{-# LANGUAGE Trustworthy #-}
{-# LANGUAGE CPP
           , NoImplicitPrelude
           , MagicHash
           , UnboxedTuples
  #-}
-- We believe we could deorphan this module, by moving lots of things
-- around, but we haven't got there yet:
{-# OPTIONS_GHC -fno-warn-orphans #-}
{-# OPTIONS_HADDOCK hide #-}

-----------------------------------------------------------------------------
-- |
-- Module      :  GHC.Float
-- Copyright   :  (c) The University of Glasgow 1994-2002
--                Portions obtained from hbc (c) Lennart Augusstson
-- License     :  see libraries/base/LICENSE
--
-- Maintainer  :  cvs-ghc@haskell.org
-- Stability   :  internal
-- Portability :  non-portable (GHC Extensions)
--
-- The types 'Float' and 'Double', and the classes 'Floating' and 'RealFloat'.
--
-----------------------------------------------------------------------------

#include "ieee-flpt.h"

module GHC.Float( module GHC.Float, Float(..), Double(..), Float#, Double#
                , double2Int, int2Double, float2Int, int2Float )
    where

import Data.Maybe

import Data.Bits
import GHC.Base
import GHC.List
import GHC.Enum
import GHC.Show
import GHC.Num
import GHC.Real
import GHC.Arr
import GHC.Float.RealFracMethods
import GHC.Float.ConversionUtils
import GHC.Integer.Logarithms ( integerLogBase# )
import GHC.Integer.Logarithms.Internals

infixr 8  **

-- | Trigonometric and hyperbolic functions and related functions.
--
-- Minimal complete definition:
--      'pi', 'exp', 'log', 'sin', 'cos', 'sinh', 'cosh',
--      'asin', 'acos', 'atan', 'asinh', 'acosh' and 'atanh'
class  (Fractional a) => Floating a  where
    pi                  :: a
    exp, log, sqrt      :: a -> a
    (**), logBase       :: a -> a -> a
    sin, cos, tan       :: a -> a
    asin, acos, atan    :: a -> a
    sinh, cosh, tanh    :: a -> a
    asinh, acosh, atanh :: a -> a

    {-# INLINE (**) #-}
    {-# INLINE logBase #-}
    {-# INLINE sqrt #-}
    {-# INLINE tan #-}
    {-# INLINE tanh #-}
    x ** y              =  exp (log x * y)
    logBase x y         =  log y / log x
    sqrt x              =  x ** 0.5
    tan  x              =  sin  x / cos  x
    tanh x              =  sinh x / cosh x

-- | Efficient, machine-independent access to the components of a
-- floating-point number.
--
-- Minimal complete definition:
--      all except 'exponent', 'significand', 'scaleFloat' and 'atan2'
class  (RealFrac a, Floating a) => RealFloat a  where
    -- | a constant function, returning the radix of the representation
    -- (often @2@)
    floatRadix          :: a -> Integer
    -- | a constant function, returning the number of digits of
    -- 'floatRadix' in the significand
    floatDigits         :: a -> Int
    -- | a constant function, returning the lowest and highest values
    -- the exponent may assume
    floatRange          :: a -> (Int,Int)
    -- | The function 'decodeFloat' applied to a real floating-point
    -- number returns the significand expressed as an 'Integer' and an
    -- appropriately scaled exponent (an 'Int').  If @'decodeFloat' x@
    -- yields @(m,n)@, then @x@ is equal in value to @m*b^^n@, where @b@
    -- is the floating-point radix, and furthermore, either @m@ and @n@
    -- are both zero or else @b^(d-1) <= 'abs' m < b^d@, where @d@ is
    -- the value of @'floatDigits' x@.
    -- In particular, @'decodeFloat' 0 = (0,0)@. If the type
    -- contains a negative zero, also @'decodeFloat' (-0.0) = (0,0)@.
    -- /The result of/ @'decodeFloat' x@ /is unspecified if either of/
    -- @'isNaN' x@ /or/ @'isInfinite' x@ /is/ 'True'.
    decodeFloat         :: a -> (Integer,Int)
    -- | 'encodeFloat' performs the inverse of 'decodeFloat' in the
    -- sense that for finite @x@ with the exception of @-0.0@,
    -- @'uncurry' 'encodeFloat' ('decodeFloat' x) = x@.
    -- @'encodeFloat' m n@ is one of the two closest representable
    -- floating-point numbers to @m*b^^n@ (or @&#177;Infinity@ if overflow
    -- occurs); usually the closer, but if @m@ contains too many bits,
    -- the result may be rounded in the wrong direction.
    encodeFloat         :: Integer -> Int -> a
    -- | 'exponent' corresponds to the second component of 'decodeFloat'.
    -- @'exponent' 0 = 0@ and for finite nonzero @x@,
    -- @'exponent' x = snd ('decodeFloat' x) + 'floatDigits' x@.
    -- If @x@ is a finite floating-point number, it is equal in value to
    -- @'significand' x * b ^^ 'exponent' x@, where @b@ is the
    -- floating-point radix.
    -- The behaviour is unspecified on infinite or @NaN@ values.
    exponent            :: a -> Int
    -- | The first component of 'decodeFloat', scaled to lie in the open
    -- interval (@-1@,@1@), either @0.0@ or of absolute value @>= 1\/b@,
    -- where @b@ is the floating-point radix.
    -- The behaviour is unspecified on infinite or @NaN@ values.
    significand         :: a -> a
    -- | multiplies a floating-point number by an integer power of the radix
    scaleFloat          :: Int -> a -> a
    -- | 'True' if the argument is an IEEE \"not-a-number\" (NaN) value
    isNaN               :: a -> Bool
    -- | 'True' if the argument is an IEEE infinity or negative infinity
    isInfinite          :: a -> Bool
    -- | 'True' if the argument is too small to be represented in
    -- normalized format
    isDenormalized      :: a -> Bool
    -- | 'True' if the argument is an IEEE negative zero
    isNegativeZero      :: a -> Bool
    -- | 'True' if the argument is an IEEE floating point number
    isIEEE              :: a -> Bool
    -- | a version of arctangent taking two real floating-point arguments.
    -- For real floating @x@ and @y@, @'atan2' y x@ computes the angle
    -- (from the positive x-axis) of the vector from the origin to the
    -- point @(x,y)@.  @'atan2' y x@ returns a value in the range [@-pi@,
    -- @pi@].  It follows the Common Lisp semantics for the origin when
    -- signed zeroes are supported.  @'atan2' y 1@, with @y@ in a type
    -- that is 'RealFloat', should return the same value as @'atan' y@.
    -- A default definition of 'atan2' is provided, but implementors
    -- can provide a more accurate implementation.
    atan2               :: a -> a -> a


