xA, xB) = decomp32 x89AB
            (xC, xD, xE, xF) = decomp32 xCDEF
        mutableArrayWrite32 ma (off + 0) $ sbox_s56785 x3 x2 xC xD x8
        mutableArrayWrite32 ma (off + 2) $ sbox_s56786 x1 x0 xE xF xD
        mutableArrayWrite32 ma (off + 4) $ sbox_s56787 x7 x6 x8 x9 x3
        mutableArrayWrite32 ma (off + 6) $ sbox_s56788 x5 x4 xA xB x7
        return (Q x0123 x4567 x89AB xCDEF)
    step3 :: MutableArray32 -> Int -> Q -> IO Q
    step3 ma off (Q x0123 x4567 x89AB xCDEF) = do
        let (x8, x9, xA, xB) = decomp32 x89AB
            (xC, xD, xE, xF) = decomp32 xCDEF
            z0123 = x0123 `xor` sbox_s56787 xD xF xC xE x8
            z4567 = x89AB `xor` sbox_s56788 z0 z2 z1 z3 xA
            z89AB = xCDEF `xor` sbox_s56785 z7 z6 z5 z4 x9
            zCDEF = x4567 `xor` sbox_s56786 zA z9 zB z8 xB
            (z0, z1, z2, z3) = decomp32 z0123
            (z4, z5, z6, z7) = decomp32 z4567
            (z8, z9, zA, zB) = decomp32 z89AB
            (zC, zD, zE, zF) = decomp32 zCDEF
        mutableArrayWrite32 ma (off + 0) $ sbox_s56785 z3 z2 zC zD z9
        mutableArrayWrite32 ma (off + 2) $ sbox_s56786 z1 z0 zE zF zC
        mutableArrayWrite32 ma (off + 4) $ sbox_s56787 z7 z6 z8 z9 z2
        mutableArrayWrite32 ma (off + 6) $ sbox_s56788 z5 z4 zA zB z6
        return (Q z0123 z4567 z89AB zCDEF)
    step4 :: MutableArray32 -> Int -> Q -> IO Q
    step4 ma off (Q z0123 z4567 z89AB zCDEF) = do
        let (z0, z1, z2, z3) = decomp32 z0123
            (z4, z5, z6, z7) = decomp32 z4567
            x0123 = z89AB `xor` sbox_s56787 z5 z7 z4 z6 z0
            x4567 = z0123 `xor` sbox_s56788 x0 x2 x1 x3 z2
            x89AB = z4567 `xor` sbox_s56785 x7 x6 x5 x4 z1
            xCDEF = zCDEF `xor` sbox_s56786 xA x9 xB x8 z3
            (x0, x1, x2, x3) = decomp32 x0123
            (x4, x5, x6, x7) = decomp32 x4567
            (x8, x9, xA, xB) = decomp32 x89AB
            (xC, xD, xE, xF) = decomp32 xCDEF
        mutableArrayWrite32 ma (off + 0) $ sbox_s56785 x8 x9 x7 x6 x3
        mutableArrayWrite32 ma (off + 2) $ sbox_s56786 xA xB x5 x4 x7
        mutableArrayWrite32 ma (off + 4) $ sbox_s56787 xC xD x3 x2 x8
        mutableArrayWrite32 ma (off + 6) $ sbox_s56788 xE xF x1 x0 xD
        return (Q x0123 x4567 x89AB xCDEF)
    skip4 :: Q -> IO Q
    skip4 (Q z0123 z4567 z89AB zCDEF) = do
        let (z0, z1, z2, z3) = decomp32 z0123
            (z4, z5, z6, z7) = decomp32 z4567
            x0123 = z89AB `xor` sbox_s56787 z5 z7 z4 z6 z0
            x4567 = z0123 `xor` sbox_s56788 x0 x2 x1 x3 z2
            x89AB = z4567 `xor` sbox_s56785 x7 x6 x5 x4 z1
            xCDEF = zCDEF `xor` sbox_s56786 xA x9 xB x8 z3
            (x0, x1, x2, x3) = decomp32 x0123
            (x4, x5, x6, x7) = decomp32 x4567
            (x8, x9, xA, xB) = decomp32 x89AB
        return (Q x0123 x4567 x89AB xCDEF)
 -- S-Boxes
 sbox_s1 :: Word8 -> Word32
 sbox_s1 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
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            \\xc6\x9d\xff\x09\xc7\x5b\x65\xf0\xd9\xdb\x40\xd8\xec\x0e\x77\x79\x47\x44\xea\xd4\xb1\x1c\x32\x74\xdd\x24\xcb\x9e\x7e\x1c\x54\xbd\
            \\xf0\x11\x44\xf9\xd2\x24\x0e\xb1\x96\x75\xb3\xfd\xa3\xac\x37\x55\xd4\x7c\x27\xaf\x51\xc8\x5f\x4d\x56\x90\x75\x96\xa5\xbb\x15\xe6\
            \\x58\x03\x04\xf0\xca\x04\x2c\xf1\x01\x1a\x37\xea\x8d\xbf\xaa\xdb\x35\xba\x3e\x4a\x35\x26\xff\xa0\xc3\x7b\x4d\x09\xbc\x30\x6e\xd9\
            \\x98\xa5\x26\x66\x56\x48\xf7\x25\xff\x5e\x56\x9d\x0c\xed\x63\xd0\x7c\x63\xb2\xcf\x70\x0b\x45\xe1\xd5\xea\x50\xf1\x85\xa9\x28\x72\
            \\xaf\x1f\xbd\xa7\xd4\x23\x48\x70\xa7\x87\x0b\xf3\x2d\x3b\x4d\x79\x42\xe0\x41\x98\x0c\xd0\xed\xe7\x26\x47\x0d\xb8\xf8\x81\x81\x4c\
            \\x47\x4d\x6a\xd7\x7c\x0c\x5e\x5c\xd1\x23\x19\x59\x38\x1b\x72\x98\xf5\xd2\xf4\xdb\xab\x83\x86\x53\x6e\x2f\x1e\x23\x83\x71\x9c\x9e\
            \\xbd\x91\xe0\x46\x9a\x56\x45\x6e\xdc\x39\x20\x0c\x20\xc8\xc5\x71\x96\x2b\xda\x1c\xe1\xe6\x96\xff\xb1\x41\xab\x08\x7c\xca\x89\xb9\
            \\x1a\x69\xe7\x83\x02\xcc\x48\x43\xa2\xf7\xc5\x79\x42\x9e\xf4\x7d\x42\x7b\x16\x9c\x5a\xc9\xf0\x49\xdd\x8f\x0f\x00\x5c\x81\x65\xbf"#
 sbox_s2 :: Word8 -> Word32
 sbox_s2 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\x1f\x20\x10\x94\xef\x0b\xa7\x5b\x69\xe3\xcf\x7e\x39\x3f\x43\x80\xfe\x61\xcf\x7a\xee\xc5\x20\x7a\x55\x88\x9c\x94\x72\xfc\x06\x51\
            \\xad\xa7\xef\x79\x4e\x1d\x72\x35\xd5\x5a\x63\xce\xde\x04\x36\xba\x99\xc4\x30\xef\x5f\x0c\x07\x94\x18\xdc\xdb\x7d\xa1\xd6\xef\xf3\
            \\xa0\xb5\x2f\x7b\x59\xe8\x36\x05\xee\x15\xb0\x94\xe9\xff\xd9\x09\xdc\x44\x00\x86\xef\x94\x44\x59\xba\x83\xcc\xb3\xe0\xc3\xcd\xfb\
            \\xd1\xda\x41\x81\x3b\x09\x2a\xb1\xf9\x97\xf1\xc1\xa5\xe6\xcf\x7b\x01\x42\x0d\xdb\xe4\xe7\xef\x5b\x25\xa1\xff\x41\xe1\x80\xf8\x06\
            \\x1f\xc4\x10\x80\x17\x9b\xee\x7a\xd3\x7a\xc6\xa9\xfe\x58\x30\xa4\x98\xde\x8b\x7f\x77\xe8\x3f\x4e\x79\x92\x92\x69\x24\xfa\x9f\x7b\
            \\xe1\x13\xc8\x5b\xac\xc4\x00\x83\xd7\x50\x35\x25\xf7\xea\x61\x5f\x62\x14\x31\x54\x0d\x55\x4b\x63\x5d\x68\x11\x21\xc8\x66\xc3\x59\
            \\x3d\x63\xcf\x73\xce\xe2\x34\xc0\xd4\xd8\x7e\x87\x5c\x67\x2b\x21\x07\x1f\x61\x81\x39\xf7\x62\x7f\x36\x1e\x30\x84\xe4\xeb\x57\x3b\
            \\x60\x2f\x64\xa4\xd6\x3a\xcd\x9c\x1b\xbc\x46\x35\x9e\x81\x03\x2d\x27\x01\xf5\x0c\x99\x84\x7a\xb4\xa0\xe3\xdf\x79\xba\x6c\xf3\x8c\
            \\x10\x84\x30\x94\x25\x37\xa9\x5e\xf4\x6f\x6f\xfe\xa1\xff\x3b\x1f\x20\x8c\xfb\x6a\x8f\x45\x8c\x74\xd9\xe0\xa2\x27\x4e\xc7\x3a\x34\
            \\xfc\x88\x4f\x69\x3e\x4d\xe8\xdf\xef\x0e\x00\x88\x35\x59\x64\x8d\x8a\x45\x38\x8c\x1d\x80\x43\x66\x72\x1d\x9b\xfd\xa5\x86\x84\xbb\
            \\xe8\x25\x63\x33\x84\x4e\x82\x12\x12\x8d\x80\x98\xfe\xd3\x3f\xb4\xce\x28\x0a\xe1\x27\xe1\x9b\xa5\xd5\xa6\xc2\x52\xe4\x97\x54\xbd\
            \\xc5\xd6\x55\xdd\xeb\x66\x70\x64\x77\x84\x0b\x4d\xa1\xb6\xa8\x01\x84\xdb\x26\xa9\xe0\xb5\x67\x14\x21\xf0\x43\xb7\xe5\xd0\x58\x60\
            \\x54\xf0\x30\x84\x06\x6f\xf4\x72\xa3\x1a\xa1\x53\xda\xdc\x47\x55\xb5\x62\x5d\xbf\x68\x56\x1b\xe6\x83\xca\x6b\x94\x2d\x6e\xd2\x3b\
            \\xec\xcf\x01\xdb\xa6\xd3\xd0\xba\xb6\x80\x3d\x5c\xaf\x77\xa7\x09\x33\xb4\xa3\x4c\x39\x7b\xc8\xd6\x5e\xe2\x2b\x95\x5f\x0e\x53\x04\
            \\x81\xed\x6f\x61\x20\xe7\x43\x64\xb4\x5e\x13\x78\xde\x18\x63\x9b\x88\x1c\xa1\x22\xb9\x67\x26\xd1\x80\x49\xa7\xe8\x22\xb7\xda\x7b\
            \\x5e\x55\x2d\x25\x52\x72\xd2\x37\x79\xd2\x95\x1c\xc6\x0d\x89\x4c\x48\x8c\xb4\x02\x1b\xa4\xfe\x5b\xa4\xb0\x9f\x6b\x1c\xa8\x15\xcf\
            \\xa2\x0c\x30\x05\x88\x71\xdf\x63\xb9\xde\x2f\xcb\x0c\xc6\xc9\xe9\x0b\xee\xff\x53\xe3\x21\x45\x17\xb4\x54\x28\x35\x9f\x63\x29\x3c\
            \\xee\x41\xe7\x29\x6e\x1d\x2d\x7c\x50\x04\x52\x86\x1e\x66\x85\xf3\xf3\x34\x01\xc6\x30\xa2\x2c\x95\x31\xa7\x08\x50\x60\x93\x0f\x13\
            \\x73\xf9\x84\x17\xa1\x26\x98\x59\xec\x64\x5c\x44\x52\xc8\x77\xa9\xcd\xff\x33\xa6\xa0\x2b\x17\x41\x7c\xba\xd9\xa2\x21\x80\x03\x6f\
            \\x50\xd9\x9c\x08\xcb\x3f\x48\x61\xc2\x6b\xd7\x65\x64\xa3\xf6\xab\x80\x34\x26\x76\x25\xa7\x5e\x7b\xe4\xe6\xd1\xfc\x20\xc7\x10\xe6\
            \\xcd\xf0\xb6\x80\x17\x84\x4d\x3b\x31\xee\xf8\x4d\x7e\x08\x24\xe4\x2c\xcb\x49\xeb\x84\x6a\x3b\xae\x8f\xf7\x78\x88\xee\x5d\x60\xf6\
            \\x7a\xf7\x56\x73\x2f\xdd\x5c\xdb\xa1\x16\x31\xc1\x30\xf6\x6f\x43\xb3\xfa\xec\x54\x15\x7f\xd7\xfa\xef\x85\x79\xcc\xd1\x52\xde\x58\
            \\xdb\x2f\xfd\x5e\x8f\x32\xce\x19\x30\x6a\xf9\x7a\x02\xf0\x3e\xf8\x99\x31\x9a\xd5\xc2\x42\xfa\x0f\xa7\xe3\xeb\xb0\xc6\x8e\x49\x06\
            \\xb8\xda\x23\x0c\x80\x82\x30\x28\xdc\xde\xf3\xc8\xd3\x5f\xb1\x71\x08\x8a\x1b\xc8\xbe\xc0\xc5\x60\x61\xa3\xc9\xe8\xbc\xa8\xf5\x4d\
            \\xc7\x2f\xef\xfa\x22\x82\x2e\x99\x82\xc5\x70\xb4\xd8\xd9\x4e\x89\x8b\x1c\x34\xbc\x30\x1e\x16\xe6\x27\x3b\xe9\x79\xb0\xff\xea\xa6\
            \\x61\xd9\xb8\xc6\x00\xb2\x48\x69\xb7\xff\xce\x3f\x08\xdc\x28\x3b\x43\xda\xf6\x5a\xf7\xe1\x97\x98\x76\x19\xb7\x2f\x8f\x1c\x9b\xa4\
            \\xdc\x86\x37\xa0\x16\xa7\xd3\xb1\x9f\xc3\x93\xb7\xa7\x13\x6e\xeb\xc6\xbc\xc6\x3e\x1a\x51\x37\x42\xef\x68\x28\xbc\x52\x03\x65\xd6\
            \\x2d\x6a\x77\xab\x35\x27\xed\x4b\x82\x1f\xd2\x16\x09\x5c\x6e\x2e\xdb\x92\xf2\xfb\x5e\xea\x29\xcb\x14\x58\x92\xf5\x91\x58\x4f\x7f\
            \\x54\x83\x69\x7b\x26\x67\xa8\xcc\x85\x19\x60\x48\x8c\x4b\xac\xea\x83\x38\x60\xd4\x0d\x23\xe0\xf9\x6c\x38\x7e\x8a\x0a\xe6\xd2\x49\
            \\xb2\x84\x60\x0c\xd8\x35\x73\x1d\xdc\xb1\xc6\x47\xac\x4c\x56\xea\x3e\xbd\x81\xb3\x23\x0e\xab\xb0\x64\x38\xbc\x87\xf0\xb5\xb1\xfa\
            \\x8f\x5e\xa2\xb3\xfc\x18\x46\x42\x0a\x03\x6b\x7a\x4f\xb0\x89\xbd\x64\x9d\xa5\x89\xa3\x45\x41\x5e\x5c\x03\x83\x23\x3e\x5d\x3b\xb9\
            \\x43\xd7\x95\x72\x7e\x6d\xd0\x7c\x06\xdf\xdf\x1e\x6c\x6c\xc4\xef\x71\x60\xa5\x39\x73\xbf\xbe\x70\x83\x87\x76\x05\x45\x23\xec\xf1"#
 sbox_s3 :: Word8 -> Word32
 sbox_s3 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\x8d\xef\xc2\x40\x25\xfa\x5d\x9f\xeb\x90\x3d\xbf\xe8\x10\xc9\x07\x47\x60\x7f\xff\x36\x9f\xe4\x4b\x8c\x1f\xc6\x44\xae\xce\xca\x90\
            \\xbe\xb1\xf9\xbf\xee\xfb\xca\xea\xe8\xcf\x19\x50\x51\xdf\x07\xae\x92\x0e\x88\x06\xf0\xad\x05\x48\xe1\x3c\x8d\x83\x92\x70\x10\xd5\
            \\x11\x10\x7d\x9f\x07\x64\x7d\xb9\xb2\xe3\xe4\xd4\x3d\x4f\x28\x5e\xb9\xaf\xa8\x20\xfa\xde\x82\xe0\xa0\x67\x26\x8b\x82\x72\x79\x2e\
            \\x55\x3f\xb2\xc0\x48\x9a\xe2\x2b\xd4\xef\x97\x94\x12\x5e\x3f\xbc\x21\xff\xfc\xee\x82\x5b\x1b\xfd\x92\x55\xc5\xed\x12\x57\xa2\x40\
            \\x4e\x1a\x83\x02\xba\xe0\x7f\xff\x52\x82\x46\xe7\x8e\x57\x14\x0e\x33\x73\xf7\xbf\x8c\x9f\x81\x88\xa6\xfc\x4e\xe8\xc9\x82\xb5\xa5\
            \\xa8\xc0\x1d\xb7\x57\x9f\xc2\x64\x67\x09\x4f\x31\xf2\xbd\x3f\x5f\x40\xff\xf7\xc1\x1f\xb7\x8d\xfc\x8e\x6b\xd2\xc1\x43\x7b\xe5\x9b\
            \\x99\xb0\x3d\xbf\xb5\xdb\xc6\x4b\x63\x8d\xc0\xe6\x55\x81\x9d\x99\xa1\x97\xc8\x1c\x4a\x01\x2d\x6e\xc5\x88\x4a\x28\xcc\xc3\x6f\x71\
            \\xb8\x43\xc2\x13\x6c\x07\x43\xf1\x83\x09\x89\x3c\x0f\xed\xdd\x5f\x2f\x7f\xe8\x50\xd7\xc0\x7f\x7e\x02\x50\x7f\xbf\x5a\xfb\x9a\x04\
            \\xa7\x47\xd2\xd0\x16\x51\x19\x2e\xaf\x70\xbf\x3e\x58\xc3\x13\x80\x5f\x98\x30\x2e\x72\x7c\xc3\xc4\x0a\x0f\xb4\x02\x0f\x7f\xef\x82\
            \\x8c\x96\xfd\xad\x5d\x2c\x2a\xae\x8e\xe9\x9a\x49\x50\xda\x88\xb8\x84\x27\xf4\xa0\x1e\xac\x57\x90\x79\x6f\xb4\x49\x82\x52\xdc\x15\
            \\xef\xbd\x7d\x9b\xa6\x72\x59\x7d\xad\xa8\x40\xd8\x45\xf5\x45\x04\xfa\x5d\x74\x03\xe8\x3e\xc3\x05\x4f\x91\x75\x1a\x92\x56\x69\xc2\
            \\x23\xef\xe9\x41\xa9\x03\xf1\x2e\x60\x27\x0d\xf2\x02\x76\xe4\xb6\x94\xfd\x65\x74\x92\x79\x85\xb2\x82\x76\xdb\xcb\x02\x77\x81\x76\
            \\xf8\xaf\x91\x8d\x4e\x48\xf7\x9e\x8f\x61\x6d\xdf\xe2\x9d\x84\x0e\x84\x2f\x7d\x83\x34\x0c\xe5\xc8\x96\xbb\xb6\x82\x93\xb4\xb1\x48\
            \\xef\x30\x3c\xab\x98\x4f\xaf\x28\x77\x9f\xaf\x9b\x92\xdc\x56\x0d\x22\x4d\x1e\x20\x84\x37\xaa\x88\x7d\x29\xdc\x96\x27\x56\xd3\xdc\
            \\x8b\x90\x7c\xee\xb5\x1f\xd2\x40\xe7\xc0\x7c\xe3\xe5\x66\xb4\xa1\xc3\xe9\x61\x5e\x3c\xf8\x20\x9d\x60\x94\xd1\xe3\xcd\x9c\xa3\x41\
            \\x5c\x76\x46\x0e\x00\xea\x98\x3b\xd4\xd6\x78\x81\xfd\x47\x57\x2c\xf7\x6c\xed\xd9\xbd\xa8\x22\x9c\x12\x7d\xad\xaa\x43\x8a\x07\x4e\
            \\x1f\x97\xc0\x90\x08\x1b\xdb\x8a\x93\xa0\x7e\xbe\xb9\x38\xca\x15\x97\xb0\x3c\xff\x3d\xc2\xc0\xf8\x8d\x1a\xb2\xec\x64\x38\x0e\x51\
            \\x68\xcc\x7b\xfb\xd9\x0f\x27\x88\x12\x49\x01\x81\x5d\xe5\xff\xd4\xdd\x7e\xf8\x6a\x76\xa2\xe2\x14\xb9\xa4\x03\x68\x92\x5d\x95\x8f\
            \\x4b\x39\xff\xfa\xba\x39\xae\xe9\xa4\xff\xd3\x0b\xfa\xf7\x93\x3b\x6d\x49\x86\x23\x19\x3c\xbc\xfa\x27\x62\x75\x45\x82\x5c\xf4\x7a\
            \\x61\xbd\x8b\xa0\xd1\x1e\x42\xd1\xce\xad\x04\xf4\x12\x7e\xa3\x92\x10\x42\x8d\xb7\x82\x72\xa9\x72\x92\x70\xc4\xa8\x12\x7d\xe5\x0b\
            \\x28\x5b\xa1\xc8\x3c\x62\xf4\x4f\x35\xc0\xea\xa5\xe8\x05\xd2\x31\x42\x89\x29\xfb\xb4\xfc\xdf\x82\x4f\xb6\x6a\x53\x0e\x7d\xc1\x5b\
            \\x1f\x08\x1f\xab\x10\x86\x18\xae\xfc\xfd\x08\x6d\xf9\xff\x28\x89\x69\x4b\xcc\x11\x23\x6a\x5c\xae\x12\xde\xca\x4d\x2c\x3f\x8c\xc5\
            \\xd2\xd0\x2d\xfe\xf8\xef\x58\x96\xe4\xcf\x52\xda\x95\x15\x5b\x67\x49\x4a\x48\x8c\xb9\xb6\xa8\x0c\x5c\x8f\x82\xbc\x89\xd3\x6b\x45\
            \\x3a\x60\x94\x37\xec\x00\xc9\xa9\x44\x71\x52\x53\x0a\x87\x4b\x49\xd7\x73\xbc\x40\x7c\x34\x67\x1c\x02\x71\x7e\xf6\x4f\xeb\x55\x36\
            \\xa2\xd0\x2f\xff\xd2\xbf\x60\xc4\xd4\x3f\x03\xc0\x50\xb4\xef\x6d\x07\x47\x8c\xd1\x00\x6e\x18\x88\xa2\xe5\x3f\x55\xb9\xe6\xd4\xbc\
            \\xa2\x04\x80\x16\x97\x57\x38\x33\xd7\x20\x7d\x67\xde\x0f\x8f\x3d\x72\xf8\x7b\x33\xab\xcc\x4f\x33\x76\x88\xc5\x5d\x7b\x00\xa6\xb0\
            \\x94\x7b\x00\x01\x57\x00\x75\xd2\xf9\xbb\x88\xf8\x89\x42\x01\x9e\x42\x64\xa5\xff\x85\x63\x02\xe0\x72\xdb\xd9\x2b\xee\x97\x1b\x69\
            \\x6e\xa2\x2f\xde\x5f\x08\xae\x2b\xaf\x7a\x61\x6d\xe5\xc9\x87\x67\xcf\x1f\xeb\xd2\x61\xef\xc8\xc2\xf1\xac\x25\x71\xcc\x82\x39\xc2\
            \\x67\x21\x4c\xb8\xb1\xe5\x83\xd1\xb7\xdc\x3e\x62\x7f\x10\xbd\xce\xf9\x0a\x5c\x38\x0f\xf0\x44\x3d\x60\x6e\x6d\xc6\x60\x54\x3a\x49\
            \\x57\x27\xc1\x48\x2b\xe9\x8a\x1d\x8a\xb4\x17\x38\x20\xe1\xbe\x24\xaf\x96\xda\x0f\x68\x45\x84\x25\x99\x83\x3b\xe5\x60\x0d\x45\x7d\
            \\x28\x2f\x93\x50\x83\x34\xb3\x62\xd9\x1d\x11\x20\x2b\x6d\x8d\xa0\x64\x2b\x1e\x31\x9c\x30\x5a\x00\x52\xbc\xe6\x88\x1b\x03\x58\x8a\
            \\xf7\xba\xef\xd5\x41\x42\xed\x9c\xa4\x31\x5c\x11\x83\x32\x3e\xc5\xdf\xef\x46\x36\xa1\x33\xc5\x01\xe9\xd3\x53\x1c\xee\x35\x37\x83"#
 sbox_s4 :: Word8 -> Word32
 sbox_s4 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\x9d\xb3\x04\x20\x1f\xb6\xe9\xde\xa7\xbe\x7b\xef\xd2\x73\xa2\x98\x4a\x4f\x7b\xdb\x64\xad\x8c\x57\x85\x51\x04\x43\xfa\x02\x0e\xd1\
            \\x7e\x28\x7a\xff\xe6\x0f\xb6\x63\x09\x5f\x35\xa1\x79\xeb\xf1\x20\xfd\x05\x9d\x43\x64\x97\xb7\xb1\xf3\x64\x1f\x63\x24\x1e\x4a\xdf\
            \\x28\x14\x7f\x5f\x4f\xa2\xb8\xcd\xc9\x43\x00\x40\x0c\xc3\x22\x20\xfd\xd3\x0b\x30\xc0\xa5\x37\x4f\x1d\x2d\x00\xd9\x24\x14\x7b\x15\
            \\xee\x4d\x11\x1a\x0f\xca\x51\x67\x71\xff\x90\x4c\x2d\x19\x5f\xfe\x1a\x05\x64\x5f\x0c\x13\xfe\xfe\x08\x1b\x08\xca\x05\x17\x01\x21\
            \\x80\x53\x01\x00\xe8\x3e\x5e\xfe\xac\x9a\xf4\xf8\x7f\xe7\x27\x01\xd2\xb8\xee\x5f\x06\xdf\x42\x61\xbb\x9e\x9b\x8a\x72\x93\xea\x25\
            \\xce\x84\xff\xdf\xf5\x71\x88\x01\x3d\xd6\x4b\x04\xa2\x6f\x26\x3b\x7e\xd4\x84\x00\x54\x7e\xeb\xe6\x44\x6d\x4c\xa0\x6c\xf3\xd6\xf5\
            \\x26\x49\xab\xdf\xae\xa0\xc7\xf5\x36\x33\x8c\xc1\x50\x3f\x7e\x93\xd3\x77\x20\x61\x11\xb6\x38\xe1\x72\x50\x0e\x03\xf8\x0e\xb2\xbb\
            \\xab\xe0\x50\x2e\xec\x8d\x77\xde\x57\x97\x1e\x81\xe1\x4f\x67\x46\xc9\x33\x54\x00\x69\x20\x31\x8f\x08\x1d\xbb\x99\xff\xc3\x04\xa5\
            \\x4d\x35\x18\x05\x7f\x3d\x5c\xe3\xa6\xc8\x66\xc6\x5d\x5b\xcc\xa9\xda\xec\x6f\xea\x9f\x92\x6f\x91\x9f\x46\x22\x2f\x39\x91\x46\x7d\
            \\xa5\xbf\x6d\x8e\x11\x43\xc4\x4f\x43\x95\x83\x02\xd0\x21\x4e\xeb\x02\x20\x83\xb8\x3f\xb6\x18\x0c\x18\xf8\x93\x1e\x28\x16\x58\xe6\
            \\x26\x48\x6e\x3e\x8b\xd7\x8a\x70\x74\x77\xe4\xc1\xb5\x06\xe0\x7c\xf3\x2d\x0a\x25\x79\x09\x8b\x02\xe4\xea\xbb\x81\x28\x12\x3b\x23\
            \\x69\xde\xad\x38\x15\x74\xca\x16\xdf\x87\x1b\x62\x21\x1c\x40\xb7\xa5\x1a\x9e\xf9\x00\x14\x37\x7b\x04\x1e\x8a\xc8\x09\x11\x40\x03\
            \\xbd\x59\xe4\xd2\xe3\xd1\x56\xd5\x4f\xe8\x76\xd5\x2f\x91\xa3\x40\x55\x7b\xe8\xde\x00\xea\xe4\xa7\x0c\xe5\xc2\xec\x4d\xb4\xbb\xa6\
            \\xe7\x56\xbd\xff\xdd\x33\x69\xac\xec\x17\xb0\x35\x06\x57\x23\x27\x99\xaf\xc8\xb0\x56\xc8\xc3\x91\x6b\x65\x81\x1c\x5e\x14\x61\x19\
            \\x6e\x85\xcb\x75\xbe\x07\xc0\x02\xc2\x32\x55\x77\x89\x3f\xf4\xec\x5b\xbf\xc9\x2d\xd0\xec\x3b\x25\xb7\x80\x1a\xb7\x8d\x6d\x3b\x24\
            \\x20\xc7\x63\xef\xc3\x66\xa5\xfc\x9c\x38\x28\x80\x0a\xce\x32\x05\xaa\xc9\x54\x8a\xec\xa1\xd7\xc7\x04\x1a\xfa\x32\x1d\x16\x62\x5a\
            \\x67\x01\x90\x2c\x9b\x75\x7a\x54\x31\xd4\x77\xf7\x91\x26\xb0\x31\x36\xcc\x6f\xdb\xc7\x0b\x8b\x46\xd9\xe6\x6a\x48\x56\xe5\x5a\x79\
            \\x02\x6a\x4c\xeb\x52\x43\x7e\xff\x2f\x8f\x76\xb4\x0d\xf9\x80\xa5\x86\x74\xcd\xe3\xed\xda\x04\xeb\x17\xa9\xbe\x04\x2c\x18\xf4\xdf\
            \\xb7\x74\x7f\x9d\xab\x2a\xf7\xb4\xef\xc3\x4d\x20\x2e\x09\x6b\x7c\x17\x41\xa2\x54\xe5\xb6\xa0\x35\x21\x3d\x42\xf6\x2c\x1c\x7c\x26\
            \\x61\xc2\xf5\x0f\x65\x52\xda\xf9\xd2\xc2\x31\xf8\x25\x13\x0f\x69\xd8\x16\x7f\xa2\x04\x18\xf2\xc8\x00\x1a\x96\xa6\x0d\x15\x26\xab\
            \\x63\x31\x5c\x21\x5e\x0a\x72\xec\x49\xba\xfe\xfd\x18\x79\x08\xd9\x8d\x0d\xbd\x86\x31\x11\x70\xa7\x3e\x9b\x64\x0c\xcc\x3e\x10\xd7\
            \\xd5\xca\xd3\xb6\x0c\xae\xc3\x88\xf7\x30\x01\xe1\x6c\x72\x8a\xff\x71\xea\xe2\xa1\x1f\x9a\xf3\x6e\xcf\xcb\xd1\x2f\xc1\xde\x84\x17\
            \\xac\x07\xbe\x6b\xcb\x44\xa1\xd8\x8b\x9b\x0f\x56\x01\x39\x88\xc3\xb1\xc5\x2f\xca\xb4\xbe\x31\xcd\xd8\x78\x28\x06\x12\xa3\xa4\xe2\
            \\x6f\x7d\xe5\x32\x58\xfd\x7e\xb6\xd0\x1e\xe9\x00\x24\xad\xff\xc2\xf4\x99\x0f\xc5\x97\x11\xaa\xc5\x00\x1d\x7b\x95\x82\xe5\xe7\xd2\
            \\x10\x98\x73\xf6\x00\x61\x30\x96\xc3\x2d\x95\x21\xad\xa1\x21\xff\x29\x90\x84\x15\x7f\xbb\x97\x7f\xaf\x9e\xb3\xdb\x29\xc9\xed\x2a\
            \\x5c\xe2\xa4\x65\xa7\x30\xf3\x2c\xd0\xaa\x3f\xe8\x8a\x5c\xc0\x91\xd4\x9e\x2c\xe7\x0c\xe4\x54\xa9\xd6\x0a\xcd\x86\x01\x5f\x19\x19\
            \\x77\x07\x91\x03\xde\xa0\x3a\xf6\x78\xa8\x56\x5e\xde\xe3\x56\xdf\x21\xf0\x5c\xbe\x8b\x75\xe3\x87\xb3\xc5\x06\x51\xb8\xa5\xc3\xef\
            \\xd8\xee\xb6\xd2\xe5\x23\xbe\x77\xc2\x15\x45\x29\x2f\x69\xef\xdf\xaf\xe6\x7a\xfb\xf4\x70\xc4\xb2\xf3\xe0\xeb\x5b\xd6\xcc\x98\x76\
            \\x39\xe4\x46\x0c\x1f\xda\x85\x38\x19\x87\x83\x2f\xca\x00\x73\x67\xa9\x91\x44\xf8\x29\x6b\x29\x9e\x49\x2f\xc2\x95\x92\x66\xbe\xab\
            \\xb5\x67\x6e\x69\x9b\xd3\xdd\xda\xdf\x7e\x05\x2f\xdb\x25\x70\x1c\x1b\x5e\x51\xee\xf6\x53\x24\xe6\x6a\xfc\xe3\x6c\x03\x16\xcc\x04\
            \\x86\x44\x21\x3e\xb7\xdc\x59\xd0\x79\x65\x29\x1f\xcc\xd6\xfd\x43\x41\x82\x39\x79\x93\x2b\xcd\xf6\xb6\x57\xc3\x4d\x4e\xdf\xd2\x82\
            \\x7a\xe5\x29\x0c\x3c\xb9\x53\x6b\x85\x1e\x20\xfe\x98\x33\x55\x7e\x13\xec\xf0\xb0\xd3\xff\xb3\x72\x3f\x85\xc5\xc1\x0a\xef\x7e\xd2"#
 sbox_s5 :: Word8 -> Word32
 sbox_s5 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\x7e\xc9\x0c\x04\x2c\x6e\x74\xb9\x9b\x0e\x66\xdf\xa6\x33\x79\x11\xb8\x6a\x7f\xff\x1d\xd3\x58\xf5\x44\xdd\x9d\x44\x17\x31\x16\x7f\
            \\x08\xfb\xf1\xfa\xe7\xf5\x11\xcc\xd2\x05\x1b\x00\x73\x5a\xba\x00\x2a\xb7\x22\xd8\x38\x63\x81\xcb\xac\xf6\x24\x3a\x69\xbe\xfd\x7a\
            \\xe6\xa2\xe7\x7f\xf0\xc7\x20\xcd\xc4\x49\x48\x16\xcc\xf5\xc1\x80\x38\x85\x16\x40\x15\xb0\xa8\x48\xe6\x8b\x18\xcb\x4c\xaa\xde\xff\
            \\x5f\x48\x0a\x01\x04\x12\xb2\xaa\x25\x98\x14\xfc\x41\xd0\xef\xe2\x4e\x40\xb4\x8d\x24\x8e\xb6\xfb\x8d\xba\x1c\xfe\x41\xa9\x9b\x02\
            \\x1a\x55\x0a\x04\xba\x8f\x65\xcb\x72\x51\xf4\xe7\x95\xa5\x17\x25\xc1\x06\xec\xd7\x97\xa5\x98\x0a\xc5\x39\xb9\xaa\x4d\x79\xfe\x6a\
            \\xf2\xf3\xf7\x63\x68\xaf\x80\x40\xed\x0c\x9e\x56\x11\xb4\x95\x8b\xe1\xeb\x5a\x88\x87\x09\xe6\xb0\xd7\xe0\x71\x56\x4e\x29\xfe\xa7\
            \\x63\x66\xe5\x2d\x02\xd1\xc0\x00\xc4\xac\x8e\x05\x93\x77\xf5\x71\x0c\x05\x37\x2a\x57\x85\x35\xf2\x22\x61\xbe\x02\xd6\x42\xa0\xc9\
            \\xdf\x13\xa2\x80\x74\xb5\x5b\xd2\x68\x21\x99\xc0\xd4\x21\xe5\xec\x53\xfb\x3c\xe8\xc8\xad\xed\xb3\x28\xa8\x7f\xc9\x3d\x95\x99\x81\
            \\x5c\x1f\xf9\x00\xfe\x38\xd3\x99\x0c\x4e\xff\x0b\x06\x24\x07\xea\xaa\x2f\x4f\xb1\x4f\xb9\x69\x76\x90\xc7\x95\x05\xb0\xa8\xa7\x74\
            \\xef\x55\xa1\xff\xe5\x9c\xa2\xc2\xa6\xb6\x2d\x27\xe6\x6a\x42\x63\xdf\x65\x00\x1f\x0e\xc5\x09\x66\xdf\xdd\x55\xbc\x29\xde\x06\x55\
            \\x91\x1e\x73\x9a\x17\xaf\x89\x75\x32\xc7\x91\x1c\x89\xf8\x94\x68\x0d\x01\xe9\x80\x52\x47\x55\xf4\x03\xb6\x3c\xc9\x0c\xc8\x44\xb2\
            \\xbc\xf3\xf0\xaa\x87\xac\x36\xe9\xe5\x3a\x74\x26\x01\xb3\xd8\x2b\x1a\x9e\x74\x49\x64\xee\x2d\x7e\xcd\xdb\xb1\xda\x01\xc9\x49\x10\
            \\xb8\x68\xbf\x80\x0d\x26\xf3\xfd\x93\x42\xed\xe7\x04\xa5\xc2\x84\x63\x67\x37\xb6\x50\xf5\xb6\x16\xf2\x47\x66\xe3\x8e\xca\x36\xc1\
            \\x13\x6e\x05\xdb\xfe\xf1\x83\x91\xfb\x88\x7a\x37\xd6\xe7\xf7\xd4\xc7\xfb\x7d\xc9\x30\x63\xfc\xdf\xb6\xf5\x89\xde\xec\x29\x41\xda\
            \\x26\xe4\x66\x95\xb7\x56\x64\x19\xf6\x54\xef\xc5\xd0\x8d\x58\xb7\x48\x92\x54\x01\xc1\xba\xcb\x7f\xe5\xff\x55\x0f\xb6\x08\x30\x49\
            \\x5b\xb5\xd0\xe8\x87\xd7\x2e\x5a\xab\x6a\x6e\xe1\x22\x3a\x66\xce\xc6\x2b\xf3\xcd\x9e\x08\x85\xf9\x68\xcb\x3e\x47\x08\x6c\x01\x0f\
            \\xa2\x1d\xe8\x20\xd1\x8b\x69\xde\xf3\xf6\x57\x77\xfa\x02\xc3\xf6\x40\x7e\xda\xc3\xcb\xb3\xd5\x50\x17\x93\x08\x4d\xb0\xd7\x0e\xba\
            \\x0a\xb3\x78\xd5\xd9\x51\xfb\x0c\xde\xd7\xda\x56\x41\x24\xbb\xe4\x94\xca\x0b\x56\x0f\x57\x55\xd1\xe0\xe1\xe5\x6e\x61\x84\xb5\xbe\
            \\x58\x0a\x24\x9f\x94\xf7\x4b\xc0\xe3\x27\x88\x8e\x9f\x7b\x55\x61\xc3\xdc\x02\x80\x05\x68\x77\x15\x64\x6c\x6b\xd7\x44\x90\x4d\xb3\
            \\x66\xb4\xf0\xa3\xc0\xf1\x64\x8a\x69\x7e\xd5\xaf\x49\xe9\x2f\xf6\x30\x9e\x37\x4f\x2c\xb6\x35\x6a\x85\x80\x85\x73\x49\x91\xf8\x40\
            \\x76\xf0\xae\x02\x08\x3b\xe8\x4d\x28\x42\x1c\x9a\x44\x48\x94\x06\x73\x6e\x4c\xb8\xc1\x09\x29\x10\x8b\xc9\x5f\xc6\x7d\x86\x9c\xf4\
            \\x13\x4f\x61\x6f\x2e\x77\x11\x8d\xb3\x1b\x2b\xe1\xaa\x90\xb4\x72\x3c\xa5\xd7\x17\x7d\x16\x1b\xba\x9c\xad\x90\x10\xaf\x46\x2b\xa2\
            \\x9f\xe4\x59\xd2\x45\xd3\x45\x59\xd9\xf2\xda\x13\xdb\xc6\x54\x87\xf3\xe4\xf9\x4e\x17\x6d\x48\x6f\x09\x7c\x13\xea\x63\x1d\xa5\xc7\
            \\x44\x5f\x73\x82\x17\x56\x83\xf4\xcd\xc6\x6a\x97\x70\xbe\x02\x88\xb3\xcd\xcf\x72\x6e\x5d\xd2\xf3\x20\x93\x60\x79\x45\x9b\x80\xa5\
            \\xbe\x60\xe2\xdb\xa9\xc2\x31\x01\xeb\xa5\x31\x5c\x22\x4e\x42\xf2\x1c\x5c\x15\x72\xf6\x72\x1b\x2c\x1a\xd2\xff\xf3\x8c\x25\x40\x4e\
            \\x32\x4e\xd7\x2f\x40\x67\xb7\xfd\x05\x23\x13\x8e\x5c\xa3\xbc\x78\xdc\x0f\xd6\x6e\x75\x92\x22\x83\x78\x4d\x6b\x17\x58\xeb\xb1\x6e\
            \\x44\x09\x4f\x85\x3f\x48\x1d\x87\xfc\xfe\xae\x7b\x77\xb5\xff\x76\x8c\x23\x02\xbf\xaa\xf4\x75\x56\x5f\x46\xb0\x2a\x2b\x09\x28\x01\
            \\x3d\x38\xf5\xf7\x0c\xa8\x1f\x36\x52\xaf\x4a\x8a\x66\xd5\xe7\xc0\xdf\x3b\x08\x74\x95\x05\x51\x10\x1b\x5a\xd7\xa8\xf6\x1e\xd5\xad\
