{-# LANGUAGE RecursiveDo, MultiParamTypeClasses, FlexibleInstances, RankNTypes #-}

-- |
-- Module     : Simulation.Aivika.Trans.Internal.Dynamics
-- Copyright  : Copyright (c) 2009-2017, David Sorokin <david.sorokin@gmail.com>
-- License    : BSD3
-- Maintainer : David Sorokin <david.sorokin@gmail.com>
-- Stability  : experimental
-- Tested with: GHC 8.0.1
--
-- The module defines the 'Dynamics' monad transformer representing a time varying polymorphic function. 
--
module Simulation.Aivika.Trans.Internal.Dynamics
       (-- * Dynamics
        Dynamics(..),
        DynamicsLift(..),
        invokeDynamics,
        runDynamicsInStartTime,
        runDynamicsInStopTime,
        runDynamicsInIntegTimes,
        runDynamicsInTime,
        runDynamicsInTimes,
        -- * Error Handling
        catchDynamics,
        finallyDynamics,
        throwDynamics,
        -- * Simulation Time
        time,
        isTimeInteg,
        integIteration,
        integPhase,
        -- * Debugging
        traceDynamics) where

import Control.Exception
import Control.Monad
import Control.Monad.Trans
import Control.Monad.Fix
import qualified Control.Monad.Catch as MC
import Control.Applicative

import Debug.Trace (trace)

import Simulation.Aivika.Trans.Exception
import Simulation.Aivika.Trans.Comp
import Simulation.Aivika.Trans.Internal.Types
import Simulation.Aivika.Trans.Internal.Specs
import Simulation.Aivika.Trans.Internal.Parameter
import Simulation.Aivika.Trans.Internal.Simulation

instance Monad m => Monad (Dynamics m) where

  {-# INLINE return #-}
  return a = Dynamics $ \p -> return a

  {-# INLINE (>>=) #-}
  (Dynamics m) >>= k =
    Dynamics $ \p ->
    do a <- m p
       let Dynamics m' = k a
       m' p

-- | Run the 'Dynamics' computation in the initial time point.
runDynamicsInStartTime :: Dynamics m a -> Simulation m a
{-# INLINABLE runDynamicsInStartTime #-}
runDynamicsInStartTime (Dynamics m) =
  Simulation $ m . integStartPoint

-- | Run the 'Dynamics' computation in the final time point.
runDynamicsInStopTime :: Dynamics m a -> Simulation m a
{-# INLINABLE runDynamicsInStopTime #-}
runDynamicsInStopTime (Dynamics m) =
  Simulation $ m . simulationStopPoint

-- | Run the 'Dynamics' computation in all integration time points.
runDynamicsInIntegTimes :: Monad m => Dynamics m a -> Simulation m [m a]
{-# INLINABLE runDynamicsInIntegTimes #-}
runDynamicsInIntegTimes (Dynamics m) =
  Simulation $ return . map m . integPoints

-- | Run the 'Dynamics' computation in the specified time point.
runDynamicsInTime :: Double -> Dynamics m a -> Simulation m a
{-# INLINABLE runDynamicsInTime #-}
runDynamicsInTime t (Dynamics m) =
  Simulation $ \r -> m $ pointAt r t

-- | Run the 'Dynamics' computation in the specified time points.
runDynamicsInTimes :: Monad m => [Double] -> Dynamics m a -> Simulation m [m a]
{-# INLINABLE runDynamicsInTimes #-}
runDynamicsInTimes ts (Dynamics m) =
  Simulation $ \r -> return $ map (m . pointAt r) ts

instance Functor m => Functor (Dynamics m) where

  {-# INLINE fmap #-}
  fmap f (Dynamics x) = Dynamics $ \p -> fmap f $ x p

instance Applicative m => Applicative (Dynamics m) where

  {-# INLINE pure #-}
  pure = Dynamics . const . pure

  {-# INLINE (<*>) #-}
  (Dynamics x) <*> (Dynamics y) = Dynamics $ \p -> x p <*> y p

