-- | -- Module : Data.Serialize.RLP -- License : LGPL-3 (see LICENSE) -- -- Maintainer : Javier Sagredo <jasataco@gmail.com> -- Stability : stable -- -- An implementation of the Recursive Length Prefix method -- as described in the Yellow Paper <https://ethereum.github.io/yellowpaper/paper.pdf>. -- -- To actually use this module, the type that is going to -- be encoded has to be instance of RLPSerialize defining -- 'toRLP' and 'fromRLP'. -------------------------------------------------------------------------------- module Data.Serialize.RLP ( -- * The RLP Type RLPT(..), -- ** Subtleties -- $subtleties -- * Helper Int functions toBigEndian, toBigEndianS, fromBigEndian, fromBigEndianS, -- * Helper String functions toByteString, toByteStringS, fromByteString, fromByteStringS, -- * The RLPSerialize class RLPSerialize(..) -- * Example -- $example ) where import Data.Serialize.RLP.Internal import qualified Data.ByteString as DBS import qualified Data.ByteString.Lazy as DBSL -------------------------------------------------------------------------------- -- $subtleties -- The idea of transforming a custom type into RLPT is to -- preserve the original structure as far as possible. For example, -- suppose we have a data structure: -- -- > data Name = (String, String) -- represents the first and last name of a Person -- > data Person = Person Name Int -- represents the whole name of a Person and its age -- -- Then the desired output of the transformation of a Person value to RLPT should be (pseudocode): -- -- > RLPL [ RLPL [ RLPB, RLPB ], RLPB ] -- -- This way the structure is clearly preserved. Eventhough this does not have -- to be true as the transformation to RLPL is defined by the user and a custom -- process can be implemented, it is advised to follow this guideline for better -- understanding of the generated code. -- -- It is important to remark that although it can't be imposed, it doesn't make sense to try -- to transform to RLP types with more than one constructor. The transformation should encode -- a way to find out which of the constructors belongs to the data so not only data is being -- encoded in the result, also information about the structure futher than the actual length -- prefixes. That's why it only makes sense to transform to RLP types with just one constructor. -------------------------------------------------------------------------------- -- | The 'RLPSerialize' class provides functions for transforming values to RLPT structures. -- For encoding and decoding values with the RLP protocol, 'toRLP' and 'fromRLP' have to -- be implemented. -- -- Instances of RLPSerialize have to satisfy the following property: -- -- > fromRLP . toRLP == id -- -- In such case, it can be assured with the default definition that: -- -- > rlpDecode . rlpEncode == id -- -- RLPSerialize makes use of the Get and Put classes together with a set of -- custom serializations for encoding and decoding RLPT data. class RLPSerialize a where -- | Transform a value to the 'RLPT' structure that best fits its internal structure toRLP :: a -> RLPT -- | Transform an 'RLPT' structure back into the value it represents fromRLP :: RLPT -> a -- | Transform a value to an 'RLPT' structure and then encode it following the -- RLP standard. rlpEncode :: a -> DBSL.ByteString rlpEncode = rlpEncodeI . toRLP -- | Transform a ByteString to an 'RLPT' structure following the RLP standard and -- then transform it to the original type. rlpDecode :: DBSL.ByteString -> Maybe a rlpDecode x = maybe Nothing fromRLP $ rlpDecodeI x {-# MINIMAL toRLP, fromRLP #-} -- RLPT values don't have to be transformed as they already are RLPT instance RLPSerialize RLPT where toRLP = id fromRLP = id -- ByteStrings just have to be encapsulated -- Also, it only makes sense to disencapsulate from a ByteString instance RLPSerialize DBS.ByteString where toRLP = RLPB fromRLP (RLPB