    exponent x          =  if m == 0 then 0 else n + floatDigits x
                           where (m,n) = decodeFloat x

    significand x       =  encodeFloat m (negate (floatDigits x))
                           where (m,_) = decodeFloat x

    scaleFloat 0 x      =  x
    scaleFloat k x
      | isFix           =  x
      | otherwise       =  encodeFloat m (n + clamp b k)
                           where (m,n) = decodeFloat x
                                 (l,h) = floatRange x
                                 d     = floatDigits x
                                 b     = h - l + 4*d
                                 -- n+k may overflow, which would lead
                                 -- to wrong results, hence we clamp the
                                 -- scaling parameter.
                                 -- If n + k would be larger than h,
                                 -- n + clamp b k must be too, simliar
                                 -- for smaller than l - d.
                                 -- Add a little extra to keep clear
                                 -- from the boundary cases.
                                 isFix = x == 0 || isNaN x || isInfinite x

    atan2 y x
      | x > 0            =  atan (y/x)
      | x == 0 && y > 0  =  pi/2
      | x <  0 && y > 0  =  pi + atan (y/x)
      |(x <= 0 && y < 0)            ||
       (x <  0 && isNegativeZero y) ||
       (isNegativeZero x && isNegativeZero y)
                         = -atan2 (-y) x
      | y == 0 && (x < 0 || isNegativeZero x)
                          =  pi    -- must be after the previous test on zero y
      | x==0 && y==0      =  y     -- must be after the other double zero tests
      | otherwise         =  x + y -- x or y is a NaN, return a NaN (via +)

instance  Num Float  where
    (+)         x y     =  plusFloat x y
    (-)         x y     =  minusFloat x y
    negate      x       =  negateFloat x
    (*)         x y     =  timesFloat x y
    abs x | x >= 0.0    =  x
          | otherwise   =  negateFloat x
    signum x | x == 0.0  = 0
             | x > 0.0   = 1
             | otherwise = negate 1

    {-# INLINE fromInteger #-}
    fromInteger i = F# (floatFromInteger i)

instance  Real Float  where
    toRational (F# x#)  =
        case decodeFloat_Int# x# of
          (# m#, e# #)
            | isTrue# (e# >=# 0#)                               ->
                    (smallInteger m# `shiftLInteger` e#) :% 1
            | isTrue# ((int2Word# m# `and#` 1##) `eqWord#` 0##) ->
                    case elimZerosInt# m# (negateInt# e#) of
                      (# n, d# #) -> n :% shiftLInteger 1 d#
            | otherwise                                         ->
                    smallInteger m# :% shiftLInteger 1 (negateInt# e#)

instance  Fractional Float  where
    (/) x y             =  divideFloat x y
    {-# INLINE fromRational #-}
    fromRational (n:%d) = rationalToFloat n d
    recip x             =  1.0 / x

rationalToFloat :: Integer -> Integer -> Float
{-# NOINLINE [1] rationalToFloat #-}
rationalToFloat n 0
    | n == 0        = 0/0
    | n < 0         = (-1)/0
    | otherwise     = 1/0
rationalToFloat n d
    | n == 0        = encodeFloat 0 0
    | n < 0         = -(fromRat'' minEx mantDigs (-n) d)
    | otherwise     = fromRat'' minEx mantDigs n d
      where
        minEx       = FLT_MIN_EXP
        mantDigs    = FLT_MANT_DIG

-- RULES for Integer and Int
{-# RULES
"properFraction/Float->Integer"     properFraction = properFractionFloatInteger
"truncate/Float->Integer"           truncate = truncateFloatInteger
"floor/Float->Integer"              floor = floorFloatInteger
"ceiling/Float->Integer"            ceiling = ceilingFloatInteger
"round/Float->Integer"              round = roundFloatInteger
"properFraction/Float->Int"         properFraction = properFractionFloatInt
"truncate/Float->Int"               truncate = float2Int
"floor/Float->Int"                  floor = floorFloatInt
"ceiling/Float->Int"                ceiling = ceilingFloatInt
"round/Float->Int"                  round = roundFloatInt
  #-}
instance  RealFrac Float  where

        -- ceiling, floor, and truncate are all small
    {-# INLINE [1] ceiling #-}
    {-# INLINE [1] floor #-}
    {-# INLINE [1] truncate #-}

