module Data.EventList.Relative.TimeTimePrivate where
import qualified Data.EventList.Relative.TimeBodyPrivate as TimeBodyList
import qualified Data.EventList.Relative.TimeBodyPrivate as TimeBodyPriv
import qualified Data.EventList.Relative.BodyTimePrivate as BodyTimeList
import qualified Data.EventList.Relative.BodyTimePrivate as BodyTimePriv
import Data.EventList.Relative.TimeBodyPrivate (($~*))
import qualified Data.AlternatingList.List.Disparate as Disp
import qualified Data.AlternatingList.List.Uniform as Uniform
import qualified Data.AlternatingList.List.Mixed as Mixed
import qualified Numeric.NonNegative.Class as NonNeg
import Numeric.NonNegative.Class (zero, add, )
import Data.Tuple.HT (mapFst, mapSnd, )
import qualified Control.Monad as Monad
import qualified Data.Foldable as Fold
import qualified Data.Traversable as Trav
import qualified Control.Applicative as App
import Control.Applicative (Applicative, )
import Data.Monoid (Monoid, mempty, mappend, mconcat, )
import Test.QuickCheck (Arbitrary(arbitrary, shrink))
import Prelude hiding (foldr, )
newtype T time body = Cons {decons :: Uniform.T body time}
deriving (Eq, Ord)
instance (Show time, Show body) => Show (T time body) where
showsPrec p = Uniform.format " ./ " " /. " p . decons
instance (Arbitrary time, Arbitrary body) =>
Arbitrary (T time body) where
arbitrary = Monad.liftM Cons arbitrary
shrink = liftM shrink
instance (NonNeg.C time) => Monoid (T time body) where
mempty = Cons (Uniform.singleton zero)
mappend = append
mconcat =
flatten . consTime zero .
mconcat .
map (consBody [] . fmap (:[]))
append, appendAlt, appendSwitch ::
(NonNeg.C time) =>
T time body -> T time body -> T time body
append xs ys =
forceTimeHead $
foldr
delay
(\b ->
consTime NonNeg.zero .
consBody b)
ys xs
appendAlt xs ys =
foldr
(\t ->
delay t .
either id (consTime NonNeg.zero))
(\b -> Right . consBody b)
(Left ys) xs
appendSwitch =
switchTimeR
(\ xs t ->
lift (Mixed.appendDisparateUniform $~* xs) .
delay t)
instance Functor (T time) where
fmap f (Cons x) = Cons (Uniform.mapFirst f x)
instance Fold.Foldable (T time) where
foldMap = Trav.foldMapDefault
instance Trav.Traversable (T time) where
traverse f =
App.liftA Cons . Uniform.traverse f App.pure . decons
infixl 5 $~~
($~~) :: (Uniform.T body time -> a) -> (T time body -> a)
($~~) f = f . decons
lift ::
(Uniform.T body0 time0 -> Uniform.T body1 time1) ->
(T time0 body0 -> T time1 body1)
lift f = Cons . f . decons
liftA :: Applicative m =>
(Uniform.T body0 time0 -> m (Uniform.T body1 time1)) ->
(T time0 body0 -> m (T time1 body1))
liftA f = App.liftA Cons . f . decons
liftM :: Monad m =>
(Uniform.T body0 time0 -> m (Uniform.T body1 time1)) ->
(T time0 body0 -> m (T time1 body1))
liftM f = Monad.liftM Cons . f . decons
unlift ::
(T time0 body0 -> T time1 body1) ->
(Uniform.T body0 time0 -> Uniform.T body1 time1)
unlift f = decons . f . Cons
consBody :: body -> T time body -> BodyTimeList.T time body
consBody b = BodyTimePriv.Cons . Mixed.consFirst b . decons
consTime :: time -> BodyTimeList.T time body -> T time body
consTime t = Cons . Mixed.consSecond t . BodyTimePriv.decons
viewTimeL :: T time body -> (time, BodyTimeList.T time body)
viewTimeL = mapSnd BodyTimePriv.Cons . Mixed.viewSecondL . decons
viewBodyL :: BodyTimeList.T time body -> Maybe (body, T time body)
viewBodyL = fmap (mapSnd Cons) . Mixed.viewFirstL . BodyTimePriv.decons
viewTimeR :: T time body -> (TimeBodyList.T time body, time)
viewTimeR = mapFst TimeBodyPriv.Cons . Mixed.viewSecondR . decons
viewBodyR :: TimeBodyList.T time body -> Maybe (T time body, body)
viewBodyR = fmap (mapFst Cons) . Mixed.viewFirstR . TimeBodyPriv.decons
switchTimeL :: (time -> BodyTimeList.T time body -> a) -> T time body -> a
switchTimeL f =
Mixed.switchSecondL (\b -> f b . BodyTimePriv.Cons) . decons
switchBodyL :: a -> (body -> T time body -> a) -> BodyTimeList.T time body -> a
switchBodyL f g =
Mixed.switchFirstL f (\t -> g t . Cons) . BodyTimePriv.decons
switchTimeR :: (TimeBodyList.T time body -> time -> a) -> T time body -> a
switchTimeR f = Mixed.switchSecondR (f . TimeBodyPriv.Cons) . decons
switchBodyR :: a -> (T time body -> body -> a) -> TimeBodyList.T time body -> a
switchBodyR f g = Mixed.switchFirstR f (g . Cons) . TimeBodyPriv.decons
mapTimeL ::
(time -> time, BodyTimeList.T time body0 -> BodyTimeList.T time body1) ->
T time body0 -> T time body1
mapTimeL = lift . Mixed.mapSecondL . mapSnd BodyTimePriv.unlift
mapTimeHead ::
(time -> time) ->
T time body -> T time body
mapTimeHead = lift . Mixed.mapSecondHead
mapTimeTail ::
(BodyTimeList.T time body0 -> BodyTimeList.T time body1) ->
T time body0 -> T time body1
mapTimeTail f =
switchTimeL (\time -> consTime time . f)
mapTimeR ::
(TimeBodyList.T time body0 -> TimeBodyList.T time body1, time -> time) ->
T time body0 -> T time body1
mapTimeR = lift . Mixed.mapSecondR . mapFst TimeBodyPriv.unlift
mapTimeLast ::
(time -> time) ->
T time body -> T time body
mapTimeLast = lift . Mixed.mapSecondLast
mapTimeInit ::
(TimeBodyList.T time body0 -> TimeBodyList.T time body1) ->
T time body0 -> T time body1
mapTimeInit = lift . Mixed.mapSecondInit . TimeBodyPriv.unlift
foldr :: (time -> a -> b) -> (body -> b -> a) -> a -> T time body -> b
foldr f g x = Uniform.foldr g f x . decons
forceTimeHead :: (NonNeg.C time) =>
T time body -> T time body
forceTimeHead =
mapTimeHead id
delay :: (NonNeg.C time) =>
time -> T time body -> T time body
delay dif =
mapTimeHead (add dif)
flatten :: (NonNeg.C time) => T time [body] -> T time body
flatten =
Cons .
Uniform.foldr
(Mixed.appendUniformUniform . Uniform.fromSecondList zero)
Mixed.consSecond
Disp.empty .
Uniform.mapSecond NonNeg.sum .
Uniform.filterFirst (not . null) .
decons