{-# LANGUAGE BangPatterns #-} {-# LANGUAGE DataKinds #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE PatternSynonyms #-} {-# LANGUAGE TypeOperators #-} -- | -- Module : Data.Massiv.Core.Index -- Copyright : (c) Alexey Kuleshevich 2018-2019 -- License : BSD3 -- Maintainer : Alexey Kuleshevich -- Stability : experimental -- Portability : non-portable -- module Data.Massiv.Core.Index ( Ix0(..) , type Ix1 , pattern Ix1 , type Ix2(Ix2, (:.)) , IxN((:>), Ix3, Ix4, Ix5) , type Ix3 , type Ix4 , type Ix5 , Ix -- ** Size , type Sz1 , type Sz2 , type Sz3 , type Sz4 , type Sz5 , Sz(Sz, Sz1, Sz2, Sz3, Sz4, Sz5) , unSz , zeroSz , oneSz , consSz , unconsSz , snocSz , unsnocSz , setSzM , insertSzM , pullOutSzM , Dim(..) , Dimension(Dim1, Dim2, Dim3, Dim4, Dim5, DimN) , IsIndexDimension , Lower , Index(..) , Stride(Stride) , unStride , toLinearIndexStride , strideStart , strideSize , oneStride , Border(..) , handleBorderIndex , zeroIndex , oneIndex , isNonEmpty , headDim , tailDim , lastDim , initDim , getDim' , getDim , setDim' , setDim , dropDimM , dropDim' , dropDim , pullOutDim' , pullOutDim , insertDim' , insertDim , fromDimension , getDimension , setDimension , dropDimension , pullOutDimension , insertDimension -- * Iterators , iter , iterLinearM , iterLinearM_ , module Data.Massiv.Core.Iterator , module Data.Massiv.Core.Index.Tuple -- * Exceptions , IndexException(..) , SizeException(..) , ShapeException(..) ) where import Control.Exception (throw) import Control.DeepSeq import Control.Monad.Catch (MonadThrow(..)) import Data.Functor.Identity (runIdentity) import Data.Massiv.Core.Index.Internal import Data.Massiv.Core.Index.Tuple import Data.Massiv.Core.Index.Ix import Data.Massiv.Core.Index.Stride import Data.Massiv.Core.Iterator import GHC.TypeLits -- | Approach to be used near the borders during various transformations. -- Whenever a function needs information not only about an element of interest, but -- also about it's neighbors, it will go out of bounds near the array edges, -- hence is this set of approaches that specify how to handle such situation. data Border e = Fill e -- ^ Fill in a constant element. -- -- @ -- outside | Array | outside -- ('Fill' 0) : 0 0 0 0 | 1 2 3 4 | 0 0 0 0 -- @ -- | Wrap -- ^ Wrap around from the opposite border of the array. -- -- @ -- outside | Array | outside -- 'Wrap' : 1 2 3 4 | 1 2 3 4 | 1 2 3 4 -- @ -- | Edge -- ^ Replicate the element at the edge. -- -- @ -- outside | Array | outside -- 'Edge' : 1 1 1 1 | 1 2 3 4 | 4 4 4 4 -- @ -- | Reflect -- ^ Mirror like reflection. -- -- @ -- outside | Array | outside -- 'Reflect' : 4 3 2 1 | 1 2 3 4 | 4 3 2 1 -- @ -- | Continue -- ^ Also mirror like reflection, but without repeating the edge element. -- -- @ -- outside | Array | outside -- 'Continue' : 1 4 3 2 | 1 2 3 4 | 3 2 1 4 -- @ -- deriving (Eq, Show) instance NFData e => NFData (Border e) where rnf b = case b of Fill e -> rnf e Wrap -> () Edge -> () Reflect -> () Continue -> () -- | Apply a border resolution technique to an index -- -- ==== __Examples__ -- -- >>> handleBorderIndex (Fill 100) (Sz (2 :. 3)) id (2 :. 3) -- 100 :. 100 -- >>> handleBorderIndex Wrap (Sz (2 :. 3)) id (2 :. 3) -- 0 :. 0 -- >>> handleBorderIndex Edge (Sz (2 :. 3)) id (2 :. 3) -- 1 :. 