{-# Language StrictData #-}
module EVM.ABI
( AbiValue (..)
, AbiType (..)
, Event (..)
, Anonymity (..)
, Indexed (..)
, putAbi
, getAbi
, getAbiSeq
, genAbiValue
, abiValueType
, abiTypeSolidity
, abiCalldata
, abiMethod
, emptyAbi
, encodeAbiValue
, decodeAbiValue
, parseTypeName
, makeAbiValue
, parseAbiValue
, selector
) where
import EVM.Keccak (abiKeccak)
import EVM.Types
import Control.Monad (replicateM, replicateM_, forM_, void)
import Data.Binary.Get (Get, runGet, label, getWord8, getWord32be, skip)
import Data.Binary.Put (Put, runPut, putWord8, putWord32be)
import Data.Bits (shiftL, shiftR, (.&.))
import Data.ByteString (ByteString)
import Data.DoubleWord (Word256, Int256, signedWord)
import Data.Functor (($>))
import Data.Monoid ((<>))
import Data.Text (Text, pack)
import Data.Text.Encoding (encodeUtf8)
import Data.Vector (Vector)
import Data.Word (Word32)
import Data.List (intercalate)
import GHC.Generics
import Test.QuickCheck hiding ((.&.), label)
import Text.ParserCombinators.ReadP
import Control.Applicative
import qualified Data.ByteString as BS
import qualified Data.ByteString.Char8 as Char8
import qualified Data.ByteString.Lazy as BSLazy
import qualified Data.Text as Text
import qualified Data.Vector as Vector
import qualified Text.Megaparsec as P
import qualified Text.Megaparsec.Char as P
data AbiValue
= AbiUInt Int Word256
| AbiInt Int Int256
| AbiAddress Addr
| AbiBool Bool
| AbiBytes Int BS.ByteString
| AbiBytesDynamic BS.ByteString
| AbiString BS.ByteString
| AbiArrayDynamic AbiType (Vector AbiValue)
| AbiArray Int AbiType (Vector AbiValue)
| AbiTuple (Vector AbiValue)
deriving (Read, Eq, Ord, Generic)
instance Show AbiValue where
show (AbiUInt _ n) = show n
show (AbiInt _ n) = show n
show (AbiAddress n) = show n
show (AbiBool b) = if b then "true" else "false"
show (AbiBytes _ b) = show (ByteStringS b)
show (AbiBytesDynamic b) = show (ByteStringS b)
show (AbiString s) = show s
show (AbiArrayDynamic _ v) =
"[" ++ intercalate ", " (show <$> Vector.toList v) ++ "]"
show (AbiArray _ _ v) =
"[" ++ intercalate ", " (show <$> Vector.toList v) ++ "]"
show (AbiTuple v) =
"(" ++ intercalate ", " (show <$> Vector.toList v) ++ ")"
data AbiType
= AbiUIntType Int
| AbiIntType Int
| AbiAddressType
| AbiBoolType
| AbiBytesType Int
| AbiBytesDynamicType
| AbiStringType
| AbiArrayDynamicType AbiType
| AbiArrayType Int AbiType
| AbiTupleType (Vector AbiType)
deriving (Read, Eq, Ord, Generic)
instance Show AbiType where
show = Text.unpack . abiTypeSolidity
data AbiKind = Dynamic | Static
deriving (Show, Read, Eq, Ord, Generic)
data Anonymity = Anonymous | NotAnonymous
deriving (Show, Ord, Eq, Generic)
data Indexed = Indexed | NotIndexed
deriving (Show, Ord, Eq, Generic)
data Event = Event Text Anonymity [(AbiType, Indexed)]
deriving (Show, Ord, Eq, Generic)
abiKind :: AbiType -> AbiKind
abiKind = \case
AbiBytesDynamicType -> Dynamic
AbiStringType -> Dynamic
AbiArrayDynamicType _ -> Dynamic
