metabrush/src/metabrushes/MetaBrush/Serialisable.hs

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{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE UndecidableInstances #-}
module MetaBrush.Serialisable
( Serialisable(..)
, encodeSequence, decodeSequence
, encodeUniqueMap, decodeUniqueMap
, encodeCurve, decodeCurve
, encodeCurves, decodeCurves
, encodeSpline, decodeSpline
)
where
-- base
import Control.Arrow
( (&&&) )
import Control.Monad.ST
( RealWorld, stToIO )
import Data.Foldable
( toList )
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import Data.Functor
( (<&>) )
import Data.Functor.Contravariant
( contramap )
import Data.Functor.Identity
( Identity(..) )
import Data.STRef
( newSTRef )
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import Data.Traversable
( for )
import GHC.Exts
( Word(W#) )
-- containers
import Data.Map.Strict
( Map )
import qualified Data.Map.Strict as Map
( elems, fromList )
import Data.Sequence
( Seq )
import qualified Data.Sequence as Seq
( fromList )
-- generic-lens
import Data.Generics.Product.Typed
( HasType(typed) )
-- lens
import Control.Lens
( view )
-- scientific
import qualified Data.Scientific as Scientific
( fromFloatDigits, toRealFloat )
-- text
import Data.Text
( Text )
-- transformers
import Control.Monad.IO.Class
( MonadIO(liftIO) )
import Control.Monad.Trans.Class
( MonadTrans(lift) )
-- waargonaut
import qualified Waargonaut.Decode as JSON
( Decoder )
import qualified Waargonaut.Decode as JSON.Decoder
( atKey, atKeyOptional, list, scientific, text )
import qualified Waargonaut.Encode as JSON
( Encoder )
import qualified Waargonaut.Encode as JSON.Encoder
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( atKey', keyValueTupleFoldable, list, mapLikeObj, scientific, text, either )
-- meta-brushes
import Math.Bezier.Spline
( Spline(..), SplineType(..), SSplineType(..), SplineTypeI(..)
, Curves(..), Curve(..), NextPoint(..)
)
import Math.Bezier.Stroke
( CachedStroke(..) )
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import Math.Linear
( Point2D(..), Vector2D(..), (..)
, Fin(..), Representable(tabulate, index)
)
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import MetaBrush.Records
import MetaBrush.Unique
( Unique )
--------------------------------------------------------------------------------
class Serialisable a where
encoder :: Monad f => JSON.Encoder f a
decoder :: Monad m => JSON.Decoder m a
instance Serialisable Double where
encoder = contramap Scientific.fromFloatDigits JSON.Encoder.scientific
decoder = fmap Scientific.toRealFloat JSON.Decoder.scientific
instance Serialisable a => Serialisable ( Point2D a ) where
encoder = JSON.Encoder.mapLikeObj \ ( Point2D x y ) ->
JSON.Encoder.atKey' "x" encoder x
. JSON.Encoder.atKey' "y" encoder y
decoder = Point2D <$> JSON.Decoder.atKey "x" decoder <*> JSON.Decoder.atKey "y" decoder
instance Serialisable a => Serialisable ( Vector2D a ) where
encoder = JSON.Encoder.mapLikeObj \ ( Vector2D x y ) ->
JSON.Encoder.atKey' "x" encoder x
. JSON.Encoder.atKey' "y" encoder y
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decoder = Vector2D <$> JSON.Decoder.atKey "x" decoder <*> JSON.Decoder.atKey "y" decoder
instance ( KnownSymbols ks, Representable ( ( Length ks ) ) ) => Serialisable ( Record ks ) where
