{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE ScopedTypeVariables #-}
module Numeric.Rounded.Hardware.Interval.ElementaryFunctions where
import Control.Exception (assert)
import Numeric.Rounded.Hardware.Internal
import Numeric.Rounded.Hardware.Interval.Class
sqrtI :: (IsInterval i, RoundedSqrt (EndPoint i)) => i -> i
sqrtI :: forall i. (IsInterval i, RoundedSqrt (EndPoint i)) => i -> i
sqrtI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
-> i
forall a b. (a -> b) -> a -> b
$ \Rounded 'TowardNegInf (EndPoint i)
x Rounded 'TowardInf (EndPoint i)
y -> case Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
-> (Rounded 'TowardNegInf (EndPoint i),
Rounded 'TowardInf (EndPoint i))
forall a.
RoundedSqrt a =>
Rounded 'TowardNegInf a
-> Rounded 'TowardInf a
-> (Rounded 'TowardNegInf a, Rounded 'TowardInf a)
intervalSqrt Rounded 'TowardNegInf (EndPoint i)
x Rounded 'TowardInf (EndPoint i)
y of (Rounded 'TowardNegInf (EndPoint i)
u, Rounded 'TowardInf (EndPoint i)
v) -> Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
u Rounded 'TowardInf (EndPoint i)
v
{-# INLINE sqrtI #-}
expP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => EndPoint i -> i
expP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP EndPoint i
x | EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
x = if EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
> EndPoint i
0
then Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
maxFinite) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
positiveInfinity)
else Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
0) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
minPositive)
expP EndPoint i
x = let a :: Integer
a = EndPoint i -> Integer
forall b. Integral b => EndPoint i -> b
forall a b. (RealFrac a, Integral b) => a -> b
round EndPoint i
x
b :: EndPoint i
b = EndPoint i
x EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
- Integer -> EndPoint i
forall a. Num a => Integer -> a
fromInteger Integer
a
b' :: i
b' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
b
series :: Int -> i -> i
series :: Int -> i -> i
series Int
n i
acc | Int
n Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = i
acc
| Bool
otherwise = Int -> i -> i
series (Int
nInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ i
acc i -> i -> i
forall a. Num a => a -> a -> a
* i
b' i -> i -> i
forall a. Fractional a => a -> a -> a
/ Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
n
in Bool -> i -> i
forall a. (?callStack::CallStack) => Bool -> a -> a
assert (Integer -> EndPoint i
forall a. Num a => Integer -> a
fromInteger Integer
a EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
+ EndPoint i
b EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== EndPoint i
x Bool -> Bool -> Bool
&& EndPoint i -> EndPoint i
forall a. Num a => a -> a
abs EndPoint i
b EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
0.5) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
exp1_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
exp1_up)i -> Integer -> i
forall a b. (Fractional a, Integral b) => a -> b -> a
^^Integer
a i -> i -> i
forall a. Num a => a -> a -> a
* Int -> i -> i
series Int
15 (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
expm1_2_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
exp1_2_up)
{-# INLINABLE expP #-}
expI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => i -> i
expI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
i -> i
expI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP EndPoint i
y))
{-# INLINABLE expI #-}
expm1P :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => EndPoint i -> i
expm1P :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expm1P EndPoint i
x | -EndPoint i
0.5 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x Bool -> Bool -> Bool
&& EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
0.5 = let b' :: i
b' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
series :: Int -> i -> i
series :: Int -> i -> i
series Int
n i
acc | Int
n Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
1 = i
acc i -> i -> i
forall a. Num a => a -> a -> a
* i
b'
| Bool
otherwise = Int -> i -> i
series (Int
nInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ i
acc i -> i -> i
forall a. Num a => a -> a -> a
* i
b' i -> i -> i
forall a. Fractional a => a -> a -> a
/ Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
n
in Int -> i -> i
series Int
15 (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
expm1_2_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
exp1_2_up)
| Bool
otherwise = EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP EndPoint i
x i -> i -> i
forall a. Num a => a -> a -> a
- i
1
{-# INLINABLE expm1P #-}
expm1I :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => i -> i
expm1I :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
i -> i
expm1I = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expm1P EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expm1P EndPoint i
y))
{-# INLINABLE expm1I #-}
logP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) => EndPoint i -> i
logP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
logP EndPoint i
x
| EndPoint i -> Integer
forall a. RealFloat a => a -> Integer
floatRadix (EndPoint i
forall a. (?callStack::CallStack) => a