AbiArrayType _ t -> abiKind t
AbiTupleType ts -> if Dynamic `elem` (abiKind <$> ts) then Dynamic else Static
_ -> Static
abiValueType :: AbiValue -> AbiType
abiValueType = \case
AbiUInt n _ -> AbiUIntType n
AbiInt n _ -> AbiIntType n
AbiAddress _ -> AbiAddressType
AbiBool _ -> AbiBoolType
AbiBytes n _ -> AbiBytesType n
AbiBytesDynamic _ -> AbiBytesDynamicType
AbiString _ -> AbiStringType
AbiArrayDynamic t _ -> AbiArrayDynamicType t
AbiArray n t _ -> AbiArrayType n t
AbiTuple v -> AbiTupleType (abiValueType <$> v)
abiTypeSolidity :: AbiType -> Text
abiTypeSolidity = \case
AbiUIntType n -> "uint" <> pack (show n)
AbiIntType n -> "int" <> pack (show n)
AbiAddressType -> "address"
AbiBoolType -> "bool"
AbiBytesType n -> "bytes" <> pack (show n)
AbiBytesDynamicType -> "bytes"
AbiStringType -> "string"
AbiArrayDynamicType t -> abiTypeSolidity t <> "[]"
AbiArrayType n t -> abiTypeSolidity t <> "[" <> pack (show n) <> "]"
AbiTupleType ts -> "(" <> (Text.intercalate "," . Vector.toList $ abiTypeSolidity <$> ts) <> ")"
getAbi :: AbiType -> Get AbiValue
getAbi t = label (Text.unpack (abiTypeSolidity t)) $
case t of
AbiUIntType n -> do
let word32Count = 8 * div (n + 255) 256
xs <- replicateM word32Count getWord32be
pure (AbiUInt n (pack32 word32Count xs))
AbiIntType n -> asUInt n (AbiInt n)
AbiAddressType -> asUInt 256 AbiAddress
AbiBoolType -> asUInt 256 (AbiBool . (== (1 :: Int)))
AbiBytesType n ->
AbiBytes n <$> getBytesWith256BitPadding n
AbiBytesDynamicType ->
AbiBytesDynamic <$>
(label "bytes length prefix" getWord256
>>= label "bytes data" . getBytesWith256BitPadding)
AbiStringType -> do
AbiBytesDynamic x <- getAbi AbiBytesDynamicType
pure (AbiString x)
AbiArrayType n t' ->
AbiArray n t' <$> getAbiSeq n (repeat t')
AbiArrayDynamicType t' -> do
AbiUInt _ n <- label "array length" (getAbi (AbiUIntType 256))
AbiArrayDynamic t' <$>
label "array body" (getAbiSeq (fromIntegral n) (repeat t'))
AbiTupleType ts ->
AbiTuple <$> getAbiSeq (Vector.length ts) (Vector.toList ts)
putAbi :: AbiValue -> Put
putAbi = \case
AbiUInt _ x ->
forM_ (reverse [0 .. 7]) $ \i ->
putWord32be (fromIntegral (shiftR x (i * 32) .&. 0xffffffff))
AbiInt n x -> putAbi (AbiUInt n (fromIntegral x))
AbiAddress x -> putAbi (AbiUInt 160 (fromIntegral x))
AbiBool x -> putAbi (AbiUInt 8 (if x then 1 else 0))
AbiBytes n xs -> do
forM_ [0 .. n-1] (putWord8 . BS.index xs)
replicateM_ (roundTo32Bytes n - n) (putWord8 0)
AbiBytesDynamic xs -> do
let n = BS.length xs
putAbi (AbiUInt 256 (fromIntegral n))
putAbi (AbiBytes n xs)
AbiString s ->
putAbi (AbiBytesDynamic s)
AbiArray _ _ xs ->
putAbiSeq xs
AbiArrayDynamic _ xs -> do
putAbi (AbiUInt 256 (fromIntegral (Vector.length xs)))
putAbiSeq xs
AbiTuple v ->
putAbiSeq v
getAbiSeq :: Int -> [AbiType] -> Get (Vector AbiValue)
getAbiSeq n ts = label "sequence" $ do
hs <- label "sequence head" (getAbiHead n ts)
Vector.fromList <$>
label "sequence tail" (mapM (either getAbi pure) hs)
getAbiHead :: Int -> [AbiType]