liftMD :: Monad m => (a -> b) -> Dynamics m a -> Dynamics m b
{-# INLINE liftMD #-}
liftMD f (Dynamics x) =
  Dynamics $ \p -> do { a <- x p; return $ f a }

liftM2D :: Monad m => (a -> b -> c) -> Dynamics m a -> Dynamics m b -> Dynamics m c
{-# INLINE liftM2D #-}
liftM2D f (Dynamics x) (Dynamics y) =
  Dynamics $ \p -> do { a <- x p; b <- y p; return $ f a b }

instance (Num a, Monad m) => Num (Dynamics m a) where

  {-# INLINE (+) #-}
  x + y = liftM2D (+) x y

  {-# INLINE (-) #-}
  x - y = liftM2D (-) x y

  {-# INLINE (*) #-}
  x * y = liftM2D (*) x y

  {-# INLINE negate #-}
  negate = liftMD negate

  {-# INLINE abs #-}
  abs = liftMD abs

  {-# INLINE signum #-}
  signum = liftMD signum

  {-# INLINE fromInteger #-}
  fromInteger i = return $ fromInteger i

instance (Fractional a, Monad m) => Fractional (Dynamics m a) where

  {-# INLINE (/) #-}
  x / y = liftM2D (/) x y

  {-# INLINE recip #-}
  recip = liftMD recip

  {-# INLINE fromRational #-}
  fromRational t = return $ fromRational t

instance (Floating a, Monad m) => Floating (Dynamics m a) where

  {-# INLINE pi #-}
  pi = return pi

  {-# INLINE exp #-}
  exp = liftMD exp

  {-# INLINE log #-}
  log = liftMD log

  {-# INLINE sqrt #-}
  sqrt = liftMD sqrt

  {-# INLINE (**) #-}
  x ** y = liftM2D (**) x y

  {-# INLINE sin #-}
  sin = liftMD sin

  {-# INLINE cos #-}
  cos = liftMD cos

  {-# INLINE tan #-}
  tan = liftMD tan

  {-# INLINE asin #-}
  asin = liftMD asin

  {-# INLINE acos #-}
  acos = liftMD acos

  {-# INLINE atan #-}
  atan = liftMD atan

  {-# INLINE sinh #-}
  sinh = liftMD sinh

  {-# INLINE cosh #-}
  cosh = liftMD cosh

  {-# INLINE tanh #-}
  tanh = liftMD tanh

  {-# INLINE asinh #-}
  asinh = liftMD asinh

  {-# INLINE acosh #-}
  acosh = liftMD acosh

  {-# INLINE atanh #-}
  atanh = liftMD atanh

instance MonadTrans Dynamics where

  {-# INLINE lift #-}
  lift = Dynamics . const

instance MonadIO m => MonadIO (Dynamics m) where

  {-# INLINE liftIO #-}
  liftIO = Dynamics . const . liftIO

instance Monad m => MonadCompTrans Dynamics m where

  {-# INLINE liftComp #-}
  liftComp = Dynamics . const

-- | A type class to lift the 'Dynamics' computations into other computations.
class DynamicsLift t m where

  -- | Lift the specified 'Dynamics' computation into another computation.
  liftDynamics :: Dynamics m a -> t m a

instance Monad m => DynamicsLift Dynamics m where

  {-# INLINE liftDynamics #-}
  liftDynamics = id

instance Monad m => SimulationLift Dynamics m where

  {-# INLINE liftSimulation #-}
  liftSimulation (Simulation x) = Dynamics $ x . pointRun

instance Monad m => ParameterLift Dynamics m where

  {-# INLINE liftParameter #-}
  liftParameter (Parameter x) = Dynamics $ x . pointRun

-- | Exception handling within 'Dynamics' computations.
catchDynamics :: (MonadException m, Exception e) => Dynamics m a -> (e -> Dynamics m a) -> Dynamics m a
{-# INLINABLE catchDynamics #-}
catchDynamics (Dynamics m) h =
  Dynamics $ \p ->
  catchComp (m p) $ \e ->
  let Dynamics m' = h e in m' p