            \\x6c\xf6\xe4\x79\x20\x75\x81\x84\xd0\xce\xfa\x65\x88\xf7\xbe\x58\x4a\x04\x68\x26\x0f\xf6\xf8\xf3\xa0\x9c\x7f\x70\x53\x46\xab\xa0\
            \\x5c\xe9\x6c\x28\xe1\x76\xed\xa3\x6b\xac\x30\x7f\x37\x68\x29\xd2\x85\x36\x0f\xa9\x17\xe3\xfe\x2a\x24\xb7\x97\x67\xf5\xa9\x6b\x20\
            \\xd6\xcd\x25\x95\x68\xff\x1e\xbf\x75\x55\x44\x2c\xf1\x9f\x06\xbe\xf9\xe0\x65\x9a\xee\xb9\x49\x1d\x34\x01\x07\x18\xbb\x30\xca\xb8\
            \\xe8\x22\xfe\x15\x88\x57\x09\x83\x75\x0e\x62\x49\xda\x62\x7e\x55\x5e\x76\xff\xa8\xb1\x53\x45\x46\x6d\x47\xde\x08\xef\xe9\xe7\xd4"#
 sbox_s6 :: Word8 -> Word32
 sbox_s6 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\xf6\xfa\x8f\x9d\x2c\xac\x6c\xe1\x4c\xa3\x48\x67\xe2\x33\x7f\x7c\x95\xdb\x08\xe7\x01\x68\x43\xb4\xec\xed\x5c\xbc\x32\x55\x53\xac\
            \\xbf\x9f\x09\x60\xdf\xa1\xe2\xed\x83\xf0\x57\x9d\x63\xed\x86\xb9\x1a\xb6\xa6\xb8\xde\x5e\xbe\x39\xf3\x8f\xf7\x32\x89\x89\xb1\x38\
            \\x33\xf1\x49\x61\xc0\x19\x37\xbd\xf5\x06\xc6\xda\xe4\x62\x5e\x7e\xa3\x08\xea\x99\x4e\x23\xe3\x3c\x79\xcb\xd7\xcc\x48\xa1\x43\x67\
            \\xa3\x14\x96\x19\xfe\xc9\x4b\xd5\xa1\x14\x17\x4a\xea\xa0\x18\x66\xa0\x84\xdb\x2d\x09\xa8\x48\x6f\xa8\x88\x61\x4a\x29\x00\xaf\x98\
            \\x01\x66\x59\x91\xe1\x99\x28\x63\xc8\xf3\x0c\x60\x2e\x78\xef\x3c\xd0\xd5\x19\x32\xcf\x0f\xec\x14\xf7\xca\x07\xd2\xd0\xa8\x20\x72\
            \\xfd\x41\x19\x7e\x93\x05\xa6\xb0\xe8\x6b\xe3\xda\x74\xbe\xd3\xcd\x37\x2d\xa5\x3c\x4c\x7f\x44\x48\xda\xb5\xd4\x40\x6d\xba\x0e\xc3\
            \\x08\x39\x19\xa7\x9f\xba\xee\xd9\x49\xdb\xcf\xb0\x4e\x67\x0c\x53\x5c\x3d\x9c\x01\x64\xbd\xb9\x41\x2c\x0e\x63\x6a\xba\x7d\xd9\xcd\
            \\xea\x6f\x73\x88\xe7\x0b\xc7\x62\x35\xf2\x9a\xdb\x5c\x4c\xdd\x8d\xf0\xd4\x8d\x8c\xb8\x81\x53\xe2\x08\xa1\x98\x66\x1a\xe2\xea\xc8\
            \\x28\x4c\xaf\x89\xaa\x92\x82\x23\x93\x34\xbe\x53\x3b\x3a\x21\xbf\x16\x43\x4b\xe3\x9a\xea\x39\x06\xef\xe8\xc3\x6e\xf8\x90\xcd\xd9\
            \\x80\x22\x6d\xae\xc3\x40\xa4\xa3\xdf\x7e\x9c\x09\xa6\x94\xa8\x07\x5b\x7c\x5e\xcc\x22\x1d\xb3\xa6\x9a\x69\xa0\x2f\x68\x81\x8a\x54\
            \\xce\xb2\x29\x6f\x53\xc0\x84\x3a\xfe\x89\x36\x55\x25\xbf\xe6\x8a\xb4\x62\x8a\xbc\xcf\x22\x2e\xbf\x25\xac\x6f\x48\xa9\xa9\x93\x87\
            \\x53\xbd\xdb\x65\xe7\x6f\xfb\xe7\xe9\x67\xfd\x78\x0b\xa9\x35\x63\x8e\x34\x2b\xc1\xe8\xa1\x1b\xe9\x49\x80\x74\x0d\xc8\x08\x7d\xfc\
            \\x8d\xe4\xbf\x99\xa1\x11\x01\xa0\x7f\xd3\x79\x75\xda\x5a\x26\xc0\xe8\x1f\x99\x4f\x95\x28\xcd\x89\xfd\x33\x9f\xed\xb8\x78\x34\xbf\
            \\x5f\x04\x45\x6d\x22\x25\x86\x98\xc9\xc4\xc8\x3b\x2d\xc1\x56\xbe\x4f\x62\x8d\xaa\x57\xf5\x5e\xc5\xe2\x22\x0a\xbe\xd2\x91\x6e\xbf\
            \\x4e\xc7\x5b\x95\x24\xf2\xc3\xc0\x42\xd1\x5d\x99\xcd\x0d\x7f\xa0\x7b\x6e\x27\xff\xa8\xdc\x8a\xf0\x73\x45\xc1\x06\xf4\x1e\x23\x2f\
            \\x35\x16\x23\x86\xe6\xea\x89\x26\x33\x33\xb0\x94\x15\x7e\xc6\xf2\x37\x2b\x74\xaf\x69\x25\x73\xe4\xe9\xa9\xd8\x48\xf3\x16\x02\x89\
            \\x3a\x62\xef\x1d\xa7\x87\xe2\x38\xf3\xa5\xf6\x76\x74\x36\x48\x53\x20\x95\x10\x63\x45\x76\x69\x8d\xb6\xfa\xd4\x07\x59\x2a\xf9\x50\
            \\x36\xf7\x35\x23\x4c\xfb\x6e\x87\x7d\xa4\xce\xc0\x6c\x15\x2d\xaa\xcb\x03\x96\xa8\xc5\x0d\xfe\x5d\xfc\xd7\x07\xab\x09\x21\xc4\x2f\
            \\x89\xdf\xf0\xbb\x5f\xe2\xbe\x78\x44\x8f\x4f\x33\x75\x46\x13\xc9\x2b\x05\xd0\x8d\x48\xb9\xd5\x85\xdc\x04\x94\x41\xc8\x09\x8f\x9b\
            \\x7d\xed\xe7\x86\xc3\x9a\x33\x73\x42\x41\x00\x05\x6a\x09\x17\x51\x0e\xf3\xc8\xa6\x89\x00\x72\xd6\x28\x20\x76\x82\xa9\xa9\xf7\xbe\
            \\xbf\x32\x67\x9d\xd4\x5b\x5b\x75\xb3\x53\xfd\x00\xcb\xb0\xe3\x58\x83\x0f\x22\x0a\x1f\x8f\xb2\x14\xd3\x72\xcf\x08\xcc\x3c\x4a\x13\
            \\x8c\xf6\x31\x66\x06\x1c\x87\xbe\x88\xc9\x8f\x88\x60\x62\xe3\x97\x47\xcf\x8e\x7a\xb6\xc8\x52\x83\x3c\xc2\xac\xfb\x3f\xc0\x69\x76\
            \\x4e\x8f\x02\x52\x64\xd8\x31\x4d\xda\x38\x70\xe3\x1e\x66\x54\x59\xc1\x09\x08\xf0\x51\x30\x21\xa5\x6c\x5b\x68\xb7\x82\x2f\x8a\xa0\
            \\x30\x07\xcd\x3e\x74\x71\x9e\xef\xdc\x87\x26\x81\x07\x33\x40\xd4\x7e\x43\x2f\xd9\x0c\x5e\xc2\x41\x88\x09\x28\x6c\xf5\x92\xd8\x91\
            \\x08\xa9\x30\xf6\x95\x7e\xf3\x05\xb7\xfb\xff\xbd\xc2\x66\xe9\x6f\x6f\xe4\xac\x98\xb1\x73\xec\xc0\xbc\x60\xb4\x2a\x95\x34\x98\xda\
            \\xfb\xa1\xae\x12\x2d\x4b\xd7\x36\x0f\x25\xfa\xab\xa4\xf3\xfc\xeb\xe2\x96\x91\x23\x25\x7f\x0c\x3d\x93\x48\xaf\x49\x36\x14\x00\xbc\
            \\xe8\x81\x6f\x4a\x38\x14\xf2\x00\xa3\xf9\x40\x43\x9c\x7a\x54\xc2\xbc\x70\x4f\x57\xda\x41\xe7\xf9\xc2\x5a\xd3\x3a\x54\xf4\xa0\x84\
            \\xb1\x7f\x55\x05\x59\x35\x7c\xbe\xed\xbd\x15\xc8\x7f\x97\xc5\xab\xba\x5a\xc7\xb5\xb6\xf6\xde\xaf\x3a\x47\x9c\x3a\x53\x02\xda\x25\
            \\x65\x3d\x7e\x6a\x54\x26\x8d\x49\x51\xa4\x77\xea\x50\x17\xd5\x5b\xd7\xd2\x5d\x88\x44\x13\x6c\x76\x04\x04\xa8\xc8\xb8\xe5\xa1\x21\
            \\xb8\x1a\x92\x8a\x60\xed\x58\x69\x97\xc5\x5b\x96\xea\xec\x99\x1b\x29\x93\x59\x13\x01\xfd\xb7\xf1\x08\x8e\x8d\xfa\x9a\xb6\xf6\xf5\
            \\x3b\x4c\xbf\x9f\x4a\x5d\xe3\xab\xe6\x05\x1d\x35\xa0\xe1\xd8\x55\xd3\x6b\x4c\xf1\xf5\x44\xed\xeb\xb0\xe9\x35\x24\xbe\xbb\x8f\xbd\
            \\xa2\xd7\x62\xcf\x49\xc9\x2f\x54\x38\xb5\xf3\x31\x71\x28\xa4\x54\x48\x39\x29\x05\xa6\x5b\x1d\xb8\x85\x1c\x97\xbd\xd6\x75\xcf\x2f"#
 sbox_s7 :: Word8 -> Word32
 sbox_s7 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\x85\xe0\x40\x19\x33\x2b\xf5\x67\x66\x2d\xbf\xff\xcf\xc6\x56\x93\x2a\x8d\x7f\x6f\xab\x9b\xc9\x12\xde\x60\x08\xa1\x20\x28\xda\x1f\
            \\x02\x27\xbc\xe7\x4d\x64\x29\x16\x18\xfa\xc3\x00\x50\xf1\x8b\x82\x2c\xb2\xcb\x11\xb2\x32\xe7\x5c\x4b\x36\x95\xf2\xb2\x87\x07\xde\
            \\xa0\x5f\xbc\xf6\xcd\x41\x81\xe9\xe1\x50\x21\x0c\xe2\x4e\xf1\xbd\xb1\x68\xc3\x81\xfd\xe4\xe7\x89\x5c\x79\xb0\xd8\x1e\x8b\xfd\x43\
            \\x4d\x49\x50\x01\x38\xbe\x43\x41\x91\x3c\xee\x1d\x92\xa7\x9c\x3f\x08\x97\x66\xbe\xba\xee\xad\xf4\x12\x86\xbe\xcf\xb6\xea\xcb\x19\
            \\x26\x60\xc2\x00\x75\x65\xbd\xe4\x64\x24\x1f\x7a\x82\x48\xdc\xa9\xc3\xb3\xad\x66\x28\x13\x60\x86\x0b\xd8\xdf\xa8\x35\x6d\x1c\xf2\
            \\x10\x77\x89\xbe\xb3\xb2\xe9\xce\x05\x02\xaa\x8f\x0b\xc0\x35\x1e\x16\x6b\xf5\x2a\xeb\x12\xff\x82\xe3\x48\x69\x11\xd3\x4d\x75\x16\
            \\x4e\x7b\x3a\xff\x5f\x43\x67\x1b\x9c\xf6\xe0\x37\x49\x81\xac\x83\x33\x42\x66\xce\x8c\x93\x41\xb7\xd0\xd8\x54\xc0\xcb\x3a\x6c\x88\
            \\x47\xbc\x28\x29\x47\x25\xba\x37\xa6\x6a\xd2\x2b\x7a\xd6\x1f\x1e\x0c\x5c\xba\xfa\x44\x37\xf1\x07\xb6\xe7\x99\x62\x42\xd2\xd8\x16\
            \\x0a\x96\x12\x88\xe1\xa5\xc0\x6e\x13\x74\x9e\x67\x72\xfc\x08\x1a\xb1\xd1\x39\xf7\xf9\x58\x37\x45\xcf\x19\xdf\x58\xbe\xc3\xf7\x56\
            \\xc0\x6e\xba\x30\x07\x21\x1b\x24\x45\xc2\x88\x29\xc9\x5e\x31\x7f\xbc\x8e\xc5\x11\x38\xbc\x46\xe9\xc6\xe6\xfa\x14\xba\xe8\x58\x4a\
            \\xad\x4e\xbc\x46\x46\x8f\x50\x8b\x78\x29\x43\x5f\xf1\x24\x18\x3b\x82\x1d\xba\x9f\xaf\xf6\x0f\xf4\xea\x2c\x4e\x6d\x16\xe3\x92\x64\
            \\x92\x54\x4a\x8b\x00\x9b\x4f\xc3\xab\xa6\x8c\xed\x9a\xc9\x6f\x78\x06\xa5\xb7\x9a\xb2\x85\x6e\x6e\x1a\xec\x3c\xa9\xbe\x83\x86\x88\
            \\x0e\x08\x04\xe9\x55\xf1\xbe\x56\xe7\xe5\x36\x3b\xb3\xa1\xf2\x5d\xf7\xde\xbb\x85\x61\xfe\x03\x3c\x16\x74\x62\x33\x3c\x03\x4c\x28\
            \\xda\x6d\x0c\x74\x79\xaa\xc5\x6c\x3c\xe4\xe1\xad\x51\xf0\xc8\x02\x98\xf8\xf3\x5a\x16\x26\xa4\x9f\xee\xd8\x2b\x29\x1d\x38\x2f\xe3\
            \\x0c\x4f\xb9\x9a\xbb\x32\x57\x78\x3e\xc6\xd9\x7b\x6e\x77\xa6\xa9\xcb\x65\x8b\x5c\xd4\x52\x30\xc7\x2b\xd1\x40\x8b\x60\xc0\x3e\xb7\
            \\xb9\x06\x8d\x78\xa3\x37\x54\xf4\xf4\x30\xc8\x7d\xc8\xa7\x13\x02\xb9\x6d\x8c\x32\xeb\xd4\xe7\xbe\xbe\x8b\x9d\x2d\x79\x79\xfb\x06\
            \\xe7\x22\x53\x08\x8b\x75\xcf\x77\x11\xef\x8d\xa4\xe0\x83\xc8\x58\x8d\x6b\x78\x6f\x5a\x63\x17\xa6\xfa\x5c\xf7\xa0\x5d\xda\x00\x33\
            \\xf2\x8e\xbf\xb0\xf5\xb9\xc3\x10\xa0\xea\xc2\x80\x08\xb9\x76\x7a\xa3\xd9\xd2\xb0\x79\xd3\x42\x17\x02\x1a\x71\x8d\x9a\xc6\x33\x6a\
            \\x27\x11\xfd\x60\x43\x80\x50\xe3\x06\x99\x08\xa8\x3d\x7f\xed\xc4\x82\x6d\x2b\xef\x4e\xeb\x84\x76\x48\x8d\xcf\x25\x36\xc9\xd5\x66\
            \\x28\xe7\x4e\x41\xc2\x61\x0a\xca\x3d\x49\xa9\xcf\xba\xe3\xb9\xdf\xb6\x5f\x8d\xe6\x92\xae\xaf\x64\x3a\xc7\xd5\xe6\x9e\xa8\x05\x09\
            \\xf2\x2b\x01\x7d\xa4\x17\x3f\x70\xdd\x1e\x16\xc3\x15\xe0\xd7\xf9\x50\xb1\xb8\x87\x2b\x9f\x4f\xd5\x62\x5a\xba\x82\x6a\x01\x79\x62\
            \\x2e\xc0\x1b\x9c\x15\x48\x8a\xa9\xd7\x16\xe7\x40\x40\x05\x5a\x2c\x93\xd2\x9a\x22\xe3\x2d\xbf\x9a\x05\x87\x45\xb9\x34\x53\xdc\x1e\
            \\xd6\x99\x29\x6e\x49\x6c\xff\x6f\x1c\x9f\x49\x86\xdf\xe2\xed\x07\xb8\x72\x42\xd1\x19\xde\x7e\xae\x05\x3e\x56\x1a\x15\xad\x6f\x8c\
            \\x66\x62\x6c\x1c\x71\x54\xc2\x4c\xea\x08\x2b\x2a\x93\xeb\x29\x39\x17\xdc\xb0\xf0\x58\xd4\xf2\xae\x9e\xa2\x94\xfb\x52\xcf\x56\x4c\
            \\x98\x83\xfe\x66\x2e\xc4\x05\x81\x76\x39\x53\xc3\x01\xd6\x69\x2e\xd3\xa0\xc1\x08\xa1\xe7\x16\x0e\xe4\xf2\xdf\xa6\x69\x3e\xd2\x85\
            \\x74\x90\x46\x98\x4c\x2b\x0e\xdd\x4f\x75\x76\x56\x5d\x39\x33\x78\xa1\x32\x23\x4f\x3d\x32\x1c\x5d\xc3\xf5\xe1\x94\x4b\x26\x93\x01\
            \\xc7\x9f\x02\x2f\x3c\x99\x7e\x7e\x5e\x4f\x95\x04\x3f\xfa\xfb\xbd\x76\xf7\xad\x0e\x29\x66\x93\xf4\x3d\x1f\xce\x6f\xc6\x1e\x45\xbe\
            \\xd3\xb5\xab\x34\xf7\x2b\xf9\xb7\x1b\x04\x34\xc0\x4e\x72\xb5\x67\x55\x92\xa3\x3d\xb5\x22\x93\x01\xcf\xd2\xa8\x7f\x60\xae\xb7\x67\
            \\x18\x14\x38\x6b\x30\xbc\xc3\x3d\x38\xa0\xc0\x7d\xfd\x16\x06\xf2\xc3\x63\x51\x9b\x58\x9d\xd3\x90\x54\x79\xf8\xe6\x1c\xb8\xd6\x47\
            \\x97\xfd\x61\xa9\xea\x77\x59\xf4\x2d\x57\x53\x9d\x56\x9a\x58\xcf\xe8\x4e\x63\xad\x46\x2e\x1b\x78\x65\x80\xf8\x7e\xf3\x81\x79\x14\
            \\x91\xda\x55\xf4\x40\xa2\x30\xf3\xd1\x98\x8f\x35\xb6\xe3\x18\xd2\x3f\xfa\x50\xbc\x3d\x40\xf0\x21\xc3\xc0\xbd\xae\x49\x58\xc2\x4c\
            \\x51\x8f\x36\xb2\x84\xb1\xd3\x70\x0f\xed\xce\x83\x87\x8d\xda\xda\xf2\xa2\x79\xc7\x94\xe0\x1b\xe8\x90\x71\x6f\x4b\x95\x4b\x8a\xa3"#
 sbox_s8 :: Word8 -> Word32
 sbox_s8 i = arrayRead32 t (fromIntegral i)
  where
    t = array32FromAddrBE 256
            "\xe2\x16\x30\x0d\xbb\xdd\xff\xfc\xa7\xeb\xda\xbd\x35\x64\x80\x95\x77\x89\xf8\xb7\xe6\xc1\x12\x1b\x0e\x24\x16\x00\x05\x2c\xe8\xb5\
            \\x11\xa9\xcf\xb0\xe5\x95\x2f\x11\xec\xe7\x99\x0a\x93\x86\xd1\x74\x2a\x42\x93\x1c\x76\xe3\x81\x11\xb1\x2d\xef\x3a\x37\xdd\xdd\xfc\
            \\xde\x9a\xde\xb1\x0a\x0c\xc3\x2c\xbe\x19\x70\x29\x84\xa0\x09\x40\xbb\x24\x3a\x0f\xb4\xd1\x37\xcf\xb4\x4e\x79\xf0\x04\x9e\xed\xfd\
            \\x0b\x15\xa1\x5d\x48\x0d\x31\x68\x8b\xbb\xde\x5a\x66\x9d\xed\x42\xc7\xec\xe8\x31\x3f\x8f\x95\xe7\x72\xdf\x19\x1b\x75\x80\x33\x0d\
            \\x94\x07\x42\x51\x5c\x7d\xcd\xfa\xab\xbe\x6d\x63\xaa\x40\x21\x64\xb3\x01\xd4\x0a\x02\xe7\xd1\xca\x53\x57\x1d\xae\x7a\x31\x82\xa2\
            \\x12\xa8\xdd\xec\xfd\xaa\x33\x5d\x17\x6f\x43\xe8\x71\xfb\x46\xd4\x38\x12\x90\x22\xce\x94\x9a\xd4\xb8\x47\x69\xad\x96\x5b\xd8\x62\
            \\x82\xf3\xd0\x55\x66\xfb\x97\x67\x15\xb8\x0b\x4e\x1d\x5b\x47\xa0\x4c\xfd\xe0\x6f\xc2\x8e\xc4\xb8\x57\xe8\x72\x6e\x64\x7a\x78\xfc\
            \\x99\x86\x5d\x44\x60\x8b\xd5\x93\x6c\x20\x0e\x03\x39\xdc\x5f\xf6\x5d\x0b\x00\xa3\xae\x63\xaf\xf2\x7e\x8b\xd6\x32\x70\x10\x8c\x0c\
            \\xbb\xd3\x50\x49\x29\x98\xdf\x04\x98\x0c\xf4\x2a\x9b\x6d\xf4\x91\x9e\x7e\xdd\x53\x06\x91\x85\x48\x58\xcb\x7e\x07\x3b\x74\xef\x2e\
            \\x52\x2f\xff\xb1\xd2\x47\x08\xcc\x1c\x7e\x27\xcd\xa4\xeb\x21\x5b\x3c\xf1\xd2\xe2\x19\xb4\x7a\x38\x42\x4f\x76\x18\x35\x85\x60\x39\
            \\x9d\x17\xde\xe7\x27\xeb\x35\xe6\xc9\xaf\xf6\x7b\x36\xba\xf5\xb8\x09\xc4\x67\xcd\xc1\x89\x10\xb1\xe1\x1d\xbf\x7b\x06\xcd\x1a\xf8\
            \\x71\x70\xc6\x08\x2d\x5e\x33\x54\xd4\xde\x49\x5a\x64\xc6\xd0\x06\xbc\xc0\xc6\x2c\x3d\xd0\x0d\xb3\x70\x8f\x8f\x34\x77\xd5\x1b\x42\
            \\x26\x4f\x62\x0f\x24\xb8\xd2\xbf\x15\xc1\xb7\x9e\x46\xa5\x25\x64\xf8\xd7\xe5\x4e\x3e\x37\x81\x60\x78\x95\xcd\xa5\x85\x9c\x15\xa5\
            \\xe6\x45\x97\x88\xc3\x7b\xc7\x5f\xdb\x07\xba\x0c\x06\x76\xa3\xab\x7f\x22\x9b\x1e\x31\x84\x2e\x7b\x24\x25\x9f\xd7\xf8\xbe\xf4\x72\
            \\x83\x5f\xfc\xb8\x6d\xf4\xc1\xf2\x96\xf5\xb1\x95\xfd\x0a\xf0\xfc\xb0\xfe\x13\x4c\xe2\x50\x6d\x3d\x4f\x9b\x12\xea\xf2\x15\xf2\x25\
            \\xa2\x23\x73\x6f\x9f\xb4\xc4\x28\x25\xd0\x49\x79\x34\xc7\x13\xf8\xc4\x61\x81\x87\xea\x7a\x6e\x98\x7c\xd1\x6e\xfc\x14\x36\x87\x6c\
            \\xf1\x54\x41\x07\xbe\xde\xee\x14\x56\xe9\xaf\x27\xa0\x4a\xa4\x41\x3c\xf7\xc8\x99\x92\xec\xba\xe6\xdd\x67\x01\x6d\x15\x16\x82\xeb\
            \\xa8\x42\xee\xdf\xfd\xba\x60\xb4\xf1\x90\x7b\x75\x20\xe3\x03\x0f\x24\xd8\xc2\x9e\xe1\x39\x67\x3b\xef\xa6\x3f\xb8\x71\x87\x30\x54\
            \\xb6\xf2\xcf\x3b\x9f\x32\x64\x42\xcb\x15\xa4\xcc\xb0\x1a\x45\x04\xf1\xe4\x7d\x8d\x84\x4a\x1b\xe5\xba\xe7\xdf\xdc\x42\xcb\xda\x70\
            \\xcd\x7d\xae\x0a\x57\xe8\x5b\x7a\xd5\x3f\x5a\xf6\x20\xcf\x4d\x8c\xce\xa4\xd4\x28\x79\xd1\x30\xa4\x34\x86\xeb\xfb\x33\xd3\xcd\xdc\
            \\x77\x85\x3b\x53\x37\xef\xfc\xb5\xc5\x06\x87\x78\xe5\x80\xb3\xe6\x4e\x68\xb8\xf4\xc5\xc8\xb3\x7e\x0d\x80\x9e\xa2\x39\x8f\xeb\x7c\
            \\x13\x2a\x4f\x94\x43\xb7\x95\x0e\x2f\xee\x7d\x1c\x22\x36\x13\xbd\xdd\x06\xca\xa2\x37\xdf\x93\x2b\xc4\x24\x82\x89\xac\xf3\xeb\xc3\
            \\x57\x15\xf6\xb7\xef\x34\x78\xdd\xf2\x67\x61\x6f\xc1\x48\xcb\xe4\x90\x52\x81\x5e\x5e\x41\x0f\xab\xb4\x8a\x24\x65\x2e\xda\x7f\xa4\
            \\xe8\x7b\x40\xe4\xe9\x8e\xa0\x84\x58\x89\xe9\xe1\xef\xd3\x90\xfc\xdd\x07\xd3\x5b\xdb\x48\x56\x94\x38\xd7\xe5\xb2\x57\x72\x01\x01\
            \\x73\x0e\xde\xbc\x5b\x64\x31\x13\x94\x91\x7e\x4f\x50\x3c\x2f\xba\x64\x6f\x12\x82\x75\x23\xd2\x4a\xe0\x77\x96\x95\xf9\xc1\x7a\x8f\
            \\x7a\x5b\x21\x21\xd1\x87\xb8\x96\x29\x26\x3a\x4d\xba\x51\x0c\xdf\x81\xf4\x7c\x9f\xad\x11\x63\xed\xea\x7b\x59\x65\x1a\x00\x72\x6e\
            \\x11\x40\x30\x92\x00\xda\x6d\x77\x4a\x0c\xdd\x61\xad\x1f\x46\x03\x60\x5b\xdf\xb0\x9e\xed\xc3\x64\x22\xeb\xe6\xa8\xce\xe7\xd2\x8a\
            \\xa0\xe7\x36\xa0\x55\x64\xa6\xb9\x10\x85\x32\x09\xc7\xeb\x8f\x37\x2d\xe7\x05\xca\x89\x51\x57\x0f\xdf\x09\x82\x2b\xbd\x69\x1a\x6c\
            \\xaa\x12\xe4\xf2\x87\x45\x1c\x0f\xe0\xf6\xa2\x7a\x3a\xda\x48\x19\x4c\xf1\x76\x4f\x0d\x77\x1c\x2b\x67\xcd\xb1\x56\x35\x0d\x83\x84\
            \\x59\x38\xfa\x0f\x42\x39\x9e\xf3\x36\x99\x7b\x07\x0e\x84\x09\x3d\x4a\xa9\x3e\x61\x83\x60\xd8\x7b\x1f\xa9\x8b\x0c\x11\x49\x38\x2c\
            \\xe9\x76\x25\xa5\x06\x14\xd1\xb7\x0e\x25\x24\x4b\x0c\x76\x83\x47\x58\x9e\x8d\x82\x0d\x20\x59\xd1\xa4\x66\xbb\x1e\xf8\xda\x0a\x82\
            \\x04\xf1\x91\x30\xba\x6e\x4e\xc0\x99\x26\x51\x64\x1e\xe7\x23\x0d\x50\xb2\xad\x80\xea\xee\x68\x01\x8d\xb2\xa2\x83\xea\x8b\xf5\x9e"#
--- a/Crypto/Cipher/Camellia/Primitive.hs
+++ b/Crypto/Cipher/Camellia/Primitive.hs
@ -6,8 +6,8 @@
 -- Stability   : experimental
 -- Portability : Good
 --
-- this only cover Camellia 128 bits for now, API will change once
+-- This only cover Camellia 128 bits for now. The API will change once
-- 192 and 256 mode are implemented too
+-- 192 and 256 mode are implemented too.
 {-# LANGUAGE MagicHash #-}
 module Crypto.Cipher.Camellia.Primitive
    ( Camellia
--- a/Crypto/Cipher/ChaCha.hs
+++ b/Crypto/Cipher/ChaCha.hs
@ -12,7 +12,7 @@ module Crypto.Cipher.ChaCha
    , combine
    , generate
    , State
-    -- * simple interface for DRG purpose
+    -- * Simple interface for DRG purpose
    , initializeSimple
    , generateSimple
    , StateSimple
@ -41,24 +41,26 @@ initialize :: (ByteArrayAccess key, ByteArrayAccess nonce)
           -> nonce -- ^ the nonce (64 or 96 bits)
           -> State -- ^ the initial ChaCha state
 initialize nbRounds key nonce
-    | not (kLen `elem` [16,32])       = error "ChaCha: key length should be 128 or 256 bits"
+    | kLen `notElem` [16,32]          = error "ChaCha: key length should be 128 or 256 bits"
-    | not (nonceLen `elem` [8,12])    = error "ChaCha: nonce length should be 64 or 96 bits"
+    | nonceLen `notElem` [8,12]       = error "ChaCha: nonce length should be 64 or 96 bits"
-    | not (nbRounds `elem` [8,12,20]) = error "ChaCha: rounds should be 8, 12 or 20"
+    | nbRounds `notElem` [8,12,20]    = error "ChaCha: rounds should be 8, 12 or 20"
    | otherwise                       = unsafeDoIO $ do
        stPtr <- B.alloc 132 $ \stPtr ->
            B.withByteArray nonce $ \noncePtr  ->
            B.withByteArray key   $ \keyPtr ->
-                ccryptonite_chacha_init stPtr (fromIntegral nbRounds) kLen keyPtr nonceLen noncePtr
+                ccryptonite_chacha_init stPtr  nbRounds kLen keyPtr nonceLen noncePtr
        return $ State stPtr
  where kLen     = B.length key
        nonceLen = B.length nonce
 -- | Initialize simple ChaCha State
-initializeSimple :: ByteArray seed
+--
 -- The seed need to be at least 40 bytes long
 initializeSimple :: ByteArrayAccess seed
                 => seed -- ^ a 40 bytes long seed
                 -> StateSimple
 initializeSimple seed
-    | sLen /= 40 = error "ChaCha Random: seed length should be 40 bytes"
+    | sLen < 40 = error "ChaCha Random: seed length should be 40 bytes"
    | otherwise = unsafeDoIO $ do
        stPtr <- B.alloc 64 $ \stPtr ->
                    B.withByteArray seed $ \seedPtr ->
--- a/Crypto/Cipher/RC4.hs
+++ b/Crypto/Cipher/RC4.hs
@ -30,6 +30,11 @@ import           Crypto.Internal.Compat
 import           Crypto.Internal.Imports
 -- | The encryption state for RC4
 --
 -- This type is an instance of 'ByteArrayAccess' for debugging purpose. Internal
 -- layout is architecture dependent, may contain uninitialized data fragments,
 -- and change in future versions.  The bytearray should not be used as input to
 -- cryptographic algorithms.
 newtype State = State ScrubbedBytes
    deriving (ByteArrayAccess,NFData)
--- a/Crypto/Cipher/Salsa.hs
+++ b/Crypto/Cipher/Salsa.hs
@ -33,14 +33,14 @@ initialize :: (ByteArrayAccess key, ByteArrayAccess nonce)
           -> nonce  -- ^ the nonce (64 or 96 bits)
           -> State  -- ^ the initial Salsa state
 initialize nbRounds key nonce
-    | not (kLen `elem` [16,32])       = error "Salsa: key length should be 128 or 256 bits"
+    | kLen `notElem` [16,32]          = error "Salsa: key length should be 128 or 256 bits"
-    | not (nonceLen `elem` [8,12])    = error "Salsa: nonce length should be 64 or 96 bits"
+    | nonceLen `notElem` [8,12]       = error "Salsa: nonce length should be 64 or 96 bits"
-    | not (nbRounds `elem` [8,12,20]) = error "Salsa: rounds should be 8, 12 or 20"
+    | nbRounds `notElem` [8,12,20]    = error "Salsa: rounds should be 8, 12 or 20"
    | otherwise = unsafeDoIO $ do
        stPtr <- B.alloc 132 $ \stPtr ->
            B.withByteArray nonce $ \noncePtr  ->
            B.withByteArray key   $ \keyPtr ->
-                ccryptonite_salsa_init stPtr (fromIntegral nbRounds) kLen keyPtr nonceLen noncePtr
+                ccryptonite_salsa_init stPtr nbRounds kLen keyPtr nonceLen noncePtr
        return $ State stPtr
  where kLen     = B.length key
        nonceLen = B.length nonce
--- a/Crypto/Cipher/Twofish.hs
+++ b/Crypto/Cipher/Twofish.hs
@ -0,0 +1,45 @@
 module Crypto.Cipher.Twofish
    ( Twofish128
    , Twofish192
    , Twofish256
    ) where
 import Crypto.Cipher.Twofish.Primitive
 import Crypto.Cipher.Types
 import Crypto.Cipher.Utils
 newtype Twofish128 = Twofish128 Twofish
 instance Cipher Twofish128 where
    cipherName    _ = "Twofish128"
    cipherKeySize _ = KeySizeFixed 16
    cipherInit key  = Twofish128 <$> (initTwofish =<< validateKeySize (undefined :: Twofish128) key)
 instance BlockCipher Twofish128 where
    blockSize                 _ = 16
    ecbEncrypt (Twofish128 key) = encrypt key
    ecbDecrypt (Twofish128 key) = decrypt key
 newtype Twofish192 = Twofish192 Twofish
 instance Cipher Twofish192 where
    cipherName    _ = "Twofish192"
    cipherKeySize _ = KeySizeFixed 24
    cipherInit key  = Twofish192 <$> (initTwofish =<< validateKeySize (undefined :: Twofish192) key)
 instance BlockCipher Twofish192 where
    blockSize                 _ = 16
    ecbEncrypt (Twofish192 key) = encrypt key
    ecbDecrypt (Twofish192 key) = decrypt key
 newtype Twofish256 = Twofish256 Twofish
 instance Cipher Twofish256 where
    cipherName    _ = "Twofish256"
    cipherKeySize _ = KeySizeFixed 32
    cipherInit key  = Twofish256 <$> (initTwofish =<< validateKeySize (undefined :: Twofish256) key)
 instance BlockCipher Twofish256 where
    blockSize                 _ = 16
    ecbEncrypt (Twofish256 key) = encrypt key
    ecbDecrypt (Twofish256 key) = decrypt key
--- a/Crypto/Cipher/Twofish/Primitive.hs
+++ b/Crypto/Cipher/Twofish/Primitive.hs
@ -0,0 +1,311 @@
 {-# LANGUAGE MagicHash #-}
 {-# LANGUAGE BangPatterns #-}
 module Crypto.Cipher.Twofish.Primitive
    ( Twofish
    , initTwofish
    , encrypt
    , decrypt
    ) where
 import           Crypto.Error
 import           Crypto.Internal.ByteArray (ByteArray)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Internal.WordArray
 import           Data.Word
 import           Data.Bits
 import           Data.List
 -- Based on the Golang referance implementation
 -- https://github.com/golang/crypto/blob/master/twofish/twofish.go
 -- BlockSize is the constant block size of Twofish.
 blockSize :: Int
 blockSize = 16
 mdsPolynomial, rsPolynomial :: Word32
 mdsPolynomial = 0x169 -- x^8 + x^6 + x^5 + x^3 + 1, see [TWOFISH] 4.2
 rsPolynomial = 0x14d  -- x^8 + x^6 + x^3 + x^2 + 1, see [TWOFISH] 4.3
 data Twofish = Twofish { s :: (Array32, Array32, Array32, Array32)
                       , k :: Array32 }
 data ByteSize = Bytes16 | Bytes24 | Bytes32 deriving (Eq)
 data KeyPackage ba = KeyPackage { rawKeyBytes :: ba
                                , byteSize :: ByteSize }
 buildPackage :: ByteArray ba => ba -> Maybe (KeyPackage ba)
 buildPackage key
    | B.length key == 16 = return $ KeyPackage key Bytes16
    | B.length key == 24 = return $ KeyPackage key Bytes24
    | B.length key == 32 = return $ KeyPackage key Bytes32
    | otherwise = Nothing
 -- | Initialize a 128-bit, 192-bit, or 256-bit key
 --
 -- Return the initialized key or a error message if the given
 -- keyseed was not 16-bytes in length.