b) = b fromRLP _ = undefined -- Ints have to be transformed into its Big-endian form -- and then they are treated as ByteStrings. -- The same applies for the inverse transformation. They -- are treated as ByteStrings and then interpreted as a -- Big-endian encoded Int. instance RLPSerialize Int where toRLP = toRLP . toBigEndianS fromRLP = fromBigEndianS . (fromRLP :: RLPT -> DBS.ByteString) -- Serializing lists implies making a list with the serialization -- of each element instance RLPSerialize a => RLPSerialize [a] where toRLP = RLPL . map toRLP fromRLP (RLPL x) = map fromRLP x fromRLP _ = undefined -- Bools are serialized as [0] or [1] in a ByteArray -- THIS IS AN ASUMPTION considering Bool equivalent to -- integers in the range 0..1 instance RLPSerialize Bool where toRLP True = RLPB $ toByteStringS "\SOH" toRLP False = RLPB $ toByteStringS "\NUL" fromRLP x | x == toRLP True = True | otherwise = False -- Chars are just length-one strings instance RLPSerialize Char where toRLP = RLPB . toByteStringS . (: []) fromRLP (RLPB x) = head $ fromByteStringS x fromRLP _ = undefined -- Tuples are transformed into Lists instance (RLPSerialize a, RLPSerialize b) => RLPSerialize (a, b) where toRLP (x, y) = RLPL [toRLP x, toRLP y] fromRLP (RLPL [x, y]) = (fromRLP x, fromRLP y) fromRLP _ = undefined instance (RLPSerialize a, RLPSerialize b, RLPSerialize c) => RLPSerialize (a, b, c) where toRLP (x, y, z) = RLPL [toRLP x, toRLP y, toRLP z] fromRLP (RLPL [x, y, z]) = (fromRLP x, fromRLP y, fromRLP z) fromRLP _ = undefined instance (RLPSerialize a, RLPSerialize b, RLPSerialize c, RLPSerialize d) => RLPSerialize (a, b, c, d) where toRLP (a1, a2, a3, a4) = RLPL [toRLP a1, toRLP a2, toRLP a3, toRLP a4] fromRLP (RLPL [a1, a2, a3, a4]) = (fromRLP a1, fromRLP a2, fromRLP a3, fromRLP a4) fromRLP _ = undefined instance (RLPSerialize a, RLPSerialize b, RLPSerialize c, RLPSerialize d, RLPSerialize e) => RLPSerialize (a, b, c, d, e) where toRLP (a1, a2, a3, a4, a5) = RLPL [toRLP a1, toRLP a2, toRLP a3, toRLP a4, toRLP a5] fromRLP (RLPL [a1, a2, a3, a4, a5]) = (fromRLP a1, fromRLP a2, fromRLP a3, fromRLP a4, fromRLP a5) fromRLP _ = undefined instance (RLPSerialize a, RLPSerialize b, RLPSerialize c, RLPSerialize d, RLPSerialize e, RLPSerialize f) => RLPSerialize (a, b, c, d, e, f) where toRLP (a1, a2, a3, a4, a5, a6) = RLPL [toRLP a1, toRLP a2, toRLP a3, toRLP a4, toRLP a5, toRLP a6] fromRLP (RLPL [a1, a2, a3, a4, a5, a6]) = (fromRLP a1, fromRLP a2, fromRLP a3, fromRLP a4, fromRLP a5, fromRLP a6) fromRLP _ = undefined -- Needed by the default rlpDecode implementation instance RLPSerialize a => RLPSerialize (Maybe a) where toRLP = undefined fromRLP = Just . fromRLP -------------------------------------------------------------------------------- -- $example -- For a full example, we reproduce the implementation of the Person type as in the -- subtleties section. -- -- First of all, we define the type: -- -- > type Name = (String, String) -- > data Person = Person { -- > name :: Name, -- > age :: Int -- > } deriving (Show) -- -- Then we have to make it an instance of RLPSerialize: -- -- > instance RLPSerialize Person where -- > toRLP p = RLPL [ -- > RLPL [ -- > toRLP . toByteStringS . fst . name $ p, -- > toRLP . toByteStringS . snd . name $ p -- > ], -- > toRLP . age $ p] -- > -- > fromRLP (RLPL [ RLPL [ RLPB a, RLPB b ], RLPB c ]) = -- > Person (fromByteStringS a, fromByteStringS b) (fromBigEndianS c :: Int) -- -- This way, if the decoding gives rise to other structure than the expected, a runtime -- exception will be thrown by the pattern matching. We can now use our decoder and encoder -- with our custom type: -- -- > p = Person ("John", "Snow") 33 -- > e = rlpEncode p -- > -- "\204\202\132John\132Snow!" ~ [204,202,132,74,111,104,110,132,83,110,111,119,33] -- > rlpDecode e :: Maybe Person -- > -- Just (Person {name = ("John","Snow"), age = 33}) --