1 {-# GHC_PRAGMA INTERFACE VERSION 5 #-}
3 data Number {-# GHC_PRAGMA I Integer | F Double #-}
4 isInteger :: Number -> Bool
5 {-# GHC_PRAGMA _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_ #-}
7 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 6 _!_ _TUP_5 [{{Ord Number}}, (Number -> [Number]), (Number -> Number -> [Number]), (Number -> Number -> [Number]), (Number -> Number -> Number -> [Number])] [_DFUN_ Ord (Number), _CONSTM_ Enum enumFrom (Number), _CONSTM_ Enum enumFromThen (Number), _CONSTM_ Enum enumFromTo (Number), _CONSTM_ Enum enumFromThenTo (Number)] _N_
8 enumFrom = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
9 enumFromThen = _A_ 2 _U_ 22 _N_ _S_ "SL" _N_ _N_,
10 enumFromTo = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
11 enumFromThenTo = _A_ 3 _U_ 222 _N_ _N_ _N_ _N_ #-}
13 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 3 _!_ _TUP_2 [(Number -> Number -> Bool), (Number -> Number -> Bool)] [_CONSTM_ Eq (==) (Number), _CONSTM_ Eq (/=) (Number)] _N_
14 (==) = _A_ 2 _U_ 22 _N_ _S_ "SS" _N_ _N_,
15 (/=) = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_ #-}
16 instance Floating Number
17 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 20 _!_ _TUP_19 [{{Fractional Number}}, Number, (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number)] [_DFUN_ Fractional (Number), _CONSTM_ Floating pi (Number), _CONSTM_ Floating exp (Number), _CONSTM_ Floating log (Number), _CONSTM_ Floating sqrt (Number), _CONSTM_ Floating (**) (Number), _CONSTM_ Floating logBase (Number), _CONSTM_ Floating sin (Number), _CONSTM_ Floating cos (Number), _CONSTM_ Floating tan (Number), _CONSTM_ Floating asin (Number), _CONSTM_ Floating acos (Number), _CONSTM_ Floating atan (Number), _CONSTM_ Floating sinh (Number), _CONSTM_ Floating cosh (Number), _CONSTM_ Floating tanh (Number), _CONSTM_ Floating asinh (Number), _CONSTM_ Floating acosh (Number), _CONSTM_ Floating atanh (Number)] _N_
18 pi = _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 2 _!_ _ORIG_ Number F [] [_CONSTM_ Floating pi (Double)] _N_,
19 exp = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
20 log = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
21 sqrt = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
22 (**) = _A_ 2 _U_ 11 _N_ _S_ "SS" _N_ _N_,
23 logBase = _A_ 2 _U_ 11 _N_ _S_ "SS" _N_ _N_,
24 sin = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
25 cos = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
26 tan = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
27 asin = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
28 acos = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
29 atan = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
30 sinh = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
31 cosh = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
32 tanh = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
33 asinh = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
34 acosh = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
35 atanh = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_ #-}
36 instance Fractional Number
37 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 5 _!_ _TUP_4 [{{Num Number}}, (Number -> Number -> Number), (Number -> Number), (Ratio Integer -> Number)] [_DFUN_ Num (Number), _CONSTM_ Fractional (/) (Number), _CONSTM_ Fractional recip (Number), _CONSTM_ Fractional fromRational (Number)] _N_
38 (/) = _A_ 2 _U_ 22 _N_ _S_ "SS" _N_ _N_,
39 recip = _A_ 0 _U_ 2 _N_ _N_ _N_ _N_,
40 fromRational = _A_ 1 _U_ 1 _N_ _S_ "U(LU(PPP))" {_A_ 4 _U_ 2222 _N_ _N_ _N_ _N_} _N_ _N_ #-}
41 instance Integral Number