-- We assume that FLT_RADIX is 2 so that we can use more efficient code
#if FLT_RADIX != 2
#error FLT_RADIX must be 2
#endif
    properFraction (F# x#)
      = case decodeFloat_Int# x# of
        (# m#, n# #) ->
            let m = I# m#
                n = I# n#
            in
            if n >= 0
            then (fromIntegral m * (2 ^ n), 0.0)
            else let i = if m >= 0 then                m `shiftR` negate n
                                   else negate (negate m `shiftR` negate n)
                     f = m - (i `shiftL` negate n)
                 in (fromIntegral i, encodeFloat (fromIntegral f) n)

    truncate x  = case properFraction x of
                     (n,_) -> n

    round x     = case properFraction x of
                     (n,r) -> let
                                m         = if r < 0.0 then n - 1 else n + 1
                                half_down = abs r - 0.5
                              in
                              case (compare half_down 0.0) of
                                LT -> n
                                EQ -> if even n then n else m
                                GT -> m

    ceiling x   = case properFraction x of
                    (n,r) -> if r > 0.0 then n + 1 else n

    floor x     = case properFraction x of
                    (n,r) -> if r < 0.0 then n - 1 else n

instance  Floating Float  where
    pi                  =  3.141592653589793238
    exp x               =  expFloat x
    log x               =  logFloat x
    sqrt x              =  sqrtFloat x
    sin x               =  sinFloat x
    cos x               =  cosFloat x
    tan x               =  tanFloat x
    asin x              =  asinFloat x
    acos x              =  acosFloat x
    atan x              =  atanFloat x
    sinh x              =  sinhFloat x
    cosh x              =  coshFloat x
    tanh x              =  tanhFloat x
    (**) x y            =  powerFloat x y
    logBase x y         =  log y / log x

    asinh x = log (x + sqrt (1.0+x*x))
    acosh x = log (x + (x+1.0) * sqrt ((x-1.0)/(x+1.0)))
    atanh x = 0.5 * log ((1.0+x) / (1.0-x))

instance  RealFloat Float  where
    floatRadix _        =  FLT_RADIX        -- from float.h
    floatDigits _       =  FLT_MANT_DIG     -- ditto
    floatRange _        =  (FLT_MIN_EXP, FLT_MAX_EXP) -- ditto

    decodeFloat (F# f#) = case decodeFloat_Int# f# of
                          (# i, e #) -> (smallInteger i, I# e)

    encodeFloat i (I# e) = F# (encodeFloatInteger i e)

    exponent x          = case decodeFloat x of
                            (m,n) -> if m == 0 then 0 else n + floatDigits x

    significand x       = case decodeFloat x of
                            (m,_) -> encodeFloat m (negate (floatDigits x))

    scaleFloat 0 x      = x
    scaleFloat k x
      | isFix           = x
      | otherwise       = case decodeFloat x of
                            (m,n) -> encodeFloat m (n + clamp bf k)
                        where bf = FLT_MAX_EXP - (FLT_MIN_EXP) + 4*FLT_MANT_DIG
                              isFix = x == 0 || isFloatFinite x == 0

    isNaN x          = 0 /= isFloatNaN x
    isInfinite x     = 0 /= isFloatInfinite x
    isDenormalized x = 0 /= isFloatDenormalized x
    isNegativeZero x = 0 /= isFloatNegativeZero x
    isIEEE _         = True

instance  Show Float  where
    showsPrec   x = showSignedFloat showFloat x
    showList = showList__ (showsPrec 0)

instance  Num Double  where
    (+)         x y     =  plusDouble x y
    (-)         x y     =  minusDouble x y
    negate      x       =  negateDouble x
    (*)         x y     =  timesDouble x y
    abs x | x >= 0.0    =  x
          | otherwise   =  negateDouble x
    signum x | x == 0.0  = 0
             | x > 0.0   = 1
             | otherwise = negate 1

    {-# INLINE fromInteger #-}
    fromInteger i = D# (doubleFromInteger i)


instance  Real Double  where
    toRational (D# x#)  =
        case decodeDoubleInteger x# of
          (# m, e# #)
            | isTrue# (e# >=# 0#)                                  ->
                shiftLInteger m e# :% 1
            | isTrue# ((integerToWord m `and#` 1##) `eqWord#` 0##) ->
                case elimZerosInteger m (negateInt# e#) of
                    (# n, d# #) ->  n :% shiftLInteger 1 d#
            | otherwise                                            ->
                m :% shiftLInteger 1 (negateInt# e#)

instance  Fractional Double  where
    (/) x y             =  divideDouble x y
    {-# INLINE fromRational #-}
    fromRational (n:%d) = rationalToDouble n d
    recip x             =  1.0 / x

rationalToDouble :: Integer -> Integer -> Double
{-# NOINLINE [1] rationalToDouble #-}
rationalToDouble n 0
    | n == 0        = 0/0
    | n < 0         = (-1)/0
    | otherwise     = 1/0
rationalToDouble n d
    | n == 0        = encodeFloat 0 0
    | n < 0         = -(fromRat'' minEx mantDigs (-n) d)
    | otherwise     = fromRat'' minEx mantDigs n d
      where
        minEx       = DBL_MIN_EXP
        mantDigs    = DBL_MANT_DIG

instance  Floating Double  where
    pi                  =  3.141592653589793238
    exp x               =  expDouble x
    log x               =  logDouble x
    sqrt x              =  sqrtDouble x
    sin  x              =  sinDouble x
    cos  x              =  cosDouble x
    tan  x              =  tanDouble x
    asin x              =  asinDouble x
    acos x              =  acosDouble x
    atan x              =  atanDouble x
    sinh x              =  sinhDouble x
    cosh x              =  coshDouble x
    tanh x              =  tanhDouble x
    (**) x y            =  powerDouble x y
    logBase x y         =  log y / log x

    asinh x = log (x + sqrt (1.0+x*x))
    acosh x = log (x + (x+1.0) * sqrt ((x-1.0)/(x+1.0)))
    atanh x = 0.5 * log ((1.0+x) / (1.0-x))

