module Thrift.Protocol.Compact
( module Thrift.Protocol
, CompactProtocol(..)
) where
import Control.Applicative
import Control.Exception ( throw )
import Control.Monad
import Data.Attoparsec.ByteString as P
import Data.Attoparsec.ByteString.Lazy as LP
import Data.Bits
import Data.ByteString.Lazy.Builder as B
import Data.Int
import Data.List as List
import Data.Monoid
import Data.Word
import Data.Text.Lazy.Encoding ( decodeUtf8, encodeUtf8 )
import Thrift.Protocol hiding (versionMask)
import Thrift.Transport
import Thrift.Types
import qualified Data.ByteString as BS
import qualified Data.ByteString.Lazy as LBS
import qualified Data.HashMap.Strict as Map
import qualified Data.Text.Lazy as LT
data CompactProtocol a = CompactProtocol a
protocolID, version, typeMask :: Int8
protocolID = 0x82
version = 0x01
versionMask = 0x1f
typeMask = 0xe0
typeBits = 0x07
typeShiftAmount :: Int
typeShiftAmount = 5
instance Protocol CompactProtocol where
getTransport (CompactProtocol t) = t
writeMessageBegin p (n, t, s) = tWrite (getTransport p) $ toLazyByteString $
B.int8 protocolID <>
B.int8 ((version .&. versionMask) .|.
(((fromIntegral $ fromEnum t) `shiftL`
typeShiftAmount) .&. typeMask)) <>
buildVarint (i32ToZigZag s) <>
buildCompactValue (TString $ encodeUtf8 n)
readMessageBegin p = runParser p $ do
pid <- fromIntegral <$> P.anyWord8
when (pid /= protocolID) $ error "Bad Protocol ID"
w <- fromIntegral <$> P.anyWord8
let ver = w .&. versionMask
when (ver /= version) $ error "Bad Protocol version"
let typ = (w `shiftR` typeShiftAmount) .&. typeBits
seqId <- parseVarint zigZagToI32
TString name <- parseCompactValue T_STRING
return (decodeUtf8 name, toEnum $ fromIntegral $ typ, seqId)
serializeVal _ = toLazyByteString . buildCompactValue
deserializeVal _ ty bs =
case LP.eitherResult $ LP.parse (parseCompactValue ty) bs of
Left s -> error s
Right val -> val
readVal p ty = runParser p $ parseCompactValue ty
buildCompactValue :: ThriftVal -> Builder
buildCompactValue (TStruct fields) = buildCompactStruct fields
buildCompactValue (TMap kt vt entries) =
let len = fromIntegral $ length entries :: Word32 in
if len == 0
then B.word8 0x00
else buildVarint len <>
B.word8 (fromTType kt `shiftL` 4 .|. fromTType vt) <>
buildCompactMap entries
buildCompactValue (TList ty entries) =
let len = length entries in
(if len < 15
then B.word8 $ (fromIntegral len `shiftL` 4) .|. fromTType ty
else B.word8 (0xF0 .|. fromTType ty) <>
buildVarint (fromIntegral len :: Word32)) <>
buildCompactList entries
buildCompactValue (TSet ty entries) = buildCompactValue (TList ty entries)
buildCompactValue (TBool b) =
B.word8 $ toEnum $ if b then 1 else 0
buildCompactValue (TByte b) = int8 b
buildCompactValue (TI16 i) = buildVarint $ i16ToZigZag i
buildCompactValue (TI32 i) = buildVarint $ i32ToZigZag i
buildCompactValue (TI64 i) = buildVarint $ i64ToZigZag i
buildCompactValue (TDouble d) = doubleBE d
buildCompactValue (TString s) = buildVarint len <> lazyByteString s
where
len = fromIntegral (LBS.length s) :: Word32
buildCompactStruct :: Map.HashMap Int16 (LT.Text, ThriftVal) -> Builder
buildCompactStruct = flip (loop 0) mempty . Map.toList
where
loop _ [] acc = acc <> B.word8 (fromTType T_STOP)
loop lastId ((fid, (_,val)) : fields) acc = loop fid fields $ acc <>
(if fid > lastId && fid lastId <= 15
then B.word8 $ fromIntegral ((fid lastId) `shiftL` 4) .|. typeOf val
else B.word8 (typeOf val) <> buildVarint (i16ToZigZag fid)) <>
(if typeOf val > 0x02
then buildCompactValue val
else mempty)
buildCompactMap :: [(ThriftVal, ThriftVal)] -> Builder
buildCompactMap = foldl combine mempty
where
combine s (key, val) = buildCompactValue key <> buildCompactValue val <> s
buildCompactList :: [ThriftVal] -> Builder
buildCompactList = foldr (mappend . buildCompactValue) mempty
parseCompactValue :: ThriftType -> Parser ThriftVal
parseCompactValue (T_STRUCT _) = TStruct <$> parseCompactStruct
parseCompactValue (T_MAP kt' vt') = do
n <- parseVarint id
if n == 0
then return $ TMap kt' vt' []
else do