encoder = contramap encodeFields ( JSON.Encoder.keyValueTupleFoldable ( encoder @Double ) )
where
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encodeFields :: Record ks -> [ ( Text, Double ) ]
encodeFields ( MkR r ) =
zip [1..] ( knownSymbols @ks ) <&> \ ( W# i, fld ) ->
( fld, index r ( Fin i ) )
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decoder = fmap decodeFields $ for ( knownSymbols @ks ) \ k -> JSON.Decoder.atKey k ( decoder @Double )
where
decodeFields :: [ Double ] -> Record ks
decodeFields coords = MkR $ tabulate \ ( Fin i# ) ->
coords !! ( fromIntegral ( W# i# ) - 1 )
--------------------------------------------------------------------------------
encodeSequence :: Applicative f => JSON.Encoder f a -> JSON.Encoder f ( Seq a )
encodeSequence enc = contramap toList ( JSON.Encoder.list enc )
decodeSequence :: Monad m => JSON.Decoder m a -> JSON.Decoder m ( Seq a )
decodeSequence dec = Seq.fromList <$> JSON.Decoder.list dec
encodeUniqueMap :: Applicative f => JSON.Encoder f a -> JSON.Encoder f ( Map Unique a )
encodeUniqueMap enc = contramap Map.elems ( JSON.Encoder.list enc )
decodeUniqueMap :: ( Monad m, HasType Unique a ) => JSON.Decoder m a -> JSON.Decoder m ( Map Unique a )
decodeUniqueMap dec = Map.fromList . map ( view typed &&& id ) <$> JSON.Decoder.list dec
{-
encodeMat22 :: Applicative f => JSON.Encoder' a -> JSON.Encoder f ( Mat22 a )
encodeMat22 enc = JSON.Encoder.mapLikeObj \ ( Mat22 m00 m01 m10 m11 ) ->
JSON.Encoder.atKey' "m00" enc m00
. JSON.Encoder.atKey' "m01" enc m01
. JSON.Encoder.atKey' "m10" enc m10
. JSON.Encoder.atKey' "m11" enc m11
decodeMat22 :: Monad m => JSON.Decoder m a -> JSON.Decoder m ( Mat22 a )
decodeMat22 dec =
Mat22 <$> JSON.Decoder.atKey "m00" dec
<*> JSON.Decoder.atKey "m01" dec
<*> JSON.Decoder.atKey "m10" dec
<*> JSON.Decoder.atKey "m11" dec
encodeAABB :: Applicative f => JSON.Encoder f AABB
encodeAABB = JSON.Encoder.mapLikeObj \ ( AABB { topLeft, botRight } ) ->
JSON.Encoder.atKey' "topLeft" enc topLeft
. JSON.Encoder.atKey' "botRight" enc botRight
where
enc :: JSON.Encoder' ( Point2D Double )
enc = encodePoint2D encodeDouble
decodeAABB :: forall m. Monad m => JSON.Decoder m AABB
decodeAABB = do
topLeft <- JSON.Decoder.atKey "topLeft" dec
botRight <- JSON.Decoder.atKey "botRight" dec
pure ( AABB { topLeft, botRight } )
where
dec :: JSON.Decoder m ( Point2D Double )
dec = decodePoint2D decodeDouble
-}
encodeCurve
:: forall clo crvData ptData f
. ( SplineTypeI clo, Applicative f )
=> JSON.Encoder Identity ptData
-> JSON.Encoder f ( Curve clo crvData ptData )
encodeCurve encodePtData = case ssplineType @clo of
SOpen -> JSON.Encoder.mapLikeObj \case
LineTo ( NextPoint p1 ) _ ->
JSON.Encoder.atKey' "p1" encodePtData p1
Bezier2To p1 ( NextPoint p2 ) _ ->
JSON.Encoder.atKey' "p1" encodePtData p1
. JSON.Encoder.atKey' "p2" encodePtData p2
Bezier3To p1 p2 ( NextPoint p3 ) _ ->
JSON.Encoder.atKey' "p1" encodePtData p1
. JSON.Encoder.atKey' "p2" encodePtData p2
. JSON.Encoder.atKey' "p3" encodePtData p3
SClosed -> JSON.Encoder.mapLikeObj \case
LineTo BackToStart _ -> id
Bezier2To p1 BackToStart _ ->
JSON.Encoder.atKey' "p1" encodePtData p1
Bezier3To p1 p2 BackToStart _ ->
JSON.Encoder.atKey' "p1" encodePtData p1
. JSON.Encoder.atKey' "p2" encodePtData p2
decodeCurve
:: forall clo ptData m