2 -- -- @since 0.1.0 handleBorderIndex :: Index ix => Border e -- ^ Broder resolution technique -> Sz ix -- ^ Size -> (ix -> e) -- ^ Index function that produces an element -> ix -- ^ Index -> e handleBorderIndex border !sz getVal !ix = case border of Fill val -> if isSafeIndex sz ix then getVal ix else val Wrap -> getVal (repairIndex sz ix wrap wrap) Edge -> getVal (repairIndex sz ix (const (const 0)) (\ (SafeSz k) _ -> k - 1)) Reflect -> getVal (repairIndex sz ix (\ (SafeSz k) !i -> (abs i - 1) `mod` k) (\ (SafeSz k) !i -> (-i - 1) `mod` k)) Continue -> getVal (repairIndex sz ix (\ (SafeSz k) !i -> abs i `mod` k) (\ (SafeSz k) !i -> (-i - 2) `mod` k)) where wrap (SafeSz k) i = i `mod` k {-# INLINE [1] wrap #-} {-# INLINE [1] handleBorderIndex #-} -- | Index with all zeros -- -- ==== __Examples__ -- -- >>> zeroIndex :: Ix4 -- 0 :> 0 :> 0 :. 0 -- -- @since 0.1.0 zeroIndex :: Index ix => ix zeroIndex = pureIndex 0 {-# INLINE [1] zeroIndex #-} -- | Index with all ones -- -- @since 0.3.0 oneIndex :: Index ix => ix oneIndex = pureIndex 1 {-# INLINE [1] oneIndex #-} -- | Checks whether array with this size can hold at least one element. -- -- ==== __Examples__ -- -- >>> isNonEmpty (Sz3 1 0 2) -- False -- -- @since 0.1.0 isNonEmpty :: Index ix => Sz ix -> Bool isNonEmpty !sz = isSafeIndex sz zeroIndex {-# INLINE [1] isNonEmpty #-} -- TODO: benchmark against (also adjust `isEmpty` with fastest): -- - foldlIndex (*) 1 (unSz sz) /= 0 -- - foldlIndex ((&&) . (==0)) True (unSz sz) -- - totalElem sz == 0 -- | Get the outmost dimension of the index. -- -- ==== __Examples__ -- -- >>> headDim (2 :> 3 :> 4 :. 5) -- 2 -- -- @since 0.1.0 headDim :: Index ix => ix -> Int headDim = fst . unconsDim {-# INLINE [1] headDim #-} -- | Drop the outmost dimension from the index -- -- ==== __Examples__ -- -- >>> tailDim (2 :> 3 :> 4 :. 5) -- 3 :> 4 :. 5 -- -- @since 0.1.0 tailDim :: Index ix => ix -> Lower ix tailDim = snd . unconsDim {-# INLINE [1] tailDim #-} -- | Get the innermost dimension from the index -- -- ==== __Examples__ -- -- >>> lastDim (2 :> 3 :> 4 :. 5) -- 5 -- -- @since 0.1.0 lastDim :: Index ix => ix -> Int lastDim = snd . unsnocDim {-# INLINE [1] lastDim #-} -- | Drop the innermost dimension from the index -- -- ==== __Examples__ -- -- >>> initDim (2 :> 3 :> 4 :. 5) -- 2 :> 3 :. 4 -- -- @since 0.1.0 initDim :: Index ix => ix -> Lower ix initDim = fst . unsnocDim {-# INLINE [1] initDim #-} -- | Change the value of a specific dimension within the index. Throws `IndexException`. See -- `setDimM` for a safer version and `setDimension` for a type safe version. -- -- ==== __Examples__ -- -- >>> setDim' (2 :> 3 :> 4 :. 5) 3 10 -- 2 :> 10 :> 4 :. 5 -- -- @since 0.2.4 setDim' :: Index ix => ix -> Dim -> Int -> ix setDim' ix dim = either throw id . setDimM ix dim {-# INLINE [1] setDim' #-} -- | See `setDimM` -- -- @since 0.2.4 setDim :: Index ix => ix -> Dim -> Int -> Maybe ix setDim = setDimM {-# INLINE [1] setDim #-} {-# DEPRECATED setDim "In favor of more general `setDimM`" #-} -- | Change the value from a specific dimension within the index. Throws `IndexException`. See -- `getDimM` for a safer version and `getDimension` for a type safe version. -- -- ==== __Examples__ -- -- >>> getDim' (2 :> 3 :> 4 :. 5) 3 -- 3 -- >>> getDim' (2 :> 3 :> 4 :. 5) 0 -- *** Exception: IndexDimensionException: (Dim 0) for 3 :> 4 :. 5 -- -- @since 0.2.4 getDim' :: Index ix => ix -> Dim -> Int getDim' ix = either throw id . getDimM ix {-# INLINE [1] getDim' #-} -- | See `getDimM` -- -- @since 0.2.4 getDim :: Index ix => ix -> Dim -> Maybe Int getDim = getDimM {-# INLINE [1] getDim #-} {-# DEPRECATED getDim "In favor of more general `getDimM`" #-} -- | Remove a dimension from the index. -- -- ==== __Examples__ -- -- λ> dropDimM (2 :> 3 :> 4 :. 