-> Get [Either AbiType AbiValue]
getAbiHead 0 _ = pure []
getAbiHead _ [] = fail "ran out of types"
getAbiHead n (t:ts) =
case abiKind t of
Dynamic ->
(Left t :) <$> (skip 32 *> getAbiHead (n - 1) ts)
Static ->
do x <- getAbi t
xs <- getAbiHead (n - 1) ts
pure (Right x : xs)
putAbiTail :: AbiValue -> Put
putAbiTail x =
case abiKind (abiValueType x) of
Static -> pure ()
Dynamic -> putAbi x
abiValueSize :: AbiValue -> Int
abiValueSize x =
case x of
AbiUInt _ _ -> 32
AbiInt _ _ -> 32
AbiBytes n _ -> roundTo32Bytes n
AbiAddress _ -> 32
AbiBool _ -> 32
AbiArray _ _ xs -> Vector.sum (Vector.map abiHeadSize xs) +
Vector.sum (Vector.map abiTailSize xs)
AbiBytesDynamic xs -> 32 + roundTo32Bytes (BS.length xs)
AbiArrayDynamic _ xs -> 32 + Vector.sum (Vector.map abiHeadSize xs) +
Vector.sum (Vector.map abiTailSize xs)
AbiString s -> 32 + roundTo32Bytes (BS.length s)
AbiTuple v -> sum (abiValueSize <$> v)
abiTailSize :: AbiValue -> Int
abiTailSize x =
case abiKind (abiValueType x) of
Static -> 0
Dynamic ->
case x of
AbiString s -> 32 + roundTo32Bytes (BS.length s)
AbiBytesDynamic s -> 32 + roundTo32Bytes (BS.length s)
AbiArrayDynamic _ xs -> 32 + Vector.sum (Vector.map abiValueSize xs)
AbiArray _ _ xs -> Vector.sum (Vector.map abiValueSize xs)
AbiTuple v -> sum (headSize <$> v) + sum (abiTailSize <$> v)
_ -> error "impossible"
where headSize y = if abiKind (abiValueType y) == Static
then abiValueSize y
else 32
abiHeadSize :: AbiValue -> Int
abiHeadSize x =
case abiKind (abiValueType x) of
Dynamic -> 32
Static ->
case x of
AbiUInt _ _ -> 32
AbiInt _ _ -> 32
AbiBytes n _ -> roundTo32Bytes n
AbiAddress _ -> 32
AbiBool _ -> 32
AbiArray _ _ xs -> Vector.sum (Vector.map abiHeadSize xs) +
Vector.sum (Vector.map abiTailSize xs)
AbiBytesDynamic _ -> 32
AbiArrayDynamic _ _ -> 32
AbiString _ -> 32
AbiTuple v -> sum (abiHeadSize <$> v) +
sum (abiTailSize <$> v)
putAbiSeq :: Vector AbiValue -> Put
putAbiSeq xs =
do snd $ Vector.foldl' f (headSize, pure ()) (Vector.zip xs tailSizes)
Vector.sequence_ (Vector.map putAbiTail xs)
where
headSize = Vector.sum $ Vector.map abiHeadSize xs
tailSizes = Vector.map abiTailSize xs
f (i, m) (x, j) =
case abiKind (abiValueType x) of
Static -> (i, m >> putAbi x)
Dynamic -> (i + j, m >> putAbi (AbiUInt 256 (fromIntegral i)))
encodeAbiValue :: AbiValue -> BS.ByteString
encodeAbiValue = BSLazy.toStrict . runPut . putAbi
decodeAbiValue :: AbiType -> BSLazy.ByteString -> AbiValue
decodeAbiValue = runGet . getAbi
selector :: Text -> BS.ByteString
selector s = BSLazy.toStrict . runPut $ putWord32be (abiKeccak (encodeUtf8 s))
abiMethod :: Text -> AbiValue -> BS.ByteString
abiMethod s args = BSLazy.toStrict . runPut $ do
putWord32be (abiKeccak (encodeUtf8 s))
putAbi args
abiCalldata :: Text -> Vector AbiValue -> BS.ByteString
abiCalldata s xs = BSLazy.toStrict . runPut $ do
putWord32be (abiKeccak (encodeUtf8 s))
putAbiSeq xs
parseTypeName :: Vector AbiType -> Text -> Maybe AbiType
parseTypeName = P.parseMaybe . typeWithArraySuffix