undefined :: EndPoint i) Integer -> Integer -> Bool
forall a. Eq a => a -> a -> Bool
/= Integer
2 = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"Unsupported float radix"
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
0 = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"Negative logarithm"
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== EndPoint i
0 = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
negativeInfinity) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded (-EndPoint i
forall a. RealFloatConstants a => a
maxFinite))
| EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
x = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
maxFinite) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
positiveInfinity)
| EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isNaN EndPoint i
x = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"NaN"
| Bool
otherwise = let m :: Integer
n :: Int
(Integer
m,Int
n) = EndPoint i -> (Integer, Int)
forall a. RealFloat a => a -> (Integer, Int)
decodeFloat EndPoint i
x
a0, b, bm1 :: i
a0 :: i
a0 = Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Int
n Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
d)
x' :: EndPoint i
x' :: EndPoint i
x' = Integer -> Int -> EndPoint i
forall a. RealFloat a => Integer -> Int -> a
encodeFloat Integer
m (- Int
d)
(i
a,i
b) | EndPoint i
0.5 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x' Bool -> Bool -> Bool
&& EndPoint i
x' EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
two_minus_sqrt2_down = (i
a0 i -> i -> i
forall a. Num a => a -> a -> a
- i
1, EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x' i -> i -> i
forall a. Num a => a -> a -> a
* i
2)
| Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
two_minus_sqrt2_up EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x' Bool -> Bool -> Bool
&& EndPoint i
x' EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
2 EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
* Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
sqrt2m1_down = (i
a0 i -> i -> i
forall a. Num a => a -> a -> a
- i
0.5, EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x' i -> i -> i
forall a. Num a => a -> a -> a
* i
sqrt2_iv)
| EndPoint i
2 EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
* Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
sqrt2m1_up EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x' Bool -> Bool -> Bool
&& EndPoint i
x' EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
1 = (i
a0, EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x')
| Bool
otherwise = [Char] -> (i, i)
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"interval log: internal error"
bm1 :: i
bm1 = i
b i -> i -> i
forall a. Num a => a -> a -> a
- i
1
series :: Int -> i -> i
series :: Int -> i -> i
series Int
k i
acc | Int
k Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = i
bm1 i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
| Bool
otherwise = Int -> i -> i
series (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i -> i
forall a. Fractional a => a -> a
recip (Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
k) i -> i -> i
forall a. Num a => a -> a -> a
- i
bm1 i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
in i
a i -> i -> i
forall a. Num a => a -> a -> a
* i
log2_iv i -> i -> i
forall a. Num a => a -> a -> a
+ Int -> i -> i
series Int
21 (i -> i -> i
forall i. IsInterval i => i -> i -> i
hull i
1 i
b i -> Int -> i
forall a b. (Fractional a, Integral b) => a -> b -> a
^^ (-Int
22 :: Int) i -> i -> i
forall a. Num a => a -> a -> a
* i
bm1 i -> i -> i
forall a. Fractional a => a -> a -> a
/ Integer -> i
forall a. Num a => Integer -> a
fromInteger Integer
22)
where
d :: Int
d = EndPoint i -> Int
forall a. RealFloat a => a -> Int
floatDigits (EndPoint i
forall a. (?callStack::CallStack) => a
undefined :: EndPoint i)
log2_iv :: i
log2_iv :: i
log2_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
log2_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
log2_up
sqrt2_iv :: i
sqrt2_iv :: i
sqrt2_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
sqrt2_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
sqrt2_up
{-# INLINABLE logP #-}
logI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
logI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
logI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
logP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
logP EndPoint i
y))
{-# INLINABLE logI #-}
log1pP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) => EndPoint i -> i
log1pP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
log1pP EndPoint i
x | - Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_minus_2sqrt2_down EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x Bool -> Bool -> Bool
&& EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_minus_2sqrt2_down =
let x' :: i
x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
series :: Int -> i -> i
series :: Int -> i -> i
series Int
k i
acc | Int
k Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = i
x' i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
| Bool
otherwise = Int -> i -> i
series (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i -> i
forall a. Fractional a => a -> a