-- RULES for Integer and Int
{-# RULES
"properFraction/Double->Integer"    properFraction = properFractionDoubleInteger
"truncate/Double->Integer"          truncate = truncateDoubleInteger
"floor/Double->Integer"             floor = floorDoubleInteger
"ceiling/Double->Integer"           ceiling = ceilingDoubleInteger
"round/Double->Integer"             round = roundDoubleInteger
"properFraction/Double->Int"        properFraction = properFractionDoubleInt
"truncate/Double->Int"              truncate = double2Int
"floor/Double->Int"                 floor = floorDoubleInt
"ceiling/Double->Int"               ceiling = ceilingDoubleInt
"round/Double->Int"                 round = roundDoubleInt
  #-}
instance  RealFrac Double  where

        -- ceiling, floor, and truncate are all small
    {-# INLINE [1] ceiling #-}
    {-# INLINE [1] floor #-}
    {-# INLINE [1] truncate #-}

    properFraction x
      = case (decodeFloat x)      of { (m,n) ->
        if n >= 0 then
            (fromInteger m * 2 ^ n, 0.0)
        else
            case (quotRem m (2^(negate n))) of { (w,r) ->
            (fromInteger w, encodeFloat r n)
            }
        }

    truncate x  = case properFraction x of
                     (n,_) -> n

    round x     = case properFraction x of
                     (n,r) -> let
                                m         = if r < 0.0 then n - 1 else n + 1
                                half_down = abs r - 0.5
                              in
                              case (compare half_down 0.0) of
                                LT -> n
                                EQ -> if even n then n else m
                                GT -> m

    ceiling x   = case properFraction x of
                    (n,r) -> if r > 0.0 then n + 1 else n

    floor x     = case properFraction x of
                    (n,r) -> if r < 0.0 then n - 1 else n

instance  RealFloat Double  where
    floatRadix _        =  FLT_RADIX        -- from float.h
    floatDigits _       =  DBL_MANT_DIG     -- ditto
    floatRange _        =  (DBL_MIN_EXP, DBL_MAX_EXP) -- ditto

    decodeFloat (D# x#)
      = case decodeDoubleInteger x#   of
          (# i, j #) -> (i, I# j)

    encodeFloat i (I# j) = D# (encodeDoubleInteger i j)

    exponent x          = case decodeFloat x of
                            (m,n) -> if m == 0 then 0 else n + floatDigits x

    significand x       = case decodeFloat x of
                            (m,_) -> encodeFloat m (negate (floatDigits x))

    scaleFloat 0 x      = x
    scaleFloat k x
      | isFix           = x
      | otherwise       = case decodeFloat x of
                            (m,n) -> encodeFloat m (n + clamp bd k)
                        where bd = DBL_MAX_EXP - (DBL_MIN_EXP) + 4*DBL_MANT_DIG
                              isFix = x == 0 || isDoubleFinite x == 0

    isNaN x             = 0 /= isDoubleNaN x
    isInfinite x        = 0 /= isDoubleInfinite x
    isDenormalized x    = 0 /= isDoubleDenormalized x
    isNegativeZero x    = 0 /= isDoubleNegativeZero x
    isIEEE _            = True

instance  Show Double  where
    showsPrec   x = showSignedFloat showFloat x
    showList = showList__ (showsPrec 0)

instance  Enum Float  where
    succ x         = x + 1
    pred x         = x - 1
    toEnum         = int2Float
    fromEnum       = fromInteger . truncate   -- may overflow
    enumFrom       = numericEnumFrom
    enumFromTo     = numericEnumFromTo
    enumFromThen   = numericEnumFromThen
    enumFromThenTo = numericEnumFromThenTo

instance  Enum Double  where
    succ x         = x + 1
    pred x         = x - 1
    toEnum         =  int2Double
    fromEnum       =  fromInteger . truncate   -- may overflow
    enumFrom       =  numericEnumFrom
    enumFromTo     =  numericEnumFromTo
    enumFromThen   =  numericEnumFromThen
    enumFromThenTo =  numericEnumFromThenTo

-- | Show a signed 'RealFloat' value to full precision
-- using standard decimal notation for arguments whose absolute value lies
-- between @0.1@ and @9,999,999@, and scientific notation otherwise.
showFloat :: (RealFloat a) => a -> ShowS
showFloat x  =  showString (formatRealFloat FFGeneric Nothing x)

-- These are the format types.  This type is not exported.