5) 3 :: Maybe Ix3 -- Just (2 :> 4 :. 5) -- λ> dropDimM (2 :> 3 :> 4 :. 5) 6 :: Maybe Ix3 -- Nothing -- -- @since 0.3.0 dropDimM :: (MonadThrow m, Index ix) => ix -> Dim -> m (Lower ix) dropDimM ix = fmap snd . pullOutDimM ix {-# INLINE [1] dropDimM #-} -- | See `dropDimM` -- -- @since 0.1.0 dropDim :: Index ix => ix -> Dim -> Maybe (Lower ix) dropDim = dropDimM {-# INLINE [1] dropDim #-} {-# DEPRECATED dropDim "In favor of more general `dropDimM`" #-} -- | Remove a dimension from the index. -- -- ==== __Examples__ -- -- >>> dropDim' (2 :> 3 :> 4 :. 5) 3 -- 2 :> 4 :. 5 -- >>> dropDim' (2 :> 3 :> 4 :. 5) 6 -- *** Exception: IndexDimensionException: (Dim 6) for 3 :> 4 :. 5 -- -- @since 0.2.4 dropDim' :: Index ix => ix -> Dim -> Lower ix dropDim' ix = either throw id . dropDimM ix {-# INLINE [1] dropDim' #-} -- | Lower the dimension of the index by pulling the specified dimension. Throws `IndexException`. See -- `pullOutDimM` for a safer version and `pullOutDimension` for a type safe version. -- -- ==== __Examples__ -- -- λ> pullOutDim' (2 :> 3 :> 4 :. 5) 3 -- (3,2 :> 4 :. 5) -- -- @since 0.2.4 pullOutDim' :: Index ix => ix -> Dim -> (Int, Lower ix) pullOutDim' ix = either throw id . pullOutDimM ix {-# INLINE [1] pullOutDim' #-} -- | See `pullOutDimM` -- -- @since 0.2.4 pullOutDim :: Index ix => ix -> Dim -> Maybe (Int, Lower ix) pullOutDim = pullOutDimM {-# INLINE [1] pullOutDim #-} {-# DEPRECATED pullOutDim "In favor of more general `pullOutDimM`" #-} -- | Raise the dimension of the index by inserting one in the specified dimension. Throws -- `IndexException`. See `insertDimM` for a safer version and `insertDimension` for a type safe -- version. -- -- ==== __Examples__ -- -- >>> insertDim' (2 :> 3 :> 4 :. 5) 3 10 :: Ix5 -- 2 :> 3 :> 10 :> 4 :. 5 -- >>> insertDim' (2 :> 3 :> 4 :. 5) 11 10 :: Ix5 -- *** Exception: IndexDimensionException: (Dim 11) for 4 :. 5 -- -- @since 0.2.4 insertDim' :: Index ix => Lower ix -> Dim -> Int -> ix insertDim' ix dim = either throw id . insertDimM ix dim {-# INLINE [1] insertDim' #-} -- | See `insertDimM` -- -- @since 0.2.4 insertDim :: Index ix => Lower ix -> Dim -> Int -> Maybe ix insertDim = insertDimM {-# INLINE [1] insertDim #-} {-# DEPRECATED insertDim "In favor of more general `insertDimM`" #-} -- | Get the value level `Dim` from the type level equivalent. -- -- ==== __Examples__ -- -- >>> fromDimension Dim4 -- (Dim 4) -- >>> :set -XDataKinds -- >>> fromDimension (DimN :: Dimension 10) -- (Dim 10) -- -- @since 0.2.4 fromDimension :: KnownNat n => Dimension n -> Dim fromDimension = fromIntegral . natVal {-# INLINE [1] fromDimension #-} -- | Type safe way to set value of index at a particular dimension. -- -- ==== __Examples__ -- -- >>> setDimension (2 :> 3 :> 4 :. 5) Dim4 10 -- 10 :> 3 :> 4 :. 5 -- -- @since 0.2.4 setDimension :: IsIndexDimension ix n => ix -> Dimension n -> Int -> ix setDimension ix d = setDim' ix (fromDimension d) {-# INLINE [1] setDimension #-} -- | Type safe way to extract value of index at a particular dimension. -- -- ==== __Examples__ -- -- >>> getDimension (2 :> 3 :> 4 :. 