 initTwofish :: ByteArray key
            => key -- ^ The key to create the twofish context
            -> CryptoFailable Twofish
 initTwofish key =
    case buildPackage key of Nothing -> CryptoFailed CryptoError_KeySizeInvalid
                             Just keyPackage -> CryptoPassed Twofish { k = generatedK, s = generatedS }
                                  where generatedK = array32 40 $ genK keyPackage
                                        generatedS = genSboxes keyPackage $ sWords key
 mapBlocks :: ByteArray ba => (ba -> ba) -> ba -> ba
 mapBlocks operation input
    | B.null rest = blockOutput
    | otherwise = blockOutput `B.append` mapBlocks operation rest
        where (block, rest) = B.splitAt blockSize input
              blockOutput = operation block
 -- | Encrypts the given ByteString using the given Key
 encrypt :: ByteArray ba
        => Twofish     -- ^ The key to use
        -> ba           -- ^ The data to encrypt
        -> ba
 encrypt cipher = mapBlocks (encryptBlock cipher)
 encryptBlock :: ByteArray ba => Twofish -> ba -> ba
 encryptBlock Twofish { s = (s1, s2, s3, s4), k = ks } message = store32ls ts
    where (a, b, c, d) = load32ls message
          a' = a `xor` arrayRead32 ks 0
          b' = b `xor` arrayRead32 ks 1
          c' = c `xor` arrayRead32 ks 2
          d' = d `xor` arrayRead32 ks 3
          (!a'', !b'', !c'', !d'') = foldl' shuffle (a', b', c', d') [0..7]
          ts = (c'' `xor` arrayRead32 ks 4, d'' `xor` arrayRead32 ks 5, a'' `xor` arrayRead32 ks 6, b'' `xor` arrayRead32 ks 7)
          shuffle :: (Word32, Word32, Word32, Word32) -> Int -> (Word32, Word32, Word32, Word32)
          shuffle (!retA, !retB, !retC, !retD) ind = (retA', retB', retC', retD')
            where [k0, k1, k2, k3] = fmap (\offset -> arrayRead32 ks $ (8 + 4 * ind) + offset) [0..3]
                  t2 = byteIndex s2 retB `xor` byteIndex s3 (shiftR retB 8) `xor` byteIndex s4 (shiftR retB 16) `xor` byteIndex s1 (shiftR retB 24)
                  t1 = (byteIndex s1 retA `xor` byteIndex s2 (shiftR retA 8) `xor` byteIndex s3 (shiftR retA 16) `xor` byteIndex s4 (shiftR retA 24)) + t2
                  retC' = rotateR (retC `xor` (t1 + k0)) 1
                  retD' = rotateL retD 1 `xor` (t1 + t2 + k1)
                  t2' = byteIndex s2 retD' `xor` byteIndex s3 (shiftR retD' 8) `xor` byteIndex s4 (shiftR retD' 16) `xor` byteIndex s1 (shiftR retD' 24)
                  t1' = (byteIndex s1 retC' `xor` byteIndex s2 (shiftR retC' 8) `xor` byteIndex s3 (shiftR retC' 16) `xor` byteIndex s4 (shiftR retC' 24)) + t2'
                  retA' = rotateR (retA `xor` (t1' + k2)) 1
                  retB' = rotateL retB 1 `xor` (t1' + t2' + k3)
 -- Unsafe, no bounds checking
 byteIndex :: Array32 -> Word32 -> Word32
 byteIndex xs ind  = arrayRead32 xs $ fromIntegral byte
    where byte = ind `mod` 256
 -- | Decrypts the given ByteString using the given Key
 decrypt :: ByteArray ba
        => Twofish     -- ^ The key to use
        -> ba           -- ^ The data to decrypt
        -> ba
 decrypt cipher = mapBlocks (decryptBlock cipher)
 {- decryption for 128 bits blocks -}
 decryptBlock :: ByteArray ba => Twofish -> ba -> ba
 decryptBlock Twofish { s = (s1, s2, s3, s4), k = ks } message = store32ls ixs
    where (a, b, c, d) = load32ls message
          a' = c `xor` arrayRead32 ks 6
          b' = d `xor` arrayRead32 ks 7
          c' = a `xor` arrayRead32 ks 4
          d' = b `xor` arrayRead32 ks 5
          (!a'', !b'', !c'', !d'') = foldl' unshuffle (a', b', c', d') [8, 7..1]
          ixs = (a'' `xor` arrayRead32 ks 0, b'' `xor` arrayRead32 ks 1, c'' `xor` arrayRead32 ks 2, d'' `xor` arrayRead32 ks 3)
          unshuffle :: (Word32, Word32, Word32, Word32) -> Int -> (Word32, Word32, Word32, Word32)
          unshuffle (!retA, !retB, !retC, !retD) ind = (retA', retB', retC', retD')
            where [k0, k1, k2, k3] = fmap (\offset -> arrayRead32 ks $ (4 + 4 * ind) + offset) [0..3]
                  t2 = byteIndex s2 retD `xor` byteIndex s3 (shiftR retD 8) `xor` byteIndex s4 (shiftR retD 16) `xor` byteIndex s1 (shiftR retD 24)
                  t1 = (byteIndex s1 retC `xor` byteIndex s2 (shiftR retC 8) `xor` byteIndex s3 (shiftR retC 16) `xor` byteIndex s4 (shiftR retC 24)) + t2
                  retA' = rotateL retA 1 `xor` (t1 + k2)
                  retB' = rotateR (retB `xor` (t2 + t1 + k3)) 1
                  t2' = byteIndex s2 retB' `xor` byteIndex s3 (shiftR retB' 8) `xor` byteIndex s4 (shiftR retB' 16) `xor` byteIndex s1 (shiftR retB' 24)
                  t1' = (byteIndex s1 retA' `xor` byteIndex s2 (shiftR retA' 8) `xor` byteIndex s3 (shiftR retA' 16) `xor` byteIndex s4 (shiftR retA' 24)) + t2'
                  retC' = rotateL retC 1 `xor` (t1' + k0)
                  retD' = rotateR (retD `xor` (t2' + t1' + k1)) 1
 sbox0 :: Int -> Word8
 sbox0 = arrayRead8 t
    where t = array8
            "\xa9\x67\xb3\xe8\x04\xfd\xa3\x76\x9a\x92\x80\x78\xe4\xdd\xd1\x38\
            \\x0d\xc6\x35\x98\x18\xf7\xec\x6c\x43\x75\x37\x26\xfa\x13\x94\x48\
            \\xf2\xd0\x8b\x30\x84\x54\xdf\x23\x19\x5b\x3d\x59\xf3\xae\xa2\x82\
            \\x63\x01\x83\x2e\xd9\x51\x9b\x7c\xa6\xeb\xa5\xbe\x16\x0c\xe3\x61\
            \\xc0\x8c\x3a\xf5\x73\x2c\x25\x0b\xbb\x4e\x89\x6b\x53\x6a\xb4\xf1\
            \\xe1\xe6\xbd\x45\xe2\xf4\xb6\x66\xcc\x95\x03\x56\xd4\x1c\x1e\xd7\
            \\xfb\xc3\x8e\xb5\xe9\xcf\xbf\xba\xea\x77\x39\xaf\x33\xc9\x62\x71\
            \\x81\x79\x09\xad\x24\xcd\xf9\xd8\xe5\xc5\xb9\x4d\x44\x08\x86\xe7\
            \\xa1\x1d\xaa\xed\x06\x70\xb2\xd2\x41\x7b\xa0\x11\x31\xc2\x27\x90\
            \\x20\xf6\x60\xff\x96\x5c\xb1\xab\x9e\x9c\x52\x1b\x5f\x93\x0a\xef\
            \\x91\x85\x49\xee\x2d\x4f\x8f\x3b\x47\x87\x6d\x46\xd6\x3e\x69\x64\
            \\x2a\xce\xcb\x2f\xfc\x97\x05\x7a\xac\x7f\xd5\x1a\x4b\x0e\xa7\x5a\
            \\x28\x14\x3f\x29\x88\x3c\x4c\x02\xb8\xda\xb0\x17\x55\x1f\x8a\x7d\
            \\x57\xc7\x8d\x74\xb7\xc4\x9f\x72\x7e\x15\x22\x12\x58\x07\x99\x34\
            \\x6e\x50\xde\x68\x65\xbc\xdb\xf8\xc8\xa8\x2b\x40\xdc\xfe\x32\xa4\
            \\xca\x10\x21\xf0\xd3\x5d\x0f\x00\x6f\x9d\x36\x42\x4a\x5e\xc1\xe0"#
 sbox1 :: Int -> Word8
 sbox1 = arrayRead8 t
    where t = array8
            "\x75\xf3\xc6\xf4\xdb\x7b\xfb\xc8\x4a\xd3\xe6\x6b\x45\x7d\xe8\x4b\
            \\xd6\x32\xd8\xfd\x37\x71\xf1\xe1\x30\x0f\xf8\x1b\x87\xfa\x06\x3f\
            \\x5e\xba\xae\x5b\x8a\x00\xbc\x9d\x6d\xc1\xb1\x0e\x80\x5d\xd2\xd5\
            \\xa0\x84\x07\x14\xb5\x90\x2c\xa3\xb2\x73\x4c\x54\x92\x74\x36\x51\
            \\x38\xb0\xbd\x5a\xfc\x60\x62\x96\x6c\x42\xf7\x10\x7c\x28\x27\x8c\
            \\x13\x95\x9c\xc7\x24\x46\x3b\x70\xca\xe3\x85\xcb\x11\xd0\x93\xb8\
            \\xa6\x83\x20\xff\x9f\x77\xc3\xcc\x03\x6f\x08\xbf\x40\xe7\x2b\xe2\
            \\x79\x0c\xaa\x82\x41\x3a\xea\xb9\xe4\x9a\xa4\x97\x7e\xda\x7a\x17\
            \\x66\x94\xa1\x1d\x3d\xf0\xde\xb3\x0b\x72\xa7\x1c\xef\xd1\x53\x3e\
            \\x8f\x33\x26\x5f\xec\x76\x2a\x49\x81\x88\xee\x21\xc4\x1a\xeb\xd9\
            \\xc5\x39\x99\xcd\xad\x31\x8b\x01\x18\x23\xdd\x1f\x4e\x2d\xf9\x48\
            \\x4f\xf2\x65\x8e\x78\x5c\x58\x19\x8d\xe5\x98\x57\x67\x7f\x05\x64\
            \\xaf\x63\xb6\xfe\xf5\xb7\x3c\xa5\xce\xe9\x68\x44\xe0\x4d\x43\x69\
            \\x29\x2e\xac\x15\x59\xa8\x0a\x9e\x6e\x47\xdf\x34\x35\x6a\xcf\xdc\
            \\x22\xc9\xc0\x9b\x89\xd4\xed\xab\x12\xa2\x0d\x52\xbb\x02\x2f\xa9\
            \\xd7\x61\x1e\xb4\x50\x04\xf6\xc2\x16\x25\x86\x56\x55\x09\xbe\x91"#
 rs :: [[Word8]]
 rs = [ [0x01, 0xA4, 0x55, 0x87, 0x5A, 0x58, 0xDB, 0x9E]
     , [0xA4, 0x56, 0x82, 0xF3, 0x1E, 0xC6, 0x68, 0xE5]
     , [0x02, 0xA1, 0xFC, 0xC1, 0x47, 0xAE, 0x3D, 0x19]
     , [0xA4, 0x55, 0x87, 0x5A, 0x58, 0xDB, 0x9E, 0x03] ]
 load32ls :: ByteArray ba => ba -> (Word32, Word32, Word32, Word32)
 load32ls message = (intify q1, intify q2, intify q3, intify q4)
    where (half1, half2) = B.splitAt 8 message
          (q1, q2) = B.splitAt 4 half1
          (q3, q4) = B.splitAt 4 half2
          intify :: ByteArray ba => ba -> Word32
          intify bytes = foldl' (\int (!word, !ind) -> int .|. shiftL (fromIntegral word) (ind * 8) ) 0 (zip (B.unpack bytes) [0..])
 store32ls :: ByteArray ba => (Word32, Word32, Word32, Word32) -> ba
 store32ls (a, b, c, d) = B.pack $ concatMap splitWordl [a, b, c, d]
    where splitWordl :: Word32 -> [Word8]
          splitWordl w = fmap (\ind -> fromIntegral $ shiftR w (8 * ind)) [0..3]
 -- Create S words
 sWords :: ByteArray ba => ba -> [Word8]
 sWords key = sWord
    where word64Count = B.length key `div` 2
          sWord = concatMap (\wordIndex ->
                        map (\rsRow ->
                            foldl' (\acc (!rsVal, !colIndex) ->
                                acc `xor` gfMult rsPolynomial (B.index key $ 8 * wordIndex + colIndex) rsVal
                                ) 0 (zip rsRow [0..])
                            ) rs
                    ) [0..word64Count - 1]
 data Column = Zero | One | Two | Three deriving (Show, Eq, Enum, Bounded)
 genSboxes :: KeyPackage ba -> [Word8] -> (Array32, Array32, Array32, Array32)
 genSboxes keyPackage ws = (mkArray b0', mkArray b1', mkArray b2', mkArray b3')
    where range = [0..255]
          mkArray = array32 256
          [w0, w1, w2, w3, w4, w5, w6, w7, w8, w9, w10, w11, w12, w13, w14, w15] = take 16 ws
          (b0', b1', b2', b3') = sboxBySize $ byteSize keyPackage
          sboxBySize :: ByteSize -> ([Word32], [Word32], [Word32], [Word32])
          sboxBySize Bytes16 = (b0, b1, b2, b3)
            where !b0 = fmap mapper range
                    where mapper :: Int -> Word32
                          mapper byte = mdsColumnMult ((sbox1 . fromIntegral) ((sbox0 . fromIntegral $ sbox0 byte `xor` w0) `xor` w4)) Zero
                  !b1 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox0 . fromIntegral) ((sbox0 . fromIntegral $ sbox1 byte `xor` w1) `xor` w5)) One
                  !b2 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox1 . fromIntegral) ((sbox1 . fromIntegral $ sbox0 byte `xor` w2) `xor` w6)) Two
                  !b3 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox0 . fromIntegral) ((sbox1 . fromIntegral $ sbox1 byte `xor` w3) `xor` w7)) Three
          sboxBySize Bytes24 = (b0, b1, b2, b3)
            where !b0 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox1 . fromIntegral) ((sbox0 . fromIntegral) ((sbox0 . fromIntegral $ sbox1 byte `xor` w0) `xor` w4) `xor` w8)) Zero
                  !b1 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox0 . fromIntegral) ((sbox0 . fromIntegral) ((sbox1 . fromIntegral $ sbox1 byte `xor` w1) `xor` w5) `xor` w9)) One
                  !b2 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox1 . fromIntegral) ((sbox1 . fromIntegral) ((sbox0 . fromIntegral $ sbox0 byte `xor` w2) `xor` w6) `xor` w10)) Two
                  !b3 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox0 . fromIntegral) ((sbox1 . fromIntegral) ((sbox1 . fromIntegral $ sbox0 byte `xor` w3) `xor` w7) `xor` w11)) Three
          sboxBySize Bytes32 = (b0, b1, b2, b3)
            where !b0 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox1 . fromIntegral) ((sbox0 . fromIntegral) ((sbox0 . fromIntegral) ((sbox1 . fromIntegral $ sbox1 byte `xor` w0) `xor` w4) `xor` w8) `xor` w12)) Zero
                  !b1 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox0 . fromIntegral) ((sbox0 . fromIntegral) ((sbox1 . fromIntegral) ((sbox1 . fromIntegral $ sbox0 byte `xor` w1) `xor` w5) `xor` w9) `xor` w13)) One
                  !b2 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox1 . fromIntegral) ((sbox1 . fromIntegral) ((sbox0 . fromIntegral) ((sbox0 . fromIntegral $ sbox0 byte `xor` w2) `xor` w6) `xor` w10) `xor` w14)) Two
                  !b3 = fmap mapper range
                    where mapper byte = mdsColumnMult ((sbox0 . fromIntegral) ((sbox1 . fromIntegral) ((sbox1 . fromIntegral) ((sbox0 . fromIntegral $ sbox1 byte `xor` w3) `xor` w7) `xor` w11) `xor` w15)) Three
 genK :: (ByteArray ba) => KeyPackage ba -> [Word32]
 genK keyPackage = concatMap makeTuple [0..19]
    where makeTuple :: Word8 -> [Word32]
          makeTuple idx = [a + b', rotateL (2 * b' + a) 9]
            where tmp1 = replicate 4 $ 2 * idx
                  tmp2 = fmap (+1) tmp1
                  a = h tmp1 keyPackage 0
                  b = h tmp2 keyPackage 1
                  b' = rotateL b 8
 h :: (ByteArray ba) => [Word8] -> KeyPackage ba -> Int -> Word32
 h input keyPackage offset =  foldl' xorMdsColMult 0 $ zip [y0f, y1f, y2f, y3f] $ enumFrom Zero
    where key = rawKeyBytes keyPackage
          [y0, y1, y2, y3] = take 4 input
          (!y0f, !y1f, !y2f, !y3f) = run (y0, y1, y2, y3) $ byteSize keyPackage
          run :: (Word8, Word8, Word8, Word8) -> ByteSize -> (Word8, Word8, Word8, Word8)
          run (!y0'', !y1'', !y2'', !y3'') Bytes32 = run (y0', y1', y2', y3') Bytes24
            where y0' = sbox1 (fromIntegral y0'') `xor` B.index key (4 * (6 + offset) + 0)
                  y1' = sbox0 (fromIntegral y1'') `xor` B.index key (4 * (6 + offset) + 1)
                  y2' = sbox0 (fromIntegral y2'') `xor` B.index key (4 * (6 + offset) + 2)
                  y3' = sbox1 (fromIntegral y3'') `xor` B.index key (4 * (6 + offset) + 3)
          run (!y0'', !y1'', !y2'', !y3'') Bytes24 = run (y0', y1', y2', y3') Bytes16
            where y0' = sbox1 (fromIntegral y0'') `xor` B.index key (4 * (4 + offset) + 0)
                  y1' = sbox1 (fromIntegral y1'') `xor` B.index key (4 * (4 + offset) + 1)
                  y2' = sbox0 (fromIntegral y2'') `xor` B.index key (4 * (4 + offset) + 2)
                  y3' = sbox0 (fromIntegral y3'') `xor` B.index key (4 * (4 + offset) + 3)
          run (!y0'', !y1'', !y2'', !y3'') Bytes16 = (y0', y1', y2', y3')
            where y0' = sbox1 . fromIntegral $ (sbox0 . fromIntegral $ (sbox0 (fromIntegral y0'') `xor` B.index key (4 * (2 + offset) + 0))) `xor` B.index key (4 * (0 + offset) + 0)
                  y1' = sbox0 . fromIntegral $ (sbox0 . fromIntegral $ (sbox1 (fromIntegral y1'') `xor` B.index key (4 * (2 + offset) + 1))) `xor` B.index key (4 * (0 + offset) + 1)
                  y2' = sbox1 . fromIntegral $ (sbox1 . fromIntegral $ (sbox0 (fromIntegral y2'') `xor` B.index key (4 * (2 + offset) + 2))) `xor` B.index key (4 * (0 + offset) + 2)
                  y3' = sbox0 . fromIntegral $ (sbox1 . fromIntegral $ (sbox1 (fromIntegral y3'') `xor` B.index key (4 * (2 + offset) + 3))) `xor` B.index key (4 * (0 + offset) + 3)
          xorMdsColMult :: Word32 -> (Word8, Column) -> Word32
          xorMdsColMult acc wordAndIndex = acc `xor` uncurry mdsColumnMult wordAndIndex
 mdsColumnMult :: Word8 -> Column -> Word32
 mdsColumnMult !byte !col =
    case col of Zero  -> input .|. rotateL mul5B 8 .|. rotateL mulEF 16 .|. rotateL mulEF 24
                One   -> mulEF .|. rotateL mulEF 8 .|. rotateL mul5B 16 .|. rotateL input 24
                Two   -> mul5B .|. rotateL mulEF 8 .|. rotateL input 16 .|. rotateL mulEF 24
                Three -> mul5B .|. rotateL input 8 .|. rotateL mulEF 16 .|. rotateL mul5B 24
        where input = fromIntegral byte
              mul5B = fromIntegral $ gfMult mdsPolynomial byte 0x5B
              mulEF = fromIntegral $ gfMult mdsPolynomial byte 0xEF
 tupInd :: (Bits b) => b -> (a, a) -> a
 tupInd b
    | testBit b 0 = snd
    | otherwise = fst
 gfMult :: Word32 -> Word8 -> Word8 -> Word8
 gfMult p a b = fromIntegral $ run a b' p' result 0
    where b' = (0, fromIntegral b)
          p' = (0, p)
          result = 0
          run :: Word8 -> (Word32, Word32) -> (Word32, Word32) -> Word32 -> Int -> Word32
          run a' b'' p'' result' count =
            if count == 7
            then result''
            else run a'' b''' p'' result'' (count + 1)
                where result'' = result' `xor` tupInd (a' .&. 1) b''
                      a'' = shiftR a' 1
                      b''' = (fst b'', tupInd (shiftR (snd b'') 7) p'' `xor` shiftL (snd b'') 1)
--- a/Crypto/Cipher/Types.hs
+++ b/Crypto/Cipher/Types.hs
@ -5,7 +5,7 @@
 -- Stability   : Stable
 -- Portability : Excellent
 --
-- symmetric cipher basic types
+-- Symmetric cipher basic types
 --
 {-# LANGUAGE DeriveDataTypeable #-}
 module Crypto.Cipher.Types
@ -21,6 +21,8 @@ module Crypto.Cipher.Types
    -- , cfb8Decrypt
    -- * AEAD functions
    , AEADMode(..)
    , CCM_M(..)
    , CCM_L(..)
    , module Crypto.Cipher.Types.AEAD
    -- * Initial Vector type and constructor
    , IV
--- a/Crypto/Cipher/Types/AEAD.hs
+++ b/Crypto/Cipher/Types/AEAD.hs
@ -27,24 +27,24 @@ data AEADModeImpl st = AEADModeImpl
 -- | Authenticated Encryption with Associated Data algorithms
 data AEAD cipher = forall st . AEAD
    { aeadModeImpl :: AEADModeImpl st
-    , aeadState    :: st
+    , aeadState    :: !st
    }
 -- | Append some header information to an AEAD context
 aeadAppendHeader :: ByteArrayAccess aad => AEAD cipher -> aad -> AEAD cipher
-aeadAppendHeader (AEAD impl st) aad = AEAD impl $ (aeadImplAppendHeader impl) st aad
+aeadAppendHeader (AEAD impl st) aad = AEAD impl $ aeadImplAppendHeader impl st aad
 -- | Encrypt some data and update the AEAD context
 aeadEncrypt :: ByteArray ba => AEAD cipher -> ba -> (ba, AEAD cipher)
-aeadEncrypt (AEAD impl st) ba = second (AEAD impl) $ (aeadImplEncrypt impl) st ba
+aeadEncrypt (AEAD impl st) ba = second (AEAD impl) $ aeadImplEncrypt impl st ba
 -- | Decrypt some data and update the AEAD context
 aeadDecrypt :: ByteArray ba => AEAD cipher -> ba -> (ba, AEAD cipher)
-aeadDecrypt (AEAD impl st) ba = second (AEAD impl) $ (aeadImplDecrypt impl) st ba
+aeadDecrypt (AEAD impl st) ba = second (AEAD impl) $ aeadImplDecrypt impl st ba
 -- | Finalize the AEAD context and return the authentication tag
 aeadFinalize :: AEAD cipher -> Int -> AuthTag
-aeadFinalize (AEAD impl st) n = (aeadImplFinalize impl) st n
+aeadFinalize (AEAD impl st) = aeadImplFinalize impl st
 -- | Simple AEAD encryption
 aeadSimpleEncrypt :: (ByteArrayAccess aad, ByteArray ba)
--- a/Crypto/Cipher/Types/Base.hs
+++ b/Crypto/Cipher/Types/Base.hs
@ -5,7 +5,7 @@
 -- Stability   : Stable
 -- Portability : Excellent
 --
-- symmetric cipher basic types
+-- Symmetric cipher basic types
 --
 {-# LANGUAGE ExistentialQuantification #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
@ -14,12 +14,15 @@ module Crypto.Cipher.Types.Base
    , Cipher(..)
    , AuthTag(..)
    , AEADMode(..)
    , CCM_M(..)
    , CCM_L(..)
    , DataUnitOffset
    ) where
 import           Data.Word
 import           Crypto.Internal.ByteArray (Bytes, ByteArrayAccess, ByteArray)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Internal.DeepSeq
 import           Crypto.Error
 -- | Different specifier for key size in bytes
@ -34,15 +37,18 @@ type DataUnitOffset = Word32
 -- | Authentication Tag for AE cipher mode
 newtype AuthTag = AuthTag { unAuthTag :: Bytes }
-    deriving (Show, ByteArrayAccess)
+    deriving (Show, ByteArrayAccess, NFData)
 instance Eq AuthTag where
    (AuthTag a) == (AuthTag b) = B.constEq a b
 data CCM_M = CCM_M4 | CCM_M6 | CCM_M8 | CCM_M10 | CCM_M12 | CCM_M14 | CCM_M16 deriving (Show, Eq)
 data CCM_L = CCM_L2 | CCM_L3 | CCM_L4 deriving (Show, Eq)
 -- | AEAD Mode
 data AEADMode =
      AEAD_OCB -- OCB3
-    | AEAD_CCM
+    | AEAD_CCM Int CCM_M CCM_L
    | AEAD_EAX
    | AEAD_CWC
    | AEAD_GCM
--- a/Crypto/Cipher/Types/Block.hs
+++ b/Crypto/Cipher/Types/Block.hs
@ -5,7 +5,7 @@
 -- Stability   : Stable
 -- Portability : Excellent
 --
-- block cipher basic types
+-- Block cipher basic types
 --
 {-# LANGUAGE MultiParamTypeClasses #-}
 {-# LANGUAGE ExistentialQuantification #-}
@ -16,7 +16,7 @@ module Crypto.Cipher.Types.Block
    -- * BlockCipher
      BlockCipher(..)
    , BlockCipher128(..)
-    -- * initialization vector (IV)
+    -- * Initialization vector (IV)
    , IV(..)
    , makeIV
    , nullIV
@ -37,7 +37,6 @@ module Crypto.Cipher.Types.Block
    ) where
 import           Data.Word
 import           Data.Monoid
 import           Crypto.Error
 import           Crypto.Cipher.Types.Base
 import           Crypto.Cipher.Types.GF
@ -164,27 +163,20 @@ nullIV = toIV undefined
 -- | Increment an IV by a number.
 --
 -- Assume the IV is in Big Endian format.
-ivAdd :: BlockCipher c => IV c -> Int -> IV c
+ivAdd :: IV c -> Int -> IV c
 ivAdd (IV b) i = IV $ copy b
  where copy :: ByteArray bs => bs -> bs
-        copy bs = B.copyAndFreeze bs $ \p -> do
+        copy bs = B.copyAndFreeze bs $ loop i (B.length bs - 1)
            let until0 accu = do
                  r <- loop accu (B.length bs - 1) p
                  case r of
                      0 -> return ()
                      _ -> until0 r
            until0 i
-        loop :: Int -> Int -> Ptr Word8 -> IO Int
+        loop :: Int -> Int -> Ptr Word8 -> IO ()
-        loop 0   _   _ = return 0
+        loop acc ofs p
-        loop acc ofs p = do
+            | ofs < 0   = return ()
            | otherwise = do
                v <- peek (p `plusPtr` ofs) :: IO Word8
                let accv    = acc + fromIntegral v
                    (hi,lo) = accv `divMod` 256
                poke (p `plusPtr` ofs) (fromIntegral lo :: Word8)
-            if ofs == 0
+                loop hi (ofs - 1) p
                then return hi
                else loop hi (ofs - 1) p
 cbcEncryptGeneric :: (ByteArray ba, BlockCipher cipher) => cipher -> IV cipher -> ba -> ba
 cbcEncryptGeneric cipher ivini input = mconcat $ doEnc ivini $ chunk (blockSize cipher) input
--- a/Crypto/Cipher/Types/Stream.hs
+++ b/Crypto/Cipher/Types/Stream.hs
@ -5,7 +5,7 @@
 -- Stability   : Stable
 -- Portability : Excellent
 --
-- stream cipher basic types
+-- Stream cipher basic types
 --
 module Crypto.Cipher.Types.Stream
    ( StreamCipher(..)
--- a/Crypto/Cipher/Types/Utils.hs
+++ b/Crypto/Cipher/Types/Utils.hs
@ -5,7 +5,7 @@
 -- Stability   : Stable
 -- Portability : Excellent
 --
-- basic utility for cipher related stuff
+-- Basic utility for cipher related stuff
 --
 module Crypto.Cipher.Types.Utils where
--- a/Crypto/Cipher/Utils.hs
+++ b/Crypto/Cipher/Utils.hs
@ -0,0 +1,18 @@
 module Crypto.Cipher.Utils
    ( validateKeySize
    ) where
 import Crypto.Error
 import Crypto.Cipher.Types
 import Data.ByteArray as BA
 validateKeySize :: (ByteArrayAccess key, Cipher cipher) => cipher -> key -> CryptoFailable key
 validateKeySize c k = if validKeyLength
                      then CryptoPassed k
                      else CryptoFailed CryptoError_KeySizeInvalid
  where keyLength = BA.length k
        validKeyLength = case cipherKeySize c of
          KeySizeRange low high -> keyLength >= low && keyLength <= high
          KeySizeEnum lengths -> keyLength `elem` lengths
          KeySizeFixed s -> keyLength == s
--- a/Crypto/Cipher/XSalsa.hs
+++ b/Crypto/Cipher/XSalsa.hs
@ -12,18 +12,17 @@
 {-# LANGUAGE ForeignFunctionInterface #-}
 module Crypto.Cipher.XSalsa
    ( initialize
    , derive
    , combine
    , generate
    , State
    ) where
-import           Crypto.Internal.ByteArray (ByteArrayAccess, ByteArray, ScrubbedBytes)
+import           Crypto.Internal.ByteArray (ByteArrayAccess)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Internal.Compat
 import           Crypto.Internal.Imports
 import           Foreign.Ptr
 import           Foreign.Storable
 import           Foreign.C.Types
 import           Crypto.Cipher.Salsa hiding (initialize)
 -- | Initialize a new XSalsa context with the number of rounds,
@ -36,15 +35,41 @@ initialize :: (ByteArrayAccess key, ByteArrayAccess nonce)
 initialize nbRounds key nonce
    | kLen /= 32                      = error "XSalsa: key length should be 256 bits"
    | nonceLen /= 24                  = error "XSalsa: nonce length should be 192 bits"
-    | not (nbRounds `elem` [8,12,20]) = error "XSalsa: rounds should be 8, 12 or 20"
+    | nbRounds `notElem` [8,12,20]    = error "XSalsa: rounds should be 8, 12 or 20"
    | otherwise = unsafeDoIO $ do
        stPtr <- B.alloc 132 $ \stPtr ->
            B.withByteArray nonce $ \noncePtr  ->
            B.withByteArray key   $ \keyPtr ->
-                ccryptonite_xsalsa_init stPtr (fromIntegral nbRounds) kLen keyPtr nonceLen noncePtr
+                ccryptonite_xsalsa_init stPtr nbRounds kLen keyPtr nonceLen noncePtr
        return $ State stPtr
  where kLen     = B.length key
        nonceLen = B.length nonce
 -- | Use an already initialized context and new nonce material to derive another
 -- XSalsa context.
 --
 -- This allows a multi-level cascade where a first key @k1@ and nonce @n1@ is
 -- used to get @HState(k1,n1)@, and this value is then used as key @k2@ to build
 -- @XSalsa(k2,n2)@.  Function 'initialize' is to be called with the first 192
 -- bits of @n1|n2@, and the call to @derive@ should add the remaining 128 bits.
 --
 -- The output context always uses the same number of rounds as the input
 -- context.
 derive :: ByteArrayAccess nonce
       => State  -- ^ base XSalsa state
       -> nonce  -- ^ the remainder nonce (128 bits)
       -> State  -- ^ the new XSalsa state
 derive (State stPtr') nonce
    | nonceLen /= 16 = error "XSalsa: nonce length should be 128 bits"
    | otherwise = unsafeDoIO $ do
        stPtr <- B.copy stPtr' $ \stPtr ->
            B.withByteArray nonce $ \noncePtr  ->
                ccryptonite_xsalsa_derive stPtr nonceLen noncePtr
        return $ State stPtr
  where nonceLen = B.length nonce
 foreign import ccall "cryptonite_xsalsa_init"
    ccryptonite_xsalsa_init :: Ptr State -> Int -> Int -> Ptr Word8 -> Int -> Ptr Word8 -> IO ()
 foreign import ccall "cryptonite_xsalsa_derive"
    ccryptonite_xsalsa_derive :: Ptr State -> Int -> Ptr Word8 -> IO ()
--- a/Crypto/ConstructHash/MiyaguchiPreneel.hs
+++ b/Crypto/ConstructHash/MiyaguchiPreneel.hs
@ -5,7 +5,7 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- provide the hash function construction method from block cipher
+-- Provide the hash function construction method from block cipher
 -- <https://en.wikipedia.org/wiki/One-way_compression_function>
 --
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
@ -44,7 +44,7 @@ compute' g = MP . foldl' (step $ g) (B.replicate bsz 0) . chunks . pad (ZERO bsz
      where
        (hd, tl) = B.splitAt bsz msg
-- | Compute Miyaguchi-Preneel one way compress using the infered block cipher.
+-- | Compute Miyaguchi-Preneel one way compress using the inferred block cipher.
 --   Only safe when KEY-SIZE equals to BLOCK-SIZE.
 --
 --   Simple usage /mp' msg :: MiyaguchiPreneel AES128/
--- a/Crypto/Data/AFIS.hs
+++ b/Crypto/Data/AFIS.hs
@ -5,7 +5,7 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- haskell implementation of the Anti-forensic information splitter
+-- Haskell implementation of the Anti-forensic information splitter
 -- available in LUKS. <http://clemens.endorphin.org/AFsplitter>
 --
 -- The algorithm bloats an arbitrary secret with many bits that are necessary for
@ -77,7 +77,7 @@ split hashAlg rng expandTimes src
            diffuse hashAlg lastBlock blockSize
        fillRandomBlock g blockPtr = do
            let (rand :: Bytes, g') = randomBytesGenerate blockSize g
-            B.withByteArray rand $ \randPtr -> memCopy blockPtr randPtr (fromIntegral blockSize)
+            B.withByteArray rand $ \randPtr -> memCopy blockPtr randPtr blockSize
            return g'
 -- | Merge previously diffused data back to the original data.
--- a/Crypto/Data/Padding.hs
+++ b/Crypto/Data/Padding.hs
@ -6,7 +6,7 @@
 -- Portability : unknown
 --
 -- Various cryptographic padding commonly used for block ciphers
-- or assymetric systems.
+-- or asymmetric systems.
 --
 module Crypto.Data.Padding
    ( Format(..)
--- a/Crypto/ECC.hs
+++ b/Crypto/ECC.hs
@ -7,6 +7,8 @@
 --
 -- Elliptic Curve Cryptography
 --
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE FlexibleContexts #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE TypeFamilies #-}
 {-# LANGUAGE ScopedTypeVariables #-}
@ -16,27 +18,33 @@ module Crypto.ECC
    , Curve_P521R1(..)
    , Curve_X25519(..)
    , Curve_X448(..)
    , Curve_Edwards25519(..)
    , EllipticCurve(..)
    , EllipticCurveDH(..)
    , EllipticCurveArith(..)
    , EllipticCurveBasepointArith(..)
    , KeyPair(..)
    , SharedSecret(..)
    ) where
 import qualified Crypto.PubKey.ECC.P256 as P256
 import qualified Crypto.ECC.Edwards25519 as Edwards25519
 import qualified Crypto.ECC.Simple.Types as Simple
 import qualified Crypto.ECC.Simple.Prim as Simple
 import           Crypto.Random
 import           Crypto.Error
 import           Crypto.Internal.Proxy
 import           Crypto.Internal.Imports
 import           Crypto.Internal.ByteArray (ByteArray, ByteArrayAccess, ScrubbedBytes)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Number.Basic (numBits)
 import           Crypto.Number.Serialize (i2ospOf_, os2ip)
 import qualified Crypto.Number.Serialize.LE as LE
 import qualified Crypto.PubKey.Curve25519 as X25519
 import qualified Crypto.PubKey.Curve448 as X448
 import           Data.Function (on)
 import           Data.ByteArray (convert)
 import           Data.Data (Data())
 import           Data.Kind (Type)
 import           Data.Proxy
 -- | An elliptic curve key pair composed of the private part (a scalar), and
 -- the associated point.
@ -46,14 +54,14 @@ data KeyPair curve = KeyPair
    }
 newtype SharedSecret = SharedSecret ScrubbedBytes
-    deriving (Eq, ByteArrayAccess)
+    deriving (Eq, ByteArrayAccess, NFData)
 class EllipticCurve curve where
    -- | Point on an Elliptic Curve
-    type Point curve  :: *
+    type Point curve  :: Type
    -- | Scalar in the Elliptic Curve domain
-    type Scalar curve :: *
+    type Scalar curve :: Type
    -- | Generate a new random scalar on the curve.
    -- The scalar will represent a number between 1 and the order of the curve non included
@ -78,22 +86,69 @@ class EllipticCurve curve => EllipticCurveDH curve where
    -- is not hashed.
    --
    -- use `pointSmul` to keep the result in Point format.
-    ecdh :: proxy curve -> Scalar curve -> Point curve -> SharedSecret
+    --
    -- /WARNING:/ Curve implementations may return a special value or an
    -- exception when the public point lies in a subgroup of small order.
    -- This function is adequate when the scalar is in expected range and
    -- contributory behaviour is not needed.  Otherwise use 'ecdh'.
    ecdhRaw :: proxy curve -> Scalar curve -> Point curve -> SharedSecret
    ecdhRaw prx s = throwCryptoError . ecdh prx s
-class EllipticCurve curve => EllipticCurveArith curve where
+    -- | Generate a Diffie hellman secret value and verify that the result
    -- is not the point at infinity.
    --
    -- This additional test avoids risks existing with function 'ecdhRaw'.
    -- Implementations always return a 'CryptoError' instead of a special
    -- value or an exception.
    ecdh :: proxy curve -> Scalar curve -> Point curve -> CryptoFailable SharedSecret
 class (EllipticCurve curve, Eq (Point curve)) => EllipticCurveArith curve where
    -- | Add points on a curve
    pointAdd :: proxy curve -> Point curve -> Point curve -> Point curve
    -- | Negate a curve point
    pointNegate :: proxy curve -> Point curve -> Point curve
    -- | Scalar Multiplication on a curve
    pointSmul :: proxy curve -> Scalar curve -> Point curve -> Point curve
 --   -- | Scalar Inverse
 --   scalarInverse :: Scalar curve -> Scalar curve
 class (EllipticCurveArith curve, Eq (Scalar curve)) => EllipticCurveBasepointArith curve where
    -- | Get the curve order size in bits
    curveOrderBits :: proxy curve -> Int
    -- | Multiply a scalar with the curve base point
    pointBaseSmul :: proxy curve -> Scalar curve -> Point curve
    -- | Multiply the point @p@ with @s2@ and add a lifted to curve value @s1@
    pointsSmulVarTime :: proxy curve -> Scalar curve -> Scalar curve -> Point curve -> Point curve
    pointsSmulVarTime prx s1 s2 p = pointAdd prx (pointBaseSmul prx s1) (pointSmul prx s2 p)
    -- | Encode an elliptic curve scalar into big-endian form
    encodeScalar :: ByteArray bs => proxy curve -> Scalar curve -> bs
    -- | Try to decode the big-endian form of an elliptic curve scalar
    decodeScalar :: ByteArray bs => proxy curve -> bs -> CryptoFailable (Scalar curve)
    -- | Convert an elliptic curve scalar to an integer
    scalarToInteger :: proxy curve -> Scalar curve -> Integer
    -- | Try to create an elliptic curve scalar from an integer
    scalarFromInteger :: proxy curve -> Integer -> CryptoFailable (Scalar curve)
    -- | Add two scalars and reduce modulo the curve order
    scalarAdd :: proxy curve -> Scalar curve -> Scalar curve -> Scalar curve
    -- | Multiply two scalars and reduce modulo the curve order
    scalarMul :: proxy curve -> Scalar curve -> Scalar curve -> Scalar curve
 -- | P256 Curve
 --
 -- also known as P256
 data Curve_P256R1 = Curve_P256R1
    deriving (Show,Data)
 instance EllipticCurve Curve_P256R1 where
    type Point Curve_P256R1 = P256.Point
@ -111,20 +166,34 @@ instance EllipticCurve Curve_P256R1 where
            uncompressed = B.singleton 4
            xy = P256.pointToBinary p
    decodePoint _ mxy = case B.uncons mxy of
-        Nothing -> CryptoFailed $ CryptoError_PointSizeInvalid
+        Nothing -> CryptoFailed CryptoError_PointSizeInvalid
        Just (m,xy)
            -- uncompressed
            | m == 4 -> P256.pointFromBinary xy
-            | otherwise -> CryptoFailed $ CryptoError_PointFormatInvalid
+            | otherwise -> CryptoFailed CryptoError_PointFormatInvalid
 instance EllipticCurveArith Curve_P256R1 where
    pointAdd  _ a b = P256.pointAdd a b
    pointNegate _ p = P256.pointNegate p
    pointSmul _ s p = P256.pointMul s p
 instance EllipticCurveDH Curve_P256R1 where
-    ecdh _ s p = SharedSecret $ P256.pointDh s p
+    ecdhRaw _ s p = SharedSecret $ P256.pointDh s p
    ecdh  prx s p = checkNonZeroDH (ecdhRaw prx s p)
 instance EllipticCurveBasepointArith Curve_P256R1 where
    curveOrderBits _ = 256
    pointBaseSmul _ = P256.toPoint
    pointsSmulVarTime _ = P256.pointsMulVarTime
    encodeScalar _ = P256.scalarToBinary
    decodeScalar _ = P256.scalarFromBinary
    scalarToInteger _ = P256.scalarToInteger
    scalarFromInteger _ = P256.scalarFromInteger
    scalarAdd _ = P256.scalarAdd
    scalarMul _ = P256.scalarMul
 data Curve_P384R1 = Curve_P384R1
    deriving (Show,Data)
 instance EllipticCurve Curve_P384R1 where
    type Point Curve_P384R1 = Simple.Point Simple.SEC_p384r1
@ -138,15 +207,27 @@ instance EllipticCurve Curve_P384R1 where
 instance EllipticCurveArith Curve_P384R1 where
    pointAdd _ a b = Simple.pointAdd a b
    pointNegate _ p = Simple.pointNegate p
    pointSmul _ s p = Simple.pointMul s p
 instance EllipticCurveDH Curve_P384R1 where
-    ecdh _ s p = SharedSecret $ i2ospOf_ (curveSizeBytes prx) x
+    ecdh _ s p = encodeECShared prx (Simple.pointMul s p)
      where
-        prx = Proxy :: Proxy Curve_P384R1
+        prx = Proxy :: Proxy Simple.SEC_p384r1
-        Simple.Point x _ = pointSmul prx s p
+
 instance EllipticCurveBasepointArith Curve_P384R1 where
    curveOrderBits _ = 384
    pointBaseSmul _ = Simple.pointBaseMul
    pointsSmulVarTime _ = ecPointsMulVarTime
    encodeScalar _ = ecScalarToBinary
    decodeScalar _ = ecScalarFromBinary
    scalarToInteger _ = ecScalarToInteger
    scalarFromInteger _ = ecScalarFromInteger
    scalarAdd _ = ecScalarAdd
    scalarMul _ = ecScalarMul
 data Curve_P521R1 = Curve_P521R1
    deriving (Show,Data)
 instance EllipticCurve Curve_P521R1 where
    type Point Curve_P521R1 = Simple.Point Simple.SEC_p521r1
@ -160,15 +241,27 @@ instance EllipticCurve Curve_P521R1 where
 instance EllipticCurveArith Curve_P521R1 where
    pointAdd _ a b = Simple.pointAdd a b
    pointNegate _ p = Simple.pointNegate p
    pointSmul _ s p = Simple.pointMul s p
 instance EllipticCurveDH Curve_P521R1 where
-    ecdh _ s p = SharedSecret $ i2ospOf_ (curveSizeBytes prx) x
+    ecdh _ s p = encodeECShared prx (Simple.pointMul s p)
      where
-        prx = Proxy :: Proxy Curve_P521R1
+        prx = Proxy :: Proxy Simple.SEC_p521r1
-        Simple.Point x _ = pointSmul prx s p
+
 instance EllipticCurveBasepointArith Curve_P521R1 where
    curveOrderBits _ = 521
    pointBaseSmul _ = Simple.pointBaseMul
    pointsSmulVarTime _ = ecPointsMulVarTime
    encodeScalar _ = ecScalarToBinary
    decodeScalar _ = ecScalarFromBinary
    scalarToInteger _ = ecScalarToInteger
    scalarFromInteger _ = ecScalarFromInteger
    scalarAdd _ = ecScalarAdd
    scalarMul _ = ecScalarMul
 data Curve_X25519 = Curve_X25519
    deriving (Show,Data)
 instance EllipticCurve Curve_X25519 where
    type Point Curve_X25519 = X25519.PublicKey
@ -182,10 +275,12 @@ instance EllipticCurve Curve_X25519 where
    decodePoint _ bs = X25519.publicKey bs
 instance EllipticCurveDH Curve_X25519 where
-    ecdh _ s p = SharedSecret $ convert secret
+    ecdhRaw _ s p = SharedSecret $ convert secret
      where secret = X25519.dh p s
    ecdh prx s p = checkNonZeroDH (ecdhRaw prx s p)
 data Curve_X448 = Curve_X448
    deriving (Show,Data)
 instance EllipticCurve Curve_X448 where
    type Point Curve_X448 = X448.PublicKey
@ -199,8 +294,52 @@ instance EllipticCurve Curve_X448 where
    decodePoint _ bs = X448.publicKey bs
 instance EllipticCurveDH Curve_X448 where
-    ecdh _ s p = SharedSecret $ convert secret
+    ecdhRaw _ s p = SharedSecret $ convert secret
      where secret = X448.dh p s
    ecdh prx s p = checkNonZeroDH (ecdhRaw prx s p)
 data Curve_Edwards25519 = Curve_Edwards25519
    deriving (Show,Data)
 instance EllipticCurve Curve_Edwards25519 where
    type Point Curve_Edwards25519 = Edwards25519.Point
    type Scalar Curve_Edwards25519 = Edwards25519.Scalar
    curveSizeBits _ = 255
    curveGenerateScalar _ = Edwards25519.scalarGenerate
    curveGenerateKeyPair _ = toKeyPair <$> Edwards25519.scalarGenerate
      where toKeyPair scalar = KeyPair (Edwards25519.toPoint scalar) scalar
    encodePoint _ point = Edwards25519.pointEncode point
    decodePoint _ bs = Edwards25519.pointDecode bs
 instance EllipticCurveArith Curve_Edwards25519 where
    pointAdd _ a b = Edwards25519.pointAdd a b
    pointNegate _ p = Edwards25519.pointNegate p
    pointSmul _ s p = Edwards25519.pointMul s p
 instance EllipticCurveBasepointArith Curve_Edwards25519 where
    curveOrderBits _ = 253
    pointBaseSmul _ = Edwards25519.toPoint
    pointsSmulVarTime _ = Edwards25519.pointsMulVarTime
    encodeScalar _ = B.reverse . Edwards25519.scalarEncode
    decodeScalar _ bs
        | B.length bs == 32 = Edwards25519.scalarDecodeLong (B.reverse bs)
        | otherwise         = CryptoFailed CryptoError_SecretKeySizeInvalid
    scalarToInteger _ s = LE.os2ip (Edwards25519.scalarEncode s :: B.Bytes)
    scalarFromInteger _ i =
        case LE.i2ospOf 32 i of
            Nothing -> CryptoFailed CryptoError_SecretKeySizeInvalid
            Just bs -> Edwards25519.scalarDecodeLong (bs :: B.Bytes)
    scalarAdd _ = Edwards25519.scalarAdd
    scalarMul _ = Edwards25519.scalarMul
 checkNonZeroDH :: SharedSecret -> CryptoFailable SharedSecret
 checkNonZeroDH s@(SharedSecret b)
    | B.constAllZero b = CryptoFailed CryptoError_ScalarMultiplicationInvalid
    | otherwise        = CryptoPassed s
 encodeECShared :: Simple.Curve curve => Proxy curve -> Simple.Point curve -> CryptoFailable SharedSecret
 encodeECShared _   Simple.PointO      = CryptoFailed CryptoError_ScalarMultiplicationInvalid
 encodeECShared prx (Simple.Point x _) = CryptoPassed . SharedSecret $ i2ospOf_ (Simple.curveSizeBytes prx) x
 encodeECPoint :: forall curve bs . (Simple.Curve curve, ByteArray bs) => Simple.Point curve -> bs
 encodeECPoint Simple.PointO      = error "encodeECPoint: cannot serialize point at infinity"
@ -214,7 +353,7 @@ encodeECPoint (Simple.Point x y) = B.concat [uncompressed,xb,yb]
 decodeECPoint :: (Simple.Curve curve, ByteArray bs) => bs -> CryptoFailable (Simple.Point curve)
 decodeECPoint mxy = case B.uncons mxy of
-    Nothing     -> CryptoFailed $ CryptoError_PointSizeInvalid
+    Nothing     -> CryptoFailed CryptoError_PointSizeInvalid
    Just (m,xy)
        -- uncompressed
        | m == 4 ->
@ -223,7 +362,47 @@ decodeECPoint mxy = case B.uncons mxy of
                x = os2ip xb
                y = os2ip yb
             in Simple.pointFromIntegers (x,y)
-        | otherwise -> CryptoFailed $ CryptoError_PointFormatInvalid
+        | otherwise -> CryptoFailed CryptoError_PointFormatInvalid
-curveSizeBytes :: EllipticCurve c => Proxy c -> Int
+ecPointsMulVarTime :: forall curve . Simple.Curve curve
-curveSizeBytes proxy = (curveSizeBits proxy + 7) `div` 8
+                   => Simple.Scalar curve
                   -> Simple.Scalar curve -> Simple.Point curve
                   -> Simple.Point curve
 ecPointsMulVarTime n1 = Simple.pointAddTwoMuls n1 g
  where g = Simple.curveEccG $ Simple.curveParameters (Proxy :: Proxy curve)
 ecScalarFromBinary :: forall curve bs . (Simple.Curve curve, ByteArrayAccess bs)
                   => bs -> CryptoFailable (Simple.Scalar curve)
 ecScalarFromBinary ba
    | B.length ba /= size = CryptoFailed CryptoError_SecretKeySizeInvalid
    | otherwise           = CryptoPassed (Simple.Scalar $ os2ip ba)
  where size = ecCurveOrderBytes (Proxy :: Proxy curve)
 ecScalarToBinary :: forall curve bs . (Simple.Curve curve, ByteArray bs)
                 => Simple.Scalar curve -> bs
 ecScalarToBinary (Simple.Scalar s) = i2ospOf_ size s
  where size = ecCurveOrderBytes (Proxy :: Proxy curve)
 ecScalarFromInteger :: forall curve . Simple.Curve curve
                    => Integer -> CryptoFailable (Simple.Scalar curve)
 ecScalarFromInteger s
    | numBits s > nb = CryptoFailed CryptoError_SecretKeySizeInvalid
    | otherwise      = CryptoPassed (Simple.Scalar s)
  where nb = 8 * ecCurveOrderBytes (Proxy :: Proxy curve)
 ecScalarToInteger :: Simple.Scalar curve -> Integer
 ecScalarToInteger (Simple.Scalar s) = s
 ecCurveOrderBytes :: Simple.Curve c => proxy c -> Int
 ecCurveOrderBytes prx = (numBits n + 7) `div` 8
  where n = Simple.curveEccN $ Simple.curveParameters prx
 ecScalarAdd :: forall curve . Simple.Curve curve
            => Simple.Scalar curve -> Simple.Scalar curve -> Simple.Scalar curve
 ecScalarAdd (Simple.Scalar a) (Simple.Scalar b) = Simple.Scalar ((a + b) `mod` n)
  where n = Simple.curveEccN $ Simple.curveParameters (Proxy :: Proxy curve)
 ecScalarMul :: forall curve . Simple.Curve curve
            => Simple.Scalar curve -> Simple.Scalar curve -> Simple.Scalar curve
 ecScalarMul (Simple.Scalar a) (Simple.Scalar b) = Simple.Scalar ((a * b) `mod` n)
  where n = Simple.curveEccN $ Simple.curveParameters (Proxy :: Proxy curve)
--- a/Crypto/ECC/Edwards25519.hs
+++ b/Crypto/ECC/Edwards25519.hs
@ -0,0 +1,370 @@
 -- |
 -- Module      : Crypto.ECC.Edwards25519
 -- License     : BSD-style
 -- Maintainer  : Olivier Chéron <olivier.cheron@gmail.com>
 -- Stability   : experimental
 -- Portability : unknown
 --
 -- Arithmetic primitives over curve edwards25519.