typeWithArraySuffix :: Vector AbiType -> P.Parsec () Text AbiType
typeWithArraySuffix v = do
base <- basicType v
sizes <-
P.many $
P.between
(P.char '[') (P.char ']')
(P.many P.digitChar)
let
parseSize :: AbiType -> String -> AbiType
parseSize t "" = AbiArrayDynamicType t
parseSize t s = AbiArrayType (read s) t
pure (foldl parseSize base sizes)
basicType :: Vector AbiType -> P.Parsec () Text AbiType
basicType v =
P.choice
[ P.string "address" $> AbiAddressType
, P.string "bool" $> AbiBoolType
, P.string "string" $> AbiStringType
, sizedType "uint" AbiUIntType
, sizedType "int" AbiIntType
, sizedType "bytes" AbiBytesType
, P.string "bytes" $> AbiBytesDynamicType
, P.string "tuple" $> AbiTupleType v
]
where
sizedType :: Text -> (Int -> AbiType) -> P.Parsec () Text AbiType
sizedType s f = P.try $ do
void (P.string s)
fmap (f . read) (P.some P.digitChar)
pack32 :: Int -> [Word32] -> Word256
pack32 n xs =
sum [ shiftL x ((n - i) * 32)
| (x, i) <- zip (map fromIntegral xs) [1..] ]
asUInt :: Integral i => Int -> (i -> a) -> Get a
asUInt n f = (\(AbiUInt _ x) -> f (fromIntegral x)) <$> getAbi (AbiUIntType n)
getWord256 :: Get Word256
getWord256 = pack32 8 <$> replicateM 8 getWord32be
roundTo32Bytes :: Integral a => a -> a
roundTo32Bytes n = 32 * div (n + 31) 32
emptyAbi :: AbiValue
emptyAbi = AbiTuple mempty
getBytesWith256BitPadding :: Integral a => a -> Get ByteString
getBytesWith256BitPadding i =
(BS.pack <$> replicateM n getWord8)
<* skip ((roundTo32Bytes n) - n)
where n = fromIntegral i
genAbiValue :: AbiType -> Gen AbiValue
genAbiValue = \case
AbiUIntType n -> genUInt n
AbiIntType n ->
do a <- genUInt n
let AbiUInt _ x = a
pure $ AbiInt n (signedWord x)
AbiAddressType ->
(\(AbiUInt _ x) -> AbiAddress (fromIntegral x)) <$> genUInt 20
AbiBoolType ->
elements [AbiBool False, AbiBool True]
AbiBytesType n ->
do xs <- replicateM n arbitrary
pure (AbiBytes n (BS.pack xs))
AbiBytesDynamicType ->
AbiBytesDynamic . BS.pack <$> listOf arbitrary
AbiStringType ->
AbiString . BS.pack <$> listOf arbitrary
AbiArrayDynamicType t ->
do xs <- listOf1 (scale (`div` 2) (genAbiValue t))
pure (AbiArrayDynamic t (Vector.fromList xs))
AbiArrayType n t ->
AbiArray n t . Vector.fromList <$>
replicateM n (scale (`div` 2) (genAbiValue t))
AbiTupleType ts ->
AbiTuple <$> mapM genAbiValue ts
where
genUInt n = AbiUInt n <$> arbitraryIntegralWithMax n
instance Arbitrary AbiType where
arbitrary = sized $ \n -> oneof $
[ (AbiUIntType . (* 8)) <$> choose (1, 32)
, (AbiIntType . (* 8)) <$> choose (1, 32)
, pure AbiAddressType
, pure AbiBoolType
, AbiBytesType . getPositive <$> arbitrary
, pure AbiBytesDynamicType
, pure AbiStringType
, AbiArrayDynamicType <$> scale (`div` 2) arbitrary
, AbiArrayType
<$> (getPositive <$> arbitrary)
<*> scale (`div` 2) arbitrary
] <>
[AbiTupleType
<$> scale (`div` 2) (Vector.fromList <$> arbitrary)
| n /= 0]
instance Arbitrary AbiValue where
arbitrary = arbitrary >>= genAbiValue
shrink = \case