recip (Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
k) i -> i -> i
forall a. Num a => a -> a -> a
- i
x' i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
in Int -> i -> i
series Int
21 (i -> i -> i
forall i. IsInterval i => i -> i -> i
hull i
1 (i
x' i -> i -> i
forall a. Num a => a -> a -> a
+ i
1) i -> Int -> i
forall a b. (Fractional a, Integral b) => a -> b -> a
^^ (-Int
22 :: Int) i -> i -> i
forall a. Num a => a -> a -> a
* i
x' i -> i -> i
forall a. Fractional a => a -> a -> a
/ Integer -> i
forall a. Num a => Integer -> a
fromInteger Integer
22)
| Bool
otherwise = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
logI (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x i -> i -> i
forall a. Num a => a -> a -> a
+ i
1)
{-# INLINABLE log1pP #-}
log1pI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
log1pI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
log1pI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
log1pP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
log1pP EndPoint i
y))
{-# INLINABLE log1pI #-}
sin_small :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
sin_small :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small i
x = let xx :: i
xx = i
x i -> i -> i
forall a. Num a => a -> a -> a
* i
x
series :: Int -> i -> i
series :: Int -> i -> i
series Int
k i
acc | Int
k Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = i
x i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
| Bool
otherwise = Int -> i -> i
series (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
2) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
xx i -> i -> i
forall a. Num a => a -> a -> a
* i
acc i -> i -> i
forall a. Fractional a => a -> a -> a
/ Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Int
k Int -> Int -> Int
forall a. Num a => a -> a -> a
* (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
+Int
1))
in Int -> i -> i
series Int
18 (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (-Rounded 'TowardNegInf (EndPoint i)
1) Rounded 'TowardInf (EndPoint i)
1)
{-# INLINABLE sin_small #-}
cos_small :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
cos_small :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small i
x = let xx :: i
xx = i
x i -> i -> i
forall a. Num a => a -> a -> a
* i
x
series :: Int -> i -> i
series :: Int -> i -> i
series Int
k i
acc | Int
k Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
1 = i
acc
| Bool
otherwise = Int -> i -> i
series (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
2) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
xx i -> i -> i
forall a. Num a => a -> a -> a
* i
acc i -> i -> i
forall a. Fractional a => a -> a -> a
/ Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral ((Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1) Int -> Int -> Int
forall a. Num a => a -> a -> a
* (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
2))
in Int -> i -> i
series Int
17 (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (-Rounded 'TowardNegInf (EndPoint i)
1) Rounded 'TowardInf (EndPoint i)
1)
{-# INLINABLE cos_small #-}
sinP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
sinP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sinP i
x | i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` - i
three_pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (i
x i -> i -> i
forall a. Num a => a -> a -> a
+ i
pi_iv)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (- i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i
x)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (i
x i -> i -> i
forall a. Num a => a -> a -> a
+ i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
0 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (- i
x)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small i
x
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i
x)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
three_pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (i
x i -> i -> i
forall a. Num a => a -> a -> a
- i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2)
| Bool
otherwise = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (i
pi_iv i -> i -> i
forall a. Num a => a -> a -> a
- i
x)
where
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
three_pi_iv :: i
three_pi_iv :: i
three_pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
three_pi_up
{-# INLINABLE sinP #-}
cosP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
cosP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cosP i
x | i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` - i
three_pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (i
x i -> i -> i
forall a. Num a => a -> a -> a
+ i
pi_iv)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (- i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i
x)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (i
x i -> i -> i
forall a. Num a => a -> a -> a
+ i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
0 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (- i
x)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small i
x
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i
x)
| i
x i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
three_pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sin_small (i