 --
 -- Twisted Edwards curves are a familly of elliptic curves allowing
 -- complete addition formulas without any special case and no point at
 -- infinity.  Curve edwards25519 is based on prime 2^255 - 19 for
 -- efficient implementation.  Equation and parameters are given in
 -- <https://tools.ietf.org/html/rfc7748 RFC 7748>.
 --
 -- This module provides types and primitive operations that are useful
 -- to implement cryptographic schemes based on curve edwards25519:
 --
 -- - arithmetic functions for point addition, doubling, negation,
 -- scalar multiplication with an arbitrary point, with the base point,
 -- etc.
 --
 -- - arithmetic functions dealing with scalars modulo the prime order
 -- L of the base point
 --
 -- All functions run in constant time unless noted otherwise.
 --
 -- Warnings:
 --
 -- 1. Curve edwards25519 has a cofactor h = 8 so the base point does
 -- not generate the entire curve and points with order 2, 4, 8 exist.
 -- When implementing cryptographic algorithms, special care must be
 -- taken using one of the following methods:
 --
 --     - points must be checked for membership in the prime-order
 --     subgroup
 --
 --     - or cofactor must be cleared by multiplying points by 8
 --
 --     Utility functions are provided to implement this.  Testing
 --     subgroup membership with 'pointHasPrimeOrder' is 50-time slower
 --     than call 'pointMulByCofactor'.
 --
 -- 2. Scalar arithmetic is always reduced modulo L, allowing fixed
 -- length and constant execution time, but this reduction is valid
 -- only when points are in the prime-order subgroup.
 --
 -- 3. Because of modular reduction in this implementation it is not
 -- possible to multiply points directly by scalars like 8.s or L.
 -- This has to be decomposed into several steps.
 --
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 module Crypto.ECC.Edwards25519
    ( Scalar
    , Point
    -- * Scalars
    , scalarGenerate
    , scalarDecodeLong
    , scalarEncode
    -- * Points
    , pointDecode
    , pointEncode
    , pointHasPrimeOrder
    -- * Arithmetic functions
    , toPoint
    , scalarAdd
    , scalarMul
    , pointNegate
    , pointAdd
    , pointDouble
    , pointMul
    , pointMulByCofactor
    , pointsMulVarTime
    ) where
 import           Data.Word
 import           Foreign.C.Types
 import           Foreign.Ptr
 import           Crypto.Error
 import           Crypto.Internal.ByteArray (Bytes, ScrubbedBytes, withByteArray)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Internal.Compat
 import           Crypto.Internal.Imports
 import           Crypto.Random
 scalarArraySize :: Int
 scalarArraySize = 40 -- maximum [9 * 4 {- 32 bits -}, 5 * 8 {- 64 bits -}]
 -- | A scalar modulo prime order of curve edwards25519.
 newtype Scalar = Scalar ScrubbedBytes
    deriving (Show,NFData)
 instance Eq Scalar where
    (Scalar s1) == (Scalar s2) = unsafeDoIO $
        withByteArray s1 $ \ps1 ->
        withByteArray s2 $ \ps2 ->
            fmap (/= 0) (ed25519_scalar_eq ps1 ps2)
    {-# NOINLINE (==) #-}
 pointArraySize :: Int
 pointArraySize = 160 -- maximum [4 * 10 * 4 {- 32 bits -}, 4 * 5 * 8 {- 64 bits -}]
 -- | A point on curve edwards25519.
 newtype Point = Point Bytes
    deriving NFData
 instance Show Point where
    showsPrec d p =
        let bs = pointEncode p :: Bytes
         in showParen (d > 10) $ showString "Point "
                               . shows (B.convertToBase B.Base16 bs :: Bytes)
 instance Eq Point where
    (Point p1) == (Point p2) = unsafeDoIO $
        withByteArray p1 $ \pp1 ->
        withByteArray p2 $ \pp2 ->
            fmap (/= 0) (ed25519_point_eq pp1 pp2)
    {-# NOINLINE (==) #-}
 -- | Generate a random scalar.
 scalarGenerate :: MonadRandom randomly => randomly Scalar
 scalarGenerate = throwCryptoError . scalarDecodeLong <$> generate
  where
    -- Scalar generation is based on a fixed number of bytes so that
    -- there is no timing leak.  But because of modular reduction
    -- distribution is not uniform.  We use many more bytes than
    -- necessary so the probability bias is small.  With 512 bits we
    -- get 22% of scalars with a higher frequency, but the relative
    -- probability difference is only 2^(-260).
    generate :: MonadRandom randomly => randomly ScrubbedBytes
    generate = getRandomBytes 64
 -- | Serialize a scalar to binary, i.e. a 32-byte little-endian
 -- number.
 scalarEncode :: B.ByteArray bs => Scalar -> bs
 scalarEncode (Scalar s) =
    B.allocAndFreeze 32 $ \out ->
        withByteArray s $ \ps -> ed25519_scalar_encode out ps
 -- | Deserialize a little-endian number as a scalar.  Input array can
 -- have any length from 0 to 64 bytes.
 --
 -- Note: it is not advised to put secret information in the 3 lowest
 -- bits of a scalar if this scalar may be multiplied to untrusted
 -- points outside the prime-order subgroup.
 scalarDecodeLong :: B.ByteArrayAccess bs => bs -> CryptoFailable Scalar
 scalarDecodeLong bs
    | B.length bs > 64 = CryptoFailed CryptoError_EcScalarOutOfBounds
    | otherwise        = unsafeDoIO $ withByteArray bs initialize
  where
    len = fromIntegral $ B.length bs
    initialize inp = do
        s <- B.alloc scalarArraySize $ \ps ->
                 ed25519_scalar_decode_long ps inp len
        return $ CryptoPassed (Scalar s)
 {-# NOINLINE scalarDecodeLong #-}
 -- | Add two scalars.
 scalarAdd :: Scalar -> Scalar -> Scalar
 scalarAdd (Scalar a) (Scalar b) =
    Scalar $ B.allocAndFreeze scalarArraySize $ \out ->
        withByteArray a $ \pa ->
        withByteArray b $ \pb ->
             ed25519_scalar_add out pa pb
 -- | Multiply two scalars.
 scalarMul :: Scalar -> Scalar -> Scalar
 scalarMul (Scalar a) (Scalar b) =
    Scalar $ B.allocAndFreeze scalarArraySize $ \out ->
        withByteArray a $ \pa ->
        withByteArray b $ \pb ->
             ed25519_scalar_mul out pa pb
 -- | Multiplies a scalar with the curve base point.
 toPoint :: Scalar -> Point
 toPoint (Scalar scalar) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray scalar $ \pscalar ->
            ed25519_point_base_scalarmul out pscalar
 -- | Serialize a point to a 32-byte array.
 --
 -- Format is binary compatible with 'Crypto.PubKey.Ed25519.PublicKey'
 -- from module "Crypto.PubKey.Ed25519".
 pointEncode :: B.ByteArray bs => Point -> bs
 pointEncode (Point p) =
    B.allocAndFreeze 32 $ \out ->
        withByteArray p $ \pp ->
             ed25519_point_encode out pp
 -- | Deserialize a 32-byte array as a point, ensuring the point is
 -- valid on edwards25519.
 --
 -- /WARNING:/ variable time
 pointDecode :: B.ByteArrayAccess bs => bs -> CryptoFailable Point
 pointDecode bs
    | B.length bs == 32 = unsafeDoIO $ withByteArray bs initialize
    | otherwise         = CryptoFailed CryptoError_PointSizeInvalid
  where
    initialize inp = do
        (res, p) <- B.allocRet pointArraySize $ \pp ->
                        ed25519_point_decode_vartime pp inp
        if res == 0 then return $ CryptoFailed CryptoError_PointCoordinatesInvalid
                    else return $ CryptoPassed (Point p)
 {-# NOINLINE pointDecode #-}
 -- | Test whether a point belongs to the prime-order subgroup
 -- generated by the base point.  Result is 'True' for the identity
 -- point.
 --
 -- @
 -- pointHasPrimeOrder p = 'pointNegate' p == 'pointMul' l_minus_one p
 -- @
 pointHasPrimeOrder :: Point -> Bool
 pointHasPrimeOrder (Point p) = unsafeDoIO $
    withByteArray p $ \pp ->
        fmap (/= 0) (ed25519_point_has_prime_order pp)
 {-# NOINLINE pointHasPrimeOrder #-}
 -- | Negate a point.
 pointNegate :: Point -> Point
 pointNegate (Point a) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray a $ \pa ->
             ed25519_point_negate out pa
 -- | Add two points.
 pointAdd :: Point -> Point -> Point
 pointAdd (Point a) (Point b) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray a $ \pa ->
        withByteArray b $ \pb ->
             ed25519_point_add out pa pb
 -- | Add a point to itself.
 --
 -- @
 -- pointDouble p = 'pointAdd' p p
 -- @
 pointDouble :: Point -> Point
 pointDouble (Point a) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray a $ \pa ->
             ed25519_point_double out pa
 -- | Multiply a point by h = 8.
 --
 -- @
 -- pointMulByCofactor p = 'pointMul' scalar_8 p
 -- @
 pointMulByCofactor :: Point -> Point
 pointMulByCofactor (Point a) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray a $ \pa ->
             ed25519_point_mul_by_cofactor out pa
 -- | Scalar multiplication over curve edwards25519.
 --
 -- Note: when the scalar had reduction modulo L and the input point
 -- has a torsion component, the output point may not be in the
 -- expected subgroup.
 pointMul :: Scalar -> Point -> Point
 pointMul (Scalar scalar) (Point base) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray scalar $ \pscalar ->
        withByteArray base   $ \pbase   ->
             ed25519_point_scalarmul out pbase pscalar
 -- | Multiply the point @p@ with @s2@ and add a lifted to curve value @s1@.
 --
 -- @
 -- pointsMulVarTime s1 s2 p = 'pointAdd' ('toPoint' s1) ('pointMul' s2 p)
 -- @
 --
 -- /WARNING:/ variable time
 pointsMulVarTime :: Scalar -> Scalar -> Point -> Point
 pointsMulVarTime (Scalar s1) (Scalar s2) (Point p) =
    Point $ B.allocAndFreeze pointArraySize $ \out ->
        withByteArray s1 $ \ps1 ->
        withByteArray s2 $ \ps2 ->
        withByteArray p  $ \pp  ->
             ed25519_base_double_scalarmul_vartime out ps1 pp ps2
 foreign import ccall unsafe "cryptonite_ed25519_scalar_eq"
    ed25519_scalar_eq :: Ptr Scalar
                      -> Ptr Scalar
                      -> IO CInt
 foreign import ccall unsafe "cryptonite_ed25519_scalar_encode"
    ed25519_scalar_encode :: Ptr Word8
                          -> Ptr Scalar
                          -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_scalar_decode_long"
    ed25519_scalar_decode_long :: Ptr Scalar
                               -> Ptr Word8
                               -> CSize
                               -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_scalar_add"
    ed25519_scalar_add :: Ptr Scalar -- sum
                       -> Ptr Scalar -- a
                       -> Ptr Scalar -- b
                       -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_scalar_mul"
    ed25519_scalar_mul :: Ptr Scalar -- out
                       -> Ptr Scalar -- a
                       -> Ptr Scalar -- b
                       -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_point_encode"
    ed25519_point_encode :: Ptr Word8
                         -> Ptr Point
                         -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_point_decode_vartime"
    ed25519_point_decode_vartime :: Ptr Point
                                 -> Ptr Word8
                                 -> IO CInt
 foreign import ccall unsafe "cryptonite_ed25519_point_eq"
    ed25519_point_eq :: Ptr Point
                     -> Ptr Point
                     -> IO CInt
 foreign import ccall "cryptonite_ed25519_point_has_prime_order"
    ed25519_point_has_prime_order :: Ptr Point
                                  -> IO CInt
 foreign import ccall unsafe "cryptonite_ed25519_point_negate"
    ed25519_point_negate :: Ptr Point -- minus_a
                         -> Ptr Point -- a
                         -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_point_add"
    ed25519_point_add :: Ptr Point -- sum
                      -> Ptr Point -- a
                      -> Ptr Point -- b
                      -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_point_double"
    ed25519_point_double :: Ptr Point -- two_a
                         -> Ptr Point -- a
                         -> IO ()
 foreign import ccall unsafe "cryptonite_ed25519_point_mul_by_cofactor"
    ed25519_point_mul_by_cofactor :: Ptr Point -- eight_a
                                  -> Ptr Point -- a
                                  -> IO ()
 foreign import ccall "cryptonite_ed25519_point_base_scalarmul"
    ed25519_point_base_scalarmul :: Ptr Point  -- scaled
                                 -> Ptr Scalar -- scalar
                                 -> IO ()
 foreign import ccall "cryptonite_ed25519_point_scalarmul"
    ed25519_point_scalarmul :: Ptr Point  -- scaled
                            -> Ptr Point  -- base
                            -> Ptr Scalar -- scalar
                            -> IO ()
 foreign import ccall "cryptonite_ed25519_base_double_scalarmul_vartime"
    ed25519_base_double_scalarmul_vartime :: Ptr Point  -- combo
                                          -> Ptr Scalar -- scalar1
                                          -> Ptr Point  -- base2
                                          -> Ptr Scalar -- scalar2
                                          -> IO ()
--- a/Crypto/ECC/Simple/Prim.hs
+++ b/Crypto/ECC/Simple/Prim.hs
@ -6,6 +6,7 @@ module Crypto.ECC.Simple.Prim
    ( scalarGenerate
    , scalarFromInteger
    , pointAdd
    , pointNegate
    , pointDouble
    , pointBaseMul
    , pointMul
@ -16,8 +17,7 @@ module Crypto.ECC.Simple.Prim
    ) where
 import Data.Maybe
-import Crypto.Internal.Imports
+import Data.Proxy
 import Crypto.Internal.Proxy
 import Crypto.Number.ModArithmetic
 import Crypto.Number.F2m
 import Crypto.Number.Generate (generateBetween)
@ -49,7 +49,7 @@ pointNegate :: Curve curve => Point curve -> Point curve
 pointNegate        PointO     = PointO
 pointNegate point@(Point x y) =
    case curveType point of
-        CurvePrime {}  -> Point x (-y)
+        CurvePrime (CurvePrimeParam p) -> Point x (p - y)
        CurveBinary {} -> Point x (x `addF2m` y)
 -- | Elliptic Curve point addition.
--- a/Crypto/ECC/Simple/Types.hs
+++ b/Crypto/ECC/Simple/Types.hs
@ -1,4 +1,5 @@
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 -- |
 -- Module      : Crypto.ECC.Simple.Types
 -- License     : BSD-style
@ -6,7 +7,7 @@
 -- Stability   : Experimental
 -- Portability : Excellent
 --
-- references:
+-- References:
 --   <https://tools.ietf.org/html/rfc5915>
 --
 {-# OPTIONS_GHC -fno-warn-missing-signatures #-}
@ -20,7 +21,7 @@ module Crypto.ECC.Simple.Types
    , curveSizeBits
    , curveSizeBytes
    , CurveParameters(..)
-    -- * specific curves definition
+    -- * Specific curves definition
    , SEC_p112r1(..)
    , SEC_p112r2(..)
    , SEC_p128r1(..)
@ -83,28 +84,28 @@ data CurveParameters curve = CurveParameters
    , curveEccG :: Point curve -- ^ base point
    , curveEccN :: Integer     -- ^ order of G
    , curveEccH :: Integer     -- ^ cofactor
-    } deriving (Show,Eq,Data,Typeable)
+    } deriving (Show,Eq,Data)
 newtype CurveBinaryParam = CurveBinaryParam Integer
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 newtype CurvePrimeParam = CurvePrimeParam Integer
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 data CurveType =
      CurveBinary CurveBinaryParam
    | CurvePrime CurvePrimeParam
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 -- | ECC Private Number
 newtype Scalar curve = Scalar Integer
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data,NFData)
 -- | Define a point on a curve.
 data Point curve =
      Point Integer Integer
    | PointO -- ^ Point at Infinity
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 instance NFData (Point curve) where
    rnf (Point x y) = x `seq` y `seq` ()
--- a/Crypto/Error/Types.hs
+++ b/Crypto/Error/Types.hs
@ -8,6 +8,7 @@
 -- Cryptographic Error enumeration and handling
 --
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE TypeFamilies       #-}
 module Crypto.Error.Types
    ( CryptoError(..)
    , CryptoFailable(..)
@ -21,13 +22,14 @@ module Crypto.Error.Types
 import qualified Control.Exception as E
 import           Data.Data
-import           Crypto.Internal.Imports
+import           Basement.Monad (MonadFailure(..))
 -- | Enumeration of all possible errors that can be found in this library
 data CryptoError =
    -- symmetric cipher errors
      CryptoError_KeySizeInvalid
    | CryptoError_IvSizeInvalid
    | CryptoError_SeedSizeInvalid
    | CryptoError_AEADModeNotSupported
    -- public key cryptography error
    | CryptoError_SecretKeySizeInvalid
@ -40,12 +42,17 @@ data CryptoError =
    | CryptoError_PointFormatInvalid
    | CryptoError_PointFormatUnsupported
    | CryptoError_PointCoordinatesInvalid
    | CryptoError_ScalarMultiplicationInvalid
    -- Message authentification error
    | CryptoError_MacKeyInvalid
    | CryptoError_AuthenticationTagSizeInvalid
    -- Prime generation error
    | CryptoError_PrimeSizeInvalid
-    deriving (Show,Eq,Enum,Data,Typeable)
+    -- Parameter errors
    | CryptoError_SaltTooSmall
    | CryptoError_OutputLengthTooSmall
    | CryptoError_OutputLengthTooBig
    deriving (Show,Eq,Enum,Data)
 instance E.Exception CryptoError
@ -75,12 +82,16 @@ instance Applicative CryptoFailable where
    pure a     = CryptoPassed a
    (<*>) fm m = fm >>= \p -> m >>= \r2 -> return (p r2)
 instance Monad CryptoFailable where
-    return a = CryptoPassed a
+    return = pure
    (>>=) m1 m2 = do
        case m1 of
            CryptoPassed a -> m2 a
            CryptoFailed e -> CryptoFailed e
 instance MonadFailure CryptoFailable where
    type Failure CryptoFailable = CryptoError
    mFail = CryptoFailed
 -- | Throw an CryptoError as exception on CryptoFailed result,
 -- otherwise return the computed value
 throwCryptoErrorIO :: CryptoFailable a -> IO a
--- a/Crypto/Hash.hs
+++ b/Crypto/Hash.hs
@ -16,6 +16,8 @@
 -- > hexSha3_512 :: ByteString -> String
 -- > hexSha3_512 bs = show (hash bs :: Digest SHA3_512)
 --
 {-# LANGUAGE ScopedTypeVariables #-}
 {-# LANGUAGE BangPatterns        #-}
 module Crypto.Hash
    (
    -- * Types
@ -23,77 +25,110 @@ module Crypto.Hash
    , Digest
    -- * Functions
    , digestFromByteString
-    -- * hash methods parametrized by algorithm
+    -- * Hash methods parametrized by algorithm
    , hashInitWith
    , hashWith
-    -- * hash methods
+    , hashPrefixWith
    -- * Hash methods
    , hashInit
    , hashUpdates
    , hashUpdate
    , hashFinalize
    , hashFinalizePrefix
    , hashBlockSize
    , hashDigestSize
    , hash
    , hashPrefix
    , hashlazy
    , hashPutContext
    , hashGetContext
    -- * Hash algorithms
    , module Crypto.Hash.Algorithms
    ) where
-import           Control.Monad
+import           Basement.Types.OffsetSize (CountOf (..))
 import           Basement.Block (Block, unsafeFreeze)
 import           Basement.Block.Mutable (copyFromPtr, new)
 import           Crypto.Internal.Compat (unsafeDoIO)
 import           Crypto.Hash.Types
 import           Crypto.Hash.Algorithms
-import           Foreign.Ptr (Ptr)
+import           Foreign.Ptr (Ptr, plusPtr)
-import           Crypto.Internal.ByteArray (ByteArrayAccess)
+import           Crypto.Internal.ByteArray (ByteArrayAccess, ByteArray)
 import qualified Crypto.Internal.ByteArray as B
 import qualified Data.ByteString.Lazy as L
 import           Data.Word (Word8)
 import           Data.Int (Int32)
 -- | Hash a strict bytestring into a digest.
 hash :: (ByteArrayAccess ba, HashAlgorithm a) => ba -> Digest a
 hash bs = hashFinalize $ hashUpdate hashInit bs
 -- | Hash the first N bytes of a bytestring, with code path independent from N.
 hashPrefix :: (ByteArrayAccess ba, HashAlgorithmPrefix a) => ba -> Int -> Digest a
 hashPrefix = hashFinalizePrefix hashInit
 -- | Hash a lazy bytestring into a digest.
 hashlazy :: HashAlgorithm a => L.ByteString -> Digest a
 hashlazy lbs = hashFinalize $ hashUpdates hashInit (L.toChunks lbs)
 -- | Initialize a new context for this hash algorithm
-hashInit :: HashAlgorithm a
+hashInit :: forall a . HashAlgorithm a => Context a
-         => Context a
+hashInit = Context $ B.allocAndFreeze (hashInternalContextSize (undefined :: a)) $ \(ptr :: Ptr (Context a)) ->
-hashInit = doInit undefined B.allocAndFreeze
+    hashInternalInit ptr
  where
        doInit :: HashAlgorithm a => a -> (Int -> (Ptr (Context a) -> IO ()) -> B.Bytes) -> Context a
        doInit alg alloc = Context $ alloc (hashInternalContextSize alg) hashInternalInit
 {-# NOINLINE hashInit #-}
 -- | run hashUpdates on one single bytestring and return the updated context.
 hashUpdate :: (ByteArrayAccess ba, HashAlgorithm a) => Context a -> ba -> Context a
-hashUpdate ctx b = hashUpdates ctx [b]
+hashUpdate ctx b
    | B.null b  = ctx
    | otherwise = hashUpdates ctx [b]
 -- | Update the context with a list of strict bytestring,
 -- and return a new context with the updates.
-hashUpdates :: (HashAlgorithm a, ByteArrayAccess ba)
+hashUpdates :: forall a ba . (HashAlgorithm a, ByteArrayAccess ba)
            => Context a
            -> [ba]
            -> Context a
-hashUpdates c l = doUpdates (B.copyAndFreeze c)
+hashUpdates c l
-  where doUpdates :: HashAlgorithm a => ((Ptr (Context a) -> IO ()) -> B.Bytes) -> Context a
+    | null ls   = c
-        doUpdates copy = Context $ copy $ \ctx ->
+    | otherwise = Context $ B.copyAndFreeze c $ \(ctx :: Ptr (Context a)) ->
-            mapM_ (\b -> B.withByteArray b $ \d -> hashInternalUpdate ctx d (fromIntegral $ B.length b)) l
+        mapM_ (\b -> B.withByteArray b (processBlocks ctx (B.length b))) ls
-{-# NOINLINE hashUpdates #-}
+  where
    ls = filter (not . B.null) l
    -- process the data in 2GB chunks to fit in uint32_t and Int on 32 bit systems
    processBlocks ctx bytesLeft dataPtr
        | bytesLeft == 0 = return ()
        | otherwise = do
            hashInternalUpdate ctx dataPtr (fromIntegral actuallyProcessed)
            processBlocks ctx (bytesLeft - actuallyProcessed) (dataPtr `plusPtr` actuallyProcessed)
        where
            actuallyProcessed = min bytesLeft (fromIntegral (maxBound :: Int32))
 -- | Finalize a context and return a digest.
-hashFinalize :: HashAlgorithm a
+hashFinalize :: forall a . HashAlgorithm a
             => Context a
             -> Digest a
-hashFinalize c = doFinalize undefined (B.copy c) (B.allocAndFreeze)
+hashFinalize !c =
-  where doFinalize :: HashAlgorithm alg
+    Digest $ B.allocAndFreeze (hashDigestSize (undefined :: a)) $ \(dig :: Ptr (Digest a)) -> do
-                   => alg
+        ((!_) :: B.Bytes) <- B.copy c $ \(ctx :: Ptr (Context a)) -> hashInternalFinalize ctx dig
-                   -> ((Ptr (Context alg) -> IO ()) -> IO B.Bytes)
+        return ()
-                   -> (Int -> (Ptr (Digest alg)  -> IO ()) -> B.Bytes)
+
-                   -> Digest alg
+-- | Update the context with the first N bytes of a bytestring and return the
-        doFinalize alg copy allocDigest =
+-- digest.  The code path is independent from N but much slower than a normal
-            Digest $ allocDigest (hashDigestSize alg) $ \dig ->
+-- 'hashUpdate'.  The function can be called for the last bytes of a message, in
-                (void $ copy $ \ctx -> hashInternalFinalize ctx dig)
+-- order to exclude a variable padding, without leaking the padding length.  The
-{-# NOINLINE hashFinalize #-}
+-- begining of the message, never impacted by the padding, should preferably go
 -- through 'hashUpdate' for better performance.
 hashFinalizePrefix :: forall a ba . (HashAlgorithmPrefix a, ByteArrayAccess ba)
                   => Context a
                   -> ba
                   -> Int
                   -> Digest a
 hashFinalizePrefix !c b len =
    Digest $ B.allocAndFreeze (hashDigestSize (undefined :: a)) $ \(dig :: Ptr (Digest a)) -> do
        ((!_) :: B.Bytes) <- B.copy c $ \(ctx :: Ptr (Context a)) ->
            B.withByteArray b $ \d ->
                hashInternalFinalizePrefix ctx d (fromIntegral $ B.length b) (fromIntegral len) dig
        return ()
 -- | Initialize a new context for a specified hash algorithm
 hashInitWith :: HashAlgorithm alg => alg -> Context alg
@ -103,14 +138,39 @@ hashInitWith _ = hashInit
 hashWith :: (ByteArrayAccess ba, HashAlgorithm alg) => alg -> ba -> Digest alg
 hashWith _ = hash
 -- | Run the 'hashPrefix' function but takes an explicit hash algorithm parameter
 hashPrefixWith :: (ByteArrayAccess ba, HashAlgorithmPrefix alg) => alg -> ba -> Int -> Digest alg
 hashPrefixWith _ = hashPrefix
 -- | Try to transform a bytearray into a Digest of specific algorithm.
 --
 -- If the digest is not the right size for the algorithm specified, then
 -- Nothing is returned.
-digestFromByteString :: (HashAlgorithm a, ByteArrayAccess ba) => ba -> Maybe (Digest a)
+digestFromByteString :: forall a ba . (HashAlgorithm a, ByteArrayAccess ba) => ba -> Maybe (Digest a)
 digestFromByteString = from undefined
  where
-        from :: (HashAlgorithm a, ByteArrayAccess ba) => a -> ba -> Maybe (Digest a)
+        from :: a -> ba -> Maybe (Digest a)
        from alg bs
-            | B.length bs == (hashDigestSize alg) = (Just $ Digest $ B.convert bs)
+            | B.length bs == (hashDigestSize alg) = Just $ Digest $ unsafeDoIO $ copyBytes bs
            | otherwise                           = Nothing
        copyBytes :: ba -> IO (Block Word8)
        copyBytes ba = do
            muArray <- new count
            B.withByteArray ba $ \ptr -> copyFromPtr ptr muArray 0 count
            unsafeFreeze muArray
          where
            count = CountOf (B.length ba)
 hashPutContext :: forall a ba. (HashAlgorithmResumable a, ByteArray ba) => Context a -> ba
 hashPutContext !c = B.allocAndFreeze (hashInternalContextSize (undefined :: a)) $ \(ptr :: Ptr Word8) ->
  B.withByteArray c $ \(ctx :: Ptr (Context a)) -> hashInternalPutContextBE ctx ptr
 hashGetContext :: forall a ba. (HashAlgorithmResumable a, ByteArrayAccess ba) => ba -> Maybe (Context a)
 hashGetContext = from undefined
  where
        from :: a -> ba -> Maybe (Context a)
        from alg bs
          | B.length bs == (hashInternalContextSize alg) = Just $ Context $ B.allocAndFreeze (B.length bs) $ \(ctx :: Ptr (Context a)) ->
              B.withByteArray bs $ \ptr -> hashInternalGetContextBE ptr ctx
          | otherwise                                    = Nothing
--- a/Crypto/Hash/Algorithms.hs
+++ b/Crypto/Hash/Algorithms.hs
@ -1,4 +1,3 @@
 {-# LANGUAGE CPP #-}
 -- |
 -- Module      : Crypto.Hash.Algorithms
 -- License     : BSD-style
@ -10,11 +9,18 @@
 --
 module Crypto.Hash.Algorithms
    ( HashAlgorithm
-    -- * hash algorithms
+    , HashAlgorithmPrefix
    , HashAlgorithmResumable
    -- * Hash algorithms
    , Blake2s_160(..)
    , Blake2s_224(..)
    , Blake2sp_224(..)
    , Blake2s_256(..)
    , Blake2sp_224(..)
    , Blake2sp_256(..)
    , Blake2b_160(..)
    , Blake2b_224(..)
    , Blake2b_256(..)
    , Blake2b_384(..)
    , Blake2b_512(..)
    , Blake2bp_512(..)
    , MD2(..)
@ -37,6 +43,10 @@ module Crypto.Hash.Algorithms
    , SHA3_256(..)
    , SHA3_384(..)
    , SHA3_512(..)
    , SHAKE128(..)
    , SHAKE256(..)
    , Blake2b(..), Blake2bp(..)
    , Blake2s(..), Blake2sp(..)
    , Skein256_224(..)
    , Skein256_256(..)
    , Skein512_224(..)
@ -46,7 +56,7 @@ module Crypto.Hash.Algorithms
    , Whirlpool(..)
    ) where
-import           Crypto.Hash.Types (HashAlgorithm)
+import           Crypto.Hash.Types (HashAlgorithm, HashAlgorithmPrefix, HashAlgorithmResumable)
 import           Crypto.Hash.Blake2s
 import           Crypto.Hash.Blake2sp
 import           Crypto.Hash.Blake2b
@ -67,3 +77,5 @@ import           Crypto.Hash.Tiger
 import           Crypto.Hash.Skein256
 import           Crypto.Hash.Skein512
 import           Crypto.Hash.Whirlpool
 import           Crypto.Hash.SHAKE
 import           Crypto.Hash.Blake2
--- a/Crypto/Hash/Blake2.hs
+++ b/Crypto/Hash/Blake2.hs
@ -0,0 +1,162 @@
 -- |
 -- Module      : Crypto.Hash.Blake2
 -- License     : BSD-style
 -- Maintainer  : Nicolas Di Prima <nicolas@primetype.co.uk>
 -- Stability   : experimental
 -- Portability : unknown
 --
 -- Module containing the binding functions to work with the
 -- Blake2
 --
 -- Implementation based from [RFC7693](https://tools.ietf.org/html/rfc7693)
 --
 -- Please consider the following when chosing a hash:
 --
 --      Algorithm     | Target | Collision | Digest Size |
 --         Identifier |  Arch  |  Security |   in bytes  |
 --     ---------------+--------+-----------+-------------+
 --      id-blake2b160 | 64-bit |   2**80   |         20  |
 --      id-blake2b256 | 64-bit |   2**128  |         32  |
 --      id-blake2b384 | 64-bit |   2**192  |         48  |
 --      id-blake2b512 | 64-bit |   2**256  |         64  |
 --     ---------------+--------+-----------+-------------+
 --      id-blake2s128 | 32-bit |   2**64   |         16  |
 --      id-blake2s160 | 32-bit |   2**80   |         20  |
 --      id-blake2s224 | 32-bit |   2**112  |         28  |
 --      id-blake2s256 | 32-bit |   2**128  |         32  |
 --     ---------------+--------+-----------+-------------+
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE ScopedTypeVariables #-}
 {-# LANGUAGE KindSignatures #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Blake2
    ( Blake2s(..)
    , Blake2sp(..)
    , Blake2b(..)
    , Blake2bp(..)
    ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Word (Word8, Word32)
 import           GHC.TypeLits (Nat, KnownNat)
 import           Crypto.Internal.Nat
 -- | Fast and secure alternative to SHA1 and HMAC-SHA1
 --
 -- It is espacially known to target 32bits architectures.
 --
 -- Known supported digest sizes:
 --
 -- * Blake2s 160
 -- * Blake2s 224
 -- * Blake2s 256
 --
 data Blake2s (bitlen :: Nat) = Blake2s
    deriving (Show,Data)
 instance (IsDivisibleBy8 bitlen, KnownNat bitlen, IsAtLeast bitlen 8, IsAtMost bitlen 256)
      => HashAlgorithm (Blake2s bitlen)
      where
    type HashBlockSize           (Blake2s bitlen) = 64
    type HashDigestSize          (Blake2s bitlen) = Div8 bitlen
    type HashInternalContextSize (Blake2s bitlen) = 136
    hashBlockSize  _          = 64
    hashDigestSize _          = byteLen (Proxy :: Proxy bitlen)
    hashInternalContextSize _ = 136
    hashInternalInit p        = c_blake2s_init p (integralNatVal (Proxy :: Proxy bitlen))
    hashInternalUpdate        = c_blake2s_update
    hashInternalFinalize p    = c_blake2s_finalize p (integralNatVal (Proxy :: Proxy bitlen))
 foreign import ccall unsafe "cryptonite_blake2s_init"
    c_blake2s_init :: Ptr (Context a) -> Word32 -> IO ()
 foreign import ccall "cryptonite_blake2s_update"
    c_blake2s_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
 foreign import ccall unsafe "cryptonite_blake2s_finalize"
    c_blake2s_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
 -- | Fast cryptographic hash.
 --
 -- It is especially known to target 64bits architectures.
 --
 -- Known supported digest sizes:
 --
 -- * Blake2b 160
 -- * Blake2b 224
 -- * Blake2b 256
 -- * Blake2b 384
 -- * Blake2b 512
 --
 data Blake2b (bitlen :: Nat) = Blake2b
    deriving (Show,Data)
 instance (IsDivisibleBy8 bitlen, KnownNat bitlen, IsAtLeast bitlen 8, IsAtMost bitlen 512)
      => HashAlgorithm (Blake2b bitlen)
      where
    type HashBlockSize           (Blake2b bitlen) = 128
    type HashDigestSize          (Blake2b bitlen) = Div8 bitlen
    type HashInternalContextSize (Blake2b bitlen) = 248
    hashBlockSize  _          = 128
    hashDigestSize _          = byteLen (Proxy :: Proxy bitlen)
    hashInternalContextSize _ = 248
    hashInternalInit p        = c_blake2b_init p (integralNatVal (Proxy :: Proxy bitlen))
    hashInternalUpdate        = c_blake2b_update
    hashInternalFinalize p    = c_blake2b_finalize p (integralNatVal (Proxy :: Proxy bitlen))
 foreign import ccall unsafe "cryptonite_blake2b_init"
    c_blake2b_init :: Ptr (Context a) -> Word32 -> IO ()
 foreign import ccall "cryptonite_blake2b_update"
    c_blake2b_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
 foreign import ccall unsafe "cryptonite_blake2b_finalize"
    c_blake2b_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
 data Blake2sp (bitlen :: Nat) = Blake2sp
    deriving (Show,Data)
 instance (IsDivisibleBy8 bitlen, KnownNat bitlen, IsAtLeast bitlen 8, IsAtMost bitlen 256)
      => HashAlgorithm (Blake2sp bitlen)
      where
    type HashBlockSize           (Blake2sp bitlen) = 64
    type HashDigestSize          (Blake2sp bitlen) = Div8 bitlen
    type HashInternalContextSize (Blake2sp bitlen) = 2185
    hashBlockSize  _          = 64
    hashDigestSize _          = byteLen (Proxy :: Proxy bitlen)
    hashInternalContextSize _ = 2185
    hashInternalInit p        = c_blake2sp_init p (integralNatVal (Proxy :: Proxy bitlen))
    hashInternalUpdate        = c_blake2sp_update
    hashInternalFinalize p    = c_blake2sp_finalize p (integralNatVal (Proxy :: Proxy bitlen))
 foreign import ccall unsafe "cryptonite_blake2sp_init"
    c_blake2sp_init :: Ptr (Context a) -> Word32 -> IO ()
 foreign import ccall "cryptonite_blake2sp_update"
    c_blake2sp_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
 foreign import ccall unsafe "cryptonite_blake2sp_finalize"
    c_blake2sp_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
 data Blake2bp (bitlen :: Nat) = Blake2bp
    deriving (Show,Data)
 instance (IsDivisibleBy8 bitlen, KnownNat bitlen, IsAtLeast bitlen 8, IsAtMost bitlen 512)
      => HashAlgorithm (Blake2bp bitlen)
      where
    type HashBlockSize           (Blake2bp bitlen) = 128
    type HashDigestSize          (Blake2bp bitlen) = Div8 bitlen
    type HashInternalContextSize (Blake2bp bitlen) = 2325
    hashBlockSize  _          = 128
    hashDigestSize _          = byteLen (Proxy :: Proxy bitlen)
    hashInternalContextSize _ = 2325
    hashInternalInit p        = c_blake2bp_init p (integralNatVal (Proxy :: Proxy bitlen))
    hashInternalUpdate        = c_blake2bp_update
    hashInternalFinalize p    = c_blake2bp_finalize p (integralNatVal (Proxy :: Proxy bitlen))
 foreign import ccall unsafe "cryptonite_blake2bp_init"
    c_blake2bp_init :: Ptr (Context a) -> Word32 -> IO ()
 foreign import ccall "cryptonite_blake2bp_update"
    c_blake2bp_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
 foreign import ccall unsafe "cryptonite_blake2bp_finalize"
    c_blake2bp_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/Blake2b.hs
+++ b/Crypto/Hash/Blake2b.hs
@ -5,30 +5,94 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Blake2b cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Blake2b
-    (  Blake2b_512 (..)