-- | A computation with finalization part like the 'finally' function.
finallyDynamics :: MonadException m => Dynamics m a -> Dynamics m b -> Dynamics m a
{-# INLINABLE finallyDynamics #-}
finallyDynamics (Dynamics m) (Dynamics m') =
  Dynamics $ \p ->
  finallyComp (m p) (m' p)

-- | Like the standard 'throw' function.
throwDynamics :: (MonadException m, Exception e) => e -> Dynamics m a
{-# INLINABLE throwDynamics #-}
throwDynamics e =
  Dynamics $ \p ->
  throwComp e

-- | Runs an action with asynchronous exceptions disabled.
maskDynamics :: MC.MonadMask m => ((forall a. Dynamics m a -> Dynamics m a) -> Dynamics m b) -> Dynamics m b
{-# INLINABLE maskDynamics #-}
maskDynamics a =
  Dynamics $ \p ->
  MC.mask $ \u ->
  invokeDynamics p (a $ q u)
  where q u (Dynamics b) = Dynamics (u . b)

-- | Like 'maskDynamics', but the masked computation is not interruptible.
uninterruptibleMaskDynamics :: MC.MonadMask m => ((forall a. Dynamics m a -> Dynamics m a) -> Dynamics m b) -> Dynamics m b
{-# INLINABLE uninterruptibleMaskDynamics #-}
uninterruptibleMaskDynamics a =
  Dynamics $ \p ->
  MC.uninterruptibleMask $ \u ->
  invokeDynamics p (a $ q u)
  where q u (Dynamics b) = Dynamics (u . b)

-- | An implementation of 'generalBracket'.
generalBracketDynamics :: MC.MonadMask m
                          => Dynamics m a
                          -> (a -> MC.ExitCase b -> Dynamics m c)
                          -> (a -> Dynamics m b)
                          -> Dynamics m (b, c)
{-# INLINABLE generalBracketDynamics #-}
generalBracketDynamics acquire release use =
  Dynamics $ \p -> do
    MC.generalBracket
      (invokeDynamics p acquire)
      (\resource e -> invokeDynamics p $ release resource e)
      (\resource -> invokeDynamics p $ use resource)

instance MonadFix m => MonadFix (Dynamics m) where

  {-# INLINE mfix #-}
  mfix f =
    Dynamics $ \p ->
    do { rec { a <- invokeDynamics p (f a) }; return a }

instance MonadException m => MC.MonadThrow (Dynamics m) where

  {-# INLINE throwM #-}
  throwM = throwDynamics

instance MonadException m => MC.MonadCatch (Dynamics m) where

  {-# INLINE catch #-}
  catch = catchDynamics

instance (MonadException m, MC.MonadMask m) => MC.MonadMask (Dynamics m) where

  {-# INLINE mask #-}
  mask = maskDynamics

  {-# INLINE uninterruptibleMask #-}
  uninterruptibleMask = uninterruptibleMaskDynamics

  {-# INLINE generalBracket #-}
  generalBracket = generalBracketDynamics

-- | Computation that returns the current simulation time.
time :: Monad m => Dynamics m Double
{-# INLINE time #-}
time = Dynamics $ return . pointTime

-- | Whether the current time is an integration time.
isTimeInteg :: Monad m => Dynamics m Bool
{-# INLINE isTimeInteg #-}
isTimeInteg = Dynamics $ \p -> return $ pointPhase p >= 0

-- | Return the integration iteration closest to the current simulation time.
integIteration :: Monad m => Dynamics m Int
{-# INLINE integIteration #-}
integIteration = Dynamics $ return . pointIteration

-- | Return the integration phase for the current simulation time.
-- It is @(-1)@ for non-integration time points.
integPhase :: Monad m => Dynamics m Int
{-# INLINE integPhase #-}
integPhase = Dynamics $ return . pointPhase

-- | Show the debug message with the current simulation time.
traceDynamics :: Monad m => String -> Dynamics m a -> Dynamics m a
{-# INLINABLE traceDynamics #-}
traceDynamics message m =
  Dynamics $ \p ->
  trace ("t = " ++ show (pointTime p) ++ ": " ++ message) $
  invokeDynamics p m