module Data.X509.PublicKey
( PubKey(..)
, PubKeyEC(..)
, SerializedPoint(..)
, pubkeyToAlg
) where
import Data.ASN1.Types
import Data.ASN1.Encoding
import Data.ASN1.BinaryEncoding
import Data.ASN1.BitArray
import Data.Bits
import Data.ByteString (ByteString)
import Data.X509.Internal
import Data.X509.OID
import Data.X509.AlgorithmIdentifier
import qualified Crypto.PubKey.RSA.Types as RSA
import qualified Crypto.PubKey.DSA as DSA
import qualified Crypto.PubKey.ECC.Types as ECC
import Crypto.Number.Serialize (os2ip)
import Data.Word
import qualified Data.ByteString as B
newtype SerializedPoint = SerializedPoint ByteString
deriving (Show,Eq)
data PubKeyEC =
PubKeyEC_Prime
{ pubkeyEC_pub :: SerializedPoint
, pubkeyEC_a :: Integer
, pubkeyEC_b :: Integer
, pubkeyEC_prime :: Integer
, pubkeyEC_generator :: SerializedPoint
, pubkeyEC_order :: Integer
, pubkeyEC_cofactor :: Integer
, pubkeyEC_seed :: Integer
}
| PubKeyEC_Named
{ pubkeyEC_name :: ECC.CurveName
, pubkeyEC_pub :: SerializedPoint
}
deriving (Show,Eq)
data PubKey =
PubKeyRSA RSA.PublicKey
| PubKeyDSA DSA.PublicKey
| PubKeyDH (Integer,Integer,Integer,Maybe Integer,([Word8], Integer))
| PubKeyEC PubKeyEC
| PubKeyUnknown OID B.ByteString
deriving (Show,Eq)
instance ASN1Object PubKey where
fromASN1 (Start Sequence:Start Sequence:OID pkalg:xs)
| pkalg == getObjectID PubKeyALG_RSA =
case removeNull xs of
End Sequence:BitString bits:End Sequence:xs2 -> decodeASN1Err "RSA" bits xs2 (toPubKeyRSA . rsaPubFromASN1)
_ -> Left ("fromASN1: X509.PubKey: unknown RSA format: " ++ show xs)
| pkalg == getObjectID PubKeyALG_DSA =
case xs of
Start Sequence:IntVal p:IntVal q:IntVal g:End Sequence:End Sequence:BitString bits:End Sequence:xs2 ->
decodeASN1Err "DSA" bits xs2 (\l -> case l of
[IntVal dsapub] ->
let pubkey = DSA.PublicKey { DSA.public_params = DSA.Params { DSA.params_p = p
, DSA.params_q = q
, DSA.params_g = g
}
, DSA.public_y = dsapub }
in Right (PubKeyDSA pubkey, [])
_ -> Left "fromASN1: X509.PubKey: unknown DSA format"
)
_ -> Left "fromASN1: X509.PubKey: unknown DSA format"
| pkalg == getObjectID PubKeyALG_EC =
case xs of
OID curveOid:End Sequence:BitString bits:End Sequence:xs2 ->
case lookupByOID curvesOIDTable curveOid of
Just curveName -> Right (PubKeyEC $ PubKeyEC_Named curveName (bitArrayToPoint bits), xs2)
Nothing -> Left ("fromASN1: X509.Pubkey: EC unknown curve " ++ show curveOid)
Start Sequence
:IntVal 1
:Start Sequence
:OID [1,2,840,10045,1,1]
:IntVal prime
:End Sequence
:Start Sequence
:OctetString a
:OctetString b
:BitString seed
:End Sequence
:OctetString generator
:IntVal order
:IntVal cofactor
:End Sequence
:End Sequence
:BitString pub
:End Sequence
:xs2 ->
Right (PubKeyEC $ PubKeyEC_Prime
{ pubkeyEC_pub = bitArrayToPoint pub
, pubkeyEC_a = os2ip a
, pubkeyEC_b = os2ip b
, pubkeyEC_prime = prime
, pubkeyEC_generator = SerializedPoint generator
, pubkeyEC_order = order
, pubkeyEC_cofactor = cofactor
, pubkeyEC_seed = os2ip $ bitArrayGetData seed
}, xs2)
_ ->
Left $ "fromASN1: X509.PubKey: unknown EC format: " ++ show xs
| otherwise = error ("unknown public key OID: " ++ show pkalg)
where decodeASN1Err format bits xs2 f =
case decodeASN1' BER (bitArrayGetData bits) of
Left err -> Left ("fromASN1: X509.PubKey " ++ format ++ " bitarray cannot be parsed: " ++ show err)
Right s -> case f s of
Left err -> Left err
Right (r, xsinner) -> Right (r, xsinner ++ xs2)