+    (  Blake2b_160 (..), Blake2b_224 (..), Blake2b_256 (..), Blake2b_384 (..), Blake2b_512 (..)
    ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Blake2b (160 bits) cryptographic hash algorithm
 data Blake2b_160 = Blake2b_160
    deriving (Show,Data)
 instance HashAlgorithm Blake2b_160 where
    type HashBlockSize           Blake2b_160 = 128
    type HashDigestSize          Blake2b_160 = 20
    type HashInternalContextSize Blake2b_160 = 248
    hashBlockSize  _          = 128
    hashDigestSize _          = 20
    hashInternalContextSize _ = 248
    hashInternalInit p        = c_blake2b_init p 160
    hashInternalUpdate        = c_blake2b_update
    hashInternalFinalize p    = c_blake2b_finalize p 160
 -- | Blake2b (224 bits) cryptographic hash algorithm
 data Blake2b_224 = Blake2b_224
    deriving (Show,Data)
 instance HashAlgorithm Blake2b_224 where
    type HashBlockSize           Blake2b_224 = 128
    type HashDigestSize          Blake2b_224 = 28
    type HashInternalContextSize Blake2b_224 = 248
    hashBlockSize  _          = 128
    hashDigestSize _          = 28
    hashInternalContextSize _ = 248
    hashInternalInit p        = c_blake2b_init p 224
    hashInternalUpdate        = c_blake2b_update
    hashInternalFinalize p    = c_blake2b_finalize p 224
 -- | Blake2b (256 bits) cryptographic hash algorithm
 data Blake2b_256 = Blake2b_256
    deriving (Show,Data)
 instance HashAlgorithm Blake2b_256 where
    type HashBlockSize           Blake2b_256 = 128
    type HashDigestSize          Blake2b_256 = 32
    type HashInternalContextSize Blake2b_256 = 248
    hashBlockSize  _          = 128
    hashDigestSize _          = 32
    hashInternalContextSize _ = 248
    hashInternalInit p        = c_blake2b_init p 256
    hashInternalUpdate        = c_blake2b_update
    hashInternalFinalize p    = c_blake2b_finalize p 256
 -- | Blake2b (384 bits) cryptographic hash algorithm
 data Blake2b_384 = Blake2b_384
    deriving (Show,Data)
 instance HashAlgorithm Blake2b_384 where
    type HashBlockSize           Blake2b_384 = 128
    type HashDigestSize          Blake2b_384 = 48
    type HashInternalContextSize Blake2b_384 = 248
    hashBlockSize  _          = 128
    hashDigestSize _          = 48
    hashInternalContextSize _ = 248
    hashInternalInit p        = c_blake2b_init p 384
    hashInternalUpdate        = c_blake2b_update
    hashInternalFinalize p    = c_blake2b_finalize p 384
 -- | Blake2b (512 bits) cryptographic hash algorithm
 data Blake2b_512 = Blake2b_512
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Blake2b_512 where
    type HashBlockSize           Blake2b_512 = 128
    type HashDigestSize          Blake2b_512 = 64
    type HashInternalContextSize Blake2b_512 = 248
    hashBlockSize  _          = 128
    hashDigestSize _          = 64
-    hashInternalContextSize _ = 361
+    hashInternalContextSize _ = 248
    hashInternalInit p        = c_blake2b_init p 512
    hashInternalUpdate        = c_blake2b_update
    hashInternalFinalize p    = c_blake2b_finalize p 512
--- a/Crypto/Hash/Blake2bp.hs
+++ b/Crypto/Hash/Blake2bp.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Blake2bp cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Blake2bp
    (  Blake2bp_512 (..)
    ) where
@ -17,28 +19,30 @@ module Crypto.Hash.Blake2bp
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Blake2bp (512 bits) cryptographic hash algorithm
 data Blake2bp_512 = Blake2bp_512
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Blake2bp_512 where
    type HashBlockSize           Blake2bp_512 = 128
    type HashDigestSize          Blake2bp_512 = 64
    type HashInternalContextSize Blake2bp_512 = 1768
    hashBlockSize  _          = 128
    hashDigestSize _          = 64
-    hashInternalContextSize _ = 2325
+    hashInternalContextSize _ = 1768
-    hashInternalInit p        = c_blake2sp_init p 512
+    hashInternalInit p        = c_blake2bp_init p 512
-    hashInternalUpdate        = c_blake2sp_update
+    hashInternalUpdate        = c_blake2bp_update
-    hashInternalFinalize p    = c_blake2sp_finalize p 512
+    hashInternalFinalize p    = c_blake2bp_finalize p 512
-foreign import ccall unsafe "cryptonite_blake2sp_init"
+foreign import ccall unsafe "cryptonite_blake2bp_init"
-    c_blake2sp_init :: Ptr (Context a) -> Word32 -> IO ()
+    c_blake2bp_init :: Ptr (Context a) -> Word32 -> IO ()
-foreign import ccall "cryptonite_blake2sp_update"
+foreign import ccall "cryptonite_blake2bp_update"
-    c_blake2sp_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
+    c_blake2bp_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
-foreign import ccall unsafe "cryptonite_blake2sp_finalize"
+foreign import ccall unsafe "cryptonite_blake2bp_finalize"
-    c_blake2sp_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
+    c_blake2bp_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/Blake2s.hs
+++ b/Crypto/Hash/Blake2s.hs
@ -5,42 +5,64 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Blake2s cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Blake2s
-    (  Blake2s_224 (..), Blake2s_256 (..)
+    (  Blake2s_160 (..), Blake2s_224 (..), Blake2s_256 (..)
    ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Blake2s (160 bits) cryptographic hash algorithm
 data Blake2s_160 = Blake2s_160
    deriving (Show,Data)
 instance HashAlgorithm Blake2s_160 where
    type HashBlockSize           Blake2s_160 = 64
    type HashDigestSize          Blake2s_160 = 20
    type HashInternalContextSize Blake2s_160 = 136
    hashBlockSize  _          = 64
    hashDigestSize _          = 20
    hashInternalContextSize _ = 136
    hashInternalInit p        = c_blake2s_init p 160
    hashInternalUpdate        = c_blake2s_update
    hashInternalFinalize p    = c_blake2s_finalize p 160
 -- | Blake2s (224 bits) cryptographic hash algorithm
 data Blake2s_224 = Blake2s_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Blake2s_224 where
    type HashBlockSize           Blake2s_224 = 64
    type HashDigestSize          Blake2s_224 = 28
    type HashInternalContextSize Blake2s_224 = 136
    hashBlockSize  _          = 64
    hashDigestSize _          = 28
-    hashInternalContextSize _ = 185
+    hashInternalContextSize _ = 136
    hashInternalInit p        = c_blake2s_init p 224
    hashInternalUpdate        = c_blake2s_update
    hashInternalFinalize p    = c_blake2s_finalize p 224
 -- | Blake2s (256 bits) cryptographic hash algorithm
 data Blake2s_256 = Blake2s_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Blake2s_256 where
    type HashBlockSize           Blake2s_256 = 64
    type HashDigestSize          Blake2s_256 = 32
    type HashInternalContextSize Blake2s_256 = 136
    hashBlockSize  _          = 64
    hashDigestSize _          = 32
-    hashInternalContextSize _ = 185
+    hashInternalContextSize _ = 136
    hashInternalInit p        = c_blake2s_init p 256
    hashInternalUpdate        = c_blake2s_update
    hashInternalFinalize p    = c_blake2s_finalize p 256
--- a/Crypto/Hash/Blake2sp.hs
+++ b/Crypto/Hash/Blake2sp.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Blake2sp cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Blake2sp
    (  Blake2sp_224 (..), Blake2sp_256 (..)
    ) where
@ -17,30 +19,35 @@ module Crypto.Hash.Blake2sp
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Blake2sp (224 bits) cryptographic hash algorithm
 data Blake2sp_224 = Blake2sp_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Blake2sp_224 where
    type HashBlockSize           Blake2sp_224 = 64
    type HashDigestSize          Blake2sp_224 = 28
    type HashInternalContextSize Blake2sp_224 = 1752
    hashBlockSize  _          = 64
    hashDigestSize _          = 28
-    hashInternalContextSize _ = 2185
+    hashInternalContextSize _ = 1752
    hashInternalInit p        = c_blake2sp_init p 224
    hashInternalUpdate        = c_blake2sp_update
    hashInternalFinalize p    = c_blake2sp_finalize p 224
 -- | Blake2sp (256 bits) cryptographic hash algorithm
 data Blake2sp_256 = Blake2sp_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Blake2sp_256 where
    type HashBlockSize           Blake2sp_256 = 64
    type HashDigestSize          Blake2sp_256 = 32
    type HashInternalContextSize Blake2sp_256 = 1752
    hashBlockSize  _          = 64
    hashDigestSize _          = 32
-    hashInternalContextSize _ = 2185
+    hashInternalContextSize _ = 1752
    hashInternalInit p        = c_blake2sp_init p 256
    hashInternalUpdate        = c_blake2sp_update
    hashInternalFinalize p    = c_blake2sp_finalize p 256
--- a/Crypto/Hash/IO.hs
+++ b/Crypto/Hash/IO.hs
@ -8,6 +8,7 @@
 -- Generalized impure cryptographic hash interface
 --
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE ScopedTypeVariables        #-}
 module Crypto.Hash.IO
    ( HashAlgorithm(..)
    , MutableContext
@ -23,6 +24,11 @@ import qualified Crypto.Internal.ByteArray as B
 import           Foreign.Ptr
 -- | A Mutable hash context
 --
 -- This type is an instance of 'B.ByteArrayAccess' for debugging purpose.
 -- Internal layout is architecture dependent, may contain uninitialized data
 -- fragments, and change in future versions.  The bytearray should not be used
 -- as input to cryptographic algorithms.
 newtype MutableContext a = MutableContext B.Bytes
    deriving (B.ByteArrayAccess)
@ -51,17 +57,9 @@ hashMutableUpdate mc dat = doUpdate mc (B.withByteArray mc)
                hashInternalUpdate ctx d (fromIntegral $ B.length dat)
 -- | Finalize a mutable hash context and compute a digest
-hashMutableFinalize :: HashAlgorithm a => MutableContext a -> IO (Digest a)
+hashMutableFinalize :: forall a . HashAlgorithm a => MutableContext a -> IO (Digest a)
-hashMutableFinalize mc = doFinalize undefined (B.withByteArray mc) B.alloc
+hashMutableFinalize mc = do
-  where doFinalize :: HashAlgorithm alg
+    b <- B.alloc (hashDigestSize (undefined :: a)) $ \dig -> B.withByteArray mc $ \(ctx :: Ptr (Context a)) -> hashInternalFinalize ctx dig
                   => alg
                   -> ((Ptr (Context alg) -> IO ()) -> IO ())
                   -> (Int -> (Ptr (Digest alg)  -> IO ()) -> IO B.Bytes)
                   -> IO (Digest alg)
        doFinalize alg withCtx allocDigest = do
            b <- allocDigest (hashDigestSize alg) $ \dig ->
                    withCtx $ \ctx ->
                        hashInternalFinalize ctx dig
    return $ Digest b
 -- | Reset the mutable context to the initial state of the hash
--- a/Crypto/Hash/Keccak.hs
+++ b/Crypto/Hash/Keccak.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Keccak cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Keccak
    (  Keccak_224 (..), Keccak_256 (..), Keccak_384 (..), Keccak_512 (..)
    ) where
@ -17,15 +19,17 @@ module Crypto.Hash.Keccak
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Keccak (224 bits) cryptographic hash algorithm
 data Keccak_224 = Keccak_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Keccak_224 where
    type HashBlockSize           Keccak_224 = 144
    type HashDigestSize          Keccak_224 = 28
    type HashInternalContextSize Keccak_224 = 352
    hashBlockSize  _          = 144
    hashDigestSize _          = 28
    hashInternalContextSize _ = 352
@ -33,11 +37,18 @@ instance HashAlgorithm Keccak_224 where
    hashInternalUpdate        = c_keccak_update
    hashInternalFinalize p    = c_keccak_finalize p 224
 instance HashAlgorithmResumable Keccak_224 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | Keccak (256 bits) cryptographic hash algorithm
 data Keccak_256 = Keccak_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Keccak_256 where
    type HashBlockSize           Keccak_256 = 136
    type HashDigestSize          Keccak_256 = 32
    type HashInternalContextSize Keccak_256 = 344
    hashBlockSize  _          = 136
    hashDigestSize _          = 32
    hashInternalContextSize _ = 344
@ -45,11 +56,18 @@ instance HashAlgorithm Keccak_256 where
    hashInternalUpdate        = c_keccak_update
    hashInternalFinalize p    = c_keccak_finalize p 256
 instance HashAlgorithmResumable Keccak_256 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | Keccak (384 bits) cryptographic hash algorithm
 data Keccak_384 = Keccak_384
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Keccak_384 where
    type HashBlockSize           Keccak_384 = 104
    type HashDigestSize          Keccak_384 = 48
    type HashInternalContextSize Keccak_384 = 312
    hashBlockSize  _          = 104
    hashDigestSize _          = 48
    hashInternalContextSize _ = 312
@ -57,11 +75,18 @@ instance HashAlgorithm Keccak_384 where
    hashInternalUpdate        = c_keccak_update
    hashInternalFinalize p    = c_keccak_finalize p 384
 instance HashAlgorithmResumable Keccak_384 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | Keccak (512 bits) cryptographic hash algorithm
 data Keccak_512 = Keccak_512
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Keccak_512 where
    type HashBlockSize           Keccak_512 = 72
    type HashDigestSize          Keccak_512 = 64
    type HashInternalContextSize Keccak_512 = 280
    hashBlockSize  _          = 72
    hashDigestSize _          = 64
    hashInternalContextSize _ = 280
@ -69,6 +94,10 @@ instance HashAlgorithm Keccak_512 where
    hashInternalUpdate        = c_keccak_update
    hashInternalFinalize p    = c_keccak_finalize p 512
 instance HashAlgorithmResumable Keccak_512 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 foreign import ccall unsafe "cryptonite_keccak_init"
    c_keccak_init :: Ptr (Context a) -> Word32 -> IO ()
@ -78,3 +107,9 @@ foreign import ccall "cryptonite_keccak_update"
 foreign import ccall unsafe "cryptonite_keccak_finalize"
    c_keccak_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_ctx_to_be"
    c_sha3_ctx_to_be :: Ptr (Context a) -> Ptr Word8 -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_be_to_ctx"
    c_sha3_be_to_ctx :: Ptr Word8 -> Ptr (Context a) -> IO ()
--- a/Crypto/Hash/MD2.hs
+++ b/Crypto/Hash/MD2.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- MD2 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.MD2 ( MD2 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | MD2 cryptographic hash algorithm
 data MD2 = MD2
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm MD2 where
    type HashBlockSize           MD2 = 16
    type HashDigestSize          MD2 = 16
    type HashInternalContextSize MD2 = 96
    hashBlockSize  _          = 16
    hashDigestSize _          = 16
    hashInternalContextSize _ = 96
--- a/Crypto/Hash/MD4.hs
+++ b/Crypto/Hash/MD4.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- MD4 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.MD4 ( MD4 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | MD4 cryptographic hash algorithm
 data MD4 = MD4
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm MD4 where
    type HashBlockSize           MD4 = 64
    type HashDigestSize          MD4 = 16
    type HashInternalContextSize MD4 = 96
    hashBlockSize  _          = 64
    hashDigestSize _          = 16
    hashInternalContextSize _ = 96
--- a/Crypto/Hash/MD5.hs
+++ b/Crypto/Hash/MD5.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- MD5 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.MD5 ( MD5 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | MD5 cryptographic hash algorithm
 data MD5 = MD5
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm MD5 where
    type HashBlockSize           MD5 = 64
    type HashDigestSize          MD5 = 16
    type HashInternalContextSize MD5 = 96
    hashBlockSize  _          = 64
    hashDigestSize _          = 16
    hashInternalContextSize _ = 96
@ -30,6 +34,9 @@ instance HashAlgorithm MD5 where
    hashInternalUpdate        = c_md5_update
    hashInternalFinalize      = c_md5_finalize
 instance HashAlgorithmPrefix MD5 where
    hashInternalFinalizePrefix = c_md5_finalize_prefix
 foreign import ccall unsafe "cryptonite_md5_init"
    c_md5_init :: Ptr (Context a)-> IO ()
@ -38,3 +45,6 @@ foreign import ccall "cryptonite_md5_update"
 foreign import ccall unsafe "cryptonite_md5_finalize"
    c_md5_finalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 foreign import ccall "cryptonite_md5_finalize_prefix"
    c_md5_finalize_prefix :: Ptr (Context a) -> Ptr Word8 -> Word32 -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/RIPEMD160.hs
+++ b/Crypto/Hash/RIPEMD160.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- RIPEMD160 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.RIPEMD160 ( RIPEMD160 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | RIPEMD160 cryptographic hash algorithm
 data RIPEMD160 = RIPEMD160
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm RIPEMD160 where
    type HashBlockSize           RIPEMD160 = 64
    type HashDigestSize          RIPEMD160 = 20
    type HashInternalContextSize RIPEMD160 = 128
    hashBlockSize  _          = 64
    hashDigestSize _          = 20
    hashInternalContextSize _ = 128
--- a/Crypto/Hash/SHA1.hs
+++ b/Crypto/Hash/SHA1.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA1 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA1 ( SHA1 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA1 cryptographic hash algorithm
 data SHA1 = SHA1
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA1 where
    type HashBlockSize           SHA1 = 64
    type HashDigestSize          SHA1 = 20
    type HashInternalContextSize SHA1 = 96
    hashBlockSize  _          = 64
    hashDigestSize _          = 20
    hashInternalContextSize _ = 96
@ -30,6 +34,9 @@ instance HashAlgorithm SHA1 where
    hashInternalUpdate        = c_sha1_update
    hashInternalFinalize      = c_sha1_finalize
 instance HashAlgorithmPrefix SHA1 where
    hashInternalFinalizePrefix = c_sha1_finalize_prefix
 foreign import ccall unsafe "cryptonite_sha1_init"
    c_sha1_init :: Ptr (Context a)-> IO ()
@ -38,3 +45,6 @@ foreign import ccall "cryptonite_sha1_update"
 foreign import ccall unsafe "cryptonite_sha1_finalize"
    c_sha1_finalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 foreign import ccall "cryptonite_sha1_finalize_prefix"
    c_sha1_finalize_prefix :: Ptr (Context a) -> Ptr Word8 -> Word32 -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/SHA224.hs
+++ b/Crypto/Hash/SHA224.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA224 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA224 ( SHA224 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA224 cryptographic hash algorithm
 data SHA224 = SHA224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA224 where
    type HashBlockSize           SHA224 = 64
    type HashDigestSize          SHA224 = 28
    type HashInternalContextSize SHA224 = 192
    hashBlockSize  _          = 64
    hashDigestSize _          = 28
    hashInternalContextSize _ = 192
@ -30,6 +34,9 @@ instance HashAlgorithm SHA224 where
    hashInternalUpdate        = c_sha224_update
    hashInternalFinalize      = c_sha224_finalize
 instance HashAlgorithmPrefix SHA224 where
    hashInternalFinalizePrefix = c_sha224_finalize_prefix
 foreign import ccall unsafe "cryptonite_sha224_init"
    c_sha224_init :: Ptr (Context a)-> IO ()
@ -38,3 +45,6 @@ foreign import ccall "cryptonite_sha224_update"
 foreign import ccall unsafe "cryptonite_sha224_finalize"
    c_sha224_finalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 foreign import ccall "cryptonite_sha224_finalize_prefix"
    c_sha224_finalize_prefix :: Ptr (Context a) -> Ptr Word8 -> Word32 -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/SHA256.hs
+++ b/Crypto/Hash/SHA256.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA256 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA256 ( SHA256 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA256 cryptographic hash algorithm
 data SHA256 = SHA256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA256 where
    type HashBlockSize           SHA256 = 64
    type HashDigestSize          SHA256 = 32
    type HashInternalContextSize SHA256 = 192
    hashBlockSize  _          = 64
    hashDigestSize _          = 32
    hashInternalContextSize _ = 192
@ -30,6 +34,9 @@ instance HashAlgorithm SHA256 where
    hashInternalUpdate        = c_sha256_update
    hashInternalFinalize      = c_sha256_finalize
 instance HashAlgorithmPrefix SHA256 where
    hashInternalFinalizePrefix = c_sha256_finalize_prefix
 foreign import ccall unsafe "cryptonite_sha256_init"
    c_sha256_init :: Ptr (Context a)-> IO ()
@ -38,3 +45,6 @@ foreign import ccall "cryptonite_sha256_update"
 foreign import ccall unsafe "cryptonite_sha256_finalize"
    c_sha256_finalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 foreign import ccall "cryptonite_sha256_finalize_prefix"
    c_sha256_finalize_prefix :: Ptr (Context a) -> Ptr Word8 -> Word32 -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/SHA3.hs
+++ b/Crypto/Hash/SHA3.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA3 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA3
    (  SHA3_224 (..), SHA3_256 (..), SHA3_384 (..), SHA3_512 (..)
    ) where
@ -17,15 +19,17 @@ module Crypto.Hash.SHA3
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA3 (224 bits) cryptographic hash algorithm
 data SHA3_224 = SHA3_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA3_224 where
    type HashBlockSize           SHA3_224 = 144
    type HashDigestSize          SHA3_224 = 28
    type HashInternalContextSize SHA3_224 = 352
    hashBlockSize  _          = 144
    hashDigestSize _          = 28
    hashInternalContextSize _ = 352
@ -33,11 +37,18 @@ instance HashAlgorithm SHA3_224 where
    hashInternalUpdate        = c_sha3_update
    hashInternalFinalize p    = c_sha3_finalize p 224
 instance HashAlgorithmResumable SHA3_224 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | SHA3 (256 bits) cryptographic hash algorithm
 data SHA3_256 = SHA3_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA3_256 where
    type HashBlockSize           SHA3_256 = 136
    type HashDigestSize          SHA3_256 = 32
    type HashInternalContextSize SHA3_256 = 344
    hashBlockSize  _          = 136
    hashDigestSize _          = 32
    hashInternalContextSize _ = 344
@ -45,11 +56,18 @@ instance HashAlgorithm SHA3_256 where
    hashInternalUpdate        = c_sha3_update
    hashInternalFinalize p    = c_sha3_finalize p 256
 instance HashAlgorithmResumable SHA3_256 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | SHA3 (384 bits) cryptographic hash algorithm
 data SHA3_384 = SHA3_384
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA3_384 where
    type HashBlockSize           SHA3_384 = 104
    type HashDigestSize          SHA3_384 = 48
    type HashInternalContextSize SHA3_384 = 312
    hashBlockSize  _          = 104
    hashDigestSize _          = 48
    hashInternalContextSize _ = 312
@ -57,11 +75,18 @@ instance HashAlgorithm SHA3_384 where
    hashInternalUpdate        = c_sha3_update
    hashInternalFinalize p    = c_sha3_finalize p 384
 instance HashAlgorithmResumable SHA3_384 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | SHA3 (512 bits) cryptographic hash algorithm
 data SHA3_512 = SHA3_512
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA3_512 where
    type HashBlockSize           SHA3_512 = 72
    type HashDigestSize          SHA3_512 = 64
    type HashInternalContextSize SHA3_512 = 280
    hashBlockSize  _          = 72
    hashDigestSize _          = 64
    hashInternalContextSize _ = 280
@ -69,6 +94,10 @@ instance HashAlgorithm SHA3_512 where
    hashInternalUpdate        = c_sha3_update
    hashInternalFinalize p    = c_sha3_finalize p 512
 instance HashAlgorithmResumable SHA3_512 where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 foreign import ccall unsafe "cryptonite_sha3_init"
    c_sha3_init :: Ptr (Context a) -> Word32 -> IO ()
@ -78,3 +107,9 @@ foreign import ccall "cryptonite_sha3_update"
 foreign import ccall unsafe "cryptonite_sha3_finalize"
    c_sha3_finalize :: Ptr (Context a) -> Word32 -> Ptr (Digest a) -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_ctx_to_be"
    c_sha3_ctx_to_be :: Ptr (Context a) -> Ptr Word8 -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_be_to_ctx"
    c_sha3_be_to_ctx :: Ptr Word8 -> Ptr (Context a) -> IO ()
--- a/Crypto/Hash/SHA384.hs
+++ b/Crypto/Hash/SHA384.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA384 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA384 ( SHA384 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA384 cryptographic hash algorithm
 data SHA384 = SHA384
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA384 where
    type HashBlockSize           SHA384 = 128
    type HashDigestSize          SHA384 = 48
    type HashInternalContextSize SHA384 = 256
    hashBlockSize  _          = 128
    hashDigestSize _          = 48
    hashInternalContextSize _ = 256
@ -30,6 +34,9 @@ instance HashAlgorithm SHA384 where
    hashInternalUpdate        = c_sha384_update
    hashInternalFinalize      = c_sha384_finalize
 instance HashAlgorithmPrefix SHA384 where
    hashInternalFinalizePrefix = c_sha384_finalize_prefix
 foreign import ccall unsafe "cryptonite_sha384_init"
    c_sha384_init :: Ptr (Context a)-> IO ()
@ -38,3 +45,6 @@ foreign import ccall "cryptonite_sha384_update"
 foreign import ccall unsafe "cryptonite_sha384_finalize"
    c_sha384_finalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 foreign import ccall "cryptonite_sha384_finalize_prefix"
    c_sha384_finalize_prefix :: Ptr (Context a) -> Ptr Word8 -> Word32 -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/SHA512.hs
+++ b/Crypto/Hash/SHA512.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA512 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA512 ( SHA512 (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA512 cryptographic hash algorithm
 data SHA512 = SHA512
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA512 where
    type HashBlockSize           SHA512 = 128
    type HashDigestSize          SHA512 = 64
    type HashInternalContextSize SHA512 = 256
    hashBlockSize  _          = 128
    hashDigestSize _          = 64
    hashInternalContextSize _ = 256
@ -30,6 +34,9 @@ instance HashAlgorithm SHA512 where
    hashInternalUpdate        = c_sha512_update
    hashInternalFinalize      = c_sha512_finalize
 instance HashAlgorithmPrefix SHA512 where
    hashInternalFinalizePrefix = c_sha512_finalize_prefix
 foreign import ccall unsafe "cryptonite_sha512_init"
    c_sha512_init :: Ptr (Context a)-> IO ()
@ -38,3 +45,6 @@ foreign import ccall "cryptonite_sha512_update"
 foreign import ccall unsafe "cryptonite_sha512_finalize"
    c_sha512_finalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 foreign import ccall "cryptonite_sha512_finalize_prefix"
    c_sha512_finalize_prefix :: Ptr (Context a) -> Ptr Word8 -> Word32 -> Word32 -> Ptr (Digest a) -> IO ()
--- a/Crypto/Hash/SHA512t.hs
+++ b/Crypto/Hash/SHA512t.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- SHA512t cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.SHA512t
    (  SHA512t_224 (..), SHA512t_256 (..)
    ) where
@ -17,15 +19,17 @@ module Crypto.Hash.SHA512t
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | SHA512t (224 bits) cryptographic hash algorithm
 data SHA512t_224 = SHA512t_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA512t_224 where
    type HashBlockSize           SHA512t_224 = 128
    type HashDigestSize          SHA512t_224 = 28
    type HashInternalContextSize SHA512t_224 = 256
    hashBlockSize  _          = 128
    hashDigestSize _          = 28
    hashInternalContextSize _ = 256
@ -35,9 +39,12 @@ instance HashAlgorithm SHA512t_224 where
 -- | SHA512t (256 bits) cryptographic hash algorithm
 data SHA512t_256 = SHA512t_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm SHA512t_256 where
    type HashBlockSize           SHA512t_256 = 128
    type HashDigestSize          SHA512t_256 = 32
    type HashInternalContextSize SHA512t_256 = 256
    hashBlockSize  _          = 128
    hashDigestSize _          = 32
    hashInternalContextSize _ = 256
--- a/Crypto/Hash/SHAKE.hs
+++ b/Crypto/Hash/SHAKE.hs
@ -0,0 +1,145 @@
 -- |
 -- Module      : Crypto.Hash.SHAKE
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : experimental
 -- Portability : unknown
 --
 -- Module containing the binding functions to work with the
 -- SHA3 extendable output functions (SHAKE).
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE KindSignatures #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE ScopedTypeVariables #-}
 {-# LANGUAGE TypeOperators #-}
 {-# LANGUAGE TypeFamilies #-}
 {-# LANGUAGE UndecidableInstances #-}
 module Crypto.Hash.SHAKE
    (  SHAKE128 (..), SHAKE256 (..), HashSHAKE (..)
    ) where
 import           Control.Monad (when)
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr, castPtr)
 import           Foreign.Storable (Storable(..))
 import           Data.Bits
 import           Data.Data
 import           Data.Word (Word8, Word32)
 import           GHC.TypeLits (Nat, KnownNat, type (+))
 import           Crypto.Internal.Nat
 -- | Type class of SHAKE algorithms.
 class HashAlgorithm a => HashSHAKE a where
    -- | Alternate finalization needed for cSHAKE
    cshakeInternalFinalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
    -- | Get the digest bit length
    cshakeOutputLength :: a -> Int
 -- | SHAKE128 (128 bits) extendable output function.  Supports an arbitrary
 -- digest size, to be specified as a type parameter of kind 'Nat'.
 --
 -- Note: outputs from @'SHAKE128' n@ and @'SHAKE128' m@ for the same input are
 -- correlated (one being a prefix of the other).  Results are unrelated to
 -- 'SHAKE256' results.
 data SHAKE128 (bitlen :: Nat) = SHAKE128
    deriving (Show, Data)
 instance KnownNat bitlen => HashAlgorithm (SHAKE128 bitlen) where
    type HashBlockSize           (SHAKE128 bitlen)  = 168
    type HashDigestSize          (SHAKE128 bitlen) = Div8 (bitlen + 7)
    type HashInternalContextSize (SHAKE128 bitlen) = 376
    hashBlockSize  _          = 168
    hashDigestSize _          = byteLen (Proxy :: Proxy bitlen)
    hashInternalContextSize _ = 376
    hashInternalInit p        = c_sha3_init p 128
    hashInternalUpdate        = c_sha3_update
    hashInternalFinalize      = shakeFinalizeOutput (Proxy :: Proxy bitlen)
 instance KnownNat bitlen => HashSHAKE (SHAKE128 bitlen) where
    cshakeInternalFinalize = cshakeFinalizeOutput (Proxy :: Proxy bitlen)
    cshakeOutputLength _ = integralNatVal (Proxy :: Proxy bitlen)
 instance KnownNat bitlen => HashAlgorithmResumable (SHAKE128 bitlen) where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 -- | SHAKE256 (256 bits) extendable output function.  Supports an arbitrary
 -- digest size, to be specified as a type parameter of kind 'Nat'.
 --
 -- Note: outputs from @'SHAKE256' n@ and @'SHAKE256' m@ for the same input are
 -- correlated (one being a prefix of the other).  Results are unrelated to
 -- 'SHAKE128' results.
 data SHAKE256 (bitlen :: Nat) = SHAKE256
    deriving (Show, Data)
 instance KnownNat bitlen => HashAlgorithm (SHAKE256 bitlen) where
    type HashBlockSize           (SHAKE256 bitlen) = 136
    type HashDigestSize          (SHAKE256 bitlen) = Div8 (bitlen + 7)
    type HashInternalContextSize (SHAKE256 bitlen) = 344
    hashBlockSize  _          = 136
    hashDigestSize _          = byteLen (Proxy :: Proxy bitlen)
    hashInternalContextSize _ = 344
    hashInternalInit p        = c_sha3_init p 256
    hashInternalUpdate        = c_sha3_update
    hashInternalFinalize      = shakeFinalizeOutput (Proxy :: Proxy bitlen)
 instance KnownNat bitlen => HashSHAKE (SHAKE256 bitlen) where
    cshakeInternalFinalize = cshakeFinalizeOutput (Proxy :: Proxy bitlen)
    cshakeOutputLength _ = integralNatVal (Proxy :: Proxy bitlen)
 instance KnownNat bitlen => HashAlgorithmResumable (SHAKE256 bitlen) where
  hashInternalPutContextBE = c_sha3_ctx_to_be
  hashInternalGetContextBE = c_sha3_be_to_ctx
 shakeFinalizeOutput :: KnownNat bitlen
                    => proxy bitlen
                    -> Ptr (Context a)
                    -> Ptr (Digest a)
                    -> IO ()
 shakeFinalizeOutput d ctx dig = do
    c_sha3_finalize_shake ctx
    c_sha3_output ctx dig (byteLen d)
    shakeTruncate d (castPtr dig)
 cshakeFinalizeOutput :: KnownNat bitlen
                     => proxy bitlen
                     -> Ptr (Context a)
                     -> Ptr (Digest a)
                     -> IO ()
 cshakeFinalizeOutput d ctx dig = do
    c_sha3_finalize_cshake ctx
    c_sha3_output ctx dig (byteLen d)
    shakeTruncate d (castPtr dig)
 shakeTruncate :: KnownNat bitlen => proxy bitlen -> Ptr Word8 -> IO ()
 shakeTruncate d ptr =
    when (bits > 0) $ do
        byte <- peekElemOff ptr index
        pokeElemOff ptr index (byte .&. mask)
  where
    mask = (1 `shiftL` bits) - 1
    (index, bits) = integralNatVal d `divMod` 8
 foreign import ccall unsafe "cryptonite_sha3_init"
    c_sha3_init :: Ptr (Context a) -> Word32 -> IO ()
 foreign import ccall "cryptonite_sha3_update"
    c_sha3_update :: Ptr (Context a) -> Ptr Word8 -> Word32 -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_finalize_shake"
    c_sha3_finalize_shake :: Ptr (Context a) -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_finalize_cshake"
    c_sha3_finalize_cshake :: Ptr (Context a) -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_output"
    c_sha3_output :: Ptr (Context a) -> Ptr (Digest a) -> Word32 -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_ctx_to_be"
    c_sha3_ctx_to_be :: Ptr (Context a) -> Ptr Word8 -> IO ()
 foreign import ccall unsafe "cryptonite_sha3_be_to_ctx"
    c_sha3_be_to_ctx :: Ptr Word8 -> Ptr (Context a) -> IO ()
--- a/Crypto/Hash/Skein256.hs
+++ b/Crypto/Hash/Skein256.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Skein256 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Skein256
    (  Skein256_224 (..), Skein256_256 (..)
    ) where
@ -17,15 +19,17 @@ module Crypto.Hash.Skein256
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Skein256 (224 bits) cryptographic hash algorithm
 data Skein256_224 = Skein256_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Skein256_224 where
    type HashBlockSize           Skein256_224 = 32
    type HashDigestSize          Skein256_224 = 28
    type HashInternalContextSize Skein256_224 = 96
    hashBlockSize  _          = 32
    hashDigestSize _          = 28
    hashInternalContextSize _ = 96
@ -35,9 +39,12 @@ instance HashAlgorithm Skein256_224 where
 -- | Skein256 (256 bits) cryptographic hash algorithm
 data Skein256_256 = Skein256_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Skein256_256 where
    type HashBlockSize           Skein256_256 = 32
    type HashDigestSize          Skein256_256 = 32
    type HashInternalContextSize Skein256_256 = 96
    hashBlockSize  _          = 32
    hashDigestSize _          = 32
    hashInternalContextSize _ = 96
--- a/Crypto/Hash/Skein512.hs
+++ b/Crypto/Hash/Skein512.hs
@ -5,11 +5,13 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Skein512 cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Skein512
    (  Skein512_224 (..), Skein512_256 (..), Skein512_384 (..), Skein512_512 (..)
    ) where
@ -17,15 +19,17 @@ module Crypto.Hash.Skein512
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Skein512 (224 bits) cryptographic hash algorithm
 data Skein512_224 = Skein512_224
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Skein512_224 where
    type HashBlockSize           Skein512_224 = 64
    type HashDigestSize          Skein512_224 = 28
    type HashInternalContextSize Skein512_224 = 160
    hashBlockSize  _          = 64
    hashDigestSize _          = 28
    hashInternalContextSize _ = 160
@ -35,9 +39,12 @@ instance HashAlgorithm Skein512_224 where
 -- | Skein512 (256 bits) cryptographic hash algorithm
 data Skein512_256 = Skein512_256
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Skein512_256 where
    type HashBlockSize           Skein512_256 = 64
    type HashDigestSize          Skein512_256 = 32
    type HashInternalContextSize Skein512_256 = 160
    hashBlockSize  _          = 64
    hashDigestSize _          = 32
    hashInternalContextSize _ = 160
@ -47,9 +54,12 @@ instance HashAlgorithm Skein512_256 where
 -- | Skein512 (384 bits) cryptographic hash algorithm
 data Skein512_384 = Skein512_384
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Skein512_384 where
    type HashBlockSize           Skein512_384 = 64
    type HashDigestSize          Skein512_384 = 48
    type HashInternalContextSize Skein512_384 = 160
    hashBlockSize  _          = 64
    hashDigestSize _          = 48
    hashInternalContextSize _ = 160
@ -59,9 +69,12 @@ instance HashAlgorithm Skein512_384 where
 -- | Skein512 (512 bits) cryptographic hash algorithm
 data Skein512_512 = Skein512_512
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Skein512_512 where
    type HashBlockSize           Skein512_512 = 64
    type HashDigestSize          Skein512_512 = 64
    type HashInternalContextSize Skein512_512 = 160
    hashBlockSize  _          = 64
    hashDigestSize _          = 64
    hashInternalContextSize _ = 160
--- a/Crypto/Hash/Tiger.hs
+++ b/Crypto/Hash/Tiger.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Tiger cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Tiger ( Tiger (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Tiger cryptographic hash algorithm
 data Tiger = Tiger
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Tiger where
    type HashBlockSize           Tiger = 64
    type HashDigestSize          Tiger = 24
    type HashInternalContextSize Tiger = 96
    hashBlockSize  _          = 64
    hashDigestSize _          = 24
    hashInternalContextSize _ = 96
--- a/Crypto/Hash/Types.hs
+++ b/Crypto/Hash/Types.hs
@ -8,8 +8,14 @@
 -- Crypto hash types definitions
 --
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE ScopedTypeVariables #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Types
    ( HashAlgorithm(..)
    , HashAlgorithmPrefix(..)
    , HashAlgorithmResumable(..)
    , Context(..)
    , Digest(..)
    ) where
@ -17,7 +23,15 @@ module Crypto.Hash.Types
 import           Crypto.Internal.Imports
 import           Crypto.Internal.ByteArray (ByteArrayAccess, Bytes)
 import qualified Crypto.Internal.ByteArray as B
 import           Control.Monad.ST
 import           Data.Char (digitToInt, isHexDigit)
 import           Foreign.Ptr (Ptr)
 import           Basement.Block (Block, unsafeFreeze)
 import           Basement.Block.Mutable (MutableBlock, new, unsafeWrite)
 import           Basement.NormalForm (deepseq)
 import           Basement.Types.OffsetSize (CountOf(..), Offset(..))
 import           GHC.TypeLits (Nat)
 import           Data.Data (Data)
 -- | Class representing hashing algorithms.
 --
@ -25,6 +39,13 @@ import           Foreign.Ptr (Ptr)
 -- and lowlevel. the Hash module takes care of
 -- hidding the mutable interface properly.
 class HashAlgorithm a where
    -- | Associated type for the block size of the hash algorithm
    type HashBlockSize a :: Nat
    -- | Associated type for the digest size of the hash algorithm
    type HashDigestSize a :: Nat
    -- | Associated type for the internal context size of the hash algorithm
    type HashInternalContextSize a :: Nat
    -- | Get the block size of a hash algorithm
    hashBlockSize           :: a -> Int
    -- | Get the digest size of a hash algorithm
@ -40,19 +61,67 @@ class HashAlgorithm a where
    -- | Finalize the context and set the digest raw memory to the right value
    hashInternalFinalize :: Ptr (Context a) -> Ptr (Digest a) -> IO ()
 -- | Hashing algorithms with a constant-time implementation.
 class HashAlgorithm a => HashAlgorithmPrefix a where
    -- | Update the context with the first N bytes of a buffer and finalize this
    -- context.  The code path executed is independent from N and depends only
    -- on the complete buffer length.
    hashInternalFinalizePrefix :: Ptr (Context a)
                               -> Ptr Word8 -> Word32
                               -> Word32
                               -> Ptr (Digest a)
                               -> IO ()
 class HashAlgorithm a => HashAlgorithmResumable a where
  hashInternalPutContextBE :: Ptr (Context a) -> Ptr Word8 -> IO ()
  hashInternalGetContextBE :: Ptr Word8 -> Ptr (Context a) -> IO ()
 {-
 hashContextGetAlgorithm :: HashAlgorithm a => Context a -> a
 hashContextGetAlgorithm = undefined
 -}
 -- | Represent a context for a given hash algorithm.