data FFFormat = FFExponent | FFFixed | FFGeneric

-- This is just a compatibility stub, as the "alt" argument formerly
-- didn't exist.
formatRealFloat :: (RealFloat a) => FFFormat -> Maybe Int -> a -> String
formatRealFloat fmt decs x = formatRealFloatAlt fmt decs False x

formatRealFloatAlt :: (RealFloat a) => FFFormat -> Maybe Int -> Bool -> a
                 -> String
formatRealFloatAlt fmt decs alt x
   | isNaN x                   = "NaN"
   | isInfinite x              = if x < 0 then "-Infinity" else "Infinity"
   | x < 0 || isNegativeZero x = '-':doFmt fmt (floatToDigits (toInteger base) (-x))
   | otherwise                 = doFmt fmt (floatToDigits (toInteger base) x)
 where
  base = 10

  doFmt format (is, e) =
    let ds = map intToDigit is in
    case format of
     FFGeneric ->
      doFmt (if e < 0 || e > 7 then FFExponent else FFFixed)
            (is,e)
     FFExponent ->
      case decs of
       Nothing ->
        let show_e' = show (e-1) in
        case ds of
          "0"     -> "0.0e0"
          [d]     -> d : ".0e" ++ show_e'
          (d:ds') -> d : '.' : ds' ++ "e" ++ show_e'
          []      -> error "formatRealFloat/doFmt/FFExponent: []"
       Just dec ->
        let dec' = max dec 1 in
        case is of
         [0] -> '0' :'.' : take dec' (repeat '0') ++ "e0"
         _ ->
          let
           (ei,is') = roundTo base (dec'+1) is
           (d:ds') = map intToDigit (if ei > 0 then init is' else is')
          in
          d:'.':ds' ++ 'e':show (e-1+ei)
     FFFixed ->
      let
       mk0 ls = case ls of { "" -> "0" ; _ -> ls}
      in
      case decs of
       Nothing
          | e <= 0    -> "0." ++ replicate (-e) '0' ++ ds
          | otherwise ->
             let
                f 0 s    rs  = mk0 (reverse s) ++ '.':mk0 rs
                f n s    ""  = f (n-1) ('0':s) ""
                f n s (r:rs) = f (n-1) (r:s) rs
             in
                f e "" ds
       Just dec ->
        let dec' = max dec 0 in
        if e >= 0 then
         let
          (ei,is') = roundTo base (dec' + e) is
          (ls,rs)  = splitAt (e+ei) (map intToDigit is')
         in
         mk0 ls ++ (if null rs && not alt then "" else '.':rs)
        else
         let
          (ei,is') = roundTo base dec' (replicate (-e) 0 ++ is)
          d:ds' = map intToDigit (if ei > 0 then is' else 0:is')
         in
         d : (if null ds' && not alt then "" else '.':ds')


roundTo :: Int -> Int -> [Int] -> (Int,[Int])
roundTo base d is =
  case f d True is of
    x@(0,_) -> x
    (1,xs)  -> (1, 1:xs)
    _       -> error "roundTo: bad Value"
 where
  b2 = base `quot` 2

  f n _ []     = (0, replicate n 0)
  f 0 e (x:xs) | x == b2 && e && all (== 0) xs = (0, [])   -- Round to even when at exactly half the base
               | otherwise = (if x >= b2 then 1 else 0, [])
  f n _ (i:xs)
     | i' == base = (1,0:ds)
     | otherwise  = (0,i':ds)
      where
       (c,ds) = f (n-1) (even i) xs
       i'     = c + i

-- Based on "Printing Floating-Point Numbers Quickly and Accurately"
-- by R.G. Burger and R.K. Dybvig in PLDI 96.
-- This version uses a much slower logarithm estimator. It should be improved.

-- | 'floatToDigits' takes a base and a non-negative 'RealFloat' number,
-- and returns a list of digits and an exponent.
-- In particular, if @x>=0@, and
--
-- > floatToDigits base x = ([d1,d2,...,dn], e)
--
-- then
--
--      (1) @n >= 1@
--
--      (2) @x = 0.d1d2...dn * (base**e)@
--
--      (3) @0 <= di <= base-1@

floatToDigits :: (RealFloat a) => Integer -> a -> ([Int], Int)
floatToDigits _ 0 = ([0], 0)
floatToDigits base x =
 let
  (f0, e0) = decodeFloat x
  (minExp0, _) = floatRange x
  p = floatDigits x
  b = floatRadix x
  minExp = minExp0 - p -- the real minimum exponent
  -- Haskell requires that f be adjusted so denormalized numbers
  -- will have an impossibly low exponent.  Adjust for this.
  (f, e) =
   let n = minExp - e0 in
   if n > 0 then (f0 `quot` (expt b n), e0+n) else (f0, e0)
  (r, s, mUp, mDn) =
   if e >= 0 then
    let be = expt b e in
    if f == expt b (p-1) then
      (f*be*b*2, 2*b, be*b, be)     -- according to Burger and Dybvig
    else
      (f*be*2, 2, be, be)
   else
    if e > minExp && f == expt b (p-1) then
      (f*b*2, expt b (-e+1)*2, b, 1)
    else
      (f*2, expt b (-e)*2, 1, 1)
  k :: Int
  k =
   let
    k0 :: Int
    k0 =
     if b == 2 && base == 10 then
        -- logBase 10 2 is very slightly larger than 8651/28738
        -- (about 5.3558e-10), so if log x >= 0, the approximation
        -- k1 is too small, hence we add one and need one fixup step less.
        -- If log x < 0, the approximation errs rather on the high side.
        -- That is usually more than compensated for by ignoring the
        -- fractional part of logBase 2 x, but when x is a power of 1/2
        -- or slightly larger and the exponent is a multiple of the
        -- denominator of the rational approximation to logBase 10 2,
        -- k1 is larger than logBase 10 x. If k1 > 1 + logBase 10 x,
        -- we get a leading zero-digit we don't want.
        -- With the approximation 3/10, this happened for
        -- 0.5^1030, 0.5^1040, ..., 0.5^1070 and values close above.
        -- The approximation 8651/28738 guarantees k1 < 1 + logBase 10 x
        -- for IEEE-ish floating point types with exponent fields
        -- <= 17 bits and mantissae of several thousand bits, earlier
        -- convergents to logBase 10 2 would fail for long double.
        -- Using quot instead of div is a little faster and requires
        -- fewer fixup steps for negative lx.
        let lx = p - 1 + e0
            k1 = (lx * 8651) `quot` 28738
        in if lx >= 0 then k1 + 1 else k1
     else
	-- f :: Integer, log :: Float -> Float,
        --               ceiling :: Float -> Int
        ceiling ((log (fromInteger (f+1) :: Float) +
                 fromIntegral e * log (fromInteger b)) /
                   log (fromInteger base))
--WAS:            fromInt e * log (fromInteger b))

