{-# LANGUAGE BangPatterns #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE TypeFamilies #-} -- | -- Module : Data.Massiv.Array.Ops.Construct -- Copyright : (c) Alexey Kuleshevich 2018 -- License : BSD3 -- Maintainer : Alexey Kuleshevich <lehins@yandex.ru> -- Stability : experimental -- Portability : non-portable -- module Data.Massiv.Array.Ops.Construct ( makeArray , makeArrayR , makeVectorR , singleton , range , rangeStep , enumFromN , enumFromStepN ) where import Data.Massiv.Array.Delayed.Internal import Data.Massiv.Core.Common import Prelude as P -- | Just like `makeArray` but with ability to specify the result representation as an -- argument. Note the `Data.Massiv.Array.U`nboxed type constructor in the below example. -- -- >>> makeArrayR U Par (2 :> 3 :. 4) (\ (i :> j :. k) -> i * i + j * j == k * k) -- (Array U Par (2 :> 3 :. 4) -- [ [ [ True,False,False,False ] -- , [ False,True,False,False ] -- , [ False,False,True,False ] -- ] -- , [ [ False,True,False,False ] -- , [ False,False,False,False ] -- , [ False,False,False,False ] -- ] -- ]) -- makeArrayR :: Construct r ix e => r -> Comp -> ix -> (ix -> e) -> Array r ix e makeArrayR _ = makeArray {-# INLINE makeArrayR #-} -- | Same as `makeArrayR`, but restricted to 1-dimensional arrays. makeVectorR :: Construct r Ix1 e => r -> Comp -> Ix1-> (Ix1 -> e) -> Array r Ix1 e makeVectorR _ = makeArray {-# INLINE makeVectorR #-} -- | Create a vector with a range of @Int@s incremented by 1. -- @range k0 k1 == rangeStep k0 k1 1@ -- -- >>> range Seq 1 6 -- (Array D Seq (5) -- [ 1,2,3,4,5 ]) -- >>> range Seq (-2) 3 -- (Array D Seq (5) -- [ -2,-1,0,1,2 ]) -- range :: Comp -> Int -> Int -> Array D Ix1 Int range comp !from !to = makeArray comp (max 0 (to - from)) (+ from) {-# INLINE range #-} -- | Same as `range`, but with a custom step. -- -- >>> rangeStep Seq 1 2 6 -- (Array D Seq (3) -- [ 1,3,5 ]) -- rangeStep :: Comp -- ^ Computation strategy -> Int -- ^ Start -> Int -- ^ Step (Can't be zero) -> Int -- ^ End -> Array D Ix1 Int rangeStep comp !from !step !to | step == 0 = error "rangeStep: Step can't be zero" | otherwise = let (sz, r) = (to - from) `divMod` step in makeArray comp (sz + signum r) (\i -> from + i * step) {-# INLINE rangeStep #-} -- | Same as `enumFromStepN` with step @delta = 1@. -- -- >>> enumFromN Seq (5 :: Double) 3 -- (Array D Seq (3) -- [ 5.0,6.0,7.0 ]) -- enumFromN :: Num e => Comp -> e -- ^ @x@ - start value -> Int -- ^ @n@ - length of resulting vector. -> Array D Ix1 e enumFromN comp !from !sz = makeArray comp sz $ \ i -> fromIntegral i + from {-# INLINE enumFromN #-} -- | Create a vector with length @n@ that has it's 0th value set to @x@ and gradually increasing -- with @step@ delta until the end. Similar to: @`Data.Massiv.Array.fromList'` `Seq` $ `take` n [x, -- x + delta ..]@. Major difference is that `fromList` constructs an `Array` with manifest -- representation, while `enumFromStepN` is delayed. -- -- >>> enumFromStepN Seq 1 (0.1 :: Double) 5 -- (Array D Seq (5) -- [ 1.0,1.1,1.2,1.3,1.4 ]) -- enumFromStepN :: Num e => Comp -> e -- ^ @x@ - start value -> e -- ^ @delta@ - step value -> Int -- ^ @n@ - length of resulting vector -> Array D Ix1 e enumFromStepN comp !from !step !sz = makeArray comp sz $ \ i -> from + fromIntegral i * step {-# INLINE enumFromStepN #-}