 --
 -- This type is an instance of 'ByteArrayAccess' for debugging purpose. Internal
 -- layout is architecture dependent, may contain uninitialized data fragments,
 -- and change in future versions.  The bytearray should not be used as input to
 -- cryptographic algorithms.
 newtype Context a = Context Bytes
    deriving (ByteArrayAccess,NFData)
 -- | Represent a digest for a given hash algorithm.
-newtype Digest a = Digest Bytes
+--
-    deriving (Eq,Ord,ByteArrayAccess,NFData)
+-- This type is an instance of 'ByteArrayAccess' from package
 -- <https://hackage.haskell.org/package/memory memory>.
 -- Module "Data.ByteArray" provides many primitives to work with those values
 -- including conversion to other types.
 --
 -- Creating a digest from a bytearray is also possible with function
 -- 'Crypto.Hash.digestFromByteString'.
 newtype Digest a = Digest (Block Word8)
    deriving (Eq,Ord,ByteArrayAccess, Data)
 instance NFData (Digest a) where
    rnf (Digest u) = u `deepseq` ()
 instance Show (Digest a) where
    show (Digest bs) = map (toEnum . fromIntegral)
                     $ B.unpack (B.convertToBase B.Base16 bs :: Bytes)
 instance HashAlgorithm a => Read (Digest a) where
    readsPrec _ str = runST $ do mut <- new (CountOf len)
                                 loop mut len str
      where
        len = hashDigestSize (undefined :: a)
        loop :: MutableBlock Word8 s -> Int -> String -> ST s [(Digest a, String)]
        loop mut 0   cs          = (\b -> [(Digest b, cs)]) <$> unsafeFreeze mut
        loop _   _   []          = return []
        loop _   _   [_]         = return []
        loop mut n   (c:(d:ds))
            | not (isHexDigit c) = return []
            | not (isHexDigit d) = return []
            | otherwise          = do
                let w8 = fromIntegral $ digitToInt c * 16 + digitToInt d
                unsafeWrite mut (Offset $ len - n) w8
                loop mut (n - 1) ds
--- a/Crypto/Hash/Whirlpool.hs
+++ b/Crypto/Hash/Whirlpool.hs
@ -5,24 +5,28 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- module containing the binding functions to work with the
+-- Module containing the binding functions to work with the
 -- Whirlpool cryptographic hash.
 --
 {-# LANGUAGE ForeignFunctionInterface #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeFamilies #-}
 module Crypto.Hash.Whirlpool ( Whirlpool (..) ) where
 import           Crypto.Hash.Types
 import           Foreign.Ptr (Ptr)
 import           Data.Data
 import           Data.Typeable
 import           Data.Word (Word8, Word32)
 -- | Whirlpool cryptographic hash algorithm
 data Whirlpool = Whirlpool
-    deriving (Show,Data,Typeable)
+    deriving (Show,Data)
 instance HashAlgorithm Whirlpool where
    type HashBlockSize           Whirlpool = 64
    type HashDigestSize          Whirlpool = 64
    type HashInternalContextSize Whirlpool = 168
    hashBlockSize  _          = 64
    hashDigestSize _          = 64
    hashInternalContextSize _ = 168
--- a/Crypto/Internal/Builder.hs
+++ b/Crypto/Internal/Builder.hs
@ -0,0 +1,53 @@
 -- |
 -- Module      : Crypto.Internal.Builder
 -- License     : BSD-style
 -- Maintainer  : Olivier Chéron <olivier.cheron@gmail.com>
 -- Stability   : stable
 -- Portability : Good
 --
 -- Delaying and merging ByteArray allocations.  This is similar to module
 -- "Data.ByteArray.Pack" except the total length is computed automatically based
 -- on what is appended.
 --
 {-# LANGUAGE BangPatterns #-}
 module Crypto.Internal.Builder
    ( Builder
    , buildAndFreeze
    , builderLength
    , byte
    , bytes
    , zero
    ) where
 import           Data.ByteArray (ByteArray, ByteArrayAccess)
 import qualified Data.ByteArray as B
 import           Data.Memory.PtrMethods (memSet)
 import           Foreign.Ptr (Ptr, plusPtr)
 import           Foreign.Storable (poke)
 import           Crypto.Internal.Imports hiding (empty)
 data Builder =  Builder !Int (Ptr Word8 -> IO ())  -- size and initializer
 instance Semigroup Builder where
    (Builder s1 f1) <> (Builder s2 f2) = Builder (s1 + s2) f
      where f p = f1 p >> f2 (p `plusPtr` s1)
 builderLength :: Builder -> Int
 builderLength (Builder s _) = s
 buildAndFreeze :: ByteArray ba => Builder -> ba
 buildAndFreeze (Builder s f) = B.allocAndFreeze s f
 byte :: Word8 -> Builder
 byte !b = Builder 1 (`poke` b)
 bytes :: ByteArrayAccess ba => ba -> Builder
 bytes bs = Builder (B.length bs) (B.copyByteArrayToPtr bs)
 zero :: Int -> Builder
 zero s = if s > 0 then Builder s (\p -> memSet p 0 s) else empty
 empty :: Builder
 empty = Builder 0 (const $ return ())
--- a/Crypto/Internal/ByteArray.hs
+++ b/Crypto/Internal/ByteArray.hs
@ -7,13 +7,33 @@
 --
 -- Simple and efficient byte array types
 --
 {-# LANGUAGE BangPatterns #-}
 {-# OPTIONS_HADDOCK hide #-}
 module Crypto.Internal.ByteArray
    ( module Data.ByteArray
    , module Data.ByteArray.Mapping
    , module Data.ByteArray.Encoding
    , constAllZero
    ) where
 import Data.ByteArray
 import Data.ByteArray.Mapping
 import Data.ByteArray.Encoding
 import Data.Bits ((.|.))
 import Data.Word (Word8)
 import Foreign.Ptr (Ptr)
 import Foreign.Storable (peekByteOff)
 import Crypto.Internal.Compat (unsafeDoIO)
 constAllZero :: ByteArrayAccess ba => ba -> Bool
 constAllZero b = unsafeDoIO $ withByteArray b $ \p -> loop p 0 0
  where
    loop :: Ptr b -> Int -> Word8 -> IO Bool
    loop p i !acc
        | i == len  = return $! acc == 0
        | otherwise = do
            e <- peekByteOff p i
            loop p (i+1) (acc .|. e)
    len = Data.ByteArray.length b
--- a/Crypto/Internal/Compat.hs
+++ b/Crypto/Internal/Compat.hs
@ -5,8 +5,8 @@
 -- Stability   : stable
 -- Portability : Good
 --
-- This module try to keep all the difference between versions of base
+-- This module tries to keep all the difference between versions of base
-- or other needed packages, so that modules don't need to use CPP
+-- or other needed packages, so that modules don't need to use CPP.
 --
 {-# LANGUAGE CPP #-}
 module Crypto.Internal.Compat
@ -19,10 +19,10 @@ import System.IO.Unsafe
 import Data.Word
 import Data.Bits
-- | perform io for hashes that do allocation and ffi.
+-- | Perform io for hashes that do allocation and FFI.
-- unsafeDupablePerformIO is used when possible as the
+-- 'unsafeDupablePerformIO' is used when possible as the
 -- computation is pure and the output is directly linked
-- to the input. we also do not modify anything after it has
+-- to the input. We also do not modify anything after it has
 -- been returned to the user.
 unsafeDoIO :: IO a -> a
 #if __GLASGOW_HASKELL__ > 704
--- a/Crypto/Internal/CompatPrim.hs
+++ b/Crypto/Internal/CompatPrim.hs
@ -5,11 +5,11 @@
 -- Stability   : stable
 -- Portability : Compat
 --
-- This module try to keep all the difference between versions of ghc primitive
+-- This module tries to keep all the difference between versions of ghc primitive
 -- or other needed packages, so that modules don't need to use CPP.
 --
 -- Note that MagicHash and CPP conflicts in places, making it "more interesting"
-- to write compat code for primitives
+-- to write compat code for primitives.
 --
 {-# LANGUAGE CPP #-}
 {-# LANGUAGE BangPatterns #-}
@ -23,15 +23,21 @@ module Crypto.Internal.CompatPrim
    , convert4To32
    ) where
 import GHC.Prim
 #if !defined(ARCH_IS_LITTLE_ENDIAN) && !defined(ARCH_IS_BIG_ENDIAN)
 import Data.Memory.Endian (getSystemEndianness, Endianness(..))
 #endif
-- | byteswap Word# to or from Big Endian
+#if __GLASGOW_HASKELL__ >= 902
 import GHC.Prim
 #else
 import GHC.Prim hiding (Word32#)
 type Word32# = Word#
 #endif
 -- | Byteswap Word# to or from Big Endian
 --
-- on a big endian machine, this function is a nop.
+-- On a big endian machine, this function is a nop.
-be32Prim :: Word# -> Word#
+be32Prim :: Word32# -> Word32#
 #ifdef ARCH_IS_LITTLE_ENDIAN
 be32Prim = byteswap32Prim
 #elif defined(ARCH_IS_BIG_ENDIAN)
@ -40,10 +46,10 @@ be32Prim = id
 be32Prim w = if getSystemEndianness == LittleEndian then byteswap32Prim w else w
 #endif
-- | byteswap Word# to or from Little Endian
+-- | Byteswap Word# to or from Little Endian
 --
-- on a little endian machine, this function is a nop.
+-- On a little endian machine, this function is a nop.
-le32Prim :: Word# -> Word#
+le32Prim :: Word32# -> Word32#
 #ifdef ARCH_IS_LITTLE_ENDIAN
 le32Prim w = w
 #elif defined(ARCH_IS_BIG_ENDIAN)
@ -54,19 +60,14 @@ le32Prim w = if getSystemEndianness == LittleEndian then w else byteswap32Prim w
 -- | Simple compatibility for byteswap the lower 32 bits of a Word#
 -- at the primitive level
-byteswap32Prim :: Word# -> Word#
+byteswap32Prim :: Word32# -> Word32#
-#if __GLASGOW_HASKELL__ >= 708
+#if __GLASGOW_HASKELL__ >= 902
-byteswap32Prim w = byteSwap32# w
+byteswap32Prim w = wordToWord32# (byteSwap32# (word32ToWord# w))
 #else
-byteswap32Prim w =
+byteswap32Prim w = byteSwap32# w
    let !a =       uncheckedShiftL# w 24#
        !b = and# (uncheckedShiftL# w 8#) 0x00ff0000##
        !c = and# (uncheckedShiftRL# w 8#) 0x0000ff00##
        !d = and# (uncheckedShiftRL# w 24#) 0x000000ff##
     in or# a (or# b (or# c d))
 #endif
-- | combine 4 word8 [a,b,c,d] to a word32 representing [a,b,c,d]
+-- | Combine 4 word8 [a,b,c,d] to a word32 representing [a,b,c,d]
 convert4To32 :: Word# -> Word# -> Word# -> Word#
             -> Word#
 convert4To32 a b c d = or# (or# c1 c2) (or# c3 c4)
--- a/Crypto/Internal/DeepSeq.hs
+++ b/Crypto/Internal/DeepSeq.hs
@ -30,4 +30,6 @@ instance NFData Word64 where rnf w = w `seq` ()
 instance NFData Bytes where rnf b = b `seq` ()
 instance NFData ScrubbedBytes where rnf b = b `seq` ()
 instance NFData Integer  where rnf i = i `seq` ()
 #endif
--- a/Crypto/Internal/Imports.hs
+++ b/Crypto/Internal/Imports.hs
@ -5,11 +5,15 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
 {-# LANGUAGE CPP #-}
 module Crypto.Internal.Imports
    ( module X
    ) where
 import Data.Word               as X
 #if !(MIN_VERSION_base(4,11,0))
 import Data.Semigroup          as X (Semigroup(..))
 #endif
 import Control.Applicative     as X
 import Control.Monad           as X (forM, forM_, void)
 import Control.Arrow           as X (first, second)
--- a/Crypto/Internal/Nat.hs
+++ b/Crypto/Internal/Nat.hs
@ -0,0 +1,213 @@
 {-# LANGUAGE CPP #-}
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE ConstraintKinds #-}
 {-# LANGUAGE TypeOperators #-}
 {-# LANGUAGE TypeFamilies #-}
 {-# LANGUAGE UndecidableInstances #-}
 module Crypto.Internal.Nat
    ( type IsDivisibleBy8
    , type IsAtMost, type IsAtLeast
    , byteLen
    , integralNatVal
    , type IsDiv8
    , type Div8
    , type Mod8
    ) where
 import           GHC.TypeLits
 byteLen :: (KnownNat bitlen, Num a) => proxy bitlen -> a
 byteLen d = fromInteger ((natVal d + 7) `div` 8)
 integralNatVal :: (KnownNat bitlen, Num a) => proxy bitlen -> a
 integralNatVal = fromInteger . natVal
 type family IsLE (bitlen :: Nat) (n :: Nat) (c :: Bool) where
    IsLE _ _ 'True  = 'True
 #if MIN_VERSION_base(4,9,0)
    IsLE bitlen n 'False = TypeError
      (     ('Text "bitlen " ':<>: 'ShowType bitlen ':<>: 'Text " is greater than " ':<>: 'ShowType n)
      ':$$: ('Text "You have tried to use an invalid Digest size. Please, refer to the documentation.")
      )
 #else
    IsLE bitlen n 'False = 'False
 #endif
 -- | ensure the given `bitlen` is lesser or equal to `n`
 --
 type IsAtMost  (bitlen :: Nat) (n :: Nat) = IsLE bitlen n (bitlen <=? n) ~ 'True
 type family IsGE (bitlen :: Nat) (n :: Nat) (c :: Bool) where
    IsGE _ _ 'True  = 'True
 #if MIN_VERSION_base(4,9,0)
    IsGE bitlen n 'False = TypeError
      (     ('Text "bitlen " ':<>: 'ShowType bitlen ':<>: 'Text " is lesser than " ':<>: 'ShowType n)
      ':$$: ('Text "You have tried to use an invalid Digest size. Please, refer to the documentation.")
      )
 #else
    IsGE bitlen n 'False = 'False
 #endif
 -- | ensure the given `bitlen` is greater or equal to `n`
 --
 type IsAtLeast (bitlen :: Nat) (n :: Nat) = IsGE bitlen n (n <=? bitlen) ~ 'True
 type family Div8 (bitLen :: Nat) where
    Div8 0 = 0
    Div8 1 = 0
    Div8 2 = 0
    Div8 3 = 0
    Div8 4 = 0
    Div8 5 = 0
    Div8 6 = 0
    Div8 7 = 0
    Div8 8 = 1
    Div8 9 = 1
    Div8 10 = 1
    Div8 11 = 1
    Div8 12 = 1
    Div8 13 = 1
    Div8 14 = 1
    Div8 15 = 1
    Div8 16 = 2
    Div8 17 = 2
    Div8 18 = 2
    Div8 19 = 2
    Div8 20 = 2
    Div8 21 = 2
    Div8 22 = 2
    Div8 23 = 2
    Div8 24 = 3
    Div8 25 = 3
    Div8 26 = 3
    Div8 27 = 3
    Div8 28 = 3
    Div8 29 = 3
    Div8 30 = 3
    Div8 31 = 3
    Div8 32 = 4
    Div8 33 = 4
    Div8 34 = 4
    Div8 35 = 4
    Div8 36 = 4
    Div8 37 = 4
    Div8 38 = 4
    Div8 39 = 4
    Div8 40 = 5
    Div8 41 = 5
    Div8 42 = 5
    Div8 43 = 5
    Div8 44 = 5
    Div8 45 = 5
    Div8 46 = 5
    Div8 47 = 5
    Div8 48 = 6
    Div8 49 = 6
    Div8 50 = 6
    Div8 51 = 6
    Div8 52 = 6
    Div8 53 = 6
    Div8 54 = 6
    Div8 55 = 6
    Div8 56 = 7
    Div8 57 = 7
    Div8 58 = 7
    Div8 59 = 7
    Div8 60 = 7
    Div8 61 = 7
    Div8 62 = 7
    Div8 63 = 7
    Div8 64 = 8
    Div8 n  = 8 + Div8 (n - 64)
 type family IsDiv8 (bitLen :: Nat) (n :: Nat) where
    IsDiv8 _ 0 = 'True
 #if MIN_VERSION_base(4,9,0)
    IsDiv8 bitLen 1 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
    IsDiv8 bitLen 2 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
    IsDiv8 bitLen 3 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
    IsDiv8 bitLen 4 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
    IsDiv8 bitLen 5 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
    IsDiv8 bitLen 6 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
    IsDiv8 bitLen 7 = TypeError ('Text "bitLen " ':<>: 'ShowType bitLen ':<>: 'Text " is not divisible by 8")
 #else
    IsDiv8 _ 1 = 'False
    IsDiv8 _ 2 = 'False
    IsDiv8 _ 3 = 'False
    IsDiv8 _ 4 = 'False
    IsDiv8 _ 5 = 'False
    IsDiv8 _ 6 = 'False
    IsDiv8 _ 7 = 'False
 #endif
    IsDiv8 _ n = IsDiv8 n (Mod8 n)
 type family Mod8 (n :: Nat) where
    Mod8 0 = 0
    Mod8 1 = 1
    Mod8 2 = 2
    Mod8 3 = 3
    Mod8 4 = 4
    Mod8 5 = 5
    Mod8 6 = 6
    Mod8 7 = 7
    Mod8 8 = 0
    Mod8 9 = 1
    Mod8 10 = 2
    Mod8 11 = 3
    Mod8 12 = 4
    Mod8 13 = 5
    Mod8 14 = 6
    Mod8 15 = 7
    Mod8 16 = 0
    Mod8 17 = 1
    Mod8 18 = 2
    Mod8 19 = 3
    Mod8 20 = 4
    Mod8 21 = 5
    Mod8 22 = 6
    Mod8 23 = 7
    Mod8 24 = 0
    Mod8 25 = 1
    Mod8 26 = 2
    Mod8 27 = 3
    Mod8 28 = 4
    Mod8 29 = 5
    Mod8 30 = 6
    Mod8 31 = 7
    Mod8 32 = 0
    Mod8 33 = 1
    Mod8 34 = 2
    Mod8 35 = 3
    Mod8 36 = 4
    Mod8 37 = 5
    Mod8 38 = 6
    Mod8 39 = 7
    Mod8 40 = 0
    Mod8 41 = 1
    Mod8 42 = 2
    Mod8 43 = 3
    Mod8 44 = 4
    Mod8 45 = 5
    Mod8 46 = 6
    Mod8 47 = 7
    Mod8 48 = 0
    Mod8 49 = 1
    Mod8 50 = 2
    Mod8 51 = 3
    Mod8 52 = 4
    Mod8 53 = 5
    Mod8 54 = 6
    Mod8 55 = 7
    Mod8 56 = 0
    Mod8 57 = 1
    Mod8 58 = 2
    Mod8 59 = 3
    Mod8 60 = 4
    Mod8 61 = 5
    Mod8 62 = 6
    Mod8 63 = 7
    Mod8 n = Mod8 (n - 64)
 -- | ensure the given `bitlen` is divisible by 8
 --
 type IsDivisibleBy8 bitLen = IsDiv8 bitLen bitLen ~ 'True
--- a/Crypto/Internal/Proxy.hs
+++ b/Crypto/Internal/Proxy.hs
@ -1,13 +0,0 @@
 -- |
 -- Module      : Crypto.Internal.Proxy
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : experimental
 -- Portability : Good
 --
 module Crypto.Internal.Proxy
    ( Proxy(..)
    ) where
 -- | A type witness for 'a' as phantom type
 data Proxy a = Proxy
--- a/Crypto/Internal/WordArray.hs
+++ b/Crypto/Internal/WordArray.hs
@ -1,5 +1,5 @@
 -- |
-- Module      : Crypto.Internal.Compat
+-- Module      : Crypto.Internal.WordArray
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : stable
@ -8,7 +8,7 @@
 -- Small and self contained array representation
 -- with limited safety for internal use.
 --
-- the array produced should never be exposed to the user directly
+-- The array produced should never be exposed to the user directly.
 --
 {-# LANGUAGE BangPatterns #-}
 {-# LANGUAGE MagicHash #-}
@ -20,6 +20,8 @@ module Crypto.Internal.WordArray
    , MutableArray32
    , array8
    , array32
    , array32FromAddrBE
    , allocArray32AndFreeze
    , mutableArray32
    , array64
    , arrayRead8
@ -58,21 +60,21 @@ array8 = Array8
 -- | Create an Array of Word32 of specific size from a list of Word32
 array32 :: Int -> [Word32] -> Array32
-array32 (I# n) l = unsafeDoIO $ IO $ \s ->
+array32 n l = unsafeDoIO (mutableArray32 n l >>= mutableArray32Freeze)
    case newAlignedPinnedByteArray# (n *# 4#) 4# s of
        (# s', mbarr #) -> loop 0# s' mbarr l
  where
        loop _ st mb [] = freezeArray mb st
        loop i st mb ((W32# x):xs)
            | booleanPrim (i ==# n) = freezeArray mb st
            | otherwise =
                let !st' = writeWord32Array# mb i x st
                 in loop (i +# 1#) st' mb xs
        freezeArray mb st =
            case unsafeFreezeByteArray# mb st of
                (# st', b #) -> (# st', Array32 b #)
 {-# NOINLINE array32 #-}
 -- | Create an Array of BE Word32 aliasing an Addr
 array32FromAddrBE :: Int -> Addr# -> Array32
 array32FromAddrBE n a =
    unsafeDoIO (mutableArray32FromAddrBE n a >>= mutableArray32Freeze)
 {-# NOINLINE array32FromAddrBE #-}
 -- | Create an Array of Word32 using an initializer
 allocArray32AndFreeze :: Int -> (MutableArray32 -> IO ()) -> Array32
 allocArray32AndFreeze n f =
    unsafeDoIO (mutableArray32 n [] >>= \m -> f m >> mutableArray32Freeze m)
 {-# NOINLINE allocArray32AndFreeze #-}
 -- | Create an Array of Word64 of specific size from a list of Word64
 array64 :: Int -> [Word64] -> Array64
 array64 (I# n) l = unsafeDoIO $ IO $ \s ->
--- a/Crypto/KDF/Argon2.hs
+++ b/Crypto/KDF/Argon2.hs
@ -0,0 +1,157 @@
 -- |
 -- Module      : Crypto.KDF.Argon2
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : experimental
 -- Portability : unknown
 --
 -- Argon2 hashing function (P-H-C winner)
 --
 -- Recommended to use this module qualified
 --
 -- File started from Argon2.hs, from Oliver Charles
 -- at https://github.com/ocharles/argon2
 --
 module Crypto.KDF.Argon2
    (
      Options(..)
    , TimeCost
    , MemoryCost
    , Parallelism
    , Variant(..)
    , Version(..)
    , defaultOptions
    -- * Hashing function
    , hash
    ) where
 import           Crypto.Internal.ByteArray (ByteArray, ByteArrayAccess)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Error
 import           Control.Monad (when)
 import           Data.Word
 import           Foreign.C
 import           Foreign.Ptr
 -- | Which variant of Argon2 to use. You should choose the variant that is most
 -- applicable to your intention to hash inputs.
 data Variant =
      Argon2d  -- ^ Argon2d is faster than Argon2i and uses data-depending memory access,
               -- which makes it suitable for cryptocurrencies and applications with no
               -- threats from side-channel timing attacks.
    | Argon2i  -- ^ Argon2i uses data-independent memory access, which is preferred
               -- for password hashing and password-based key derivation. Argon2i
               -- is slower as it makes more passes over the memory to protect from
               -- tradeoff attacks.
    | Argon2id -- ^ Argon2id is a hybrid of Argon2i and Argon2d, using a combination
               -- of data-depending and data-independent memory accesses, which gives
               -- some of Argon2i's resistance to side-channel cache timing attacks
               -- and much of Argon2d's resistance to GPU cracking attacks
    deriving (Eq,Ord,Read,Show,Enum,Bounded)
 -- | Which version of Argon2 to use
 data Version = Version10 | Version13
    deriving (Eq,Ord,Read,Show,Enum,Bounded)
 -- | The time cost, which defines the amount of computation realized and therefore the execution time, given in number of iterations.
 --
 -- 'FFI.ARGON2_MIN_TIME' <= 'hashIterations' <= 'FFI.ARGON2_MAX_TIME'
 type TimeCost = Word32
 -- | The memory cost, which defines the memory usage, given in kibibytes.
 --
 -- max 'FFI.ARGON2_MIN_MEMORY' (8 * 'hashParallelism') <= 'hashMemory' <= 'FFI.ARGON2_MAX_MEMORY'
 type MemoryCost = Word32
 -- | A parallelism degree, which defines the number of parallel threads.
 --
 -- 'FFI.ARGON2_MIN_LANES' <= 'hashParallelism' <= 'FFI.ARGON2_MAX_LANES' && 'FFI.ARGON_MIN_THREADS' <= 'hashParallelism' <= 'FFI.ARGON2_MAX_THREADS'
 type Parallelism = Word32
 -- | Parameters that can be adjusted to change the runtime performance of the
 -- hashing.
 data Options = Options
    { iterations  :: !TimeCost
    , memory      :: !MemoryCost
    , parallelism :: !Parallelism
    , variant     :: !Variant     -- ^ Which variant of Argon2 to use.
    , version     :: !Version     -- ^ Which version of Argon2 to use.
    }
    deriving (Eq,Ord,Read,Show)
 saltMinLength :: Int
 saltMinLength = 8
 outputMinLength :: Int
 outputMinLength = 4
 -- specification allows up to 2^32-1 but this is too big for a signed Int
 -- on a 32-bit architecture, so we limit tag length to 2^31-1 bytes
 outputMaxLength :: Int
 outputMaxLength = 0x7fffffff
 defaultOptions :: Options
 defaultOptions =
    Options { iterations  = 1
            , memory      = 2 ^ (17 :: Int)
            , parallelism = 4
            , variant     = Argon2i
            , version     = Version13
            }
 hash :: (ByteArrayAccess password, ByteArrayAccess salt, ByteArray out)
     => Options
     -> password
     -> salt
     -> Int
     -> CryptoFailable out
 hash options password salt outLen
    | saltLen < saltMinLength  = CryptoFailed CryptoError_SaltTooSmall
    | outLen < outputMinLength = CryptoFailed CryptoError_OutputLengthTooSmall
    | outLen > outputMaxLength = CryptoFailed CryptoError_OutputLengthTooBig
    | otherwise                = CryptoPassed $ B.allocAndFreeze outLen $ \out -> do
        res <- B.withByteArray password $ \pPass ->
               B.withByteArray salt     $ \pSalt ->
                    argon2_hash (iterations options)
                                (memory options)
                                (parallelism options)
                                pPass
                                (csizeOfInt passwordLen)
                                pSalt
                                (csizeOfInt saltLen)
                                out
                                (csizeOfInt outLen)
                                (cOfVariant $ variant options)
                                (cOfVersion $ version options)
        when (res /= 0) $ error "argon2: hash: internal error"
  where
    saltLen = B.length salt
    passwordLen = B.length password
 data Pass
 data Salt
 data HashOut
 type CVariant = CInt -- valid value is 0 (Argon2d), 1 (Argon2i) and 2 (Argon2id)
 type CVersion = CInt -- valid value is 0x10, 0x13
 cOfVersion :: Version -> CVersion
 cOfVersion Version10 = 0x10
 cOfVersion Version13 = 0x13
 cOfVariant :: Variant -> CVariant
 cOfVariant Argon2d  = 0
 cOfVariant Argon2i  = 1
 cOfVariant Argon2id = 2
 csizeOfInt :: Int -> CSize
 csizeOfInt = fromIntegral
 foreign import ccall unsafe "cryptonite_argon2_hash"
    argon2_hash :: Word32 -> Word32 -> Word32
                -> Ptr Pass -> CSize
                -> Ptr Salt -> CSize
                -> Ptr HashOut -> CSize
                -> CVariant
                -> CVersion
                -> IO CInt
--- a/Crypto/KDF/BCrypt.hs
+++ b/Crypto/KDF/BCrypt.hs
@ -11,7 +11,7 @@
 -- >>> validatePassword password bcryptHash
 -- >>> True
 -- >>> let otherPassword = B.pack "otherpassword"
-- >>> otherHash <- hashPassword 12 otherPasssword :: IO B.ByteString
+-- >>> otherHash <- hashPassword 12 otherPassword :: IO B.ByteString
 -- >>> validatePassword otherPassword otherHash
 -- >>> True
 --
@ -27,13 +27,16 @@
 -- salt and hash bytes (each separately Base64 encoded. Incrementing the
 -- cost parameter approximately doubles the time taken to calculate the hash.
 --
-- The different version numbers have evolved because of bugs in the standard
+-- The different version numbers evolved to account for bugs in the standard
-- C implementations. The most up to date version is @2b@ and this
+-- C implementations. They don't represent different versions of the algorithm
-- implementation the @2b@ version prefix, but will also attempt to validate
+-- itself and in most cases should produce identical results.
 -- The most up to date version is @2b@ and this implementation uses the
 -- @2b@ version prefix, but will also attempt to validate
 -- against hashes with versions @2a@ and @2y@. Version @2@ or @2x@ will be
 -- rejected. No attempt is made to differentiate between the different versions
 -- when validating a password, but in practice this shouldn't cause any problems
-- if passwords are UTF-8 encoded (which they should be).
+-- if passwords are UTF-8 encoded (which they should be) and less than 256
 -- characters long.
 --
 -- The cost parameter can be between 4 and 31 inclusive, but anything less than
 -- 10 is probably not strong enough. High values may be prohibitively slow
@ -49,10 +52,15 @@ module Crypto.KDF.BCrypt
    )
 where
-import           Control.Monad (unless, when)
+import           Control.Monad                    (forM_, unless, when)
-import           Crypto.Cipher.Blowfish.Primitive (eksBlowfish, encrypt)
+import           Crypto.Cipher.Blowfish.Primitive (Context, createKeySchedule,
                                                   encrypt, expandKey,
                                                   expandKeyWithSalt,
                                                   freezeKeySchedule)
 import           Crypto.Internal.Compat
 import           Crypto.Random                    (MonadRandom, getRandomBytes)
-import           Data.ByteArray (ByteArrayAccess, ByteArray, Bytes)
+import           Data.ByteArray                   (ByteArray, ByteArrayAccess,
                                                   Bytes)
 import qualified Data.ByteArray                   as B
 import           Data.ByteArray.Encoding
 import           Data.Char
@ -93,7 +101,7 @@ bcrypt :: (ByteArray salt, ByteArray password, ByteArray output)
 bcrypt cost salt password = B.concat [header, B.snoc costBytes dollar, b64 salt, b64 hash]
  where
    hash   = rawHash 'b' realCost salt password
-    header = B.pack [dollar, fromIntegral (ord '2'), fromIntegral (ord 'a'), dollar]
+    header = B.pack [dollar, fromIntegral (ord '2'), fromIntegral (ord 'b'), dollar]
    dollar = fromIntegral (ord '$')
    zero   = fromIntegral (ord '0')
    costBytes  = B.pack [zero + fromIntegral (realCost `div` 10), zero + fromIntegral (realCost `mod` 10)]
@ -133,7 +141,7 @@ rawHash _ cost salt password = B.take 23 hash -- Another compatibility bug. Igno
    -- Truncate the password if necessary and append a null byte for C compatibility
    key = B.snoc (B.take 72 password) 0
-    ctx = eksBlowfish cost salt key
+    ctx = expensiveBlowfishContext key salt cost
    -- The BCrypt plaintext: "OrpheanBeholderScryDoubt"
    orpheanBeholder = B.pack [79,114,112,104,101,97,110,66,101,104,111,108,100,101,114,83,99,114,121,68,111,117,98,116]
@ -156,10 +164,26 @@ parseBCryptHash bc = do
    costTens  = fromIntegral (B.index bc 4) - zero
    costUnits = fromIntegral (B.index bc 5) - zero
    version   = chr (fromIntegral (B.index bc 2))
-    cost      = costUnits + (if costTens == 0 then 0 else 10^costTens) :: Int
+    cost      = costUnits + 10*costTens :: Int
    decodeSaltHash saltHash = do
        let (s, h) = B.splitAt 22 saltHash
        salt <- convertFromBase Base64OpenBSD s
        hash <- convertFromBase Base64OpenBSD h
        return (salt, hash)
 -- | Create a key schedule for the BCrypt "EKS" version.
 --
 -- Salt must be a 128-bit byte array.
 -- Cost must be between 4 and 31 inclusive
 -- See <https://www.usenix.org/conference/1999-usenix-annual-technical-conference/future-adaptable-password-scheme>
 expensiveBlowfishContext :: (ByteArrayAccess key, ByteArrayAccess salt) => key-> salt -> Int -> Context
 expensiveBlowfishContext keyBytes saltBytes cost
  | B.length saltBytes /= 16 = error "bcrypt salt must be 16 bytes"
  | otherwise = unsafeDoIO $ do
        ks <- createKeySchedule
        expandKeyWithSalt ks keyBytes saltBytes
        forM_ [1..2^cost :: Int] $ \_ -> do
            expandKey ks keyBytes
            expandKey ks saltBytes
        freezeKeySchedule ks
--- a/Crypto/KDF/BCryptPBKDF.hs
+++ b/Crypto/KDF/BCryptPBKDF.hs
@ -0,0 +1,187 @@
 -- |
 -- Module      : Crypto.KDF.BCryptPBKDF
 -- License     : BSD-style
 -- Stability   : experimental
 -- Portability : Good
 --
 -- Port of the bcrypt_pbkdf key derivation function from OpenBSD
 -- as described at <http://man.openbsd.org/bcrypt_pbkdf.3>.
 module Crypto.KDF.BCryptPBKDF
    ( Parameters (..)
    , generate
    , hashInternal
    )
 where
 import           Basement.Block                   (MutableBlock)
 import qualified Basement.Block                   as Block
 import qualified Basement.Block.Mutable           as Block
 import           Basement.Monad                   (PrimState)
 import           Basement.Types.OffsetSize        (CountOf (..), Offset (..))
 import           Control.Exception                (finally)
 import           Control.Monad                    (when)
 import qualified Crypto.Cipher.Blowfish.Box       as Blowfish
 import qualified Crypto.Cipher.Blowfish.Primitive as Blowfish
 import           Crypto.Hash.Algorithms           (SHA512 (..))
 import           Crypto.Hash.Types                (Context,
                                                   hashDigestSize,
                                                   hashInternalContextSize,
                                                   hashInternalFinalize,
                                                   hashInternalInit,
                                                   hashInternalUpdate)
 import           Crypto.Internal.Compat           (unsafeDoIO)
 import           Data.Bits
 import qualified Data.ByteArray                   as B
 import           Data.Foldable                    (forM_)
 import           Data.Memory.PtrMethods           (memCopy, memSet, memXor)
 import           Data.Word
 import           Foreign.Ptr                      (Ptr, castPtr)
 import           Foreign.Storable                 (peekByteOff, pokeByteOff)
 data Parameters = Parameters
  { iterCounts   :: Int -- ^ The number of user-defined iterations for the algorithm
                        --   (must be > 0)
  , outputLength :: Int -- ^ The number of bytes to generate out of BCryptPBKDF
                        --   (must be in 1..1024)
  } deriving (Eq, Ord, Show)
 -- | Derive a key of specified length using the bcrypt_pbkdf algorithm.
 generate :: (B.ByteArray pass, B.ByteArray salt, B.ByteArray output)
       => Parameters
       -> pass
       -> salt
       -> output
 generate params pass salt
    | iterCounts params < 1       = error "BCryptPBKDF: iterCounts must be > 0"
    | keyLen < 1 || keyLen > 1024 = error "BCryptPBKDF: outputLength must be in 1..1024"
    | otherwise                   = B.unsafeCreate keyLen deriveKey
  where
    outLen, tmpLen, blkLen, keyLen, passLen, saltLen, ctxLen, hashLen, blocks :: Int
    outLen  = 32
    tmpLen  = 32
    blkLen  = 4
    passLen = B.length pass
    saltLen = B.length salt
    keyLen  = outputLength params
    ctxLen  = hashInternalContextSize SHA512
    hashLen = hashDigestSize SHA512 -- 64
    blocks  = (keyLen + outLen - 1) `div` outLen
    deriveKey :: Ptr Word8 -> IO ()
    deriveKey keyPtr = do
        -- Allocate all necessary memory. The algorihm shall not allocate
        -- any more dynamic memory after this point. Blocks need to be pinned
        -- as pointers to them are passed to the SHA512 implementation.
        ksClean        <- Blowfish.createKeySchedule
        ksDirty        <- Blowfish.createKeySchedule
        ctxMBlock      <- Block.newPinned (CountOf ctxLen  :: CountOf Word8)
        outMBlock      <- Block.newPinned (CountOf outLen  :: CountOf Word8)
        tmpMBlock      <- Block.newPinned (CountOf tmpLen  :: CountOf Word8)
        blkMBlock      <- Block.newPinned (CountOf blkLen  :: CountOf Word8)
        passHashMBlock <- Block.newPinned (CountOf hashLen :: CountOf Word8)
        saltHashMBlock <- Block.newPinned (CountOf hashLen :: CountOf Word8)
        -- Finally erase all memory areas that contain information from
        -- which the derived key could be reconstructed.
        -- As all MutableBlocks are pinned it shall be guaranteed that
        -- no temporary trampoline buffers are allocated.
        finallyErase outMBlock $ finallyErase passHashMBlock $
            B.withByteArray pass                $ \passPtr->
            B.withByteArray salt                $ \saltPtr->
            Block.withMutablePtr ctxMBlock      $ \ctxPtr->
            Block.withMutablePtr outMBlock      $ \outPtr->
            Block.withMutablePtr tmpMBlock      $ \tmpPtr->
            Block.withMutablePtr blkMBlock      $ \blkPtr->
            Block.withMutablePtr passHashMBlock $ \passHashPtr->
            Block.withMutablePtr saltHashMBlock $ \saltHashPtr-> do
                -- Hash the password.
                let shaPtr = castPtr ctxPtr :: Ptr (Context SHA512)
                hashInternalInit     shaPtr
                hashInternalUpdate   shaPtr passPtr (fromIntegral passLen)
                hashInternalFinalize shaPtr (castPtr passHashPtr)
                passHashBlock <- Block.unsafeFreeze passHashMBlock
                forM_ [1..blocks] $ \block-> do
                    -- Poke the increased block counter.
                    Block.unsafeWrite blkMBlock 0 (fromIntegral $ block `shiftR` 24)
                    Block.unsafeWrite blkMBlock 1 (fromIntegral $ block `shiftR` 16)
                    Block.unsafeWrite blkMBlock 2 (fromIntegral $ block `shiftR`  8)
                    Block.unsafeWrite blkMBlock 3 (fromIntegral $ block `shiftR`  0)
                    -- First round (slightly different).
                    hashInternalInit     shaPtr
                    hashInternalUpdate   shaPtr saltPtr (fromIntegral saltLen)
                    hashInternalUpdate   shaPtr blkPtr  (fromIntegral blkLen)
                    hashInternalFinalize shaPtr (castPtr saltHashPtr)
                    Block.unsafeFreeze saltHashMBlock >>= \x-> do
                        Blowfish.copyKeySchedule ksDirty ksClean
                        hashInternalMutable ksDirty passHashBlock x tmpMBlock
                    memCopy outPtr tmpPtr outLen
                    -- Remaining rounds.
                    forM_ [2..iterCounts params] $ const $ do
                        hashInternalInit     shaPtr
                        hashInternalUpdate   shaPtr tmpPtr (fromIntegral tmpLen)
                        hashInternalFinalize shaPtr (castPtr saltHashPtr)
                        Block.unsafeFreeze saltHashMBlock >>= \x-> do
                            Blowfish.copyKeySchedule ksDirty ksClean
                            hashInternalMutable ksDirty passHashBlock x tmpMBlock
                        memXor outPtr outPtr tmpPtr outLen
                    -- Spread the current out buffer evenly over the key buffer.
                    -- After both loops have run every byte of the key buffer
                    -- will have been written to exactly once and every byte
                    -- of the output will have been used.
                    forM_ [0..outLen - 1] $ \outIdx-> do
                        let keyIdx = outIdx * blocks + block - 1
                        when (keyIdx < keyLen) $ do
                            w8 <- peekByteOff outPtr outIdx :: IO Word8
                            pokeByteOff keyPtr keyIdx w8
 -- | Internal hash function used by `generate`.