    fixup n =
      if n >= 0 then
        if r + mUp <= expt base n * s then n else fixup (n+1)
      else
        if expt base (-n) * (r + mUp) <= s then n else fixup (n+1)
   in
   fixup k0

  gen ds rn sN mUpN mDnN =
   let
    (dn, rn') = (rn * base) `quotRem` sN
    mUpN' = mUpN * base
    mDnN' = mDnN * base
   in
   case (rn' < mDnN', rn' + mUpN' > sN) of
    (True,  False) -> dn : ds
    (False, True)  -> dn+1 : ds
    (True,  True)  -> if rn' * 2 < sN then dn : ds else dn+1 : ds
    (False, False) -> gen (dn:ds) rn' sN mUpN' mDnN'

  rds =
   if k >= 0 then
      gen [] r (s * expt base k) mUp mDn
   else
     let bk = expt base (-k) in
     gen [] (r * bk) s (mUp * bk) (mDn * bk)
 in
 (map fromIntegral (reverse rds), k)

-- | Converts a 'Rational' value into any type in class 'RealFloat'.
{-# RULES
"fromRat/Float"     fromRat = (fromRational :: Rational -> Float)
"fromRat/Double"    fromRat = (fromRational :: Rational -> Double)
  #-}

{-# NOINLINE [1] fromRat #-}
fromRat :: (RealFloat a) => Rational -> a

-- Deal with special cases first, delegating the real work to fromRat'
fromRat (n :% 0) | n > 0     =  1/0        -- +Infinity
                 | n < 0     = -1/0        -- -Infinity
                 | otherwise =  0/0        -- NaN

fromRat (n :% d) | n > 0     = fromRat' (n :% d)
                 | n < 0     = - fromRat' ((-n) :% d)
                 | otherwise = encodeFloat 0 0             -- Zero

-- Conversion process:
-- Scale the rational number by the RealFloat base until
-- it lies in the range of the mantissa (as used by decodeFloat/encodeFloat).
-- Then round the rational to an Integer and encode it with the exponent
-- that we got from the scaling.
-- To speed up the scaling process we compute the log2 of the number to get
-- a first guess of the exponent.

fromRat' :: (RealFloat a) => Rational -> a
-- Invariant: argument is strictly positive
fromRat' x = r
  where b = floatRadix r
        p = floatDigits r
        (minExp0, _) = floatRange r
        minExp = minExp0 - p            -- the real minimum exponent
        xMax   = toRational (expt b p)
        p0 = (integerLogBase b (numerator x) - integerLogBase b (denominator x) - p) `max` minExp
        -- if x = n/d and ln = integerLogBase b n, ld = integerLogBase b d,
        -- then b^(ln-ld-1) < x < b^(ln-ld+1)
        f = if p0 < 0 then 1 :% expt b (-p0) else expt b p0 :% 1
        x0 = x / f
        -- if ln - ld >= minExp0, then b^(p-1) < x0 < b^(p+1), so there's at most
        -- one scaling step needed, otherwise, x0 < b^p and no scaling is needed
        (x', p') = if x0 >= xMax then (x0 / toRational b, p0+1) else (x0, p0)
        r = encodeFloat (round x') p'

-- Exponentiation with a cache for the most common numbers.
minExpt, maxExpt :: Int
minExpt = 0
maxExpt = 1100

expt :: Integer -> Int -> Integer
expt base n =
    if base == 2 && n >= minExpt && n <= maxExpt then
        expts!n
    else
        if base == 10 && n <= maxExpt10 then
            expts10!n
        else
            base^n

expts :: Array Int Integer
expts = array (minExpt,maxExpt) [(n,2^n) | n <- [minExpt .. maxExpt]]

maxExpt10 :: Int
maxExpt10 = 324

expts10 :: Array Int Integer
expts10 = array (minExpt,maxExpt10) [(n,10^n) | n <- [minExpt .. maxExpt10]]

-- Compute the (floor of the) log of i in base b.
-- Simplest way would be just divide i by b until it's smaller then b, but that would
-- be very slow!  We are just slightly more clever, except for base 2, where
-- we take advantage of the representation of Integers.
-- The general case could be improved by a lookup table for
-- approximating the result by integerLog2 i / integerLog2 b.
integerLogBase :: Integer -> Integer -> Int
integerLogBase b i
   | i < b     = 0
   | b == 2    = I# (integerLog2# i)
   | otherwise = I# (integerLogBase# b i)

