{-# LANGUAGE BangPatterns #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE RecordWildCards #-} {-# LANGUAGE ScopedTypeVariables #-} -- | -- Module : Data.Massiv.Array.Stencil.Internal -- Copyright : (c) Alexey Kuleshevich 2018-2019 -- License : BSD3 -- Maintainer : Alexey Kuleshevich -- Stability : experimental -- Portability : non-portable -- module Data.Massiv.Array.Stencil.Internal ( Stencil(..) , Value(..) , dimapStencil , lmapStencil , rmapStencil , validateStencil ) where import Control.Applicative import Control.DeepSeq import Data.Massiv.Array.Delayed.Pull import Data.Massiv.Core.Common import Data.Massiv.Core.Index.Internal -- | Stencil is abstract description of how to handle elements in the neighborhood of every array -- cell in order to compute a value for the cells in the new array. Use `Data.Array.makeStencil` and -- `Data.Array.makeConvolutionStencil` in order to create a stencil. data Stencil ix e a = Stencil { stencilSize :: !(Sz ix) , stencilCenter :: !ix , stencilFunc :: (ix -> Value e) -> ix -> Value a } instance Index ix => NFData (Stencil ix e a) where rnf (Stencil sz ix f) = sz `deepseq` ix `deepseq` f `seq` () -- | This is a simple wrapper for value of an array cell. It is used in order to improve safety of -- `Stencil` mapping. Using various class instances, such as `Num` and `Functor` for example, make -- it possible to manipulate the value, without having direct access to it. newtype Value e = Value { unValue :: e } deriving (Show, Bounded) instance Functor Value where fmap f (Value e) = Value (f e) {-# INLINE fmap #-} instance Applicative Value where pure = Value {-# INLINE pure #-} (<*>) (Value f) (Value e) = Value (f e) {-# INLINE (<*>) #-} -- | @since 0.1.5 instance Semigroup a => Semigroup (Value a) where Value a <> Value b = Value (a <> b) {-# INLINE (<>) #-} -- | @since 0.1.5 instance Monoid a => Monoid (Value a) where mempty = Value mempty {-# INLINE mempty #-} Value a `mappend` Value b = Value (a `mappend` b) {-# INLINE mappend #-} instance Num e => Num (Value e) where (+) = liftA2 (+) {-# INLINE (+) #-} (*) = liftA2 (*) {-# INLINE (*) #-} negate = fmap negate {-# INLINE negate #-} abs = fmap abs {-# INLINE abs #-} signum = fmap signum {-# INLINE signum #-} fromInteger = Value . fromInteger {-# INLINE fromInteger #-} instance Fractional e => Fractional (Value e) where (/) = liftA2 (/) {-# INLINE (/) #-} recip = fmap recip {-# INLINE recip #-} fromRational = pure . fromRational {-# INLINE fromRational #-} instance Floating e => Floating (Value e) where pi = pure pi {-# INLINE pi #-} exp = fmap exp {-# INLINE exp #-} log = fmap log {-# INLINE log #-} sqrt = fmap sqrt {-# INLINE sqrt #-} (**) = liftA2 (**) {-# INLINE (**) #-} logBase = liftA2 logBase {-# INLINE logBase #-} sin = fmap sin {-# INLINE sin #-} cos = fmap cos {-# INLINE cos #-} tan = fmap tan {-# INLINE tan #-} asin = fmap asin {-# INLINE asin #-} acos = fmap acos {-# INLINE acos #-} atan = fmap atan {-# INLINE atan #-} sinh = fmap sinh {-# INLINE sinh #-} cosh = fmap cosh {-# INLINE cosh #-} tanh = fmap tanh {-# INLINE tanh #-} asinh = fmap asinh {-# INLINE asinh #-} acosh = fmap acosh {-# INLINE acosh #-} atanh = fmap atanh {-# INLINE atanh #-} instance Functor (Stencil ix e) where fmap = rmapStencil {-# INLINE fmap #-} -- Profunctor -- | A Profunctor dimap. Same caviat applies as in `lmapStencil` -- -- @since 0.2.3 dimapStencil :: (c -> d) -> (a -> b) -> Stencil ix d a -> Stencil ix c b dimapStencil f g stencil@Stencil {stencilFunc = sf} = stencil {stencilFunc = sf'} where sf' s = Value . g . unValue . sf (Value . f . unValue . s) {-# INLINE sf' #-} {-# INLINE dimapStencil #-} -- | A contravariant map of a second