42 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 13 _!_ _TUP_12 [{{Real Number}}, {{Ix Number}}, (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number -> (Number, Number)), (Number -> Number -> (Number, Number)), (Number -> Bool), (Number -> Bool), (Number -> Integer), (Number -> Int)] [_DFUN_ Real (Number), _DFUN_ Ix (Number), _CONSTM_ Integral quot (Number), _CONSTM_ Integral rem (Number), _CONSTM_ Integral div (Number), _CONSTM_ Integral mod (Number), _CONSTM_ Integral quotRem (Number), _CONSTM_ Integral divMod (Number), _CONSTM_ Integral even (Number), _CONSTM_ Integral odd (Number), _CONSTM_ Integral toInteger (Number), _CONSTM_ Integral toInt (Number)] _N_
43 quot = _A_ 2 _U_ 22 _N_ _S_ "SL" _F_ _IF_ARGS_ 0 2 XX 5 \ (u0 :: Number) (u1 :: Number) -> case _APP_ _CONSTM_ Integral quotRem (Number) [ u0, u1 ] of { _ALG_ _TUP_2 (u2 :: Number) (u3 :: Number) -> u2; _NO_DEFLT_ } _N_,
44 rem = _A_ 2 _U_ 22 _N_ _S_ "SL" _F_ _IF_ARGS_ 0 2 XX 5 \ (u0 :: Number) (u1 :: Number) -> case _APP_ _CONSTM_ Integral quotRem (Number) [ u0, u1 ] of { _ALG_ _TUP_2 (u2 :: Number) (u3 :: Number) -> u3; _NO_DEFLT_ } _N_,
45 div = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
46 mod = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
47 quotRem = _A_ 2 _U_ 22 _N_ _S_ "SL" _N_ _N_,
48 divMod = _A_ 0 _U_ 22 _N_ _N_ _N_ _N_,
49 even = _A_ 0 _U_ 2 _N_ _N_ _N_ _N_,
50 odd = _A_ 0 _U_ 2 _N_ _N_ _N_ _N_,
51 toInteger = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
52 toInt = _A_ 1 _U_ 2 _N_ _S_ _!_ _F_ _IF_ARGS_ 0 1 X 3 \ (u0 :: Number) -> _APP_ _TYAPP_ patError# { (Number -> Int) } [ _NOREP_S_ "%DPreludeCore.Integral.toInt\"", u0 ] _N_ #-}
54 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 5 _!_ _TUP_4 [{{Ord Number}}, ((Number, Number) -> [Number]), ((Number, Number) -> Number -> Int), ((Number, Number) -> Number -> Bool)] [_DFUN_ Ord (Number), _CONSTM_ Ix range (Number), _CONSTM_ Ix index (Number), _CONSTM_ Ix inRange (Number)] _N_
55 range = _A_ 1 _U_ 1 _N_ _S_ "U(LL)" {_A_ 2 _U_ 11 _N_ _N_ _N_ _N_} _N_ _N_,
56 index = _A_ 2 _U_ 11 _N_ _S_ "U(SA)S" {_A_ 2 _U_ 11 _N_ _N_ _N_ _N_} _N_ _N_,
57 inRange = _A_ 2 _U_ 12 _N_ _S_ "U(SL)S" {_A_ 3 _U_ 112 _N_ _N_ _N_ _N_} _N_ _N_ #-}
59 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 11 _!_ _TUP_10 [{{Eq Number}}, {{Text Number}}, (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number), (Number -> Number), (Number -> Number), (Integer -> Number), (Int -> Number)] [_DFUN_ Eq (Number), _DFUN_ Text (Number), _CONSTM_ Num (+) (Number), _CONSTM_ Num (-) (Number), _CONSTM_ Num (*) (Number), _CONSTM_ Num negate (Number), _CONSTM_ Num abs (Number), _CONSTM_ Num signum (Number), _CONSTM_ Num fromInteger (Number), _CONSTM_ Num fromInt (Number)] _N_
60 (+) = _A_ 2 _U_ 22 _N_ _S_ "SS" _N_ _N_,
61 (-) = _A_ 2 _U_ 22 _N_ _S_ "SS" _N_ _N_,
62 (*) = _A_ 2 _U_ 22 _N_ _S_ "SS" _N_ _N_,
63 negate = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
64 abs = _A_ 1 _U_ 2 _N_ _S_ "S" _N_ _N_,
65 signum = _A_ 1 _U_ 2 _N_ _S_ "S" _N_ _N_,
66 fromInteger = _A_ 1 _U_ 2 _N_ _N_ _F_ _IF_ARGS_ 0 1 X 2 \ (u0 :: Integer) -> _!_ _ORIG_ Number I [] [u0] _N_,
67 fromInt = _A_ 1 _U_ 1 _N_ _N_ _F_ _IF_ARGS_ 0 1 C 5 \ (u0 :: Int) -> let {(u2 :: Integer) = case u0 of { _ALG_ I# (u1 :: Int#) -> _#_ int2Integer# [] [u1]; _NO_DEFLT_ }} in _!_ _ORIG_ Number I [] [u2] _N_ #-}
69 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 9 _!_ _TUP_8 [{{Eq Number}}, (Number -> Number -> Bool), (Number -> Number -> Bool), (Number -> Number -> Bool), (Number -> Number -> Bool), (Number -> Number -> Number), (Number -> Number -> Number), (Number -> Number -> _CMP_TAG)] [_DFUN_ Eq (Number), _CONSTM_ Ord (<) (Number), _CONSTM_ Ord (<=) (Number), _CONSTM_ Ord (>=) (Number), _CONSTM_ Ord (>) (Number), _CONSTM_ Ord max (Number), _CONSTM_ Ord min (Number), _CONSTM_ Ord _tagCmp (Number)] _N_