x i -> i -> i
forall a. Num a => a -> a -> a
- i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2)
| Bool
otherwise = - i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cos_small (i
pi_iv i -> i -> i
forall a. Num a => a -> a -> a
- i
x)
where
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
three_pi_iv :: i
three_pi_iv :: i
three_pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
three_pi_up
{-# INLINABLE cosP #-}
sinI :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
sinI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sinI i
t = ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints i
t ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) ->
if EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
x Bool -> Bool -> Bool
|| EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
y
then i
wholeRange
else ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv)) ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x0) (Rounded EndPoint i
_) ->
let n :: Integer
n = EndPoint i -> Integer
forall b. Integral b => EndPoint i -> b
forall a b. (RealFrac a, Integral b) => a -> b
round EndPoint i
x0
t' :: i
t' = i
t i -> i -> i
forall a. Num a => a -> a -> a
- i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv i -> i -> i
forall a. Num a => a -> a -> a
* Integer -> i
forall a. Num a => Integer -> a
fromInteger Integer
n
in ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints i
t' ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x') (Rounded EndPoint i
y') ->
if EndPoint i
y' EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
- EndPoint i
x' EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
>= Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded (Rounded 'TowardInf (EndPoint i)
2 Rounded 'TowardInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
forall a. Num a => a -> a -> a
* Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up)
then i
wholeRange
else
let include_minus_1 :: Bool
include_minus_1 = i
minus_half_pi_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t' Bool -> Bool -> Bool
|| i
three_pi_2_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t'
include_plus_1 :: Bool
include_plus_1 = i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t' Bool -> Bool -> Bool
|| i
five_pi_2_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t'
u :: i
u = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sinP (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x') (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sinP (if EndPoint i
y EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down then EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
y' else EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
y' i -> i -> i
forall a. Num a => a -> a -> a
- i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv)
v :: i
v | Bool
include_minus_1 = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (-i
1) i
u
| Bool
otherwise = i
u
w :: i
w | Bool
include_plus_1 = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull i
1 i
v
| Bool
otherwise = i
v
in i -> i -> i
forall i. IsInterval i => i -> i -> i
intersection i
wholeRange i
w
where
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
minus_half_pi_iv :: i
minus_half_pi_iv :: i
minus_half_pi_iv = - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
three_pi_2_iv :: i
three_pi_2_iv :: i
three_pi_2_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
three_pi_up i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
five_pi_2_iv :: i
five_pi_2_iv :: i
five_pi_2_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
five_pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
five_pi_up i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
wholeRange :: i
wholeRange :: i
wholeRange = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (-Rounded 'TowardNegInf (EndPoint i)
1) Rounded 'TowardInf (EndPoint i)
1
{-# INLINABLE sinI #-}
cosI :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
cosI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cosI i
t = ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints i
t ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) ->
if EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
x Bool -> Bool -> Bool
|| EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
y
then i
wholeRange
else ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv)) ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x0) (Rounded EndPoint i
_) ->
let n :: Integer
n = EndPoint i -> Integer
forall b. Integral b => EndPoint i -> b
forall a b. (RealFrac a, Integral b) => a -> b
round EndPoint i
x0
t' :: i
t' = i
t i -> i -> i
forall a. Num a => a -> a -> a
- i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv i -> i -> i
forall a. Num a => a -> a -> a
* Integer -> i
forall a. Num a => Integer -> a
fromInteger Integer
n
in ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints i
t' ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x') (Rounded EndPoint i
y') ->
if EndPoint i
y' EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
- EndPoint i
x' EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
>= Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded (Rounded 'TowardInf (EndPoint i)
2 Rounded 'TowardInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