5) Dim2 -- 4 -- -- @since 0.2.4 getDimension :: IsIndexDimension ix n => ix -> Dimension n -> Int getDimension ix d = getDim' ix (fromDimension d) {-# INLINE [1] getDimension #-} -- | Type safe way of dropping a particular dimension, thus lowering index -- dimensionality. -- -- ==== __Examples__ -- -- >>> dropDimension (2 :> 3 :> 4 :. 5) Dim2 -- 2 :> 3 :. 5 -- -- @since 0.2.4 dropDimension :: IsIndexDimension ix n => ix -> Dimension n -> Lower ix dropDimension ix d = dropDim' ix (fromDimension d) {-# INLINE [1] dropDimension #-} -- | Type safe way of pulling out a particular dimension, thus lowering index -- dimensionality and returning the value at specified dimension. -- -- ==== __Examples__ -- -- >>> pullOutDimension (2 :> 3 :> 4 :. 5) Dim2 -- (4,2 :> 3 :. 5) -- -- @since 0.2.4 pullOutDimension :: IsIndexDimension ix n => ix -> Dimension n -> (Int, Lower ix) pullOutDimension ix d = pullOutDim' ix (fromDimension d) {-# INLINE [1] pullOutDimension #-} -- | Type safe way of inserting a particular dimension, thus raising index dimensionality. -- -- ==== __Examples__ -- -- >>> insertDimension (2 :> 3 :> 4 :. 5) Dim5 10 :: Ix5 -- 10 :> 2 :> 3 :> 4 :. 5 -- >>> insertDimension (2 :> 3 :> 4 :. 5) Dim4 10 :: Ix5 -- 2 :> 10 :> 3 :> 4 :. 5 -- >>> insertDimension (2 :> 3 :> 4 :. 5) Dim3 10 :: Ix5 -- 2 :> 3 :> 10 :> 4 :. 5 -- >>> insertDimension (2 :> 3 :> 4 :. 5) Dim2 10 :: Ix5 -- 2 :> 3 :> 4 :> 10 :. 5 -- >>> insertDimension (2 :> 3 :> 4 :. 5) Dim1 10 :: Ix5 -- 2 :> 3 :> 4 :> 5 :. 10 -- -- @since 0.2.5 insertDimension :: IsIndexDimension ix n => Lower ix -> Dimension n -> Int -> ix insertDimension ix d = insertDim' ix (fromDimension d) {-# INLINE [1] insertDimension #-} -- | Row-major iterator for the index. Same as `iterM`, but pure. -- -- ==== __Examples__ -- -- >>> iter (Ix1 0) 1000 1 (<) 0 (+) -- 499500 -- >>> iter (0 :. 0) (2 :. 3) oneIndex (<) 100 $ \ (i :. j) acc -> (acc + i) * (j + 1) -- 3615 -- -- @since 0.1.0 iter :: Index ix => ix -- ^ Start index -> ix -- ^ End index -> ix -- ^ Increment -> (Int -> Int -> Bool) -- ^ Continuation confition -> a -- ^ Accumulator -> (ix -> a -> a) -- ^ Iterating function -> a iter sIx eIx incIx cond acc f = runIdentity $ iterM sIx eIx incIx cond acc (\ix -> return . f ix) {-# INLINE iter #-} -- | Iterate over N-dimensional space linearly from start to end in row-major fashion with an -- accumulator -- -- ==== __Examples__ -- -- >>> sz = Sz2 3 4 -- >>> iterLinearM sz 0 3 1 (<) 100 $ \ k ix acc -> print (fromLinearIndex sz k == ix) >> pure (acc + k) -- True -- True -- True -- 103 -- -- @since 0.1.0 iterLinearM :: (Index ix, Monad m) => Sz ix -- ^ Size -> Int -- ^ Linear start -> Int -- ^ Linear end -> Int -- ^ Increment -> (Int -> Int -> Bool) -- ^ Continuation condition (continue if True) -> a -- ^ Accumulator -> (Int -> ix -> a -> m a) -> m a iterLinearM !sz !k0 !k1 !inc cond !acc f = loopM k0 (`cond` k1) (+ inc) acc $ \ !i !acc0 -> f i (fromLinearIndex sz i) acc0 {-# INLINE iterLinearM #-} -- | Same as `iterLinearM`, except without an accumulator. -- -- ==== __Examples__ -- -- >>> sz = Sz2 3 4 -- >>> iterLinearM_ sz 0 3 1 (<) $ \ k ix -> print (toLinearIndex sz ix == k) -- True -- True -- True -- -- @since 0.1.0 iterLinearM_ :: (Index ix, Monad m) => Sz ix -- ^ Size -> Int -- ^ Start -> Int -- ^ End -> Int -- ^ Increment -> (Int -> Int -> Bool) -- ^ Continuation condition -> (Int -> ix -> m ()) -- ^ Monadic action that takes index in both forms -> m () iterLinearM_ sz !k0 !k1 !inc cond f = loopM_ k0 (`cond` k1) (+ inc) $ \ !i -> f i (fromLinearIndex sz i) {-# INLINE iterLinearM_ #-}