w <- P.anyWord8
let kt = typeFrom $ w `shiftR` 4
vt = typeFrom $ w .&. 0x0F
TMap kt vt <$> parseCompactMap kt vt n
parseCompactValue (T_LIST ty) = TList ty <$> parseCompactList
parseCompactValue (T_SET ty) = TSet ty <$> parseCompactList
parseCompactValue T_BOOL = TBool . (/=0) <$> P.anyWord8
parseCompactValue T_BYTE = TByte . fromIntegral <$> P.anyWord8
parseCompactValue T_I16 = TI16 <$> parseVarint zigZagToI16
parseCompactValue T_I32 = TI32 <$> parseVarint zigZagToI32
parseCompactValue T_I64 = TI64 <$> parseVarint zigZagToI64
parseCompactValue T_DOUBLE = TDouble . bsToDouble <$> P.take 8
parseCompactValue T_STRING = do
len :: Word32 <- parseVarint id
TString . LBS.fromStrict <$> P.take (fromIntegral len)
parseCompactValue ty = error $ "Cannot read value of type " ++ show ty
parseCompactStruct :: Parser (Map.HashMap Int16 (LT.Text, ThriftVal))
parseCompactStruct = Map.fromList <$> parseFields 0
where
parseFields :: Int16 -> Parser [(Int16, (LT.Text, ThriftVal))]
parseFields lastId = do
w <- P.anyWord8
if w == 0x00
then return []
else do
let ty = typeFrom (w .&. 0x0F)
modifier = (w .&. 0xF0) `shiftR` 4
fid <- if modifier /= 0
then return (lastId + fromIntegral modifier)
else parseVarint zigZagToI16
val <- if ty == T_BOOL
then return (TBool $ (w .&. 0x0F) == 0x01)
else parseCompactValue ty
((fid, (LT.empty, val)) : ) <$> parseFields fid
parseCompactMap :: ThriftType -> ThriftType -> Int32 ->
Parser [(ThriftVal, ThriftVal)]
parseCompactMap kt vt n | n <= 0 = return []
| otherwise = do
k <- parseCompactValue kt
v <- parseCompactValue vt
((k,v) :) <$> parseCompactMap kt vt (n1)
parseCompactList :: Parser [ThriftVal]
parseCompactList = do
w <- P.anyWord8
let ty = typeFrom $ w .&. 0x0F
lsize = w `shiftR` 4
size <- if lsize == 0xF
then parseVarint id
else return $ fromIntegral lsize
loop ty size
where
loop :: ThriftType -> Int32 -> Parser [ThriftVal]
loop ty n | n <= 0 = return []
| otherwise = liftM2 (:) (parseCompactValue ty)
(loop ty (n1))
i16ToZigZag :: Int16 -> Word16
i16ToZigZag n = fromIntegral $ (n `shiftL` 1) `xor` (n `shiftR` 15)
zigZagToI16 :: Word16 -> Int16
zigZagToI16 n = fromIntegral $ (n `shiftR` 1) `xor` negate (n .&. 0x1)
i32ToZigZag :: Int32 -> Word32
i32ToZigZag n = fromIntegral $ (n `shiftL` 1) `xor` (n `shiftR` 31)
zigZagToI32 :: Word32 -> Int32
zigZagToI32 n = fromIntegral $ (n `shiftR` 1) `xor` negate (n .&. 0x1)
i64ToZigZag :: Int64 -> Word64
i64ToZigZag n = fromIntegral $ (n `shiftL` 1) `xor` (n `shiftR` 63)
zigZagToI64 :: Word64 -> Int64
zigZagToI64 n = fromIntegral $ (n `shiftR` 1) `xor` negate (n .&. 0x1)
buildVarint :: (Bits a, Integral a) => a -> Builder
buildVarint n | n .&. complement 0x7F == 0 = B.word8 $ fromIntegral n
| otherwise = B.word8 (0x80 .|. (fromIntegral n .&. 0x7F)) <>
buildVarint (n `shiftR` 7)
parseVarint :: (Bits a, Integral a, Ord a) => (a -> b) -> Parser b
parseVarint fromZigZag = do
bytestemp <- BS.unpack <$> P.takeTill (not . flip testBit 7)
lsb <- P.anyWord8
let bytes = lsb : List.reverse bytestemp
return $ fromZigZag $ List.foldl' combine 0x00 bytes
where combine a b = (a `shiftL` 7) .|. (fromIntegral b .&. 0x7f)
fromTType :: ThriftType -> Word8
fromTType ty = case ty of
T_STOP -> 0x00
T_BOOL -> 0x01
T_BYTE -> 0x03
T_I16 -> 0x04
T_I32 -> 0x05
T_I64 -> 0x06
T_DOUBLE -> 0x07
T_STRING -> 0x08
T_LIST{} -> 0x09
T_SET{} -> 0x0A
T_MAP{} -> 0x0B
T_STRUCT{} -> 0x0C
T_VOID -> error "No Compact type for T_VOID"
typeOf :: ThriftVal -> Word8
typeOf v = case v of
TBool True -> 0x01
TBool False -> 0x02
TByte _ -> 0x03
TI16 _ -> 0x04
TI32 _ -> 0x05
TI64 _ -> 0x06
TDouble _ -> 0x07
TString _ -> 0x08
TList{} -> 0x09
TSet{} -> 0x0A
TMap{} -> 0x0B
TStruct{} -> 0x0C
typeFrom :: Word8 -> ThriftType
typeFrom w = case w of
0x01 -> T_BOOL
0x02 -> T_BOOL
0x03 -> T_BYTE
0x04 -> T_I16
0x05 -> T_I32
0x06 -> T_I64
0x07 -> T_DOUBLE
0x08 -> T_STRING
0x09 -> T_LIST T_VOID
0x0A -> T_SET T_VOID
0x0B -> T_MAP T_VOID T_VOID
0x0C -> T_STRUCT Map.empty
n -> error $ "typeFrom: " ++ show n ++ " is not a compact type"