forall a. Num a => a -> a -> a
* Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up)
then i
wholeRange
else
let include_minus_1 :: Bool
include_minus_1 = -i
pi_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t' Bool -> Bool -> Bool
|| i
pi_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t' Bool -> Bool -> Bool
|| i
three_pi_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t'
include_plus_1 :: Bool
include_plus_1 = i
0 i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t' Bool -> Bool -> Bool
|| i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`subset` i
t'
u :: i
u = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cosP (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x') (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cosP (if EndPoint i
y EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down then EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
y' else EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
y' i -> i -> i
forall a. Num a => a -> a -> a
- i
2 i -> i -> i
forall a. Num a => a -> a -> a
* i
pi_iv)
v :: i
v | Bool
include_minus_1 = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (-i
1) i
u
| Bool
otherwise = i
u
w :: i
w | Bool
include_plus_1 = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull i
1 i
v
| Bool
otherwise = i
v
in i -> i -> i
forall i. IsInterval i => i -> i -> i
intersection i
wholeRange i
w
where
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
three_pi_iv :: i
three_pi_iv :: i
three_pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
three_pi_up
wholeRange :: i
wholeRange :: i
wholeRange = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (-Rounded 'TowardNegInf (EndPoint i)
1) Rounded 'TowardInf (EndPoint i)
1
{-# INLINABLE cosI #-}
tanI :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
tanI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
tanI i
t = ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints i
t ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) ->
if EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
x Bool -> Bool -> Bool
|| EndPoint i -> Bool
forall a. RealFloat a => a -> Bool
isInfinite EndPoint i
y
then i
wholeRange
else ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (i
t i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
pi_iv) ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x0) (Rounded EndPoint i
_) ->
let n :: Integer
n = EndPoint i -> Integer
forall b. Integral b => EndPoint i -> b
forall a b. (RealFrac a, Integral b) => a -> b
round EndPoint i
x0
t' :: i
t' = i
t i -> i -> i
forall a. Num a => a -> a -> a
- i
pi_iv i -> i -> i
forall a. Num a => a -> a -> a
* Integer -> i
forall a. Num a => Integer -> a
fromInteger Integer
n
in ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> i
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b c. (a -> b -> c) -> b -> a -> c
flip (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints i
t' ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x') (Rounded EndPoint i
y') ->
if EndPoint i
y' EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
>= Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up EndPoint i -> EndPoint i -> EndPoint i
forall a. Fractional a => a -> a -> a
/ EndPoint i
2
then i
wholeRange
else let lb :: i
lb = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sinP (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x') i -> i -> i
forall a. Fractional a => a -> a -> a
/ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cosP (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x')
ub :: i
ub = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
sinP (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
y') i -> i -> i
forall a. Fractional a => a -> a -> a
/ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
cosP (EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
y')
in i -> i -> i
forall i. IsInterval i => i -> i -> i
hull i
lb i
ub
where
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
wholeRange :: i
wholeRange :: i
wholeRange = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
negativeInfinity) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
positiveInfinity)
{-# INLINABLE tanI #-}
atan_small :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
atan_small :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small i
x = let n :: Int
n = Int
39
in Int -> i -> i
series Int
n (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (-Rounded 'TowardNegInf (EndPoint i)
1) Rounded 'TowardInf (EndPoint i)
1 i -> i -> i
forall a. Fractional a => a -> a -> a
/ Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
n)
where
xx :: i
xx = i
x i -> i -> i
forall a. Num a => a -> a -> a
* i
x
series :: Int -> i -> i
series :: Int -> i -> i
series Int
k i
acc | Int
k Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
1 = i
x i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
| Bool
otherwise = Int -> i -> i
series (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
2) (i -> i) -> i -> i
forall a b. (a -> b) -> a -> b
$ i -> i
forall a. Fractional a => a -> a
recip (Int -> i
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Int
kInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
2)) i -> i -> i
forall a. Num a => a -> a -> a