{-# SPECIALISE fromRat'' :: Int -> Int -> Integer -> Integer -> Float,
                            Int -> Int -> Integer -> Integer -> Double #-}
fromRat'' :: RealFloat a => Int -> Int -> Integer -> Integer -> a
-- Invariant: n and d strictly positive
fromRat'' minEx@(I# me#) mantDigs@(I# md#) n d =
    case integerLog2IsPowerOf2# d of
      (# ld#, pw# #)
        | isTrue# (pw# ==# 0#) ->
          case integerLog2# n of
            ln# | isTrue# (ln# >=# (ld# +# me# -# 1#)) ->
                  -- this means n/d >= 2^(minEx-1), i.e. we are guaranteed to get
                  -- a normalised number, round to mantDigs bits
                  if isTrue# (ln# <# md#)
                    then encodeFloat n (I# (negateInt# ld#))
                    else let n'  = n `shiftR` (I# (ln# +# 1# -# md#))
                             n'' = case roundingMode# n (ln# -# md#) of
                                    0# -> n'
                                    2# -> n' + 1
                                    _  -> case fromInteger n' .&. (1 :: Int) of
                                            0 -> n'
                                            _ -> n' + 1
                         in encodeFloat n'' (I# (ln# -# ld# +# 1# -# md#))
                | otherwise ->
                  -- n/d < 2^(minEx-1), a denorm or rounded to 2^(minEx-1)
                  -- the exponent for encoding is always minEx-mantDigs
                  -- so we must shift right by (minEx-mantDigs) - (-ld)
                  case ld# +# (me# -# md#) of
                    ld'# | isTrue# (ld'# <=# 0#) -> -- we would shift left, so we don't shift
                           encodeFloat n (I# ((me# -# md#) -# ld'#))
                         | isTrue# (ld'# <=# ln#) ->
                           let n' = n `shiftR` (I# ld'#)
                           in case roundingMode# n (ld'# -# 1#) of
                                0# -> encodeFloat n' (minEx - mantDigs)
                                1# -> if fromInteger n' .&. (1 :: Int) == 0
                                        then encodeFloat n' (minEx-mantDigs)
                                        else encodeFloat (n' + 1) (minEx-mantDigs)
                                _  -> encodeFloat (n' + 1) (minEx-mantDigs)
                         | isTrue# (ld'# ># (ln# +# 1#)) -> encodeFloat 0 0 -- result of shift < 0.5
                         | otherwise ->  -- first bit of n shifted to 0.5 place
                           case integerLog2IsPowerOf2# n of
                            (# _, 0# #) -> encodeFloat 0 0  -- round to even
                            (# _, _ #)  -> encodeFloat 1 (minEx - mantDigs)
        | otherwise ->
          let ln = I# (integerLog2# n)
              ld = I# ld#
              -- 2^(ln-ld-1) < n/d < 2^(ln-ld+1)
              p0 = max minEx (ln - ld)
              (n', d')
                | p0 < mantDigs = (n `shiftL` (mantDigs - p0), d)
                | p0 == mantDigs = (n, d)
                | otherwise     = (n, d `shiftL` (p0 - mantDigs))
              -- if ln-ld < minEx, then n'/d' < 2^mantDigs, else
              -- 2^(mantDigs-1) < n'/d' < 2^(mantDigs+1) and we
              -- may need one scaling step
              scale p a b
                | (b `shiftL` mantDigs) <= a = (p+1, a, b `shiftL` 1)
                | otherwise = (p, a, b)
              (p', n'', d'') = scale (p0-mantDigs) n' d'
              -- n''/d'' < 2^mantDigs and p' == minEx-mantDigs or n''/d'' >= 2^(mantDigs-1)
              rdq = case n'' `quotRem` d'' of
                     (q,r) -> case compare (r `shiftL` 1) d'' of
                                LT -> q
                                EQ -> if fromInteger q .&. (1 :: Int) == 0
                                        then q else q+1
                                GT -> q+1
          in  encodeFloat rdq p'

plusFloat, minusFloat, timesFloat, divideFloat :: Float -> Float -> Float
plusFloat   (F# x) (F# y) = F# (plusFloat# x y)
minusFloat  (F# x) (F# y) = F# (minusFloat# x y)
timesFloat  (F# x) (F# y) = F# (timesFloat# x y)
divideFloat (F# x) (F# y) = F# (divideFloat# x y)

negateFloat :: Float -> Float
negateFloat (F# x)        = F# (negateFloat# x)

gtFloat, geFloat, eqFloat, neFloat, ltFloat, leFloat :: Float -> Float -> Bool
gtFloat     (F# x) (F# y) = isTrue# (gtFloat# x y)
geFloat     (F# x) (F# y) = isTrue# (geFloat# x y)
eqFloat     (F# x) (F# y) = isTrue# (eqFloat# x y)
neFloat     (F# x) (F# y) = isTrue# (neFloat# x y)
ltFloat     (F# x) (F# y) = isTrue# (ltFloat# x y)
leFloat     (F# x) (F# y) = isTrue# (leFloat# x y)

expFloat, logFloat, sqrtFloat :: Float -> Float
sinFloat, cosFloat, tanFloat  :: Float -> Float
asinFloat, acosFloat, atanFloat  :: Float -> Float
sinhFloat, coshFloat, tanhFloat  :: Float -> Float
expFloat    (F# x) = F# (expFloat# x)
logFloat    (F# x) = F# (logFloat# x)
sqrtFloat   (F# x) = F# (sqrtFloat# x)
sinFloat    (F# x) = F# (sinFloat# x)
cosFloat    (F# x) = F# (cosFloat# x)
tanFloat    (F# x) = F# (tanFloat# x)
asinFloat   (F# x) = F# (asinFloat# x)
acosFloat   (F# x) = F# (acosFloat# x)
atanFloat   (F# x) = F# (atanFloat# x)
sinhFloat   (F# x) = F# (sinhFloat# x)
coshFloat   (F# x) = F# (coshFloat# x)
tanhFloat   (F# x) = F# (tanhFloat# x)

powerFloat :: Float -> Float -> Float
powerFloat  (F# x) (F# y) = F# (powerFloat# x y)

