module Network.TLS.Crypto
( HashContext
, HashCtx
, hashInit
, hashUpdate
, hashUpdateSSL
, hashFinal
, module Network.TLS.Crypto.DH
, module Network.TLS.Crypto.ECDH
, hash
, Hash(..)
, hashName
, hashDigestSize
, hashBlockSize
, PubKey(..)
, PrivKey(..)
, PublicKey
, PrivateKey
, kxEncrypt
, kxDecrypt
, kxSign
, kxVerify
, KxError(..)
) where
import qualified Crypto.Hash as H
import qualified Data.ByteString as B
import qualified Data.ByteArray as B (convert)
import Data.ByteString (ByteString)
import Crypto.Random
import qualified Crypto.PubKey.DSA as DSA
import qualified Crypto.PubKey.ECC.ECDSA as ECDSA
import qualified Crypto.PubKey.ECC.Prim as ECC
import qualified Crypto.PubKey.ECC.Types as ECC
import qualified Crypto.PubKey.RSA as RSA
import qualified Crypto.PubKey.RSA.PKCS15 as RSA
import Crypto.Number.Serialize (os2ip)
import Data.X509 (PrivKey(..), PubKey(..), PubKeyEC(..), SerializedPoint(..))
import Network.TLS.Crypto.DH
import Network.TLS.Crypto.ECDH
import Data.ASN1.Types
import Data.ASN1.Encoding
import Data.ASN1.BinaryEncoding (DER(..), BER(..))
import Data.List (find)
type PublicKey = PubKey
type PrivateKey = PrivKey
data KxError =
RSAError RSA.Error
| KxUnsupported
deriving (Show)
hashInit :: Hash -> HashContext
hashInit MD5 = HashContext $ ContextSimple (H.hashInit :: H.Context H.MD5)
hashInit SHA1 = HashContext $ ContextSimple (H.hashInit :: H.Context H.SHA1)
hashInit SHA224 = HashContext $ ContextSimple (H.hashInit :: H.Context H.SHA224)
hashInit SHA256 = HashContext $ ContextSimple (H.hashInit :: H.Context H.SHA256)
hashInit SHA384 = HashContext $ ContextSimple (H.hashInit :: H.Context H.SHA384)
hashInit SHA512 = HashContext $ ContextSimple (H.hashInit :: H.Context H.SHA512)
hashInit SHA1_MD5 = HashContextSSL H.hashInit H.hashInit
hashUpdate :: HashContext -> B.ByteString -> HashCtx
hashUpdate (HashContext (ContextSimple h)) b = HashContext $ ContextSimple (H.hashUpdate h b)
hashUpdate (HashContextSSL sha1Ctx md5Ctx) b =
HashContextSSL (H.hashUpdate sha1Ctx b) (H.hashUpdate md5Ctx b)
hashUpdateSSL :: HashCtx
-> (B.ByteString,B.ByteString)
-> HashCtx
hashUpdateSSL (HashContext _) _ = error "internal error: update SSL without a SSL Context"
hashUpdateSSL (HashContextSSL sha1Ctx md5Ctx) (b1,b2) =
HashContextSSL (H.hashUpdate sha1Ctx b2) (H.hashUpdate md5Ctx b1)
hashFinal :: HashCtx -> B.ByteString
hashFinal (HashContext (ContextSimple h)) = B.convert $ H.hashFinalize h
hashFinal (HashContextSSL sha1Ctx md5Ctx) =
B.concat [B.convert (H.hashFinalize md5Ctx), B.convert (H.hashFinalize sha1Ctx)]
data Hash = MD5 | SHA1 | SHA224 | SHA256 | SHA384 | SHA512 | SHA1_MD5
deriving (Show,Eq)
data HashContext =
HashContext ContextSimple
| HashContextSSL (H.Context H.SHA1) (H.Context H.MD5)
instance Show HashContext where
show _ = "hash-context"
data ContextSimple = forall alg . H.HashAlgorithm alg => ContextSimple (H.Context alg)
type HashCtx = HashContext
hash :: Hash -> B.ByteString -> B.ByteString
hash MD5 b = B.convert . (H.hash :: B.ByteString -> H.Digest H.MD5) $ b
hash SHA1 b = B.convert . (H.hash :: B.ByteString -> H.Digest H.SHA1) $ b
hash SHA224 b = B.convert . (H.hash :: B.ByteString -> H.Digest H.SHA224) $ b
hash SHA256 b = B.convert . (H.hash :: B.ByteString -> H.Digest H.SHA256) $ b
hash SHA384 b = B.convert . (H.hash :: B.ByteString -> H.Digest H.SHA384) $ b
hash SHA512 b = B.convert . (H.hash :: B.ByteString -> H.Digest H.SHA512) $ b
hash SHA1_MD5 b =
B.concat [B.convert (md5Hash b), B.convert (sha1Hash b)]
where
sha1Hash :: B.ByteString -> H.Digest H.SHA1
sha1Hash = H.hash
md5Hash :: B.ByteString -> H.Digest H.MD5
md5Hash = H.hash
hashName :: Hash -> String
hashName = show
hashDigestSize :: Hash -> Int
hashDigestSize MD5 = 16
hashDigestSize SHA1 = 20
hashDigestSize SHA224 = 28
hashDigestSize SHA256 = 32
hashDigestSize SHA384 = 48
hashDigestSize SHA512 = 64
hashDigestSize SHA1_MD5 = 36
hashBlockSize :: Hash -> Int
hashBlockSize MD5 = 64
hashBlockSize SHA1 = 64
hashBlockSize SHA224 = 64
hashBlockSize SHA256 = 64
hashBlockSize SHA384 = 128