70 (<) = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
71 (<=) = _A_ 2 _U_ 22 _N_ _S_ "SS" _N_ _N_,
72 (>=) = _A_ 2 _U_ 22 _N_ _S_ "SS" _F_ _IF_ARGS_ 0 2 XX 3 \ (u0 :: Number) (u1 :: Number) -> _APP_ _CONSTM_ Ord (<=) (Number) [ u1, u0 ] _N_,
73 (>) = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
74 max = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
75 min = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_,
76 _tagCmp = _A_ 2 _U_ 22 _N_ _N_ _N_ _N_ #-}
78 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 4 _!_ _TUP_3 [{{Num Number}}, {{Enum Number}}, (Number -> Ratio Integer)] [_DFUN_ Num (Number), _DFUN_ Enum (Number), _CONSTM_ Real toRational (Number)] _N_
79 toRational = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_ #-}
80 instance RealFloat Number
81 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 11 _!_ _TUP_10 [{{RealFrac Number}}, {{Floating Number}}, (Number -> Integer), (Number -> Int), (Number -> (Int, Int)), (Number -> (Integer, Int)), (Integer -> Int -> Number), (Number -> Int), (Number -> Number), (Int -> Number -> Number)] [_DFUN_ RealFrac (Number), _DFUN_ Floating (Number), _CONSTM_ RealFloat floatRadix (Number), _CONSTM_ RealFloat floatDigits (Number), _CONSTM_ RealFloat floatRange (Number), _CONSTM_ RealFloat decodeFloat (Number), _CONSTM_ RealFloat encodeFloat (Number), _CONSTM_ RealFloat exponent (Number), _CONSTM_ RealFloat significand (Number), _CONSTM_ RealFloat scaleFloat (Number)] _N_
82 floatRadix = _A_ 1 _U_ 0 _N_ _S_ "A" {_A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 1 _#_ int2Integer# [] [2#] _N_} _F_ _IF_ARGS_ 0 1 X 1 \ (u0 :: Number) -> _#_ int2Integer# [] [2#] _N_,
83 floatDigits = _A_ 1 _U_ 0 _N_ _S_ "A" {_A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 2 _!_ I# [] [53#] _N_} _F_ _IF_ARGS_ 0 1 X 2 \ (u0 :: Number) -> _!_ I# [] [53#] _N_,
84 floatRange = _A_ 1 _U_ 0 _N_ _S_ "A" {_A_ 0 _N_ _N_ _N_ _N_ _N_} _N_ _N_,
85 decodeFloat = _A_ 1 _U_ 1 _N_ _S_ "S" _N_ _N_,
86 encodeFloat = _A_ 2 _U_ 11 _N_ _S_ "U(PPP)U(P)" {_A_ 4 _U_ 2222 _N_ _N_ _N_ _N_} _N_ _N_,
87 exponent = _A_ 1 _U_ 1 _N_ _N_ _N_ _N_,
88 significand = _A_ 1 _U_ 1 _N_ _N_ _N_ _N_,
89 scaleFloat = _A_ 2 _U_ 21 _N_ _N_ _N_ _N_ #-}
90 instance RealFrac Number
91 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 8 _!_ _TUP_7 [{{Real Number}}, {{Fractional Number}}, _forall_ a$z1 =>{{Integral a$z1}} -> (Number -> (a$z1, Number)), _forall_ a$z1 =>{{Integral a$z1}} -> (Number -> a$z1), _forall_ a$z1 =>{{Integral a$z1}} -> (Number -> a$z1), _forall_ a$z1 =>{{Integral a$z1}} -> (Number -> a$z1), _forall_ a$z1 =>{{Integral a$z1}} -> (Number -> a$z1)] [_DFUN_ Real (Number), _DFUN_ Fractional (Number), _CONSTM_ RealFrac properFraction (Number), _CONSTM_ RealFrac truncate (Number), _CONSTM_ RealFrac round (Number), _CONSTM_ RealFrac ceiling (Number), _CONSTM_ RealFrac floor (Number)] _N_
92 properFraction = _A_ 1 _U_ 21 _N_ _N_ _N_ _N_,
93 truncate = _A_ 1 _U_ 21 _N_ _N_ _N_ _N_,
94 round = _A_ 1 _U_ 21 _N_ _N_ _N_ _N_,
95 ceiling = _A_ 1 _U_ 21 _N_ _N_ _N_ _N_,
96 floor = _A_ 1 _U_ 21 _N_ _N_ _N_ _N_ #-}
98 {-# GHC_PRAGMA _M_ Number {-dfun-} _A_ 0 _N_ _N_ _N_ _F_ _IF_ARGS_ 0 0 X 5 _!_ _TUP_4 [(Int -> [Char] -> [(Number, [Char])]), (Int -> Number -> [Char] -> [Char]), ([Char] -> [([Number], [Char])]), ([Number] -> [Char] -> [Char])] [_CONSTM_ Text readsPrec (Number), _CONSTM_ Text showsPrec (Number), _CONSTM_ Text readList (Number), _CONSTM_ Text showList (Number)] _N_
99 readsPrec = _A_ 2 _U_ 02 _N_ _S_ "AL" {_A_ 1 _U_ 2 _N_ _N_ _N_ _N_} _N_ _N_,
100 showsPrec = _A_ 2 _U_ 212 _N_ _S_ "LS" _N_ _N_,
101 readList = _A_ 0 _U_ 2 _N_ _N_ _N_ _N_,
102 showList = _A_ 0 _U_ 12 _N_ _N_ _N_ _N_ #-}