- i
xx i -> i -> i
forall a. Num a => a -> a -> a
* i
acc
{-# INLINABLE atan_small #-}
atanP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => EndPoint i -> i
atanP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
atanP EndPoint i
x | Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded (Rounded 'TowardInf (EndPoint i)
1 Rounded 'TowardInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i)
forall a. Num a => a -> a -> a
+ Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
sqrt2_up) EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x = i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small (i -> i
forall a. Fractional a => a -> a
recip i
x')
| Rounded 'TowardInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
sqrt2m1_up EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x = i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 i -> i -> i
forall a. Num a => a -> a -> a
+ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small ((i
x' i -> i -> i
forall a. Num a => a -> a -> a
- i
1) i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
x' i -> i -> i
forall a. Num a => a -> a -> a
+ i
1))
| - Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
sqrt2m1_down EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small i
x'
| - Rounded 'TowardNegInf (EndPoint i) -> EndPoint i
forall (r :: RoundingMode) a. Rounded r a -> a
getRounded (Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
sqrt2_down Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardNegInf (EndPoint i)
forall a. Num a => a -> a -> a
+ Rounded 'TowardNegInf (EndPoint i)
1) EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x = - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 i -> i -> i
forall a. Num a => a -> a -> a
+ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small ((i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ i
x') i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
x'))
| Bool
otherwise = - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small (i -> i
forall a. Fractional a => a -> a
recip i
x')
where
x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
{-# INLINABLE atanP #-}
atanI :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
atanI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atanI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
atanP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
atanP EndPoint i
y))
{-# INLINABLE atanI #-}
asinP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) => EndPoint i -> i
asinP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
asinP EndPoint i
x | EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< -EndPoint i
1 Bool -> Bool -> Bool
|| EndPoint i
1 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
x = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"asin"
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== -EndPoint i
1 = - i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== EndPoint i
1 = i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
| Bool
otherwise = i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atanI (i
x' i -> i -> i
forall a. Fractional a => a -> a -> a
/ i -> i
forall i. (IsInterval i, RoundedSqrt (EndPoint i)) => i -> i
sqrtI (i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
x'i -> i -> i
forall a. Num a => a -> a -> a
*i
x'))
where
x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
{-# INLINABLE asinP #-}
asinI :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
asinI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
asinI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
asinP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
asinP EndPoint i
y))
{-# INLINABLE asinI #-}
acosP :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) => EndPoint i -> i
acosP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
acosP EndPoint i
x | EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< -EndPoint i
1 Bool -> Bool -> Bool
|| EndPoint i
1 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
x = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"asin"
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== -EndPoint i
1 = i
pi_iv
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== EndPoint i
1 = i
0
| Bool
otherwise = case i
x' i -> i -> i
forall a. Fractional a => a -> a -> a
/ i -> i
forall i. (IsInterval i, RoundedSqrt (EndPoint i)) => i -> i
sqrtI (i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
x'i -> i -> i
forall a. Num a => a -> a -> a
*i
x') of
i
y' | i
one_plus_sqrt2 i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
y' -> i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small (i -> i
forall a. Fractional a => a -> a
recip i
y')
| i
sqrt2_minus_one i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
y' -> i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 i -> i -> i
forall a. Num a => a -> a -> a
- i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small ((i
y' i -> i -> i
forall a. Num a => a -> a -> a
- i
1) i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
y' i -> i -> i
forall a. Num a => a -> a -> a
+ i
1))
| - i
sqrt2_minus_one i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
y' -> i
pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2 i -> i -> i
