{-# LANGUAGE FlexibleContexts #-} {-# OPTIONS_HADDOCK not-home #-} -- | -- Module : Prelude.Backprop.Num -- Copyright : (c) Justin Le 2018 -- License : BSD3 -- -- Maintainer : justin@jle.im -- Stability : experimental -- Portability : non-portable -- -- Provides the exact same API as "Prelude.Backprop", except requiring -- 'Num' instances for all types involved instead of 'Backprop' instances. -- -- @since 0.2.0.0 module Prelude.Backprop.Num ( -- * Foldable and Traversable sum , product , length , minimum , maximum , traverse , toList , mapAccumL , mapAccumR -- * Functor and Applicative , fmap , (<$>) , pure , liftA2 , liftA3 -- * Misc , fromIntegral , realToFrac , E.coerce ) where import Numeric.Backprop.Num import Prelude (Num(..), Fractional(..), Ord(..), Functor, Foldable, Traversable, Applicative) import qualified Numeric.Backprop.Explicit as E import qualified Prelude as P import qualified Prelude.Backprop.Explicit as E -- | 'Prelude.Backprop.sum', but with 'Num' constraints instead of -- 'Backprop' constraints. sum :: (Foldable t, Functor t, Num (t a), Num a, Reifies s W) => BVar s (t a) -> BVar s a sum = E.sum E.afNum E.zfNum {-# INLINE sum #-} -- | 'Prelude.Backprop.pure', but with 'Num' constraints instead of -- 'Backprop' constraints. pure :: (Foldable t, Applicative t, Num (t a), Num a, Reifies s W) => BVar s a -> BVar s (t a) pure = E.pure E.afNum E.zfNum E.zfNum {-# INLINE pure #-} -- | 'Prelude.Backprop.product', but with 'Num' constraints instead of -- 'Backprop' constraints. product :: (Foldable t, Functor t, Num (t a), Fractional a, Reifies s W) => BVar s (t a) -> BVar s a product = E.product E.afNum E.zfNum {-# INLINE product #-} -- | 'Prelude.Backprop.length', but with 'Num' constraints instead of -- 'Backprop' constraints. length :: (Foldable t, Num (t a), Num b, Reifies s W) => BVar s (t a) -> BVar s b length = E.length E.afNum E.zfNum E.zfNum {-# INLINE length #-} -- | 'Prelude.Backprop.minimum', but with 'Num' constraints instead of -- 'Backprop' constraints. minimum :: (Foldable t, Functor t, Num a, Ord a, Num (t a), Reifies s W) => BVar s (t a) -> BVar s a minimum = E.minimum E.afNum E.zfNum {-# INLINE minimum #-} -- | 'Prelude.Backprop.maximum', but with 'Num' constraints instead of -- 'Backprop' constraints. maximum :: (Foldable t, Functor t, Num a, Ord a, Num (t a), Reifies s W) => BVar s (t a) -> BVar s a maximum = E.maximum E.afNum E.zfNum {-# INLINE maximum #-} -- | 'Prelude.Backprop.fmap', but with 'Num' constraints instead of -- 'Backprop' constraints. fmap :: (Traversable f, Num a, Num b, Num (f b), Reifies s W) => (BVar s a -> BVar s b) -> BVar s (f a) -> BVar s (f b) fmap = E.fmap E.afNum E.afNum E.zfNum E.zfNum E.zfNum {-# INLINE fmap #-} -- | Alias for 'fmap'. (<$>) :: (Traversable f, Num a, Num b, Num (f b), Reifies s W) => (BVar s a -> BVar s b) -> BVar s (f a) -> BVar s (f b) (<$>) = fmap {-# INLINE (<$>) #-} -- | 'Prelude.Backprop.traverse', but with 'Num' constraints instead of -- 'Backprop' constraints. traverse :: (Traversable t, Applicative f, Foldable f, Num a, Num b, Num (f (t b)), Num (t b), Reifies s W) => (BVar s a -> f (BVar s b)) -> BVar s (t a) -> BVar s (f (t b)) traverse = E.traverse E.afNum E.afNum E.afNum E.zfNum E.zfNum E.zfNum E.zfNum {-# INLINE traverse #-} -- | 'Prelude.Backprop.liftA2', but with 'Num' constraints instead of -- 'Backprop' constraints. liftA2 :: ( Traversable f , Applicative f , Num a, Num b, Num c, Num (f c) , Reifies s W ) => (BVar s a -> BVar s b -> BVar s c) -> BVar s (f a) -> BVar s (f b) -> BVar s (f c) liftA2 = E.liftA2 E.afNum E.afNum E.afNum E.zfNum E.zfNum E.zfNum E.zfNum {-# INLINE liftA2 #-} -- | 'Prelude.Backprop.liftA3', but with 'Num' constraints instead of -- 'Backprop' constraints. liftA3 :: ( Traversable f , Applicative f , Num a, Num b, Num c, Num d, Num (f d) , Reifies s W ) => (BVar s a -> BVar s b -> BVar s c -> BVar s d) -> BVar s (f a) -> BVar s (f b) -> BVar s (f c) -> BVar s (f d) liftA3 = E.liftA3 E.afNum E.afNum E.afNum E.afNum E.zfNum E.zfNum E.zfNum E.zfNum E.zfNum {-# INLINE liftA3 #-} -- | 'Prelude.Backprop.fromIntegral', but with 'Num' constraints instead of -- 'Backprop' constraints. -- -- @since 0.2.1.0 fromIntegral :: (P.Integral a, P.Integral b, Reifies s W) => BVar s a -> BVar s b fromIntegral = E.fromIntegral E.afNum E.zfNum {-# INLINE fromIntegral #-} -- | 'Prelude.Backprop.realToFrac', but with 'Num' constraints instead of -- 'Backprop' constraints. -- -- @since 0.2.1.0 realToFrac :: (Fractional a, P.Real a, Fractional b, P.Real b, Reifies s W) => BVar s a -> BVar s b realToFrac = E.realToFrac E.afNum E.zfNum {-# INLINE realToFrac #-} -- | 'Prelude.Backprop.toList', but with 'Num' constraints instead of -- 'Backprop' constraints. -- -- @since 0.2.2.0 toList :: (Traversable t, Num a, Reifies s W) => BVar s (t a) -> [BVar s a] toList = E.toList E.afNum E.zfNum {-# INLINE toList #-} -- | 'Prelude.Backprop.mapAccumL', but with 'Num' constraints instead of -- 'Backprop' constraints. -- -- @since 0.2.2.0 mapAccumL :: (Traversable t, Num b, Num c, Num (t c), Reifies s W) => (BVar s a -> BVar s b -> (BVar s a, BVar s c)) -> BVar s a -> BVar s (t b) -> (BVar s a, BVar s (t c)) mapAccumL = E.mapAccumL E.afNum E.afNum E.zfNum E.zfNum E.zfNum {-# INLINE mapAccumL #-} -- | 'Prelude.Backprop.mapAccumR', but with 'Num' constraints instead of -- 'Backprop' constraints. -- -- @since 0.2.2.0 mapAccumR :: (Traversable t, Num b, Num c, Num (t c), Reifies s W) => (BVar s a -> BVar s b -> (BVar s a, BVar s c)) -> BVar s a -> BVar s (t b) -> (BVar s a, BVar s (t c)) mapAccumR = E.mapAccumR E.afNum E.afNum E.zfNum E.zfNum E.zfNum {-# INLINE mapAccumR #-}