 --
 -- Normal users should not need this.
 hashInternal :: (B.ByteArrayAccess pass, B.ByteArrayAccess salt, B.ByteArray output)
    => pass
    -> salt
    -> output
 hashInternal passHash saltHash
    | B.length passHash /= 64 = error "passHash must be 512 bits"
    | B.length saltHash /= 64 = error "saltHash must be 512 bits"
    | otherwise = unsafeDoIO $ do
        ks0 <- Blowfish.createKeySchedule
        outMBlock <- Block.newPinned 32
        hashInternalMutable ks0 passHash saltHash outMBlock
        B.convert `fmap` Block.freeze outMBlock
 hashInternalMutable :: (B.ByteArrayAccess pass, B.ByteArrayAccess salt)
    => Blowfish.KeySchedule
    -> pass
    -> salt
    -> MutableBlock Word8 (PrimState IO)
    -> IO ()
 hashInternalMutable bfks passHash saltHash outMBlock = do
    Blowfish.expandKeyWithSalt bfks passHash saltHash
    forM_ [0..63 :: Int] $ const $ do
        Blowfish.expandKey bfks saltHash
        Blowfish.expandKey bfks passHash
    -- "OxychromaticBlowfishSwatDynamite" represented as 4 Word64 in big-endian.
    store  0 =<< cipher 64 0x4f78796368726f6d
    store  8 =<< cipher 64 0x61746963426c6f77
    store 16 =<< cipher 64 0x6669736853776174
    store 24 =<< cipher 64 0x44796e616d697465
    where
        store :: Offset Word8 -> Word64 -> IO ()
        store o w64 = do
            Block.unsafeWrite outMBlock (o + 0) (fromIntegral $ w64 `shiftR` 32)
            Block.unsafeWrite outMBlock (o + 1) (fromIntegral $ w64 `shiftR` 40)
            Block.unsafeWrite outMBlock (o + 2) (fromIntegral $ w64 `shiftR` 48)
            Block.unsafeWrite outMBlock (o + 3) (fromIntegral $ w64 `shiftR` 56)
            Block.unsafeWrite outMBlock (o + 4) (fromIntegral $ w64 `shiftR`  0)
            Block.unsafeWrite outMBlock (o + 5) (fromIntegral $ w64 `shiftR`  8)
            Block.unsafeWrite outMBlock (o + 6) (fromIntegral $ w64 `shiftR` 16)
            Block.unsafeWrite outMBlock (o + 7) (fromIntegral $ w64 `shiftR` 24)
        cipher :: Int -> Word64 -> IO Word64
        cipher 0 block = return block
        cipher i block = Blowfish.cipherBlockMutable bfks block >>= cipher (i - 1)
 finallyErase :: MutableBlock Word8 (PrimState IO) -> IO () -> IO ()
 finallyErase mblock action =
    action `finally` Block.withMutablePtr mblock (\ptr-> memSet ptr 0 len)
    where
        CountOf len = Block.mutableLengthBytes mblock
--- a/Crypto/KDF/PBKDF2.hs
+++ b/Crypto/KDF/PBKDF2.hs
@ -24,7 +24,7 @@ import           Data.Word
 import           Data.Bits
 import           Foreign.Marshal.Alloc
 import           Foreign.Ptr (plusPtr, Ptr)
-import           Foreign.C.Types (CUInt(..), CInt(..), CSize(..))
+import           Foreign.C.Types (CUInt(..), CSize(..))
 import           Crypto.Hash (HashAlgorithm)
 import qualified Crypto.MAC.HMAC as HMAC
--- a/Crypto/MAC/CMAC.hs
+++ b/Crypto/MAC/CMAC.hs
@ -5,7 +5,7 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- provide the CMAC (Cipher based Message Authentification Code) base algorithm.
+-- Provide the CMAC (Cipher based Message Authentification Code) base algorithm.
 -- <http://en.wikipedia.org/wiki/CMAC>
 -- <http://csrc.nist.gov/publications/nistpubs/800-38B/SP_800-38B.pdf>
 --
@ -94,7 +94,7 @@ bxor = B.xor
 cipherIPT :: BlockCipher k => k -> [Word8]
-cipherIPT = expandIPT . blockSize   where
+cipherIPT = expandIPT . blockSize
 -- Data type which represents the smallest irreducibule binary polynomial
 -- against specified degree.
--- a/Crypto/MAC/HMAC.hs
+++ b/Crypto/MAC/HMAC.hs
@ -5,15 +5,16 @@
 -- Stability   : experimental
 -- Portability : unknown
 --
-- provide the HMAC (Hash based Message Authentification Code) base algorithm.
+-- Provide the HMAC (Hash based Message Authentification Code) base algorithm.
 -- <http://en.wikipedia.org/wiki/HMAC>
 --
 {-# LANGUAGE BangPatterns #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 module Crypto.MAC.HMAC
    ( hmac
    , hmacLazy
    , HMAC(..)
-    -- * incremental
+    -- * Incremental
    , Context(..)
    , initialize
    , update
@ -24,28 +25,36 @@ module Crypto.MAC.HMAC
 import           Crypto.Hash hiding (Context)
 import qualified Crypto.Hash as Hash (Context)
 import           Crypto.Hash.IO
-import           Crypto.Internal.ByteArray (ScrubbedBytes, ByteArray, ByteArrayAccess)
+import           Crypto.Internal.ByteArray (ScrubbedBytes, ByteArrayAccess)
 import qualified Crypto.Internal.ByteArray as B
 import           Data.Memory.PtrMethods
 import           Crypto.Internal.Compat
-import           Crypto.Internal.Imports
+import qualified Data.ByteString.Lazy as L
 -- | Represent an HMAC that is a phantom type with the hash used to produce the mac.
 --
-- The Eq instance is constant time.
+-- The Eq instance is constant time.  No Show instance is provided, to avoid
 -- printing by mistake.
 newtype HMAC a = HMAC { hmacGetDigest :: Digest a }
    deriving (ByteArrayAccess)
 instance Eq (HMAC a) where
    (HMAC b1) == (HMAC b2) = B.constEq b1 b2
-- | compute a MAC using the supplied hashing function
+-- | Compute a MAC using the supplied hashing function
 hmac :: (ByteArrayAccess key, ByteArrayAccess message, HashAlgorithm a)
     => key     -- ^ Secret key
     -> message -- ^ Message to MAC
     -> HMAC a
 hmac secret msg = finalize $ updates (initialize secret) [msg]
 -- | Compute a MAC using the supplied hashing function, for a lazy input
 hmacLazy :: (ByteArrayAccess key, HashAlgorithm a)
     => key     -- ^ Secret key
     -> L.ByteString -- ^ Message to MAC
     -> HMAC a
 hmacLazy secret msg = finalize $ updates (initialize secret) (L.toChunks msg)
 -- | Represent an ongoing HMAC state, that can be appended with 'update'
 -- and finalize to an HMAC with 'hmacFinalize'
 data Context hashalg = Context !(Hash.Context hashalg) !(Hash.Context hashalg)
--- a/Crypto/MAC/KMAC.hs
+++ b/Crypto/MAC/KMAC.hs
@ -0,0 +1,144 @@
 -- |
 -- Module      : Crypto.MAC.KMAC
 -- License     : BSD-style
 -- Maintainer  : Olivier Chéron <olivier.cheron@gmail.com>
 -- Stability   : experimental
 -- Portability : unknown
 --
 -- Provide the KMAC (Keccak Message Authentication Code) algorithm, derived from
 -- the SHA-3 base algorithm Keccak and defined in NIST SP800-185.
 --
 {-# LANGUAGE BangPatterns #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE ScopedTypeVariables #-}
 module Crypto.MAC.KMAC
    ( HashSHAKE
    , kmac
    , KMAC(..)
    -- * Incremental
    , Context
    , initialize
    , update
    , updates
    , finalize
    ) where
 import qualified Crypto.Hash as H
 import           Crypto.Hash.SHAKE (HashSHAKE(..))
 import           Crypto.Hash.Types (HashAlgorithm(..), Digest(..))
 import qualified Crypto.Hash.Types as H
 import           Crypto.Internal.Builder
 import           Crypto.Internal.Imports
 import           Foreign.Ptr (Ptr)
 import           Data.Bits (shiftR)
 import           Data.ByteArray (ByteArrayAccess)
 import qualified Data.ByteArray as B
 -- cSHAKE
 cshakeInit :: forall a name string prefix . (HashSHAKE a, ByteArrayAccess name, ByteArrayAccess string, ByteArrayAccess prefix)
           => name -> string -> prefix -> H.Context a
 cshakeInit n s p = H.Context $ B.allocAndFreeze c $ \(ptr :: Ptr (H.Context a)) -> do
    hashInternalInit ptr
    B.withByteArray b $ \d -> hashInternalUpdate ptr d (fromIntegral $ B.length b)
    B.withByteArray p $ \d -> hashInternalUpdate ptr d (fromIntegral $ B.length p)
  where
    c = hashInternalContextSize (undefined :: a)
    w = hashBlockSize (undefined :: a)
    x = encodeString n <> encodeString s
    b = buildAndFreeze (bytepad x w) :: B.Bytes
 cshakeUpdate :: (HashSHAKE a, ByteArrayAccess ba)
             => H.Context a -> ba -> H.Context a
 cshakeUpdate = H.hashUpdate
 cshakeUpdates :: (HashSHAKE a, ByteArrayAccess ba)
              => H.Context a -> [ba] -> H.Context a
 cshakeUpdates = H.hashUpdates
 cshakeFinalize :: forall a suffix . (HashSHAKE a, ByteArrayAccess suffix)
               => H.Context a -> suffix -> Digest a
 cshakeFinalize !c s =
    Digest $ B.allocAndFreeze (hashDigestSize (undefined :: a)) $ \dig -> do
        ((!_) :: B.Bytes) <- B.copy c $ \(ctx :: Ptr (H.Context a)) -> do
            B.withByteArray s $ \d ->
                hashInternalUpdate ctx d (fromIntegral $ B.length s)
            cshakeInternalFinalize ctx dig
        return ()
 -- KMAC
 -- | Represent a KMAC that is a phantom type with the hash used to produce the
 -- mac.
 --
 -- The Eq instance is constant time.  No Show instance is provided, to avoid
 -- printing by mistake.
 newtype KMAC a = KMAC { kmacGetDigest :: Digest a }
    deriving (ByteArrayAccess,NFData)
 instance Eq (KMAC a) where
    (KMAC b1) == (KMAC b2) = B.constEq b1 b2
 -- | Compute a KMAC using the supplied customization string and key.
 kmac :: (HashSHAKE a, ByteArrayAccess string, ByteArrayAccess key, ByteArrayAccess ba)
     => string -> key -> ba -> KMAC a
 kmac str key msg = finalize $ updates (initialize str key) [msg]
 -- | Represent an ongoing KMAC state, that can be appended with 'update' and
 -- finalized to a 'KMAC' with 'finalize'.
 newtype Context a = Context (H.Context a)
 -- | Initialize a new incremental KMAC context with the supplied customization
 -- string and key.
 initialize :: forall a string key . (HashSHAKE a, ByteArrayAccess string, ByteArrayAccess key)
           => string -> key -> Context a
 initialize str key = Context $ cshakeInit n str p
  where
    n = B.pack [75,77,65,67] :: B.Bytes  -- "KMAC"
    w = hashBlockSize (undefined :: a)
    p = buildAndFreeze (bytepad (encodeString key) w) :: B.ScrubbedBytes
 -- | Incrementally update a KMAC context.
 update :: (HashSHAKE a, ByteArrayAccess ba) => Context a -> ba -> Context a
 update (Context ctx) = Context . cshakeUpdate ctx
 -- | Incrementally update a KMAC context with multiple inputs.
 updates :: (HashSHAKE a, ByteArrayAccess ba) => Context a -> [ba] -> Context a
 updates (Context ctx) = Context . cshakeUpdates ctx
 -- | Finalize a KMAC context and return the KMAC.
 finalize :: forall a . HashSHAKE a => Context a -> KMAC a
 finalize (Context ctx) = KMAC $ cshakeFinalize ctx suffix
  where
    l = cshakeOutputLength (undefined :: a)
    suffix = buildAndFreeze (rightEncode l) :: B.Bytes
 -- Utilities
 bytepad :: Builder -> Int -> Builder
 bytepad x w = prefix <> x <> zero padLen
  where
    prefix = leftEncode w
    padLen = (w - builderLength prefix - builderLength x) `mod` w
 encodeString :: ByteArrayAccess bin => bin -> Builder
 encodeString s = leftEncode (8 * B.length s) <> bytes s
 leftEncode :: Int -> Builder
 leftEncode x = byte len <> digits
  where
    digits = i2osp x
    len    = fromIntegral (builderLength digits)
 rightEncode :: Int -> Builder
 rightEncode x = digits <> byte len
  where
    digits = i2osp x
    len    = fromIntegral (builderLength digits)
 i2osp :: Int -> Builder
 i2osp i | i >= 256  = i2osp (shiftR i 8) <> byte (fromIntegral i)
        | otherwise = byte (fromIntegral i)
--- a/Crypto/MAC/Poly1305.hs
+++ b/Crypto/MAC/Poly1305.hs
@ -33,6 +33,11 @@ import           Crypto.Internal.DeepSeq
 import           Crypto.Error
 -- | Poly1305 State
 --
 -- This type is an instance of 'ByteArrayAccess' for debugging purpose. Internal
 -- layout is architecture dependent, may contain uninitialized data fragments,
 -- and change in future versions.  The bytearray should not be used as input to
 -- cryptographic algorithms.
 newtype State = State ScrubbedBytes
    deriving (ByteArrayAccess)
--- a/Crypto/Math/Polynomial.hs
+++ b/Crypto/Math/Polynomial.hs
@ -8,7 +8,7 @@
 module Crypto.Math.Polynomial
    ( Monomial(..)
-    -- * polynomial operations
+    -- * Polynomial operations
    , Polynomial
    , toList
    , fromList
--- a/Crypto/Number/Basic.hs
+++ b/Crypto/Number/Basic.hs
@ -13,12 +13,15 @@ module Crypto.Number.Basic
    , log2
    , numBits
    , numBytes
    , asPowerOf2AndOdd
    ) where
 import Data.Bits
 import Crypto.Number.Compat
-- | sqrti returns two integer (l,b) so that l <= sqrt i <= b
+-- | @sqrti@ returns two integers @(l,b)@ so that @l <= sqrt i <= b@.
-- the implementation is quite naive, use an approximation for the first number
+-- The implementation is quite naive, use an approximation for the first number
 -- and use a dichotomy algorithm to compute the bound relatively efficiently.
 sqrti :: Integer -> (Integer, Integer)
 sqrti i
@ -49,7 +52,7 @@ sqrti i
                        else iter (lb+d) ub
            sq a = a * a
-- | get the extended GCD of two integer using integer divMod
+-- | Get the extended GCD of two integer using integer divMod
 --
 -- gcde 'a' 'b' find (x,y,gcd(a,b)) where ax + by = d
 --
@ -63,7 +66,7 @@ gcde a b = onGmpUnsupported (gmpGcde a b) $
        let (q, r) = a' `divMod` b' in
        f t (r, sa - (q * sb), ta - (q * tb))
-- | check if a list of integer are all even
+-- | Check if a list of integer are all even
 areEven :: [Integer] -> Bool
 areEven = and . map even
@ -98,3 +101,16 @@ numBits n = gmpSizeInBits n `onGmpUnsupported` (if n == 0 then 1 else computeBit
 -- | Compute the number of bytes for an integer
 numBytes :: Integer -> Int
 numBytes n = gmpSizeInBytes n `onGmpUnsupported` ((numBits n + 7) `div` 8)
 -- | Express an integer as an odd number and a power of 2
 asPowerOf2AndOdd :: Integer -> (Int, Integer)
 asPowerOf2AndOdd a
    | a == 0       = (0, 0)
    | odd a        = (0, a)
    | a < 0        = let (e, a1) = asPowerOf2AndOdd $ abs a in (e, -a1)
    | isPowerOf2 a = (log2 a, 1)
    | otherwise    = loop a 0
        where      
          isPowerOf2 n = (n /= 0) && ((n .&. (n - 1)) == 0)
          loop n pw = if n `mod` 2 == 0 then loop (n `div` 2) (pw + 1)
                      else (pw, n)
--- a/Crypto/Number/Compat.hs
+++ b/Crypto/Number/Compat.hs
@ -22,7 +22,9 @@ module Crypto.Number.Compat
    , gmpSizeInBytes
    , gmpSizeInBits
    , gmpExportInteger
    , gmpExportIntegerLE
    , gmpImportInteger
    , gmpImportIntegerLE
    ) where
 #ifndef MIN_VERSION_integer_gmp
@ -70,7 +72,11 @@ gmpLog2 _ = GmpUnsupported
 -- | Compute the power modulus using extra security to remain constant
 -- time wise through GMP
 gmpPowModSecInteger :: Integer -> Integer -> Integer -> GmpSupported Integer
-#if MIN_VERSION_integer_gmp(1,0,0)
+#if MIN_VERSION_integer_gmp(1,1,0)
 gmpPowModSecInteger _ _ _ = GmpUnsupported
 #elif MIN_VERSION_integer_gmp(1,0,2)
 gmpPowModSecInteger b e m = GmpSupported (powModSecInteger b e m)
 #elif MIN_VERSION_integer_gmp(1,0,0)
 gmpPowModSecInteger _ _ _ = GmpUnsupported
 #elif MIN_VERSION_integer_gmp(0,5,1)
 gmpPowModSecInteger b e m = GmpSupported (powModSecInteger b e m)
@ -99,7 +105,9 @@ gmpInverse _ _ = GmpUnsupported
 -- | Get the next prime from a specific value through GMP
 gmpNextPrime :: Integer -> GmpSupported Integer
-#if MIN_VERSION_integer_gmp(0,5,1)
+#if MIN_VERSION_integer_gmp(1,1,0)
 gmpNextPrime _ = GmpUnsupported
 #elif MIN_VERSION_integer_gmp(0,5,1)
 gmpNextPrime n = GmpSupported (nextPrimeInteger n)
 #else
 gmpNextPrime _ = GmpUnsupported
@ -107,7 +115,9 @@ gmpNextPrime _ = GmpUnsupported
 -- | Test if a number is prime using Miller Rabin
 gmpTestPrimeMillerRabin :: Int -> Integer -> GmpSupported Bool
-#if MIN_VERSION_integer_gmp(0,5,1)
+#if MIN_VERSION_integer_gmp(1,1,0)
 gmpTestPrimeMillerRabin _ _ = GmpUnsupported
 #elif MIN_VERSION_integer_gmp(0,5,1)
 gmpTestPrimeMillerRabin (I# tries) !n = GmpSupported $
    case testPrimeInteger n tries of
        0# -> False
@ -132,7 +142,7 @@ gmpSizeInBits n = GmpSupported (I# (word2Int# (sizeInBaseInteger n 2#)))
 gmpSizeInBits _ = GmpUnsupported
 #endif
-- | Export an integer to a memory
+-- | Export an integer to a memory (big-endian)
 gmpExportInteger :: Integer -> Ptr Word8 -> GmpSupported (IO ())
 #if MIN_VERSION_integer_gmp(1,0,0)
 gmpExportInteger n (Ptr addr) = GmpSupported $ do
@ -146,7 +156,21 @@ gmpExportInteger n (Ptr addr) = GmpSupported $ IO $ \s ->
 gmpExportInteger _ _ = GmpUnsupported
 #endif
-- | Import an integer from a memory
+-- | Export an integer to a memory (little-endian)
 gmpExportIntegerLE :: Integer -> Ptr Word8 -> GmpSupported (IO ())
 #if MIN_VERSION_integer_gmp(1,0,0)
 gmpExportIntegerLE n (Ptr addr) = GmpSupported $ do
    _ <- exportIntegerToAddr n addr 0#
    return ()
 #elif MIN_VERSION_integer_gmp(0,5,1)
 gmpExportIntegerLE n (Ptr addr) = GmpSupported $ IO $ \s ->
    case exportIntegerToAddr n addr 0# s of
        (# s2, _ #) -> (# s2, () #)
 #else
 gmpExportIntegerLE _ _ = GmpUnsupported
 #endif
 -- | Import an integer from a memory (big-endian)
 gmpImportInteger :: Int -> Ptr Word8 -> GmpSupported (IO Integer)
 #if MIN_VERSION_integer_gmp(1,0,0)
 gmpImportInteger (I# n) (Ptr addr) = GmpSupported $
@ -157,3 +181,15 @@ gmpImportInteger (I# n) (Ptr addr) = GmpSupported $ IO $ \s ->
 #else
 gmpImportInteger _ _ = GmpUnsupported
 #endif
 -- | Import an integer from a memory (little-endian)
 gmpImportIntegerLE :: Int -> Ptr Word8 -> GmpSupported (IO Integer)
 #if MIN_VERSION_integer_gmp(1,0,0)
 gmpImportIntegerLE (I# n) (Ptr addr) = GmpSupported $
    importIntegerFromAddr addr (int2Word# n) 0#
 #elif MIN_VERSION_integer_gmp(0,5,1)
 gmpImportIntegerLE (I# n) (Ptr addr) = GmpSupported $ IO $ \s ->
    importIntegerFromAddr addr (int2Word# n) 0# s
 #else
 gmpImportIntegerLE _ _ = GmpUnsupported
 #endif
--- a/Crypto/Number/F2m.hs
+++ b/Crypto/Number/F2m.hs
@ -16,14 +16,15 @@ module Crypto.Number.F2m
    , mulF2m
    , squareF2m'
    , squareF2m
    , powF2m
    , modF2m
    , sqrtF2m
    , invF2m
    , divF2m
    ) where
 import Data.Bits (xor, shift, testBit, setBit)
 import Data.List
 import Crypto.Internal.Imports
 import Crypto.Number.Basic
 -- | Binary Polynomial represented by an integer
@ -67,8 +68,8 @@ mulF2m :: BinaryPolynomial -- ^ Modulus
 mulF2m fx n1 n2
    |    fx < 0
      || n1 < 0
-      || n2 < 0 = error "mulF2m: negative number represent no binary binary polynomial"
+      || n2 < 0 = error "mulF2m: negative number represent no binary polynomial"
-    | fx == 0   = error "modF2m: cannot multiply modulo zero polynomial"
+    | fx == 0   = error "mulF2m: cannot multiply modulo zero polynomial"
    | otherwise = modF2m fx $ go (if n2 `mod` 2 == 1 then n1 else 0) (log2 n2)
      where
        go n s | s == 0  = n
@ -97,10 +98,37 @@ squareF2m fx = modF2m fx . squareF2m'
 squareF2m' :: Integer
           -> Integer
 squareF2m' n
-    | n < 0     = error "mulF2m: negative number represent no binary binary polynomial"
+    | n < 0     = error "mulF2m: negative number represent no binary polynomial"
    | otherwise = foldl' (\acc s -> if testBit n s then setBit acc (2 * s) else acc) 0 [0 .. log2 n]
 {-# INLINE squareF2m' #-}
 -- | Exponentiation in F₂m by computing @a^b mod fx@.
 --
 -- This implements an exponentiation by squaring based solution. It inherits the
 -- same restrictions as 'squareF2m'. Negative exponents are disallowed.
 powF2m :: BinaryPolynomial -- ^Modulus
       -> Integer          -- ^a
       -> Integer          -- ^b
       -> Integer
 powF2m fx a b
  | b < 0     = error "powF2m: negative exponents disallowed"
  | b == 0    = if fx > 1 then 1 else 0
  | even b    = squareF2m fx x
  | otherwise = mulF2m fx a (squareF2m' x)
  where x = powF2m fx a (b `div` 2)
 -- | Square rooot in F₂m.
 --
 -- We exploit the fact that @a^(2^m) = a@, or in particular, @a^(2^m - 1) = 1@
 -- from a classical result by Lagrange. Thus the square root is simply @a^(2^(m
 -- - 1))@.
 sqrtF2m :: BinaryPolynomial -- ^Modulus
        -> Integer          -- ^a
        -> Integer
 sqrtF2m fx a = go (log2 fx - 1) a
  where go 0 x = x
        go n x = go (n - 1) (squareF2m fx x)
 -- | Extended GCD algorithm for polynomials. For @a@ and @b@ returns @(g, u, v)@ such that @a * u + b * v == g@.
 --
 -- Reference: https://en.wikipedia.org/wiki/Polynomial_greatest_common_divisor#B.C3.A9zout.27s_identity_and_extended_GCD_algorithm
--- a/Crypto/Number/Generate.hs
+++ b/Crypto/Number/Generate.hs
@ -120,6 +120,4 @@ generateMax range
 -- | generate a number between the inclusive bound [low,high].
 generateBetween :: MonadRandom m => Integer -> Integer -> m Integer
-generateBetween low high
+generateBetween low high = (low +) <$> generateMax (high - low + 1)
    | low == 1  = generateMax high >>= \r -> if r == 0 then generateBetween low high else return r
    | otherwise = (low +) <$> generateMax (high - low + 1)
--- a/Crypto/Number/ModArithmetic.hs
+++ b/Crypto/Number/ModArithmetic.hs
@ -1,5 +1,4 @@
 {-# LANGUAGE BangPatterns #-}
 {-# LANGUAGE DeriveDataTypeable #-}
 -- |
 -- Module      : Crypto.Number.ModArithmetic
 -- License     : BSD-style
@ -9,26 +8,29 @@
 module Crypto.Number.ModArithmetic
    (
-    -- * exponentiation
+    -- * Exponentiation
      expSafe
    , expFast
-    -- * inverse computing
+    -- * Inverse computing
    , inverse
    , inverseCoprimes
    , inverseFermat
    -- * Squares
    , jacobi
    , squareRoot
    ) where
 import Control.Exception (throw, Exception)
 import Data.Typeable
 import Crypto.Number.Basic
 import Crypto.Number.Compat
 -- | Raised when two numbers are supposed to be coprimes but are not.
 data CoprimesAssertionError = CoprimesAssertionError
-    deriving (Show,Typeable)
+    deriving (Show)
 instance Exception CoprimesAssertionError
-- | Compute the modular exponentiation of base^exponant using
+-- | Compute the modular exponentiation of base^exponent using
 -- algorithms design to avoid side channels and timing measurement
 --
 -- Modulo need to be odd otherwise the normal fast modular exponentiation
@ -38,11 +40,10 @@ instance Exception CoprimesAssertionError
 -- from expFast, and thus provide the same unstudied and dubious
 -- timing and side channels claims.
 --
-- with GHC 7.10, the powModSecInteger is missing from integer-gmp
+-- Before GHC 8.4.2, powModSecInteger is missing from integer-gmp,
-- (which is now integer-gmp2), so is has the same security as old
+-- so expSafe has the same security as expFast.
 -- ghc version.
 expSafe :: Integer -- ^ base
-        -> Integer -- ^ exponant
+        -> Integer -- ^ exponent
        -> Integer -- ^ modulo
        -> Integer -- ^ result
 expSafe b e m
@ -52,30 +53,30 @@ expSafe b e m
    | otherwise = gmpPowModInteger b e m    `onGmpUnsupported`
                  exponentiation b e m
-- | Compute the modular exponentiation of base^exponant using
+-- | Compute the modular exponentiation of base^exponent using
 -- the fastest algorithm without any consideration for
 -- hiding parameters.
 --
 -- Use this function when all the parameters are public,
-- otherwise 'expSafe' should be prefered.
+-- otherwise 'expSafe' should be preferred.
 expFast :: Integer -- ^ base
-        -> Integer -- ^ exponant
+        -> Integer -- ^ exponent
        -> Integer -- ^ modulo
        -> Integer -- ^ result
 expFast b e m = gmpPowModInteger b e m `onGmpUnsupported` exponentiation b e m
-- | exponentiation computes modular exponentiation as b^e mod m
+-- | @exponentiation@ computes modular exponentiation as /b^e mod m/
 -- using repetitive squaring.
 exponentiation :: Integer -> Integer -> Integer -> Integer
 exponentiation b e m
    | b == 1    = b
    | e == 0    = 1
    | e == 1    = b `mod` m
-    | even e    = let p = (exponentiation b (e `div` 2) m) `mod` m
+    | even e    = let p = exponentiation b (e `div` 2) m `mod` m
                   in (p^(2::Integer)) `mod` m
    | otherwise = (b * exponentiation b (e-1) m) `mod` m
-- | inverse computes the modular inverse as in g^(-1) mod m
+-- | @inverse@ computes the modular inverse as in /g^(-1) mod m/.
 inverse :: Integer -> Integer -> Maybe Integer
 inverse g m = gmpInverse g m `onGmpUnsupported` v
  where
@ -84,14 +85,133 @@ inverse g m = gmpInverse g m `onGmpUnsupported` v
        | otherwise = Just (x `mod` m)
    (x,_,d) = gcde g m
-- | Compute the modular inverse of 2 coprime numbers.
+-- | Compute the modular inverse of two coprime numbers.
 -- This is equivalent to inverse except that the result
 -- is known to exists.
 --
-- if the numbers are not defined as coprime, this function
+-- If the numbers are not defined as coprime, this function
-- will raise a CoprimesAssertionError.
+-- will raise a 'CoprimesAssertionError'.
 inverseCoprimes :: Integer -> Integer -> Integer
 inverseCoprimes g m =
    case inverse g m of
        Nothing -> throw CoprimesAssertionError
        Just i  -> i
 -- | Computes the Jacobi symbol (a/n).
 -- 0 ≤ a < n; n ≥ 3 and odd.
 --
 -- The Legendre and Jacobi symbols are indistinguishable exactly when the
 -- lower argument is an odd prime, in which case they have the same value.
 --
 -- See algorithm 2.149 in "Handbook of Applied Cryptography" by Alfred J. Menezes et al.
 jacobi :: Integer -> Integer -> Maybe Integer
 jacobi a n
    | n < 3 || even n  = Nothing
    | a == 0 || a == 1 = Just a
    | n <= a           = jacobi (a `mod` n) n
    | a < 0            =
      let b = if n `mod` 4 == 1 then 1 else -1
       in fmap (*b) (jacobi (-a) n)
    | otherwise        =
      let (e, a1) = asPowerOf2AndOdd a
          nMod8   = n `mod` 8
          nMod4   = n `mod` 4
          a1Mod4  = a1 `mod` 4
          s'      = if even e || nMod8 == 1 || nMod8 == 7 then 1 else -1
          s       = if nMod4 == 3 && a1Mod4 == 3 then -s' else s'
          n1      = n `mod` a1
       in if a1 == 1 then Just s
          else fmap (*s) (jacobi n1 a1)
 -- | Modular inverse using Fermat's little theorem.  This works only when
 -- the modulus is prime but avoids side channels like in 'expSafe'.
 inverseFermat :: Integer -> Integer -> Integer
 inverseFermat g p = expSafe g (p - 2) p
 -- | Raised when the assumption about the modulus is invalid.
 data ModulusAssertionError = ModulusAssertionError
    deriving (Show)
 instance Exception ModulusAssertionError
 -- | Modular square root of @g@ modulo a prime @p@.
 --
 -- If the modulus is found not to be prime, the function will raise a
 -- 'ModulusAssertionError'.
 --
 -- This implementation is variable time and should be used with public
 -- parameters only.
 squareRoot :: Integer -> Integer -> Maybe Integer
 squareRoot p
    | p < 2     = throw ModulusAssertionError
    | otherwise =
        case p `divMod` 8 of
           (v, 3) -> method1 (2 * v + 1)
           (v, 7) -> method1 (2 * v + 2)
           (u, 5) -> method2 u
           (_, 1) -> tonelliShanks p
           (0, 2) -> \a -> Just (if even a then 0 else 1)
           _      -> throw ModulusAssertionError
  where
    x `eqMod` y = (x - y) `mod` p == 0
    validate g y | (y * y) `eqMod` g = Just y
                 | otherwise         = Nothing
    -- p == 4u + 3 and u' == u + 1
    method1 u' g =
        let y = expFast g u' p
         in validate g y
    -- p == 8u + 5
    method2 u g =
        let gamma = expFast (2 * g) u p
            g_gamma = g * gamma
            i = (2 * g_gamma * gamma) `mod` p
            y = (g_gamma * (i - 1)) `mod` p
         in validate g y
 tonelliShanks :: Integer -> Integer -> Maybe Integer
 tonelliShanks p a
    | aa == 0   = Just 0
    | otherwise =
        case expFast aa p2 p of
            b | b == p1   -> Nothing
              | b == 1    -> Just $ go (expFast aa ((s + 1) `div` 2) p)
                                       (expFast aa s p)
                                       (expFast n  s p)
                                       e
              | otherwise -> throw ModulusAssertionError
  where
    aa = a `mod` p
    p1 = p - 1
    p2 = p1 `div` 2
    n  = findN 2
    x `mul` y = (x * y) `mod` p
    pow2m 0 x = x
    pow2m i x = pow2m (i - 1) (x `mul` x)
    (e, s) = asPowerOf2AndOdd p1
    -- find a quadratic non-residue
    findN i
        | expFast i p2 p == p1 = i
        | otherwise            = findN (i + 1)
    -- find m such that b^(2^m) == 1 (mod p)
    findM b i
        | b == 1    = i
        | otherwise = findM (b `mul` b) (i + 1)
    go !x b g !r
        | b == 1    = x
        | otherwise =
            let r' = findM b 0
                z = pow2m (r - r' - 1) g
                x' = x `mul` z
                b' = b `mul` g'
                g' = z `mul` z
             in go x' b' g' r'
--- a/Crypto/Number/Nat.hs
+++ b/Crypto/Number/Nat.hs
@ -0,0 +1,63 @@
 -- |
 -- Module      : Crypto.Number.Nat
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : experimental
 -- Portability : Good
 --
 -- Numbers at type level.
 --
 -- This module provides extensions to "GHC.TypeLits" and "GHC.TypeNats" useful
 -- to work with cryptographic algorithms parameterized with a variable bit
 -- length.  Constraints like @'IsDivisibleBy8' n@ ensure that the type-level
 -- parameter is applicable to the algorithm.
 --
 -- Functions are also provided to test whether constraints are satisfied from
 -- values known at runtime.  The following example shows how to discharge
 -- 'IsDivisibleBy8' in a computation @fn@ requiring this constraint:
 --
 -- > withDivisibleBy8 :: Integer
 -- >                  -> (forall proxy n . (KnownNat n, IsDivisibleBy8 n) => proxy n -> a)
 -- >                  -> Maybe a
 -- > withDivisibleBy8 len fn = do
 -- >     SomeNat p <- someNatVal len
 -- >     Refl <- isDivisibleBy8 p
 -- >     pure (fn p)
 --
 -- Function @withDivisibleBy8@ above returns 'Nothing' when the argument @len@
 -- is negative or not divisible by 8.
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE TypeOperators #-}
 module Crypto.Number.Nat
    ( type IsDivisibleBy8
    , type IsAtMost, type IsAtLeast
    , isDivisibleBy8
    , isAtMost
    , isAtLeast
    ) where
 import           Data.Type.Equality
 import           GHC.TypeLits
 import           Unsafe.Coerce (unsafeCoerce)
 import           Crypto.Internal.Nat
 -- | get a runtime proof that the constraint @'IsDivisibleBy8' n@ is satified
 isDivisibleBy8 :: KnownNat n => proxy n -> Maybe (IsDiv8 n n :~: 'True)
 isDivisibleBy8 n
    | mod (natVal n) 8 == 0 = Just (unsafeCoerce Refl)
    | otherwise             = Nothing
 -- | get a runtime proof that the constraint @'IsAtMost' value bound@ is
 -- satified
 isAtMost :: (KnownNat value, KnownNat bound)
         => proxy value -> proxy' bound -> Maybe ((value <=? bound) :~: 'True)
 isAtMost x y
    | natVal x <= natVal y  = Just (unsafeCoerce Refl)
    | otherwise             = Nothing
 -- | get a runtime proof that the constraint @'IsAtLeast' value bound@ is
 -- satified
 isAtLeast :: (KnownNat value, KnownNat bound)
          => proxy value -> proxy' bound -> Maybe ((bound <=? value) :~: 'True)
 isAtLeast = flip isAtMost
--- a/Crypto/Number/Prime.hs
+++ b/Crypto/Number/Prime.hs
@ -19,8 +19,6 @@ module Crypto.Number.Prime
    , isCoprime
    ) where
 import Crypto.Internal.Imports
 import Crypto.Number.Compat
 import Crypto.Number.Generate
 import Crypto.Number.Basic (sqrti, gcde)
@ -31,10 +29,10 @@ import Crypto.Error
 import Data.Bits
-- | returns if the number is probably prime.
+-- | Returns if the number is probably prime.
-- first a list of small primes are implicitely tested for divisibility,
+-- First a list of small primes are implicitely tested for divisibility,
 -- then a fermat primality test is used with arbitrary numbers and
-- then the Miller Rabin algorithm is used with an accuracy of 30 recursions
+-- then the Miller Rabin algorithm is used with an accuracy of 30 recursions.
 isProbablyPrime :: Integer -> Bool
 isProbablyPrime !n
    | any (\p -> p `divides` n) (filter (< n) firstPrimes) = False
@ -42,10 +40,10 @@ isProbablyPrime !n
    | primalityTestFermat 50 (n `div` 2) n                 = primalityTestMillerRabin 30 n
    | otherwise                                            = False
-- | generate a prime number of the required bitsize (i.e. in the range
+-- | Generate a prime number of the required bitsize (i.e. in the range
 -- [2^(b-1)+2^(b-2), 2^b)).
 --
--   May throw a CryptoError_PrimeSizeInvalid if the requested size is less
+-- May throw a 'CryptoError_PrimeSizeInvalid' if the requested size is less
 -- than 5 bits, as the smallest prime meeting these conditions is 29.
 -- This function requires that the two highest bits are set, so that when
 -- multiplied with another prime to create a key, it is guaranteed to be of
@ -61,13 +59,13 @@ generatePrime bits = do
            return $ prime
        else generatePrime bits
-- | generate a prime number of the form 2p+1 where p is also prime.
+-- | Generate a prime number of the form 2p+1 where p is also prime.
 -- it is also knowed as a Sophie Germaine prime or safe prime.
 --
 -- The number of safe prime is significantly smaller to the number of prime,
 -- as such it shouldn't be used if this number is supposed to be kept safe.
 --
-- May throw a CryptoError_PrimeSizeInvalid if the requested size is less than
+-- May throw a 'CryptoError_PrimeSizeInvalid' if the requested size is less than
 -- 6 bits, as the smallest safe prime with the two highest bits set is 59.
 generateSafePrime :: MonadRandom m => Int -> m Integer
 generateSafePrime bits = do
@ -81,7 +79,7 @@ generateSafePrime bits = do
            return $ val
        else generateSafePrime bits
-- | find a prime from a starting point where the property hold.
+-- | Find a prime from a starting point where the property hold.
 findPrimeFromWith :: (Integer -> Bool) -> Integer -> Integer
 findPrimeFromWith prop !n
    | even n        = findPrimeFromWith prop (n+1)
@ -93,7 +91,7 @@ findPrimeFromWith prop !n
                    then n
                    else findPrimeFromWith prop (n+2)
-- | find a prime from a starting point with no specific property.
+-- | Find a prime from a starting point with no specific property.
 findPrimeFrom :: Integer -> Integer
 findPrimeFrom n =
    case gmpNextPrime n of
@ -129,7 +127,7 @@ primalityTestMillerRabin tries !n =
    factorise :: Integer -> Integer -> (Integer, Integer)
    factorise !si !vi
        | vi `testBit` 0 = (si, vi)
-        | otherwise     = factorise (si+1) (vi `shiftR` 1) -- probably faster to not shift v continously, but just once.
+        | otherwise     = factorise (si+1) (vi `shiftR` 1) -- probably faster to not shift v continuously, but just once.
    expmod = expSafe
    -- when iteration reach zero, we have a probable prime
@ -185,7 +183,7 @@ primalityTestNaive n
 isCoprime :: Integer -> Integer -> Bool
 isCoprime m n = case gcde m n of (_,_,d) -> d == 1
-- | list of the first primes till 2903..
+-- | List of the first primes till 2903.
 firstPrimes :: [Integer]
 firstPrimes =
    [ 2    , 3    , 5    , 7    , 11   , 13   , 17   , 19   , 23   , 29
--- a/Crypto/Number/Serialize.hs
+++ b/Crypto/Number/Serialize.hs
@ -5,7 +5,7 @@
 -- Stability   : experimental
 -- Portability : Good
 --
-- fast serialization primitives for integer
+-- Fast serialization primitives for integer
 {-# LANGUAGE BangPatterns #-}
 module Crypto.Number.Serialize
    ( i2osp
@ -19,22 +19,23 @@ import           Crypto.Internal.Compat (unsafeDoIO)
 import qualified Crypto.Internal.ByteArray as B
 import qualified Crypto.Number.Serialize.Internal as Internal
-- | os2ip converts a byte string into a positive integer
+-- | @os2ip@ converts a byte string into a positive integer.
 os2ip :: B.ByteArrayAccess ba => ba -> Integer
 os2ip bs = unsafeDoIO $ B.withByteArray bs (\p -> Internal.os2ip p (B.length bs))
-- | i2osp converts a positive integer into a byte string
+-- | @i2osp@ converts a positive integer into a byte string.
 --
-- first byte is MSB (most significant byte), last byte is the LSB (least significant byte)
+-- The first byte is MSB (most significant byte); the last byte is the LSB (least significant byte)
 i2osp :: B.ByteArray ba => Integer -> ba
 i2osp 0 = B.allocAndFreeze 1  (\p -> Internal.i2osp 0 p 1 >> return ())
 i2osp m = B.allocAndFreeze sz (\p -> Internal.i2osp m p sz >> return ())
  where
        !sz = numBytes m
-- | just like i2osp, but take an extra parameter for size.
+-- | Just like 'i2osp', but takes an extra parameter for size.
-- if the number is too big to fit in @len@ bytes, 'Nothing' is returned
+-- If the number is too big to fit in @len@ bytes, 'Nothing' is returned
 -- otherwise the number is padded with 0 to fit the @len@ required.
 {-# INLINABLE i2ospOf #-}
 i2ospOf :: B.ByteArray ba => Int -> Integer -> Maybe ba
 i2ospOf len m
    | len <= 0  = Nothing
@ -44,10 +45,10 @@ i2ospOf len m
  where
        !sz = numBytes m
-- | just like i2ospOf except that it doesn't expect a failure: i.e.
+-- | Just like 'i2ospOf' except that it doesn't expect a failure: i.e.
-- an integer larger than the number of output bytes requested
+-- an integer larger than the number of output bytes requested.
 --
-- for example if you just took a modulo of the number that represent
+-- For example if you just took a modulo of the number that represent
 -- the size (example the RSA modulo n).
 i2ospOf_ :: B.ByteArray ba => Int -> Integer -> ba
 i2ospOf_ len = maybe (error "i2ospOf_: integer is larger than expected") id . i2ospOf len
--- a/Crypto/Number/Serialize/Internal.hs
+++ b/Crypto/Number/Serialize/Internal.hs
@ -5,7 +5,7 @@
 -- Stability   : experimental
 -- Portability : Good
 --
-- fast serialization primitives for integer using raw pointers
+-- Fast serialization primitives for integer using raw pointers
 {-# LANGUAGE BangPatterns #-}
 module Crypto.Number.Serialize.Internal
    ( i2osp
@ -21,12 +21,12 @@ import           Data.Word (Word8)
 import           Foreign.Ptr
 import           Foreign.Storable
-- | fill a pointer with the big endian binary representation of an integer
+-- | Fill a pointer with the big endian binary representation of an integer
 --
-- if the room available @ptrSz is less than the number of bytes needed,
+-- If the room available @ptrSz@ is less than the number of bytes needed,
 -- 0 is returned. Likewise if a parameter is invalid, 0 is returned.