type parameter. In other words map a function over each element -- of the array, that the stencil will be applied to. -- -- __Note__: This map can be very inefficient, since for stencils larger than 1 element in size, the -- supllied function will be repeatedly applied to the same element. It is better to simply map that -- function over the source array instead. -- -- @since 0.2.3 lmapStencil :: (c -> d) -> Stencil ix d a -> Stencil ix c a lmapStencil f stencil@Stencil {stencilFunc = sf} = stencil {stencilFunc = sf'} where sf' s = sf (Value . f . unValue . s) {-# INLINE sf' #-} {-# INLINE lmapStencil #-} -- | A covariant map over the right most type argument. In other words a usual Functor `fmap`: -- -- > fmap == rmapStencil -- -- @since 0.2.3 rmapStencil :: (a -> b) -> Stencil ix e a -> Stencil ix e b rmapStencil f stencil@Stencil {stencilFunc = sf} = stencil {stencilFunc = sf'} where sf' s = Value . f . unValue . sf s {-# INLINE sf' #-} {-# INLINE rmapStencil #-} -- TODO: Figure out interchange law (u <*> pure y = pure ($ y) <*> u) and issue -- with discarding size and center. Best idea so far is to increase stencil size to -- the maximum one and shift the center of the other stencil so that they both match -- up. This approach would also remove requirement to validate the result -- Stencil - both stencils are trusted, increasing the size will not affect the -- safety. instance Index ix => Applicative (Stencil ix e) where pure a = Stencil oneSz zeroIndex (const (const (Value a))) {-# INLINE pure #-} (<*>) (Stencil (SafeSz sSz1) sC1 f1) (Stencil (SafeSz sSz2) sC2 f2) = Stencil newSz maxCenter stF where stF gV !ix = Value (unValue (f1 gV ix) (unValue (f2 gV ix))) {-# INLINE stF #-} !newSz = Sz (liftIndex2 (+) maxCenter (liftIndex2 max (liftIndex2 (-) sSz1 sC1) (liftIndex2 (-) sSz2 sC2))) !maxCenter = liftIndex2 max sC1 sC2 {-# INLINE (<*>) #-} instance (Index ix, Num a) => Num (Stencil ix e a) where (+) = liftA2 (+) {-# INLINE (+) #-} (-) = liftA2 (-) {-# INLINE (-) #-} (*) = liftA2 (*) {-# INLINE (*) #-} negate = fmap negate {-# INLINE negate #-} abs = fmap abs {-# INLINE abs #-} signum = fmap signum {-# INLINE signum #-} fromInteger = pure . fromInteger {-# INLINE fromInteger #-} instance (Index ix, Fractional a) => Fractional (Stencil ix e a) where (/) = liftA2 (/) {-# INLINE (/) #-} recip = fmap recip {-# INLINE recip #-} fromRational = pure . fromRational {-# INLINE fromRational #-} instance (Index ix, Floating a) => Floating (Stencil ix e a) where pi = pure pi {-# INLINE pi #-} exp = fmap exp {-# INLINE exp #-} log = fmap log {-# INLINE log #-} sqrt = fmap sqrt {-# INLINE sqrt #-} (**) = liftA2 (**) {-# INLINE (**) #-} logBase = liftA2 logBase {-# INLINE logBase #-} sin = fmap sin {-# INLINE sin #-} cos = fmap cos {-# INLINE cos #-} tan = fmap tan {-# INLINE tan #-} asin = fmap asin {-# INLINE asin #-} acos = fmap acos {-# INLINE acos #-} atan = fmap atan {-# INLINE atan #-} sinh = fmap sinh {-# INLINE sinh #-} cosh = fmap cosh {-# INLINE cosh #-} tanh = fmap tanh {-# INLINE tanh #-} asinh = fmap asinh {-# INLINE asinh #-} acosh = fmap acosh {-# INLINE acosh #-} atanh = fmap atanh {-# INLINE atanh #-} safeStencilIndex :: Index ix => Array D ix e -> ix -> e safeStencilIndex DArray {..} ix | isSafeIndex dSize ix = dIndex ix | otherwise = throw $ IndexOutOfBoundsException dSize ix -- | Make sure constructed stencil doesn't index outside the allowed stencil size boundary. validateStencil :: Index ix => e -> Stencil ix e a -> Stencil ix e a validateStencil d s@(Stencil sSz sCenter stencil) = let valArr = DArray Seq sSz (const d) in stencil (Value . safeStencilIndex valArr) sCenter `seq` s {-# INLINE validateStencil #-}