AbiArrayDynamic t v ->
Vector.toList v ++
map (AbiArrayDynamic t . Vector.fromList)
(shrinkList shrink (Vector.toList v))
AbiBytesDynamic b -> AbiBytesDynamic . BS.pack <$> shrinkList shrinkIntegral (BS.unpack b)
AbiString b -> AbiString . BS.pack <$> shrinkList shrinkIntegral (BS.unpack b)
AbiBytes n a | n <= 32 -> shrink $ AbiUInt (n * 8) (word256 a)
AbiBytes _ _ | otherwise -> []
AbiArray _ t v ->
Vector.toList v ++
map (\x -> AbiArray (length x) t (Vector.fromList x))
(shrinkList shrink (Vector.toList v))
AbiTuple v -> Vector.toList $ AbiTuple . Vector.fromList . shrink <$> v
AbiUInt n a -> AbiUInt n <$> (shrinkIntegral a)
AbiInt n a -> AbiInt n <$> (shrinkIntegral a)
AbiBool b -> AbiBool <$> shrink b
AbiAddress a -> [AbiAddress 0xacab, AbiAddress 0xdeadbeef, AbiAddress 0xbabeface]
<> (AbiAddress <$> shrinkIntegral a)
data Boolz = Boolz Bool
instance Read Boolz where
readsPrec _ ('T':'r':'u':'e':x) = [(Boolz True, x)]
readsPrec _ ('t':'r':'u':'e':x) = [(Boolz True, x)]
readsPrec _ ('f':'a':'l':'s':'e':x) = [(Boolz False, x)]
readsPrec _ ('F':'a':'l':'s':'e':x) = [(Boolz False, x)]
readsPrec _ [] = []
readsPrec n (_:t) = readsPrec n t
makeAbiValue :: AbiType -> String -> AbiValue
makeAbiValue typ str = case readP_to_S (parseAbiValue typ) str of
[] -> error "could not parse abi arguments"
((val,_):_) -> val
parseAbiValue :: AbiType -> ReadP AbiValue
parseAbiValue (AbiUIntType n) = do W256 w256 <- readS_to_P reads
return $ AbiUInt n w256
parseAbiValue (AbiIntType n) = do W256 w256 <- readS_to_P reads
return $ AbiInt n (num w256)
parseAbiValue AbiAddressType = AbiAddress <$> readS_to_P reads
parseAbiValue AbiBoolType = (do W256 w256 <- readS_to_P reads
return $ AbiBool (w256 /= 0))
<|> (do Boolz b <- readS_to_P reads
return $ AbiBool b)
parseAbiValue (AbiBytesType n) = AbiBytes n <$> do ByteStringS bytes <- readS_to_P reads
return bytes
parseAbiValue AbiBytesDynamicType = AbiBytesDynamic <$> do ByteStringS bytes <- readS_to_P reads
return bytes
parseAbiValue AbiStringType = AbiString <$> do Char8.pack <$> readS_to_P reads
parseAbiValue (AbiArrayDynamicType typ) =
AbiArrayDynamic typ <$> do a <- listP (parseAbiValue typ)
return $ Vector.fromList a
parseAbiValue (AbiArrayType n typ) =
AbiArray n typ <$> do a <- listP (parseAbiValue typ)
return $ Vector.fromList a
parseAbiValue (AbiTupleType _) = error "tuple types not supported"
listP :: ReadP a -> ReadP [a]
listP parser = between (char '[') (char ']') ((do skipSpaces
a <- parser
skipSpaces
return a) `sepBy` (char ','))
arbitraryIntegralWithMax :: (Integral a) => Int -> Gen a
arbitraryIntegralWithMax maxbound =
sized $ \s ->
do let mn = 0 :: Int
mx = maxbound
bits n | n `quot` 2 == 0 = 0
| otherwise = 1 + bits (n `quot` 2)
k = 2^(s*(bits mn `max` bits mx `max` 40) `div` 100)
smol <- choose (toInteger mn `max` (-k), toInteger mx `min` k)
mid <- choose (0, maxbound)
elements [fromIntegral smol, fromIntegral mid, fromIntegral (maxbound - (fromIntegral smol))]