{-# LANGUAGE BangPatterns #-}
module Data.Aeson.Encoding.Builder
(
encodeToBuilder
, null_
, bool
, array
, emptyArray_
, emptyObject_
, object
, text
, string
, unquoted
, quote
, scientific
, day
, localTime
, utcTime
, timeOfDay
, zonedTime
, ascii2
, ascii4
, ascii5
) where
import Prelude ()
import Prelude.Compat
import Data.Aeson.Internal.Time
import Data.Aeson.Types.Internal (Value (..))
import Data.ByteString.Builder as B
import Data.ByteString.Builder.Prim as BP
import Data.ByteString.Builder.Scientific (scientificBuilder)
import Data.Char (chr, ord)
import Data.Semigroup ((<>))
import Data.Scientific (Scientific, base10Exponent, coefficient)
import Data.Text.Encoding (encodeUtf8BuilderEscaped)
import Data.Time (UTCTime(..))
import Data.Time.Calendar (Day(..), toGregorian)
import Data.Time.LocalTime
import Data.Word (Word8)
import qualified Data.HashMap.Strict as HMS
import qualified Data.Text as T
import qualified Data.Vector as V
encodeToBuilder :: Value -> Builder
encodeToBuilder Null = null_
encodeToBuilder (Bool b) = bool b
encodeToBuilder (Number n) = scientific n
encodeToBuilder (String s) = text s
encodeToBuilder (Array v) = array v
encodeToBuilder (Object m) = object m
null_ :: Builder
null_ = BP.primBounded (ascii4 ('n',('u',('l','l')))) ()
bool :: Bool -> Builder
bool = BP.primBounded (BP.condB id (ascii4 ('t',('r',('u','e'))))
(ascii5 ('f',('a',('l',('s','e'))))))
array :: V.Vector Value -> Builder
array v
| V.null v = emptyArray_
| otherwise = B.char8 '[' <>
encodeToBuilder (V.unsafeHead v) <>
V.foldr withComma (B.char8 ']') (V.unsafeTail v)
where
withComma a z = B.char8 ',' <> encodeToBuilder a <> z
object :: HMS.HashMap T.Text Value -> Builder
object m = case HMS.toList m of
(x:xs) -> B.char8 '{' <> one x <> foldr withComma (B.char8 '}') xs
_ -> emptyObject_
where
withComma a z = B.char8 ',' <> one a <> z
one (k,v) = text k <> B.char8 ':' <> encodeToBuilder v
text :: T.Text -> Builder
text t = B.char8 '"' <> unquoted t <> B.char8 '"'
unquoted :: T.Text -> Builder
unquoted = encodeUtf8BuilderEscaped escapeAscii
quote :: Builder -> Builder
quote b = B.char8 '"' <> b <> B.char8 '"'
string :: String -> Builder
string t = B.char8 '"' <> BP.primMapListBounded go t <> B.char8 '"'
where go = BP.condB (> '\x7f') BP.charUtf8 (c2w >$< escapeAscii)
escapeAscii :: BP.BoundedPrim Word8
escapeAscii =
BP.condB (== c2w '\\' ) (ascii2 ('\\','\\')) $
BP.condB (== c2w '\"' ) (ascii2 ('\\','"' )) $
BP.condB (>= c2w '\x20') (BP.liftFixedToBounded BP.word8) $
BP.condB (== c2w '\n' ) (ascii2 ('\\','n' )) $
BP.condB (== c2w '\r' ) (ascii2 ('\\','r' )) $
BP.condB (== c2w '\t' ) (ascii2 ('\\','t' )) $
BP.liftFixedToBounded hexEscape
where
hexEscape :: BP.FixedPrim Word8
hexEscape = (\c -> ('\\', ('u', fromIntegral c))) BP.>$<
BP.char8 >*< BP.char8 >*< BP.word16HexFixed
{-# INLINE escapeAscii #-}
c2w :: Char -> Word8
c2w c = fromIntegral (ord c)
scientific :: Scientific -> Builder
scientific s
| e < 0 || e > 1024 = scientificBuilder s
| otherwise = B.integerDec (coefficient s * 10 ^ e)
where
e = base10Exponent s
emptyArray_ :: Builder
emptyArray_ = BP.primBounded (ascii2 ('[',']')) ()
emptyObject_ :: Builder
emptyObject_ = BP.primBounded (ascii2 ('{','}')) ()
ascii2 :: (Char, Char) -> BP.BoundedPrim a
ascii2 cs = BP.liftFixedToBounded $ const cs BP.>$< BP.char7 >*< BP.char7
{-# INLINE ascii2 #-}
ascii4 :: (Char, (Char, (Char, Char))) -> BP.BoundedPrim a
