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linear-base-0.5.0: src/Data/Array/Mutable/Unlifted/Linear.hs

{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE KindSignatures #-}
{-# LANGUAGE LinearTypes #-}
{-# LANGUAGE MagicHash #-}
{-# LANGUAGE PolyKinds #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE UnboxedTuples #-}
{-# LANGUAGE UnliftedNewtypes #-}
{-# LANGUAGE NoImplicitPrelude #-}

-- |
-- This module provides an unlifted mutable array with a pure
-- interface. Though the array itself is unlifted, it's elements are
-- lifted types. This is made possible by using linear types to make
-- sure array references are single threaded through reads and writes.
--
-- Accessing out-of-bounds indices causes undefined behaviour.
--
-- This module is meant to be imported qualified.
module Data.Array.Mutable.Unlifted.Linear
  ( Array#,
    unArray#,
    alloc,
    allocBeside,
    lseq,
    size,
    get,
    set,
    copyInto,
    map,
    toList,
    freeze,
    dup2,
  )
where

import Data.Unrestricted.Linear hiding (dup2, lseq)
import qualified GHC.Exts as GHC
import qualified Unsafe.Linear as Unsafe
import Prelude (Int)
import qualified Prelude as Prelude

-- | A mutable array holding @a@s
newtype Array# a = Array# (GHC.MutableArray# GHC.RealWorld a)

-- | Extract the underlying 'GHC.MutableArray#', consuming the 'Array#'
-- in process.
unArray# :: (GHC.MutableArray# GHC.RealWorld a -> b) -> Array# a %1 -> Ur b
unArray# f = Unsafe.toLinear (\(Array# a) -> Ur (f a))

-- | Consume an 'Array#'.
--
-- Note that we can not implement a 'Consumable' instance because 'Array#'
-- is unlifted.
lseq :: Array# a %1 -> b %1 -> b
lseq = Unsafe.toLinear2 (\_ b -> b)

infixr 0 `lseq` -- same fixity as base.seq

-- | Allocate a mutable array of given size using a default value.
--
-- The size should be non-negative.
alloc :: (Movable b) => Int -> a -> (Array# a %1 -> b) %1 -> b
alloc i a f = case move (unsafe_alloc i a f) of
  Ur b -> b
{-# INLINEABLE alloc #-}

-- The `alloc` function is split in two. One very unsafe below (it's very
-- unsafe, because `unafe_alloc 57 0 id` returns an unrestricted _mutable_
-- `Array#` breaking the module's invariants). Because `unsafe_alloc` calls
-- `runRW#`, it's marked as `NOINLINE`.
--
-- It's made safe by the wrapping function `alloc`, which restricts `b` to be
-- `Movable` (`Array#` is crucially not `Movable`, therefore `alloc 57 0 id`
-- doesn't type). Furthermore, `alloc` cases on `move` to make sure that all the
-- effects have been run by the time we evaluate the result of an `alloc`. It's
-- fine that `alloc` is inlined: its semantics is preserved by program
-- transformations. It's useful that `alloc` be inlined, because in most
-- instance `case move … of` will trigger a case-of-known-constructor avoiding
-- an extra allocation. This is in particular the case for the common case where
-- `b = Ur x`.
unsafe_alloc :: Int -> a -> (Array# a %1 -> b) %1 -> b
unsafe_alloc (GHC.I# s) a f =
  let new = GHC.runRW# Prelude.$ \st ->
        case GHC.newArray# s a st of
          (# _, arr #) -> Array# arr
   in f new
{-# NOINLINE unsafe_alloc #-} -- prevents runRW# from floating outwards

-- For the reasoning behind these NOINLINE pragmas, see the discussion at:
-- https://github.com/tweag/linear-base/pull/187#pullrequestreview-489183531

-- | Allocate a mutable array of given size using a default value,
-- using another 'Array#' as a uniqueness proof.
--
-- The size should be non-negative.
allocBeside :: Int -> a -> Array# b %1 -> (# Array# a, Array# b #)
allocBeside (GHC.I# s) a orig =
  let new = GHC.runRW# Prelude.$ \st ->
        case GHC.newArray# s a st of
          (# _, arr #) -> Array# arr
   in (# new, orig #)
{-# NOINLINE allocBeside #-} -- prevents runRW# from floating outwards

size :: Array# a %1 -> (# Ur Int, Array# a #)
size = Unsafe.toLinear go
  where
    go :: Array# a -> (# Ur Int, Array# a #)
    go (Array# arr) =
      let !s = GHC.sizeofMutableArray# arr
       in (# Ur (GHC.I# s), Array# arr #)