toPubKeyRSA = either Left (\(rsaKey, r) -> Right (PubKeyRSA rsaKey, r))
bitArrayToPoint = SerializedPoint . bitArrayGetData
removeNull (Null:r) = r
removeNull l = l
fromASN1 l = Left ("fromASN1: X509.PubKey: unknown format:" ++ show l)
toASN1 a = \xs -> encodePK a ++ xs
pubkeyToAlg :: PubKey -> PubKeyALG
pubkeyToAlg (PubKeyRSA _) = PubKeyALG_RSA
pubkeyToAlg (PubKeyDSA _) = PubKeyALG_DSA
pubkeyToAlg (PubKeyDH _) = PubKeyALG_DH
pubkeyToAlg (PubKeyEC _) = PubKeyALG_EC
pubkeyToAlg (PubKeyUnknown oid _) = PubKeyALG_Unknown oid
encodePK :: PubKey -> [ASN1]
encodePK key = asn1Container Sequence (encodeInner key)
where
pkalg = OID $ getObjectID $ pubkeyToAlg key
encodeInner (PubKeyRSA pubkey) =
asn1Container Sequence [pkalg,Null] ++ [BitString $ toBitArray bits 0]
where bits = encodeASN1' DER $ rsaPubToASN1 pubkey []
encodeInner (PubKeyDSA pubkey) =
asn1Container Sequence ([pkalg] ++ dsaseq) ++ [BitString $ toBitArray bits 0]
where
dsaseq = asn1Container Sequence [IntVal (DSA.params_p params)
,IntVal (DSA.params_q params)
,IntVal (DSA.params_g params)]
params = DSA.public_params pubkey
bits = encodeASN1' DER [IntVal $ DSA.public_y pubkey]
encodeInner (PubKeyEC (PubKeyEC_Named curveName (SerializedPoint bits))) =
asn1Container Sequence [pkalg,OID eOid] ++ [BitString $ toBitArray bits 0]
where
eOid = case curveName of
ECC.SEC_p384r1 -> [1,3,132,0,34]
_ -> error ("undefined curve OID: " ++ show curveName)
encodeInner (PubKeyEC (PubKeyEC_Prime {})) =
error "encodeInner: unimplemented public key EC_Prime"
encodeInner (PubKeyDH _) = error "encodeInner: unimplemented public key DH"
encodeInner (PubKeyUnknown _ l) =
asn1Container Sequence [pkalg,Null] ++ [BitString $ toBitArray l 0]
rsaPubToASN1 :: RSA.PublicKey -> [ASN1] -> [ASN1]
rsaPubToASN1 pubkey xs =
Start Sequence : IntVal (RSA.public_n pubkey) : IntVal (RSA.public_e pubkey) : End Sequence : xs
rsaPubFromASN1 :: [ASN1] -> Either String (RSA.PublicKey, [ASN1])
rsaPubFromASN1 (Start Sequence:IntVal smodulus:IntVal pubexp:End Sequence:xs) =
Right (pub, xs)
where
pub = RSA.PublicKey { RSA.public_size = calculate_modulus modulus 1
, RSA.public_n = modulus
, RSA.public_e = pubexp
}
calculate_modulus n i = if (2 ^ (i * 8)) > n then i else calculate_modulus n (i+1)
modulus = toPositive smodulus
rsaPubFromASN1 ( Start Sequence
: IntVal ver
: Start Sequence
: OID oid
: Null
: End Sequence
: OctetString bs
: xs
)
| ver /= 0 = Left "rsaPubFromASN1: Invalid version, expecting 0"
| oid /= [1,2,840,113549,1,1,1] =
Left "rsaPubFromASN1: invalid OID"
| otherwise =
let inner = either strError rsaPubFromASN1 $ decodeASN1' BER bs
strError = Left . ("fromASN1: RSA.PublicKey: " ++) . show
in either Left (\(k, _) -> Right (k, xs)) inner
rsaPubFromASN1 _ =
Left "fromASN1: RSA.PublicKey: unexpected format"
toPositive :: Integer -> Integer
toPositive int
| int < 0 = uintOfBytes $ bytesOfInt int
| otherwise = int
where
uintOfBytes = foldl (\acc n -> (acc `shiftL` 8) + fromIntegral n) 0
bytesOfInt :: Integer -> [Word8]
bytesOfInt n = if testBit (head nints) 7 then nints else 0xff : nints
where nints = reverse $ plusOne $ reverse $ map complement $ bytesOfUInt (abs n)
plusOne [] = [1]
plusOne (x:xs) = if x == 0xff then 0 : plusOne xs else (x+1) : xs
bytesOfUInt x = reverse (list x)
where list i = if i <= 0xff then [fromIntegral i] else (fromIntegral i .&. 0xff) : list (i `shiftR` 8)