hashBlockSize SHA512 = 128
hashBlockSize SHA1_MD5 = 64
generalizeRSAError :: Either RSA.Error a -> Either KxError a
generalizeRSAError (Left e) = Left (RSAError e)
generalizeRSAError (Right x) = Right x
kxEncrypt :: MonadRandom r => PublicKey -> ByteString -> r (Either KxError ByteString)
kxEncrypt (PubKeyRSA pk) b = generalizeRSAError `fmap` RSA.encrypt pk b
kxEncrypt _ _ = return (Left KxUnsupported)
kxDecrypt :: MonadRandom r => PrivateKey -> ByteString -> r (Either KxError ByteString)
kxDecrypt (PrivKeyRSA pk) b = generalizeRSAError `fmap` RSA.decryptSafer pk b
kxDecrypt _ _ = return (Left KxUnsupported)
kxVerify :: PublicKey -> Hash -> ByteString -> ByteString -> Bool
kxVerify (PubKeyRSA pk) alg msg sign = rsaVerifyHash alg pk msg sign
kxVerify (PubKeyDSA pk) _ msg signBS =
case dsaToSignature signBS of
Just sig -> DSA.verify H.SHA1 pk sig msg
_ -> False
where
dsaToSignature :: ByteString -> Maybe DSA.Signature
dsaToSignature b =
case decodeASN1' BER b of
Left _ -> Nothing
Right asn1 ->
case asn1 of
Start Sequence:IntVal r:IntVal s:End Sequence:_ ->
Just $ DSA.Signature { DSA.sign_r = r, DSA.sign_s = s }
_ ->
Nothing
kxVerify (PubKeyEC key) alg msg sigBS = maybe False id $ do
(curveName, pubBS) <- case key of
PubKeyEC_Named curveName' pub -> Just (curveName',pub)
PubKeyEC_Prime {} ->
case find matchPrimeCurve $ enumFrom $ toEnum 0 of
Nothing -> Nothing
Just curveName' -> Just (curveName', pubkeyEC_pub key)
signature <- case decodeASN1' BER sigBS of
Left _ -> Nothing
Right [Start Sequence,IntVal r,IntVal s,End Sequence] -> Just $ ECDSA.Signature r s
Right _ -> Nothing
pubkey <- unserializePoint (ECC.getCurveByName curveName) pubBS
verifyF <- case alg of
MD5 -> Just (ECDSA.verify H.MD5)
SHA1 -> Just (ECDSA.verify H.SHA1)
SHA224 -> Just (ECDSA.verify H.SHA224)
SHA256 -> Just (ECDSA.verify H.SHA256)
SHA384 -> Just (ECDSA.verify H.SHA384)
SHA512 -> Just (ECDSA.verify H.SHA512)
_ -> Nothing
return $ verifyF pubkey signature msg
where
matchPrimeCurve c =
case ECC.getCurveByName c of
ECC.CurveFP (ECC.CurvePrime p cc) ->
ECC.ecc_a cc == pubkeyEC_a key &&
ECC.ecc_b cc == pubkeyEC_b key &&
ECC.ecc_n cc == pubkeyEC_order key &&
p == pubkeyEC_prime key
_ -> False
unserializePoint curve (SerializedPoint bs) =
case B.uncons bs of
Nothing -> Nothing
Just (ptFormat, input) ->
case ptFormat of
4 -> if B.length input /= 2 * bytes
then Nothing
else
let (x, y) = B.splitAt bytes input
p = ECC.Point (os2ip x) (os2ip y)
in if ECC.isPointValid curve p
then Just $ ECDSA.PublicKey curve p
else Nothing
_ -> Nothing
where bits = ECC.curveSizeBits curve
bytes = (bits + 7) `div` 8
kxVerify _ _ _ _ = False
kxSign :: MonadRandom r
=> PrivateKey
-> Hash
-> ByteString
-> r (Either KxError ByteString)
kxSign (PrivKeyRSA pk) hashAlg msg =
generalizeRSAError `fmap` rsaSignHash hashAlg pk msg
kxSign (PrivKeyDSA pk) _ msg = do
sign <- DSA.sign pk H.SHA1 msg
return (Right $ encodeASN1' DER $ dsaSequence sign)
where dsaSequence sign = [Start Sequence,IntVal (DSA.sign_r sign),IntVal (DSA.sign_s sign),End Sequence]
rsaSignHash :: MonadRandom m => Hash -> RSA.PrivateKey -> ByteString -> m (Either RSA.Error ByteString)
rsaSignHash SHA1_MD5 pk msg = RSA.signSafer noHash pk msg
rsaSignHash MD5 pk msg = RSA.signSafer (Just H.MD5) pk msg
rsaSignHash SHA1 pk msg = RSA.signSafer (Just H.SHA1) pk msg
rsaSignHash SHA224 pk msg = RSA.signSafer (Just H.SHA224) pk msg
rsaSignHash SHA256 pk msg = RSA.signSafer (Just H.SHA256) pk msg
rsaSignHash SHA384 pk msg = RSA.signSafer (Just H.SHA384) pk msg
rsaSignHash SHA512 pk msg = RSA.signSafer (Just H.SHA512) pk msg
rsaVerifyHash :: Hash -> RSA.PublicKey -> ByteString -> ByteString -> Bool
rsaVerifyHash SHA1_MD5 = RSA.verify noHash
rsaVerifyHash MD5 = RSA.verify (Just H.MD5)
rsaVerifyHash SHA1 = RSA.verify (Just H.SHA1)
rsaVerifyHash SHA224 = RSA.verify (Just H.SHA224)
rsaVerifyHash SHA256 = RSA.verify (Just H.SHA256)
rsaVerifyHash SHA384 = RSA.verify (Just H.SHA384)
rsaVerifyHash SHA512 = RSA.verify (Just H.SHA512)
noHash :: Maybe H.MD5
noHash = Nothing