 --
-- returns the number of bytes written
+-- Returns the number of bytes written
 i2osp :: Integer -> Ptr Word8 -> Int -> IO Int
 i2osp m ptr ptrSz
    | ptrSz <= 0 = return 0
@ -61,7 +61,7 @@ fillPtr p sz m = gmpExportInteger m p `onGmpUnsupported` export (sz-1) m
            pokeByteOff p ofs (fromIntegral b :: Word8)
            export (ofs-1) i'
-- | transform a big endian binary integer representation pointed by a pointer and a size
+-- | Transform a big endian binary integer representation pointed by a pointer and a size
 -- into an integer
 os2ip :: Ptr Word8 -> Int -> IO Integer
 os2ip ptr ptrSz
@ -69,7 +69,7 @@ os2ip ptr ptrSz
    | otherwise  = gmpImportInteger ptrSz ptr `onGmpUnsupported` loop 0 0 ptr
  where
    loop :: Integer -> Int -> Ptr Word8 -> IO Integer
-    loop !acc i p
+    loop !acc i !p
        | i == ptrSz = return acc
        | otherwise  = do
            w <- peekByteOff p i :: IO Word8
--- a/Crypto/Number/Serialize/Internal/LE.hs
+++ b/Crypto/Number/Serialize/Internal/LE.hs
@ -0,0 +1,75 @@
 -- |
 -- Module      : Crypto.Number.Serialize.Internal.LE
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : experimental
 -- Portability : Good
 --
 -- Fast serialization primitives for integer using raw pointers (little endian)
 {-# LANGUAGE BangPatterns #-}
 module Crypto.Number.Serialize.Internal.LE
    ( i2osp
    , i2ospOf
    , os2ip
    ) where
 import           Crypto.Number.Compat
 import           Crypto.Number.Basic
 import           Data.Bits
 import           Data.Memory.PtrMethods
 import           Data.Word (Word8)
 import           Foreign.Ptr
 import           Foreign.Storable
 -- | Fill a pointer with the little endian binary representation of an integer
 --
 -- If the room available @ptrSz@ is less than the number of bytes needed,
 -- 0 is returned. Likewise if a parameter is invalid, 0 is returned.
 --
 -- Returns the number of bytes written
 i2osp :: Integer -> Ptr Word8 -> Int -> IO Int
 i2osp m ptr ptrSz
    | ptrSz <= 0 = return 0
    | m < 0      = return 0
    | m == 0     = pokeByteOff ptr 0 (0 :: Word8) >> return 1
    | ptrSz < sz = return 0
    | otherwise  = fillPtr ptr sz m >> return sz
  where
    !sz    = numBytes m
 -- | Similar to 'i2osp', except it will pad any remaining space with zero.
 i2ospOf :: Integer -> Ptr Word8 -> Int -> IO Int
 i2ospOf m ptr ptrSz
    | ptrSz <= 0 = return 0
    | m < 0      = return 0
    | ptrSz < sz = return 0
    | otherwise  = do
        memSet ptr 0 ptrSz
        fillPtr ptr sz m
        return ptrSz
  where
    !sz    = numBytes m
 fillPtr :: Ptr Word8 -> Int -> Integer -> IO ()
 fillPtr p sz m = gmpExportIntegerLE m p `onGmpUnsupported` export 0 m
  where
    export ofs i
        | ofs >= sz = return ()
        | otherwise = do
            let (i', b) = i `divMod` 256
            pokeByteOff p ofs (fromIntegral b :: Word8)
            export (ofs+1) i'
 -- | Transform a little endian binary integer representation pointed by a
 -- pointer and a size into an integer
 os2ip :: Ptr Word8 -> Int -> IO Integer
 os2ip ptr ptrSz
    | ptrSz <= 0 = return 0
    | otherwise  = gmpImportIntegerLE ptrSz ptr `onGmpUnsupported` loop 0 (ptrSz-1) ptr
  where
    loop :: Integer -> Int -> Ptr Word8 -> IO Integer
    loop !acc i !p
        | i < 0      = return acc
        | otherwise  = do
            w <- peekByteOff p i :: IO Word8
            loop ((acc `shiftL` 8) .|. fromIntegral w) (i-1) p
--- a/Crypto/Number/Serialize/LE.hs
+++ b/Crypto/Number/Serialize/LE.hs
@ -0,0 +1,54 @@
 -- |
 -- Module      : Crypto.Number.Serialize.LE
 -- License     : BSD-style
 -- Maintainer  : Vincent Hanquez <vincent@snarc.org>
 -- Stability   : experimental
 -- Portability : Good
 --
 -- Fast serialization primitives for integer (little endian)
 {-# LANGUAGE BangPatterns #-}
 module Crypto.Number.Serialize.LE
    ( i2osp
    , os2ip
    , i2ospOf
    , i2ospOf_
    ) where
 import           Crypto.Number.Basic
 import           Crypto.Internal.Compat (unsafeDoIO)
 import qualified Crypto.Internal.ByteArray as B
 import qualified Crypto.Number.Serialize.Internal.LE as Internal
 -- | @os2ip@ converts a byte string into a positive integer.
 os2ip :: B.ByteArrayAccess ba => ba -> Integer
 os2ip bs = unsafeDoIO $ B.withByteArray bs (\p -> Internal.os2ip p (B.length bs))
 -- | @i2osp@ converts a positive integer into a byte string.
 --
 -- The first byte is LSB (least significant byte); the last byte is the MSB (most significant byte)
 i2osp :: B.ByteArray ba => Integer -> ba
 i2osp 0 = B.allocAndFreeze 1  (\p -> Internal.i2osp 0 p 1 >> return ())
 i2osp m = B.allocAndFreeze sz (\p -> Internal.i2osp m p sz >> return ())
  where
        !sz = numBytes m
 -- | Just like 'i2osp', but takes an extra parameter for size.
 -- If the number is too big to fit in @len@ bytes, 'Nothing' is returned
 -- otherwise the number is padded with 0 to fit the @len@ required.
 {-# INLINABLE i2ospOf #-}
 i2ospOf :: B.ByteArray ba => Int -> Integer -> Maybe ba
 i2ospOf len m
    | len <= 0  = Nothing
    | m < 0     = Nothing
    | sz > len  = Nothing
    | otherwise = Just $ B.unsafeCreate len (\p -> Internal.i2ospOf m p len >> return ())
  where
        !sz = numBytes m
 -- | Just like 'i2ospOf' except that it doesn't expect a failure: i.e.
 -- an integer larger than the number of output bytes requested.
 --
 -- For example if you just took a modulo of the number that represent
 -- the size (example the RSA modulo n).
 i2ospOf_ :: B.ByteArray ba => Int -> Integer -> ba
 i2ospOf_ len = maybe (error "i2ospOf_: integer is larger than expected") id . i2ospOf len
--- a/Crypto/OTP.hs
+++ b/Crypto/OTP.hs
@ -42,15 +42,14 @@ module Crypto.OTP
    )
 where
-import           Data.Bits (shiftL, shiftR, (.&.), (.|.))
+import           Data.Bits (shiftL, (.&.), (.|.))
 import           Data.ByteArray.Mapping (fromW64BE)
 import           Data.List (elemIndex)
 import           Data.Word
 import           Foreign.Storable (poke)
 import           Control.Monad (unless)
 import           Crypto.Hash (HashAlgorithm, SHA1(..))
 import           Crypto.MAC.HMAC
-import           Crypto.Internal.ByteArray (ByteArrayAccess, ByteArray, Bytes)
+import           Crypto.Internal.ByteArray (ByteArrayAccess, Bytes)
 import qualified Crypto.Internal.ByteArray as B
--- a/Crypto/PubKey/Curve25519.hs
+++ b/Crypto/PubKey/Curve25519.hs
@ -18,7 +18,7 @@ module Crypto.PubKey.Curve25519
    , dhSecret
    , publicKey
    , secretKey
-    -- * methods
+    -- * Methods
    , dh
    , toPublic
    , generateSecretKey
@ -33,9 +33,8 @@ import           GHC.Ptr
 import           Crypto.Error
 import           Crypto.Internal.Compat
 import           Crypto.Internal.Imports
-import           Crypto.Internal.ByteArray (ByteArrayAccess, ByteArray, ScrubbedBytes, Bytes, withByteArray)
+import           Crypto.Internal.ByteArray (ByteArrayAccess, ScrubbedBytes, Bytes, withByteArray)
 import qualified Crypto.Internal.ByteArray as B
 import           Crypto.Error (CryptoFailable(..))
 import           Crypto.Random
 -- | A Curve25519 Secret key
@ -92,7 +91,10 @@ dhSecret bs
    | B.length bs == 32 = CryptoPassed $ DhSecret $ B.copyAndFreeze bs (\_ -> return ())
    | otherwise         = CryptoFailed CryptoError_SharedSecretSizeInvalid
-- | Compute the Diffie Hellman secret from a public key and a secret key
+-- | Compute the Diffie Hellman secret from a public key and a secret key.
 --
 -- This implementation may return an all-zero value as it does not check for
 -- the condition.
 dh :: PublicKey -> SecretKey -> DhSecret
 dh (PublicKey pub) (SecretKey sec) = DhSecret <$>
    B.allocAndFreeze 32        $ \result ->
--- a/Crypto/PubKey/Curve448.hs
+++ b/Crypto/PubKey/Curve448.hs
@ -7,8 +7,11 @@
 --
 -- Curve448 support
 --
 -- Internally uses Decaf point compression to omit the cofactor
 -- and implementation by Mike Hamburg.  Externally API and
 -- data types are compatible with the encoding specified in RFC 7748.
 --
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE MagicHash #-}
 module Crypto.PubKey.Curve448
    ( SecretKey
    , PublicKey
@ -17,7 +20,7 @@ module Crypto.PubKey.Curve448
    , dhSecret
    , publicKey
    , secretKey
-    -- * methods
+    -- * Methods
    , dh
    , toPublic
    , generateSecretKey
@ -25,7 +28,6 @@ module Crypto.PubKey.Curve448
 import           Data.Word
 import           Foreign.Ptr
 import           GHC.Ptr
 import           Crypto.Error
 import           Crypto.Random
@ -75,13 +77,16 @@ dhSecret bs
    | B.length bs == x448_bytes = CryptoPassed $ DhSecret $ B.copyAndFreeze bs (\_ -> return ())
    | otherwise                 = CryptoFailed CryptoError_SharedSecretSizeInvalid
-- | Compute the Diffie Hellman secret from a public key and a secret key
+-- | Compute the Diffie Hellman secret from a public key and a secret key.
 --
 -- This implementation may return an all-zero value as it does not check for
 -- the condition.
 dh :: PublicKey -> SecretKey -> DhSecret
 dh (PublicKey pub) (SecretKey sec) = DhSecret <$>
    B.allocAndFreeze x448_bytes $ \result ->
    withByteArray sec           $ \psec   ->
    withByteArray pub           $ \ppub   ->
-        ccryptonite_ed448 result psec ppub
+        decaf_x448 result ppub psec
 {-# NOINLINE dh #-}
 -- | Create a public key from a secret key
@ -89,9 +94,7 @@ toPublic :: SecretKey -> PublicKey
 toPublic (SecretKey sec) = PublicKey <$>
    B.allocAndFreeze x448_bytes     $ \result ->
    withByteArray sec               $ \psec   ->
-        ccryptonite_ed448 result psec basePoint
+        decaf_x448_derive_public_key result psec
  where
        basePoint = Ptr "\x05\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"#
 {-# NOINLINE toPublic #-}
 -- | Generate a secret key.
@ -101,8 +104,13 @@ generateSecretKey = SecretKey <$> getRandomBytes x448_bytes
 x448_bytes :: Int
 x448_bytes = 448 `quot` 8
-foreign import ccall "cryptonite_x448"
+foreign import ccall "cryptonite_decaf_x448"
-    ccryptonite_ed448 :: Ptr Word8 -- ^ public
+    decaf_x448 :: Ptr Word8 -- ^ public
                      -> Ptr Word8 -- ^ secret
               -> Ptr Word8 -- ^ basepoint
               -> Ptr Word8 -- ^ secret
               -> IO ()
 foreign import ccall "cryptonite_decaf_x448_derive_public_key"
    decaf_x448_derive_public_key :: Ptr Word8 -- ^ public
                                 -> Ptr Word8 -- ^ secret
                                 -> IO ()
--- a/Crypto/PubKey/DH.hs
+++ b/Crypto/PubKey/DH.hs
@ -33,19 +33,22 @@ data Params = Params
    { params_p :: Integer
    , params_g :: Integer
    , params_bits :: Int
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 instance NFData Params where
    rnf (Params p g bits) = rnf p `seq` rnf g `seq` bits `seq` ()
 -- | Represent Diffie Hellman public number Y.
 newtype PublicNumber = PublicNumber Integer
-    deriving (Show,Read,Eq,Enum,Real,Num,Ord)
+    deriving (Show,Read,Eq,Enum,Real,Num,Ord,NFData)
 -- | Represent Diffie Hellman private number X.
 newtype PrivateNumber = PrivateNumber Integer
-    deriving (Show,Read,Eq,Enum,Real,Num,Ord)
+    deriving (Show,Read,Eq,Enum,Real,Num,Ord,NFData)
 -- | Represent Diffie Hellman shared secret.
 newtype SharedKey = SharedKey ScrubbedBytes
-    deriving (Show,Eq,ByteArrayAccess)
+    deriving (Show,Eq,ByteArrayAccess,NFData)
 -- | generate params from a specific generator (2 or 5 are common values)
 -- we generate a safe prime (a prime number of the form 2p+1 where p is also prime)
--- a/Crypto/PubKey/DSA.hs
+++ b/Crypto/PubKey/DSA.hs
@ -14,13 +14,13 @@ module Crypto.PubKey.DSA
    , PrivateKey(..)
    , PublicNumber
    , PrivateNumber
-    -- * generation
+    -- * Generation
    , generatePrivate
    , calculatePublic
-    -- * signature primitive
+    -- * Signature primitive
    , sign
    , signWith
-    -- * verification primitive
+    -- * Verification primitive
    , verify
    -- * Key pair
    , KeyPair(..)
@ -28,18 +28,17 @@ module Crypto.PubKey.DSA
    , toPrivateKey
    ) where
-import           Crypto.Random.Types
+
 import           Data.Bits (testBit)
 import Data.Data
 import Data.Maybe
-import           Crypto.Number.Basic (numBits)
+
 import Crypto.Number.ModArithmetic (expFast, expSafe, inverse)
 import           Crypto.Number.Serialize
 import Crypto.Number.Generate
-import           Crypto.Internal.ByteArray (ByteArrayAccess(length), convert, index, dropView, takeView)
+import Crypto.Internal.ByteArray (ByteArrayAccess)
 import Crypto.Internal.Imports
 import Crypto.Hash
-import           Prelude hiding (length)
+import Crypto.PubKey.Internal (dsaTruncHash)
 import Crypto.Random.Types
 -- | DSA Public Number, usually embedded in DSA Public Key
 type PublicNumber = Integer
@ -52,7 +51,7 @@ data Params = Params
    { params_p :: Integer -- ^ DSA p
    , params_g :: Integer -- ^ DSA g
    , params_q :: Integer -- ^ DSA q
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 instance NFData Params where
    rnf (Params p g q) = p `seq` g `seq` q `seq` ()
@ -61,7 +60,7 @@ instance NFData Params where
 data Signature = Signature
    { sign_r :: Integer -- ^ DSA r
    , sign_s :: Integer -- ^ DSA s
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 instance NFData Signature where
    rnf (Signature r s) = r `seq` s `seq` ()
@ -70,7 +69,7 @@ instance NFData Signature where
 data PublicKey = PublicKey
    { public_params :: Params       -- ^ DSA parameters
    , public_y      :: PublicNumber -- ^ DSA public Y
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 instance NFData PublicKey where
    rnf (PublicKey params y) = y `seq` params `seq` ()
@ -82,14 +81,14 @@ instance NFData PublicKey where
 data PrivateKey = PrivateKey
    { private_params :: Params        -- ^ DSA parameters
    , private_x      :: PrivateNumber -- ^ DSA private X
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 instance NFData PrivateKey where
    rnf (PrivateKey params x) = x `seq` params `seq` ()
 -- | Represent a DSA key pair
 data KeyPair = KeyPair Params PublicNumber PrivateNumber
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 instance NFData KeyPair where
    rnf (KeyPair params y x) = x `seq` y `seq` params `seq` ()
@ -126,7 +125,7 @@ signWith k pk hashAlg msg
          x              = private_x pk
          -- compute r,s
          kInv      = fromJust $ inverse k q
-          hm        = os2ip $ hashWith hashAlg msg
+          hm        = dsaTruncHash hashAlg msg q
          r         = expSafe g k p `mod` q
          s         = (kInv * (hm + x * r)) `mod` q
@ -148,11 +147,8 @@ verify hashAlg pk (Signature r s) m
    | otherwise                            = v == r
    where (Params p g q) = public_params pk
          y       = public_y pk
-          hm      = os2ip . truncateHash $ hashWith hashAlg m
+          hm      = dsaTruncHash hashAlg m q
          w       = fromJust $ inverse s q
          u1      = (hm*w) `mod` q
          u2      = (r*w) `mod` q
          v       = ((expFast g u1 p) * (expFast y u2 p)) `mod` p `mod` q
          -- if the hash is larger than the size of q, truncate it; FIXME: deal with the case of a q not evenly divisible by 8
          truncateHash h = if numBits (os2ip h) > numBits q then takeView h (numBits q `div` 8) else dropView h 0
--- a/Crypto/PubKey/ECC/ECDSA.hs
+++ b/Crypto/PubKey/ECC/ECDSA.hs
@ -11,45 +11,46 @@ module Crypto.PubKey.ECC.ECDSA
    , toPublicKey
    , toPrivateKey
    , signWith
    , signDigestWith
    , sign
    , signDigest
    , verify
    , verifyDigest
    ) where
 import Control.Monad
 import Crypto.Random.Types
 import Data.Bits (shiftR)
 import Crypto.Internal.ByteArray (ByteArrayAccess)
 import Data.Data
-import Crypto.Number.Basic (numBits)
+
 import Crypto.Hash
 import Crypto.Internal.ByteArray (ByteArrayAccess)
 import Crypto.Number.ModArithmetic (inverse)
 import Crypto.Number.Serialize
 import Crypto.Number.Generate
 import Crypto.PubKey.ECC.Types
 import Crypto.PubKey.ECC.Prim
-import Crypto.Hash
+import Crypto.PubKey.Internal (dsaTruncHashDigest)
-import Crypto.Hash.Types (hashDigestSize)
+import Crypto.Random.Types
 -- | Represent a ECDSA signature namely R and S.
 data Signature = Signature
    { sign_r :: Integer -- ^ ECDSA r
    , sign_s :: Integer -- ^ ECDSA s
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 -- | ECDSA Private Key.
 data PrivateKey = PrivateKey
    { private_curve :: Curve
    , private_d     :: PrivateNumber
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 -- | ECDSA Public Key.
 data PublicKey = PublicKey
    { public_curve :: Curve
    , public_q     :: PublicPoint
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 -- | ECDSA Key Pair.
 data KeyPair = KeyPair Curve PublicPoint PrivateNumber
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 -- | Public key of a ECDSA Key pair.
 toPublicKey :: KeyPair -> PublicKey
@ -59,17 +60,16 @@ toPublicKey (KeyPair curve pub _) = PublicKey curve pub
 toPrivateKey :: KeyPair -> PrivateKey
 toPrivateKey (KeyPair curve _ priv) = PrivateKey curve priv
-- | Sign message using the private key and an explicit k number.
+-- | Sign digest using the private key and an explicit k number.
 --
 -- /WARNING:/ Vulnerable to timing attacks.
-signWith :: (ByteArrayAccess msg, HashAlgorithm hash)
+signDigestWith :: HashAlgorithm hash
               => Integer     -- ^ k random number
               -> PrivateKey  -- ^ private key
-         -> hash       -- ^ hash function
+               -> Digest hash -- ^ digest to sign
         -> msg        -- ^ message to sign
               -> Maybe Signature
-signWith k (PrivateKey curve d) hashAlg msg = do
+signDigestWith k (PrivateKey curve d) digest = do
-    let z = tHash hashAlg msg n
+    let z = dsaTruncHashDigest digest n
        CurveCommon _ _ g n _ = common_curve curve
    let point = pointMul curve k g
    r <- case point of
@ -80,26 +80,44 @@ signWith k (PrivateKey curve d) hashAlg msg = do
    when (r == 0 || s == 0) Nothing
    return $ Signature r s
 -- | Sign message using the private key and an explicit k number.
 --
 -- /WARNING:/ Vulnerable to timing attacks.
 signWith :: (ByteArrayAccess msg, HashAlgorithm hash)
         => Integer    -- ^ k random number
         -> PrivateKey -- ^ private key
         -> hash       -- ^ hash function
         -> msg        -- ^ message to sign
         -> Maybe Signature
 signWith k pk hashAlg msg = signDigestWith k pk (hashWith hashAlg msg)
 -- | Sign digest using the private key.
 --
 -- /WARNING:/ Vulnerable to timing attacks.
 signDigest :: (HashAlgorithm hash, MonadRandom m)
           => PrivateKey -> Digest hash -> m Signature
 signDigest pk digest = do
    k <- generateBetween 1 (n - 1)
    case signDigestWith k pk digest of
         Nothing  -> signDigest pk digest
         Just sig -> return sig
  where n = ecc_n . common_curve $ private_curve pk
 -- | Sign message using the private key.
 --
 -- /WARNING:/ Vulnerable to timing attacks.
 sign :: (ByteArrayAccess msg, HashAlgorithm hash, MonadRandom m)
     => PrivateKey -> hash -> msg -> m Signature
-sign pk hashAlg msg = do
+sign pk hashAlg msg = signDigest pk (hashWith hashAlg msg)
    k <- generateBetween 1 (n - 1)
    case signWith k pk hashAlg msg of
         Nothing  -> sign pk hashAlg msg
         Just sig -> return sig
  where n = ecc_n . common_curve $ private_curve pk
-- | Verify a bytestring using the public key.
+-- | Verify a digest using the public key.
-verify :: (ByteArrayAccess msg, HashAlgorithm hash) => hash -> PublicKey -> Signature -> msg -> Bool
+verifyDigest :: HashAlgorithm hash => PublicKey -> Signature -> Digest hash -> Bool
-verify _       (PublicKey _ PointO) _ _ = False
+verifyDigest (PublicKey _ PointO) _ _ = False
-verify hashAlg pk@(PublicKey curve q) (Signature r s) msg
+verifyDigest pk@(PublicKey curve q) (Signature r s) digest
    | r < 1 || r >= n || s < 1 || s >= n = False
    | otherwise = maybe False (r ==) $ do
        w <- inverse s n
-        let z  = tHash hashAlg msg n
+        let z  = dsaTruncHashDigest digest n
            u1 = z * w `mod` n
            u2 = r * w `mod` n
            x  = pointAddTwoMuls curve u1 g u2 q
@ -110,10 +128,6 @@ verify hashAlg pk@(PublicKey curve q) (Signature r s) msg
        g = ecc_g cc
        cc = common_curve $ public_curve pk
-- | Truncate and hash.
+-- | Verify a bytestring using the public key.
-tHash :: (ByteArrayAccess msg, HashAlgorithm hash) => hash -> msg -> Integer -> Integer
+verify :: (ByteArrayAccess msg, HashAlgorithm hash) => hash -> PublicKey -> Signature -> msg -> Bool
-tHash hashAlg m n
+verify hashAlg pk sig msg = verifyDigest pk sig (hashWith hashAlg msg)
    | d > 0 = shiftR e d
    | otherwise = e
  where e = os2ip $ hashWith hashAlg m
        d = hashDigestSize hashAlg * 8 - numBits n
--- a/Crypto/PubKey/ECC/P256.hs
+++ b/Crypto/PubKey/ECC/P256.hs
@ -8,31 +8,37 @@
 -- P256 support
 --
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE BangPatterns #-}
 {-# LANGUAGE EmptyDataDecls #-}
 {-# OPTIONS_GHC -fno-warn-unused-binds #-}
 module Crypto.PubKey.ECC.P256
    ( Scalar
    , Point
-    -- * point arithmetic
+    -- * Point arithmetic
    , pointBase
    , pointAdd
    , pointNegate
    , pointMul
    , pointDh
    , pointsMulVarTime
    , pointIsValid
    , pointIsAtInfinity
    , toPoint
    , pointX
    , pointToIntegers
    , pointFromIntegers
    , pointToBinary
    , pointFromBinary
-    -- * scalar arithmetic
+    , unsafePointFromBinary
    -- * Scalar arithmetic
    , scalarGenerate
    , scalarZero
    , scalarN
    , scalarIsZero
    , scalarAdd
    , scalarSub
    , scalarMul
    , scalarInv
    , scalarInvSafe
    , scalarCmp
    , scalarFromBinary
    , scalarToBinary
@ -43,7 +49,6 @@ module Crypto.PubKey.ECC.P256
 import           Data.Word
 import           Foreign.Ptr
 import           Foreign.C.Types
 import           Control.Monad
 import           Crypto.Internal.Compat
 import           Crypto.Internal.Imports
@ -57,11 +62,11 @@ import qualified Crypto.Number.Serialize as S (os2ip, i2ospOf)
 -- | A P256 scalar
 newtype Scalar = Scalar ScrubbedBytes
-    deriving (Show,Eq,ByteArrayAccess)
+    deriving (Show,Eq,ByteArrayAccess,NFData)
 -- | A P256 point
 newtype Point = Point Bytes
-    deriving (Show,Eq)
+    deriving (Show,Eq,NFData)
 scalarSize :: Int
 scalarSize = 32
@ -75,6 +80,9 @@ data P256Scalar
 data P256Y
 data P256X
 order :: Integer
 order = 0xffffffff00000000ffffffffffffffffbce6faada7179e84f3b9cac2fc632551
 ------------------------------------------------------------------------
 -- Point methods
 ------------------------------------------------------------------------
@ -105,20 +113,27 @@ pointAdd a b = withNewPoint $ \dx dy ->
    withPoint a $ \ax ay -> withPoint b $ \bx by ->
        ccryptonite_p256e_point_add ax ay bx by dx dy
 -- | Negate a point
 pointNegate :: Point -> Point
 pointNegate a = withNewPoint $ \dx dy ->
    withPoint a $ \ax ay ->
        ccryptonite_p256e_point_negate ax ay dx dy
 -- | Multiply a point by a scalar
 --
 -- warning: variable time
 pointMul :: Scalar -> Point -> Point
 pointMul scalar p = withNewPoint $ \dx dy ->
-    withScalar scalar $ \n -> withPoint p $ \px py -> withScalarZero $ \nzero ->
+    withScalar scalar $ \n -> withPoint p $ \px py ->
-        ccryptonite_p256_points_mul_vartime nzero n px py dx dy
+        ccryptonite_p256e_point_mul n px py dx dy
-- | Similar to 'pointMul', serializing the x coordinate as binary
+-- | Similar to 'pointMul', serializing the x coordinate as binary.
 -- When scalar is multiple of point order the result is all zero.
 pointDh :: ByteArray binary => Scalar -> Point -> binary
 pointDh scalar p =
    B.unsafeCreate scalarSize $ \dst -> withTempPoint $ \dx dy -> do
-        withScalar scalar $ \n -> withPoint p $ \px py -> withScalarZero $ \nzero ->
+        withScalar scalar $ \n -> withPoint p $ \px py ->
-            ccryptonite_p256_points_mul_vartime nzero n px py dx dy
+            ccryptonite_p256e_point_mul n px py dx dy
        ccryptonite_p256_to_bin (castPtr dx) dst
 -- | multiply the point @p with @n2 and add a lifted to curve value @n1
@ -137,6 +152,19 @@ pointIsValid p = unsafeDoIO $ withPoint p $ \px py -> do
    r <- ccryptonite_p256_is_valid_point px py
    return (r /= 0)
 -- | Check if a 'Point' is the point at infinity
 pointIsAtInfinity :: Point -> Bool
 pointIsAtInfinity (Point b) = constAllZero b
 -- | Return the x coordinate as a 'Scalar' if the point is not at infinity
 pointX :: Point -> Maybe Scalar
 pointX p
    | pointIsAtInfinity p = Nothing
    | otherwise           = Just $
        withNewScalarFreeze $ \d    ->
        withPoint p         $ \px _ ->
            ccryptonite_p256_mod ccryptonite_SECP256r1_n (castPtr px) (castPtr d)
 -- | Convert a point to (x,y) Integers
 pointToIntegers :: Point -> (Integer, Integer)
 pointToIntegers p = unsafeDoIO $ withPoint p $ \px py ->
@ -172,10 +200,19 @@ pointToBinary p = B.unsafeCreate pointSize $ \dst -> withPoint p $ \px py -> do
    ccryptonite_p256_to_bin (castPtr px) dst
    ccryptonite_p256_to_bin (castPtr py) (dst `plusPtr` 32)
-- | Convert from binary to a point
+-- | Convert from binary to a valid point
 pointFromBinary :: ByteArrayAccess ba => ba -> CryptoFailable Point
-pointFromBinary ba
+pointFromBinary ba = unsafePointFromBinary ba >>= validatePoint
-    | B.length ba /= pointSize = CryptoFailed $ CryptoError_PublicKeySizeInvalid
+  where
    validatePoint :: Point -> CryptoFailable Point
    validatePoint p
        | pointIsValid p = CryptoPassed p
        | otherwise      = CryptoFailed CryptoError_PointCoordinatesInvalid
 -- | Convert from binary to a point, possibly invalid
 unsafePointFromBinary :: ByteArrayAccess ba => ba -> CryptoFailable Point
 unsafePointFromBinary ba
    | B.length ba /= pointSize = CryptoFailed CryptoError_PublicKeySizeInvalid
    | otherwise                =
        CryptoPassed $ withNewPoint $ \px py -> B.withByteArray ba $ \src -> do
            ccryptonite_p256_from_bin src                        (castPtr px)
@ -198,40 +235,39 @@ scalarGenerate = unwrap . scalarFromBinary . witness <$> getRandomBytes 32
 scalarZero :: Scalar
 scalarZero = withNewScalarFreeze $ \d -> ccryptonite_p256_init d
 -- | The scalar representing the curve order
 scalarN :: Scalar
 scalarN = throwCryptoError (scalarFromInteger order)
 -- | Check if the scalar is 0
 scalarIsZero :: Scalar -> Bool
 scalarIsZero s = unsafeDoIO $ withScalar s $ \d -> do
    result <- ccryptonite_p256_is_zero d
    return $ result /= 0
 scalarNeedReducing :: Ptr P256Scalar -> IO Bool
 scalarNeedReducing d = do
    c <- ccryptonite_p256_cmp d ccryptonite_SECP256r1_n
    return (c >= 0)
 -- | Perform addition between two scalars
 --
 -- > a + b
 scalarAdd :: Scalar -> Scalar -> Scalar
 scalarAdd a b =
-    withNewScalarFreeze $ \d -> withScalar a $ \pa -> withScalar b $ \pb -> do
+    withNewScalarFreeze $ \d -> withScalar a $ \pa -> withScalar b $ \pb ->
-        carry <- ccryptonite_p256_add pa pb d
+        ccryptonite_p256e_modadd ccryptonite_SECP256r1_n pa pb d
        when (carry /= 0) $ void $ ccryptonite_p256_sub d ccryptonite_SECP256r1_n d
        needReducing <- scalarNeedReducing d
        when needReducing $ do
            ccryptonite_p256_mod ccryptonite_SECP256r1_n d d
 -- | Perform subtraction between two scalars
 --
 -- > a - b
 scalarSub :: Scalar -> Scalar -> Scalar
 scalarSub a b =
-    withNewScalarFreeze $ \d -> withScalar a $ \pa -> withScalar b $ \pb -> do
+    withNewScalarFreeze $ \d -> withScalar a $ \pa -> withScalar b $ \pb ->
-        borrow <- ccryptonite_p256_sub pa pb d
+        ccryptonite_p256e_modsub ccryptonite_SECP256r1_n pa pb d
-        when (borrow /= 0) $ void $ ccryptonite_p256_add d ccryptonite_SECP256r1_n d
+
-        --needReducing <- scalarNeedReducing d
+-- | Perform multiplication between two scalars
-        --when needReducing $ do
+--
-        --    ccryptonite_p256_mod ccryptonite_SECP256r1_n d d
+-- > a * b
 scalarMul :: Scalar -> Scalar -> Scalar
 scalarMul a b =
    withNewScalarFreeze $ \d -> withScalar a $ \pa -> withScalar b $ \pb ->
         ccryptonite_p256_modmul ccryptonite_SECP256r1_n pa 0 pb d
 -- | Give the inverse of the scalar
 --
@ -243,6 +279,14 @@ scalarInv a =
    withNewScalarFreeze $ \b -> withScalar a $ \pa ->
        ccryptonite_p256_modinv_vartime ccryptonite_SECP256r1_n pa b
 -- | Give the inverse of the scalar using safe exponentiation
 --
 -- > 1 / a
 scalarInvSafe :: Scalar -> Scalar
 scalarInvSafe a =
    withNewScalarFreeze $ \b -> withScalar a $ \pa ->
        ccryptonite_p256e_scalar_invert pa b
 -- | Compare 2 Scalar
 scalarCmp :: Scalar -> Scalar -> Ordering
 scalarCmp a b = unsafeDoIO $
@ -253,7 +297,7 @@ scalarCmp a b = unsafeDoIO $
 -- | convert a scalar from binary
 scalarFromBinary :: ByteArrayAccess ba => ba -> CryptoFailable Scalar
 scalarFromBinary ba
-    | B.length ba /= scalarSize = CryptoFailed $ CryptoError_SecretKeySizeInvalid
+    | B.length ba /= scalarSize = CryptoFailed CryptoError_SecretKeySizeInvalid
    | otherwise                 =
        CryptoPassed $ withNewScalarFreeze $ \p -> B.withByteArray ba $ \b ->
            ccryptonite_p256_from_bin b p
@ -292,20 +336,11 @@ withNewScalarFreeze f = Scalar $ B.allocAndFreeze scalarSize f
 {-# NOINLINE withNewScalarFreeze #-}
 withTempPoint :: (Ptr P256X -> Ptr P256Y -> IO a) -> IO a
-withTempPoint f = allocTempScrubbed scalarSize (\p -> let px = castPtr p in f px (pxToPy px))
+withTempPoint f = allocTempScrubbed pointSize (\p -> let px = castPtr p in f px (pxToPy px))
 withTempScalar :: (Ptr P256Scalar -> IO a) -> IO a
 withTempScalar f = allocTempScrubbed scalarSize (f . castPtr)
 withScalar :: Scalar -> (Ptr P256Scalar -> IO a) -> IO a
 withScalar (Scalar d) f = B.withByteArray d f
 withScalarZero :: (Ptr P256Scalar -> IO a) -> IO a
 withScalarZero f =
    withTempScalar $ \d -> do
        ccryptonite_p256_init d
        f d
 allocTemp :: Int -> (Ptr Word8 -> IO a) -> IO a
 allocTemp n f = ignoreSnd <$> B.allocRet n f
  where
@ -334,18 +369,20 @@ foreign import ccall "cryptonite_p256_is_zero"
    ccryptonite_p256_is_zero :: Ptr P256Scalar -> IO CInt
 foreign import ccall "cryptonite_p256_clear"
    ccryptonite_p256_clear :: Ptr P256Scalar -> IO ()
-foreign import ccall "cryptonite_p256_add"
+foreign import ccall "cryptonite_p256e_modadd"
-    ccryptonite_p256_add :: Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> IO CInt
+    ccryptonite_p256e_modadd :: Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> IO ()
 foreign import ccall "cryptonite_p256_add_d"
    ccryptonite_p256_add_d :: Ptr P256Scalar -> P256Digit -> Ptr P256Scalar -> IO CInt
-foreign import ccall "cryptonite_p256_sub"
+foreign import ccall "cryptonite_p256e_modsub"
-    ccryptonite_p256_sub :: Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> IO CInt
+    ccryptonite_p256e_modsub :: Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> IO ()
 foreign import ccall "cryptonite_p256_cmp"
    ccryptonite_p256_cmp :: Ptr P256Scalar -> Ptr P256Scalar -> IO CInt
 foreign import ccall "cryptonite_p256_mod"
    ccryptonite_p256_mod :: Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> IO ()
 foreign import ccall "cryptonite_p256_modmul"
    ccryptonite_p256_modmul :: Ptr P256Scalar -> Ptr P256Scalar -> P256Digit -> Ptr P256Scalar -> Ptr P256Scalar -> IO ()
 foreign import ccall "cryptonite_p256e_scalar_invert"
    ccryptonite_p256e_scalar_invert :: Ptr P256Scalar -> Ptr P256Scalar -> IO ()
 --foreign import ccall "cryptonite_p256_modinv"
 --    ccryptonite_p256_modinv :: Ptr P256Scalar -> Ptr P256Scalar -> Ptr P256Scalar -> IO ()
 foreign import ccall "cryptonite_p256_modinv_vartime"
@ -361,6 +398,18 @@ foreign import ccall "cryptonite_p256e_point_add"
                                -> Ptr P256X -> Ptr P256Y
                                -> IO ()
 foreign import ccall "cryptonite_p256e_point_negate"
    ccryptonite_p256e_point_negate :: Ptr P256X -> Ptr P256Y
                                   -> Ptr P256X -> Ptr P256Y
                                   -> IO ()
 -- compute (out_x,out_y) = n * (in_x,in_y)
 foreign import ccall "cryptonite_p256e_point_mul"
    ccryptonite_p256e_point_mul :: Ptr P256Scalar -- n
                                -> Ptr P256X -> Ptr P256Y -- in_{x,y}
                                -> Ptr P256X -> Ptr P256Y -- out_{x,y}
                                -> IO ()
 -- compute (out_x,out,y) = n1 * G + n2 * (in_x,in_y)
 foreign import ccall "cryptonite_p256_points_mul_vartime"
    ccryptonite_p256_points_mul_vartime :: Ptr P256Scalar -- n1
--- a/Crypto/PubKey/ECC/Prim.hs
+++ b/Crypto/PubKey/ECC/Prim.hs
@ -4,6 +4,7 @@
 module Crypto.PubKey.ECC.Prim
    ( scalarGenerate
    , pointAdd
    , pointNegate
    , pointDouble
    , pointBaseMul
    , pointMul
@ -31,7 +32,7 @@ scalarGenerate curve = generateBetween 1 (n - 1)
 -- @pointNegate c p@ returns point @q@ such that @pointAdd c p q == PointO@.
 pointNegate :: Curve -> Point -> Point
 pointNegate _            PointO     = PointO
-pointNegate CurveFP{}  (Point x y) = Point x (-y)
+pointNegate (CurveFP c) (Point x y) = Point x (ecc_p c - y)
 pointNegate CurveF2m{}  (Point x y) = Point x (x `addF2m` y)
 -- | Elliptic Curve point addition.
--- a/Crypto/PubKey/ECC/Types.hs
+++ b/Crypto/PubKey/ECC/Types.hs
@ -6,7 +6,7 @@
 -- Stability   : Experimental
 -- Portability : Excellent
 --
-- references:
+-- References:
 --   <https://tools.ietf.org/html/rfc5915>
 --
 module Crypto.PubKey.ECC.Types
@ -21,7 +21,7 @@ module Crypto.PubKey.ECC.Types
    , ecc_fx
    , ecc_p
    , CurveCommon(..)
-    -- * recommended curves definition
+    -- * Recommended curves definition
    , CurveName(..)
    , getCurveByName
    ) where
@ -33,7 +33,7 @@ import           Crypto.Number.Basic (numBits)
 -- | Define either a binary curve or a prime curve.
 data Curve = CurveF2m CurveBinary -- ^ 𝔽(2^m)
           | CurveFP  CurvePrime  -- ^ 𝔽p
-           deriving (Show,Read,Eq,Data,Typeable)
+           deriving (Show,Read,Eq,Data)
 -- | ECC Public Point
 type PublicPoint = Point
@ -44,7 +44,7 @@ type PrivateNumber = Integer
 -- | Define a point on a curve.
 data Point = Point Integer Integer
           | PointO -- ^ Point at Infinity
-           deriving (Show,Read,Eq,Data,Typeable)
+           deriving (Show,Read,Eq,Data)
 instance NFData Point where
    rnf (Point x y) = x `seq` y `seq` ()
@ -53,7 +53,7 @@ instance NFData Point where
 -- | Define an elliptic curve in 𝔽(2^m).
 -- The firt parameter is the Integer representatioin of the irreducible polynomial f(x).
 data CurveBinary = CurveBinary Integer CurveCommon
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 instance NFData CurveBinary where
    rnf (CurveBinary i cc) = i `seq` cc `seq` ()
@ -61,7 +61,7 @@ instance NFData CurveBinary where
 -- | Define an elliptic curve in 𝔽p.
 -- The first parameter is the Prime Number.
 data CurvePrime = CurvePrime Integer CurveCommon
-    deriving (Show,Read,Eq,Data,Typeable)
+    deriving (Show,Read,Eq,Data)
 -- | Parameters in common between binary and prime curves.
 common_curve :: Curve -> CurveCommon
@ -84,7 +84,7 @@ data CurveCommon = CurveCommon
    , ecc_g :: Point   -- ^ base point
    , ecc_n :: Integer -- ^ order of G
    , ecc_h :: Integer -- ^ cofactor
-    } deriving (Show,Read,Eq,Data,Typeable)
+    } deriving (Show,Read,Eq,Data)
 -- | Define names for known recommended curves.
 data CurveName =
@ -121,7 +121,7 @@ data CurveName =
    | SEC_t409r1
    | SEC_t571k1
    | SEC_t571r1
-    deriving (Show,Read,Eq,Ord,Enum,Bounded,Data,Typeable)
+    deriving (Show,Read,Eq,Ord,Enum,Bounded,Data)
 {-
 curvesOIDs :: [ (CurveName, [Integer]) ]
--- a/Show More
+++ b/Show More