forall a. Num a => a -> a -> a
- i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small i
y'
| - i
one_plus_sqrt2 i -> i -> Bool
forall i. IsInterval i => i -> i -> Bool
`weaklyLess` i
y' -> i
three_pi_iv i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
4 i -> i -> i
forall a. Num a => a -> a -> a
- i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small ((i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ i
y') i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
y'))
| Bool
otherwise -> i
pi_iv i -> i -> i
forall a. Num a => a -> a -> a
+ i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RealFloatConstants (EndPoint i)) =>
i -> i
atan_small (i -> i
forall a. Fractional a => a -> a
recip i
y')
where
x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
pi_iv :: i
pi_iv :: i
pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
pi_up
three_pi_iv :: i
three_pi_iv :: i
three_pi_iv = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
three_pi_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
three_pi_up
one_plus_sqrt2 :: i
one_plus_sqrt2 :: i
one_plus_sqrt2 = i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
sqrt2_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
sqrt2_up
sqrt2_minus_one :: i
sqrt2_minus_one :: i
sqrt2_minus_one = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval Rounded 'TowardNegInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardNegInf a
sqrt2m1_down Rounded 'TowardInf (EndPoint i)
forall a. RealFloatConstants a => Rounded 'TowardInf a
sqrt2m1_up
{-# INLINABLE acosP #-}
acosI :: forall i. (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RoundedRing (EndPoint i), RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
acosI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
acosI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
acosP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RoundedRing (EndPoint i),
RoundedSqrt (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
acosP EndPoint i
y))
{-# INLINABLE acosI #-}
sinhP :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => EndPoint i -> i
sinhP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
sinhP EndPoint i
x | EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
>= EndPoint i
0 = let y :: i
y = EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP EndPoint i
x
in (i
y i -> i -> i
forall a. Num a => a -> a -> a
- i -> i
forall a. Fractional a => a -> a
recip i
y) i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
| Bool
otherwise = let y :: i
y = EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP (- EndPoint i
x)
in (i -> i
forall a. Fractional a => a -> a
recip i
y i -> i -> i
forall a. Num a => a -> a -> a
- i
y) i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
{-# INLINABLE sinhP #-}
sinhI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => i -> i
sinhI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
i -> i
sinhI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints (\(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
sinhP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
sinhP EndPoint i
y))
{-# INLINABLE sinhI #-}
coshP :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => EndPoint i -> i
coshP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
coshP EndPoint i
x | EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
>= EndPoint i
0 = let y :: i
y = EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP EndPoint i
x
in (i
y i -> i -> i
forall a. Num a => a -> a -> a
+ i -> i
forall a. Fractional a => a -> a
recip i
y) i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
| Bool
otherwise = let y :: i
y = EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP (- EndPoint i
x)
in (i -> i
forall a. Fractional a => a -> a
recip i
y i -> i -> i
forall a. Num a => a -> a -> a
+ i
y) i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
{-# INLINABLE coshP #-}
coshI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => i -> i
coshI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
i -> i
coshI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) ->
let z :: i
z = i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
coshP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
coshP EndPoint i
y)
in if EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
0 Bool -> Bool -> Bool
&& EndPoint i
0 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
y
then i -> i -> i
forall i. IsInterval i => i -> i -> i
hull i
0 i
z
else i
z
{-# INLINABLE coshI #-}
tanhP :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => EndPoint i -> i
tanhP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
tanhP EndPoint i
x | -EndPoint i
0.5 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
x Bool -> Bool -> Bool
&& EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
<= EndPoint i
0.5 = EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
sinhP EndPoint i
x i -> i -> i
forall a. Fractional a => a -> a -> a
/ EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
coshP EndPoint i
x
| EndPoint i
0 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
x = i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
2 i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP (EndPoint i
2 EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