-- definitions of the boxed PrimOps; these will be
-- used in the case of partial applications, etc.

plusDouble, minusDouble, timesDouble, divideDouble :: Double -> Double -> Double
plusDouble   (D# x) (D# y) = D# (x +## y)
minusDouble  (D# x) (D# y) = D# (x -## y)
timesDouble  (D# x) (D# y) = D# (x *## y)
divideDouble (D# x) (D# y) = D# (x /## y)

negateDouble :: Double -> Double
negateDouble (D# x)        = D# (negateDouble# x)

gtDouble, geDouble, eqDouble, neDouble, leDouble, ltDouble :: Double -> Double -> Bool
gtDouble    (D# x) (D# y) = isTrue# (x >##  y)
geDouble    (D# x) (D# y) = isTrue# (x >=## y)
eqDouble    (D# x) (D# y) = isTrue# (x ==## y)
neDouble    (D# x) (D# y) = isTrue# (x /=## y)
ltDouble    (D# x) (D# y) = isTrue# (x <##  y)
leDouble    (D# x) (D# y) = isTrue# (x <=## y)

double2Float :: Double -> Float
double2Float (D# x) = F# (double2Float# x)

float2Double :: Float -> Double
float2Double (F# x) = D# (float2Double# x)

expDouble, logDouble, sqrtDouble :: Double -> Double
sinDouble, cosDouble, tanDouble  :: Double -> Double
asinDouble, acosDouble, atanDouble  :: Double -> Double
sinhDouble, coshDouble, tanhDouble  :: Double -> Double
expDouble    (D# x) = D# (expDouble# x)
logDouble    (D# x) = D# (logDouble# x)
sqrtDouble   (D# x) = D# (sqrtDouble# x)
sinDouble    (D# x) = D# (sinDouble# x)
cosDouble    (D# x) = D# (cosDouble# x)
tanDouble    (D# x) = D# (tanDouble# x)
asinDouble   (D# x) = D# (asinDouble# x)
acosDouble   (D# x) = D# (acosDouble# x)
atanDouble   (D# x) = D# (atanDouble# x)
sinhDouble   (D# x) = D# (sinhDouble# x)
coshDouble   (D# x) = D# (coshDouble# x)
tanhDouble   (D# x) = D# (tanhDouble# x)

powerDouble :: Double -> Double -> Double
powerDouble  (D# x) (D# y) = D# (x **## y)

foreign import ccall unsafe "isFloatNaN" isFloatNaN :: Float -> Int
foreign import ccall unsafe "isFloatInfinite" isFloatInfinite :: Float -> Int
foreign import ccall unsafe "isFloatDenormalized" isFloatDenormalized :: Float -> Int
foreign import ccall unsafe "isFloatNegativeZero" isFloatNegativeZero :: Float -> Int
foreign import ccall unsafe "isFloatFinite" isFloatFinite :: Float -> Int

foreign import ccall unsafe "isDoubleNaN" isDoubleNaN :: Double -> Int
foreign import ccall unsafe "isDoubleInfinite" isDoubleInfinite :: Double -> Int
foreign import ccall unsafe "isDoubleDenormalized" isDoubleDenormalized :: Double -> Int
foreign import ccall unsafe "isDoubleNegativeZero" isDoubleNegativeZero :: Double -> Int
foreign import ccall unsafe "isDoubleFinite" isDoubleFinite :: Double -> Int

word2Double :: Word -> Double
word2Double (W# w) = D# (word2Double# w)

word2Float :: Word -> Float
word2Float (W# w) = F# (word2Float# w)

{-# RULES
"fromIntegral/Int->Float"   fromIntegral = int2Float
"fromIntegral/Int->Double"  fromIntegral = int2Double
"fromIntegral/Word->Float"  fromIntegral = word2Float
"fromIntegral/Word->Double" fromIntegral = word2Double
"realToFrac/Float->Float"   realToFrac   = id :: Float -> Float
"realToFrac/Float->Double"  realToFrac   = float2Double
"realToFrac/Double->Float"  realToFrac   = double2Float
"realToFrac/Double->Double" realToFrac   = id :: Double -> Double
"realToFrac/Int->Double"    realToFrac   = int2Double	-- See Note [realToFrac int-to-float]
"realToFrac/Int->Float"     realToFrac   = int2Float	-- 	..ditto
    #-}

showSignedFloat :: (RealFloat a)
  => (a -> ShowS)       -- ^ a function that can show unsigned values
  -> Int                -- ^ the precedence of the enclosing context
  -> a                  -- ^ the value to show
  -> ShowS
showSignedFloat showPos p x
   | x < 0 || isNegativeZero x
       = showParen (p > 6) (showChar '-' . showPos (-x))
   | otherwise = showPos x

clamp :: Int -> Int -> Int
clamp bd k = max (-bd) (min bd k)