. ( SplineTypeI clo, MonadIO m )
=> JSON.Decoder m ptData
-> JSON.Decoder m ( Curve clo ( CachedStroke RealWorld ) ptData )
decodeCurve decodePtData = do
noCache <- lift . liftIO . stToIO $ CachedStroke <$> newSTRef Nothing
case ssplineType @clo of
SOpen -> do
p1 <- JSON.Decoder.atKey "p1" decodePtData
mb_p2 <- JSON.Decoder.atKeyOptional "p2" decodePtData
case mb_p2 of
Nothing ->
pure ( LineTo ( NextPoint p1 ) noCache )
Just p2 -> do
mb_p3 <- JSON.Decoder.atKeyOptional "p3" decodePtData
case mb_p3 of
Nothing -> pure ( Bezier2To p1 ( NextPoint p2 ) noCache )
Just p3 -> pure ( Bezier3To p1 p2 ( NextPoint p3 ) noCache )
SClosed -> do
mb_p1 <- JSON.Decoder.atKeyOptional "p1" decodePtData
case mb_p1 of
Nothing ->
pure ( LineTo BackToStart noCache )
Just p1 -> do
mb_p2 <- JSON.Decoder.atKeyOptional "p2" decodePtData
case mb_p2 of
Nothing -> pure ( Bezier2To p1 BackToStart noCache )
Just p2 -> pure ( Bezier3To p1 p2 BackToStart noCache )
encodeCurves
:: forall clo crvData ptData f
. ( SplineTypeI clo, Applicative f )
=> JSON.Encoder Identity ptData
-> JSON.Encoder f ( Curves clo crvData ptData )
encodeCurves encodePtData = case ssplineType @clo of
SOpen -> contramap ( openCurves ) ( encodeSequence $ encodeCurve @Open encodePtData )
SClosed -> contramap ( \case { NoCurves -> Left (); ClosedCurves prevs lst -> Right ( prevs, lst ) } ) ( JSON.Encoder.either encodeL encodeR )
where
encodeL :: JSON.Encoder f ()
encodeL = contramap ( const "NoCurves" ) JSON.Encoder.text
encodeR :: JSON.Encoder f ( Seq ( Curve Open crvData ptData ), Curve Closed crvData ptData )
encodeR = JSON.Encoder.mapLikeObj \ ( openCurves, closedCurve ) ->
JSON.Encoder.atKey' "prevOpenCurves" ( encodeSequence $ encodeCurve @Open encodePtData ) openCurves
. JSON.Encoder.atKey' "lastClosedCurve" ( encodeCurve @Closed encodePtData ) closedCurve
decodeCurves
:: forall clo ptData m
. ( SplineTypeI clo, MonadIO m )
=> JSON.Decoder m ptData
-> JSON.Decoder m ( Curves clo ( CachedStroke RealWorld ) ptData )
decodeCurves decodePtData = case ssplineType @clo of
SOpen -> OpenCurves <$> decodeSequence ( decodeCurve @Open decodePtData )
SClosed -> do
mbNoCurves <- JSON.Decoder.atKeyOptional "NoCurves" ( JSON.Decoder.text )
case mbNoCurves of
Just _ -> pure NoCurves
Nothing -> do
prevCurves <- JSON.Decoder.atKey "prevOpenCurves" ( decodeSequence $ decodeCurve @Open decodePtData )
lastCurve <- JSON.Decoder.atKey "lastClosedCurve" ( decodeCurve @Closed decodePtData )
pure ( ClosedCurves prevCurves lastCurve )
encodeSpline
:: forall clo crvData ptData f
. ( SplineTypeI clo, Applicative f )
=> JSON.Encoder Identity ptData
-> JSON.Encoder f ( Spline clo crvData ptData )
encodeSpline encodePtData = JSON.Encoder.mapLikeObj \ ( Spline { splineStart, splineCurves } ) ->
JSON.Encoder.atKey' "splineStart" encodePtData splineStart
. JSON.Encoder.atKey' "splineCurves" ( encodeCurves @clo encodePtData ) splineCurves
decodeSpline
:: forall clo ptData m
. ( SplineTypeI clo, MonadIO m )
=> JSON.Decoder m ptData
-> JSON.Decoder m ( Spline clo ( CachedStroke RealWorld ) ptData )
decodeSpline decodePtData = do
splineStart <- JSON.Decoder.atKey "splineStart" decodePtData
splineCurves <- JSON.Decoder.atKey "splineCurves" ( decodeCurves @clo decodePtData )
pure ( Spline { splineStart, splineCurves } )