get :: Int -> Array# a %1 -> (# Ur a, Array# a #)
get (GHC.I# i) = Unsafe.toLinear go
  where
    go :: Array# a -> (# Ur a, Array# a #)
    go (Array# arr) =
      case GHC.runRW# (GHC.readArray# arr i) of
        (# _, ret #) -> (# Ur ret, Array# arr #)
{-# NOINLINE get #-} -- prevents the runRW# effect from being reordered

set :: Int -> a -> Array# a %1 -> Array# a
set (GHC.I# i) (a :: a) = Unsafe.toLinear go
  where
    go :: Array# a -> Array# a
    go (Array# arr) =
      case GHC.runRW# (GHC.writeArray# arr i a) of
        _ -> Array# arr
{-# NOINLINE set #-} -- prevents the runRW# effect from being reordered

-- | Copy the first mutable array into the second mutable array, starting
-- from the given index of the source array.
--
-- It copies fewer elements if the second array is smaller than the
-- first. 'n' should be within [0..size src).
--
-- @
--  copyInto n src dest:
--   dest[i] = src[n+i] for i < size dest, i < size src + n
-- @
copyInto :: Int -> Array# a %1 -> Array# a %1 -> (# Array# a, Array# a #)
copyInto start@(GHC.I# start#) = Unsafe.toLinear2 go
  where
    go :: Array# a -> Array# a -> (# Array# a, Array# a #)
    go (Array# src) (Array# dst) =
      let !(GHC.I# len#) =
            Prelude.min
              (GHC.I# (GHC.sizeofMutableArray# src) Prelude.- start)
              (GHC.I# (GHC.sizeofMutableArray# dst))
       in case GHC.runRW# (GHC.copyMutableArray# src start# dst 0# len#) of
            _ -> (# Array# src, Array# dst #)
{-# NOINLINE copyInto #-} -- prevents the runRW# effect from being reordered

map :: (a -> b) -> Array# a %1 -> Array# b
map (f :: a -> b) =
  Unsafe.toLinear
    ( \(Array# as) ->
        let -- We alias the input array to write the resulting -- 'b's to,
            -- just to make the typechecker happy. Care must be taken to
            -- only read indices from 'as' that is not yet written to 'bs'.
            bs :: GHC.MutableArray# GHC.RealWorld b
            bs = GHC.unsafeCoerce# as
            len :: GHC.Int#
            len = GHC.sizeofMutableArray# as

            -- For each index ([0..len]), we read the element on 'as', pass
            -- it through 'f' and write to the same location on 'bs'.
            go :: GHC.Int# -> GHC.State# GHC.RealWorld -> ()
            go i st
              | GHC.I# i Prelude.== GHC.I# len = ()
              | Prelude.otherwise =
                  case GHC.readArray# as i st of
                    (# st', a #) ->
                      case GHC.writeArray# bs i (f a) st' of
                        !st'' -> go (i GHC.+# 1#) st''
         in GHC.runRW# (go 0#) `GHC.seq` Array# bs
    )
{-# NOINLINE map #-}

-- | Return the array elements as a lazy list.
toList :: Array# a %1 -> Ur [a]
toList = unArray# Prelude.$ \arr ->
  go
    0
    (GHC.I# (GHC.sizeofMutableArray# arr))
    arr
  where
    go i len arr
      | i Prelude.== len = []
      | GHC.I# i# <- i =
          case GHC.runRW# (GHC.readArray# arr i#) of
            (# _, ret #) -> ret : go (i Prelude.+ 1) len arr

-- | /O(1)/ Convert an 'Array#' to an immutable 'GHC.Array#'.
freeze :: (GHC.Array# a -> b) -> Array# a %1 -> Ur b
freeze f = unArray# go
  where
    go mut =
      case GHC.runRW# (GHC.unsafeFreezeArray# mut) of
        (# _, ret #) -> f ret

-- | Clone an array.
dup2 :: Array# a %1 -> (# Array# a, Array# a #)
dup2 = Unsafe.toLinear go
  where
    go :: Array# a -> (# Array# a, Array# a #)
    go (Array# arr) =
      case GHC.runRW#
        (GHC.cloneMutableArray# arr 0# (GHC.sizeofMutableArray# arr)) of
        (# _, new #) -> (# Array# arr, Array# new #)
{-# NOINLINE dup2 #-}