ascii4 cs = BP.liftFixedToBounded $ const cs >$<
BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7
{-# INLINE ascii4 #-}
ascii5 :: (Char, (Char, (Char, (Char, Char)))) -> BP.BoundedPrim a
ascii5 cs = BP.liftFixedToBounded $ const cs >$<
BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7
{-# INLINE ascii5 #-}
ascii6 :: (Char, (Char, (Char, (Char, (Char, Char))))) -> BP.BoundedPrim a
ascii6 cs = BP.liftFixedToBounded $ const cs >$<
BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7
{-# INLINE ascii6 #-}
ascii8 :: (Char, (Char, (Char, (Char, (Char, (Char, (Char, Char)))))))
-> BP.BoundedPrim a
ascii8 cs = BP.liftFixedToBounded $ const cs >$<
BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7 >*<
BP.char7 >*< BP.char7 >*< BP.char7 >*< BP.char7
{-# INLINE ascii8 #-}
day :: Day -> Builder
day dd = encodeYear yr <>
BP.primBounded (ascii6 ('-',(mh,(ml,('-',(dh,dl)))))) ()
where (yr,m,d) = toGregorian dd
!(T mh ml) = twoDigits m
!(T dh dl) = twoDigits d
encodeYear y
| y >= 1000 = B.integerDec y
| y >= 0 = BP.primBounded (ascii4 (padYear y)) ()
| y >= -999 = BP.primBounded (ascii5 ('-',padYear (- y))) ()
| otherwise = B.integerDec y
padYear y =
let (ab,c) = fromIntegral y `quotRem` 10
(a,b) = ab `quotRem` 10
in ('0',(digit a,(digit b,digit c)))
{-# INLINE day #-}
timeOfDay :: TimeOfDay -> Builder
timeOfDay t = timeOfDay64 (toTimeOfDay64 t)
{-# INLINE timeOfDay #-}
timeOfDay64 :: TimeOfDay64 -> Builder
timeOfDay64 (TOD h m s)
| frac == 0 = hhmmss
| otherwise = hhmmss <> BP.primBounded showFrac frac
where
hhmmss = BP.primBounded (ascii8 (hh,(hl,(':',(mh,(ml,(':',(sh,sl)))))))) ()
!(T hh hl) = twoDigits h
!(T mh ml) = twoDigits m
!(T sh sl) = twoDigits (fromIntegral real)
(real,frac) = s `quotRem` pico
showFrac = (\x -> ('.', x)) >$< (BP.liftFixedToBounded BP.char7 >*< trunc12)
trunc12 = (`quotRem` micro) >$<
BP.condB (\(_,y) -> y == 0) (fst >$< trunc6) (digits6 >*< trunc6)
digits6 = ((`quotRem` milli) . fromIntegral) >$< (digits3 >*< digits3)
trunc6 = ((`quotRem` milli) . fromIntegral) >$<
BP.condB (\(_,y) -> y == 0) (fst >$< trunc3) (digits3 >*< trunc3)
digits3 = (`quotRem` 10) >$< (digits2 >*< digits1)
digits2 = (`quotRem` 10) >$< (digits1 >*< digits1)
digits1 = BP.liftFixedToBounded (digit >$< BP.char7)
trunc3 = BP.condB (== 0) BP.emptyB $
(`quotRem` 100) >$< (digits1 >*< trunc2)
trunc2 = BP.condB (== 0) BP.emptyB $
(`quotRem` 10) >$< (digits1 >*< trunc1)
trunc1 = BP.condB (== 0) BP.emptyB digits1
pico = 1000000000000
micro = 1000000
milli = 1000
timeZone :: TimeZone -> Builder
timeZone (TimeZone off _ _)
| off == 0 = B.char7 'Z'
| otherwise = BP.primBounded (ascii6 (s,(hh,(hl,(':',(mh,ml)))))) ()
where !s = if off < 0 then '-' else '+'
!(T hh hl) = twoDigits h
!(T mh ml) = twoDigits m
(h,m) = abs off `quotRem` 60
{-# INLINE timeZone #-}
dayTime :: Day -> TimeOfDay64 -> Builder
dayTime d t = day d <> B.char7 'T' <> timeOfDay64 t
{-# INLINE dayTime #-}
utcTime :: UTCTime -> B.Builder
utcTime (UTCTime d s) = dayTime d (diffTimeOfDay64 s) <> B.char7 'Z'
{-# INLINE utcTime #-}
localTime :: LocalTime -> Builder
localTime (LocalTime d t) = dayTime d (toTimeOfDay64 t)
{-# INLINE localTime #-}
zonedTime :: ZonedTime -> Builder
zonedTime (ZonedTime t z) = localTime t <> timeZone z
{-# INLINE zonedTime #-}
data T = T {-# UNPACK #-} !Char {-# UNPACK #-} !Char
twoDigits :: Int -> T
twoDigits a = T (digit hi) (digit lo)
where (hi,lo) = a `quotRem` 10
digit :: Int -> Char
digit x = chr (x + 48)