module Synthesizer.CausalIO.Gate (
Chunk(Chunk), chunk,
allToStorableVector,
toStorableVector,
allToChunkySize,
toChunkySize,
shorten,
) where
import qualified Synthesizer.CausalIO.Process as PIO
import qualified Synthesizer.Zip as Zip
import qualified Synthesizer.Generic.Cut as CutG
import qualified Synthesizer.Generic.Signal as SigG
import Synthesizer.PiecewiseConstant.Signal (StrictTime, )
import qualified Control.Monad.Trans.State as MS
import Control.Arrow (Arrow, arr, (^<<), )
import Control.Monad (when, )
import qualified Data.StorableVector as SV
import qualified Data.Monoid as Mn
import qualified Data.Semigroup as Sg
import Data.Maybe.HT (toMaybe, )
import qualified Numeric.NonNegative.Class as NonNeg
import qualified Numeric.NonNegative.Wrapper as NonNegW
import NumericPrelude.Numeric
import NumericPrelude.Base
import Prelude ()
data Chunk a = Chunk StrictTime (Maybe (StrictTime, a))
deriving (Show)
chunk :: StrictTime -> Maybe (StrictTime, a) -> Chunk a
chunk dur mrel =
if maybe True (\(rel,_attr) -> rel<dur) mrel
then Chunk dur mrel
else error "release time must be strictly before chunk end"
instance CutG.Read (Chunk a) where
null (Chunk dur _) = isZero dur
length (Chunk dur _) = fromIntegral dur
instance CutG.NormalForm (Chunk a) where
evaluateHead (Chunk dur rel) =
dur `seq` rel `seq` ()
instance Sg.Semigroup (Chunk a) where
(<>) = error "Gate.mappend cannot be defined"
instance Mn.Monoid (Chunk a) where
mempty = error "Gate.mempty cannot be defined"
mappend = error "Gate.mappend cannot be defined"
instance CutG.Transform (Chunk a) where
take n (Chunk dur mrel) =
let nn = NonNegW.fromNumberClip $ fromIntegral n
in Chunk (min nn dur) $
mrel >>= \rel -> toMaybe (fst rel < nn) rel
drop n (Chunk dur mrel) =
let nn = NonNegW.fromNumberClip $ fromIntegral n
in Chunk (dur NonNeg.-| nn) $
mrel >>= \(rel,attr) -> toMaybe (nn <= rel) (rel-nn, attr)
splitAt n c = (CutG.take n c, CutG.drop n c)
dropMarginRem = error "Gate.dropMarginRem is not defined"
reverse = error "Gate.reverse cannot be defined"
allToStorableVector ::
(Arrow arrow) =>
arrow (Chunk a) (SV.Vector ())
allToStorableVector = arr $
(\(SigG.LazySize n) -> SV.replicate n ())
^<<
allToChunkySize
toStorableVector ::
PIO.T (Chunk a) (SV.Vector ())
toStorableVector =
(\(SigG.LazySize n) -> SV.replicate n ())
^<<
toChunkySize
allToChunkySize ::
(Arrow arrow) =>
arrow (Chunk a) SigG.LazySize
allToChunkySize = arr $
\(Chunk time _) -> SigG.LazySize (fromIntegral time)
toChunkySize ::
PIO.T (Chunk a) SigG.LazySize
toChunkySize =
PIO.traverse True $
\(Chunk time mRelease) -> do
running <- MS.get
if not running
then return $ SigG.LazySize 0
else
case mRelease of
Nothing ->
return $ SigG.LazySize (fromIntegral time)
Just (relTime, _) -> do
MS.put False
return $ SigG.LazySize (fromIntegral relTime)
shorten ::
(CutG.Transform signal) =>
PIO.T (Zip.T (Chunk a) signal) signal
shorten =
PIO.traverse True $
\(Zip.Cons (Chunk time mRelease) sig) -> do
when (NonNegW.toNumber time /= fromIntegral (CutG.length sig))
(error "Gate.shorten: durations mismatch")
running <- MS.get
if not running
then return CutG.empty
else
case mRelease of
Nothing ->
return $ sig
Just (relTime, _) -> do
MS.put False
return $ CutG.take (fromIntegral relTime) sig