* EndPoint i
x))
| Bool
otherwise = i
2 i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
expP (- EndPoint i
2 EndPoint i -> EndPoint i -> EndPoint i
forall a. Num a => a -> a -> a
* EndPoint i
x)) i -> i -> i
forall a. Num a => a -> a -> a
- i
1
{-# INLINABLE tanhP #-}
tanhI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedFractional (EndPoint i)) => i -> i
tanhI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
i -> i
tanhI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
tanhP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedFractional (EndPoint i)) =>
EndPoint i -> i
tanhP EndPoint i
y)
{-# INLINABLE tanhI #-}
asinhP :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedSqrt (EndPoint i)) => EndPoint i -> i
asinhP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
EndPoint i -> i
asinhP EndPoint i
x = let x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
in i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
logI (i
x' i -> i -> i
forall a. Num a => a -> a -> a
+ i -> i
forall i. (IsInterval i, RoundedSqrt (EndPoint i)) => i -> i
sqrtI (i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ i
x' i -> Int -> i
forall a b. (Num a, Integral b) => a -> b -> a
^ (Int
2 :: Int)))
{-# INLINABLE asinhP #-}
asinhI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedSqrt (EndPoint i)) => i -> i
asinhI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
i -> i
asinhI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
EndPoint i -> i
asinhP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
EndPoint i -> i
asinhP EndPoint i
y)
{-# INLINABLE asinhI #-}
acoshP :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedSqrt (EndPoint i)) => EndPoint i -> i
acoshP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
EndPoint i -> i
acoshP EndPoint i
x | EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
1 = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"acosh: domain"
| Bool
otherwise = let x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
in i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
logI (i
x' i -> i -> i
forall a. Num a => a -> a -> a
+ i -> i
forall i. (IsInterval i, RoundedSqrt (EndPoint i)) => i -> i
sqrtI (i
x' i -> Int -> i
forall a b. (Num a, Integral b) => a -> b -> a
^ (Int
2 :: Int) i -> i -> i
forall a. Num a => a -> a -> a
- i
1))
{-# INLINABLE acoshP #-}
acoshI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i), RoundedSqrt (EndPoint i)) => i -> i
acoshI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
i -> i
acoshI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
EndPoint i -> i
acoshP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i),
RoundedSqrt (EndPoint i)) =>
EndPoint i -> i
acoshP EndPoint i
y)
{-# INLINABLE acoshI #-}
atanhP :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) => EndPoint i -> i
atanhP :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
atanhP EndPoint i
x | EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< -EndPoint i
1 Bool -> Bool -> Bool
|| EndPoint i
1 EndPoint i -> EndPoint i -> Bool
forall a. Ord a => a -> a -> Bool
< EndPoint i
x = [Char] -> i
forall a. (?callStack::CallStack) => [Char] -> a
error [Char]
"atanh: domain"
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== -EndPoint i
1 = - Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
maxFinite) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
positiveInfinity)
| EndPoint i
x EndPoint i -> EndPoint i -> Bool
forall a. Eq a => a -> a -> Bool
== EndPoint i
1 = Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
forall i.
IsInterval i =>
Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i
makeInterval (EndPoint i -> Rounded 'TowardNegInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
maxFinite) (EndPoint i -> Rounded 'TowardInf (EndPoint i)
forall (r :: RoundingMode) a. a -> Rounded r a
Rounded EndPoint i
forall a. RealFloatConstants a => a
positiveInfinity)
| Bool
otherwise = let x' :: i
x' = EndPoint i -> i
forall i. IsInterval i => EndPoint i -> i
singleton EndPoint i
x
in i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
logI ((i
1 i -> i -> i
forall a. Num a => a -> a -> a
+ i
x') i -> i -> i
forall a. Fractional a => a -> a -> a
/ (i
1 i -> i -> i
forall a. Num a => a -> a -> a
- i
x')) i -> i -> i
forall a. Fractional a => a -> a -> a
/ i
2
{-# INLINABLE atanhP #-}
atanhI :: (IsInterval i, Fractional i, Eq (EndPoint i), RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) => i -> i
atanhI :: forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
i -> i
atanhI = (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
forall i.
IsInterval i =>
(Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i
withEndPoints ((Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i -> i)
-> (Rounded 'TowardNegInf (EndPoint i)
-> Rounded 'TowardInf (EndPoint i) -> i)
-> i
-> i
forall a b. (a -> b) -> a -> b
$ \(Rounded EndPoint i
x) (Rounded EndPoint i
y) -> i -> i -> i
forall i. IsInterval i => i -> i -> i
hull (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
atanhP EndPoint i
x) (EndPoint i -> i
forall i.
(IsInterval i, Fractional i, Eq (EndPoint i),
RealFloat (EndPoint i), RealFloatConstants (EndPoint i)) =>
EndPoint i -> i
atanhP EndPoint i
y)
{-# INLINABLE atanhI #-}