{-# LANGUAGE DerivingStrategies #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE NoImplicitPrelude #-}
{-# LANGUAGE Trustworthy #-}

-----------------------------------------------------------------------------
-- |
-- Module      :  Data.Bits
-- Copyright   :  (c) The University of Glasgow 2001
-- License     :  BSD-style (see the file libraries/base/LICENSE)
--
-- Maintainer  :  libraries@haskell.org
-- Stability   :  experimental
-- Portability :  portable
--
-- This module defines bitwise operations for signed and unsigned
-- integers.  Instances of the class 'Bits' for the 'Int' and
-- 'Integer' types are available from this module, and instances for
-- explicitly sized integral types are available from the
-- "Data.Int" and "Data.Word" modules.
--
-----------------------------------------------------------------------------

module Data.Bits (
  -- * Type classes
  Bits(
    (.&.), (.|.), xor,
    complement,
    shift,
    rotate,
    zeroBits,
    bit,
    setBit,
    clearBit,
    complementBit,
    testBit,
    bitSizeMaybe,
    bitSize,
    isSigned,
    shiftL, shiftR,
    unsafeShiftL, unsafeShiftR,
    rotateL, rotateR,
    popCount
  ),
  FiniteBits(
    finiteBitSize,
    countLeadingZeros,
    countTrailingZeros
  ),
  -- * Extra functions
  bitDefault,
  testBitDefault,
  popCountDefault,
  toIntegralSized,
  oneBits,
  -- * Newtypes
  And(..), Ior(..), Xor(..), Iff(..)
 ) where

import GHC.Base
import GHC.Bits
import GHC.Enum
import GHC.Read
import GHC.Show

-- $setup
-- >>> import Prelude
-- >>> import Data.Word

-- | A more concise version of @complement zeroBits@.
--
-- >>> complement (zeroBits :: Word) == (oneBits :: Word)
-- True
--
-- >>> complement (oneBits :: Word) == (zeroBits :: Word)
-- True
--
-- = Note
--
-- The constraint on 'oneBits' is arguably too strong. However, as some types
-- (such as 'Natural') have undefined 'complement', this is the only safe
-- choice.
--
-- @since 4.16
oneBits :: (FiniteBits a) => a
oneBits = complement zeroBits
{-# INLINE oneBits #-}

-- | Monoid under bitwise AND.
--
-- >>> getAnd (And 0xab <> And 0x12) :: Word8
-- 2
--
-- @since 4.16
newtype And a = And { getAnd :: a }
  deriving newtype (
                    Bounded, -- ^ @since 4.16
                    Enum, -- ^ @since 4.16
                    Bits, -- ^ @since 4.16
                    FiniteBits, -- ^ @since 4.16
                    Eq -- ^ @since 4.16
                    )
  deriving stock (
                  Show, -- ^ @since 4.16
                  Read -- ^ @since 4.16
                 )

-- | @since 4.16
instance (Bits a) => Semigroup (And a) where
  And x <> And y = And (x .&. y)

-- | This constraint is arguably too strong. However,
-- as some types (such as 'Natural') have undefined 'complement', this is the
-- only safe choice.
--
-- @since 4.16
instance (FiniteBits a) => Monoid (And a) where
  mempty = And oneBits

-- | Monoid under bitwise inclusive OR.
--
-- >>> getIor (Ior 0xab <> Ior 0x12) :: Word8
-- 187
--
-- @since 4.16
newtype Ior a = Ior { getIor :: a }
  deriving newtype (
                    Bounded, -- ^ @since 4.16
                    Enum, -- ^ @since 4.16
                    Bits, -- ^ @since 4.16
                    FiniteBits, -- ^ @since 4.16
                    Eq -- ^ @since 4.16
                    )
  deriving stock (
                  Show, -- ^ @since 4.16
                  Read -- ^ @since 4.16
                 )

-- | @since 4.16
instance (Bits a) => Semigroup (Ior a) where
  Ior x <> Ior y = Ior (x .|. y)

-- | @since 4.16
instance (Bits a) => Monoid (Ior a) where
  mempty = Ior zeroBits

-- | Monoid under bitwise XOR.
--
-- >>> getXor (Xor 0xab <> Xor 0x12) :: Word8
-- 185
--
-- @since 4.16
newtype Xor a = Xor { getXor :: a }
  deriving newtype (
                    Bounded, -- ^ @since 4.16
                    Enum, -- ^ @since 4.16
                    Bits, -- ^ @since 4.16
                    FiniteBits, -- ^ @since 4.16
                    Eq -- ^ @since 4.16
                    )
  deriving stock (
                  Show, -- ^ @since 4.16
                  Read -- ^ @since 4.16
                 )

-- | @since 4.16
instance (Bits a) => Semigroup (Xor a) where
  Xor x <> Xor y = Xor (x `xor` y)

-- | @since 4.16
instance (Bits a) => Monoid (Xor a) where
  mempty = Xor zeroBits

-- | Monoid under bitwise \'equality\'; defined as @1@ if the corresponding
-- bits match, and @0@ otherwise.
--
-- >>> getIff (Iff 0xab <> Iff 0x12) :: Word8
-- 70
--
-- @since 4.16
newtype Iff a = Iff { getIff :: a }
  deriving newtype (
                    Bounded, -- ^ @since 4.16
                    Enum, -- ^ @since 4.16
                    Bits, -- ^ @since 4.16
                    FiniteBits, -- ^ @since 4.16
                    Eq -- ^ @since 4.16
                    )
  deriving stock (
                  Show, -- ^ @since 4.16
                  Read -- ^ @since 4.16
                 )

-- | This constraint is arguably
-- too strong. However, as some types (such as 'Natural') have undefined
-- 'complement', this is the only safe choice.
--
-- @since 4.16
instance (FiniteBits a) => Semigroup (Iff a) where
  Iff x <> Iff y = Iff . complement $ (x `xor` y)

-- | This constraint is arguably
-- too strong. However, as some types (such as 'Natural') have undefined
-- 'complement', this is the only safe choice.
--
-- @since 4.16
instance (FiniteBits a) => Monoid (Iff a) where
  mempty = Iff oneBits