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220 lines
5.1 KiB
V
220 lines
5.1 KiB
V
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module math
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// The original C code, the long comment, and the constants below were
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// from http://netlib.sandia.gov/cephes/cmath/atan.c, available from
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// http://www.netlib.org/cephes/ctgz.
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// The go code is a version of the original C.
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//
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// atan.c
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// Inverse circular tangent (arctangent)
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//
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// SYNOPSIS:
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// double x, y, atan()
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// y = atan( x )
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//
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// DESCRIPTION:
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// Returns radian angle between -pi/2.0 and +pi/2.0 whose tangent is x.
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//
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// Range reduction is from three intervals into the interval from zero to 0.66.
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// The approximant uses a rational function of degree 4/5 of the form
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// x + x**3 P(x)/Q(x).
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//
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// ACCURACY:
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// Relative error:
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// arithmetic domain # trials peak rms
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// DEC -10, 10 50000 2.4e-17 8.3e-18
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// IEEE -10, 10 10^6 1.8e-16 5.0e-17
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//
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// Cephes Math Library Release 2.8: June, 2000
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// Copyright 1984, 1987, 1989, 1992, 2000 by Stephen L. Moshier
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//
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// The readme file at http://netlib.sandia.gov/cephes/ says:
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// Some software in this archive may be from the book _Methods and
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// Programs for Mathematical Functions_ (Prentice-Hall or Simon & Schuster
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// International, 1989) or from the Cephes Mathematical Library, a
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// commercial product. In either event, it is copyrighted by the author.
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// What you see here may be used freely but it comes with no support or
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// guarantee.
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//
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// The two known misprints in the book are repaired here in the
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// source listings for the gamma function and the incomplete beta
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// integral.
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//
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// Stephen L. Moshier
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// moshier@na-net.ornl.gov
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// pi/2.0 = PIO2 + morebits
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// tan3pio8 = tan(3*pi/8)
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const (
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morebits = 6.123233995736765886130e-17
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tan3pio8 = 2.41421356237309504880
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)
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// xatan evaluates a series valid in the range [0, 0.66].
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[inline]
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fn xatan(x f64) f64 {
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xatan_p0 := -8.750608600031904122785e-01
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xatan_p1 := -1.615753718733365076637e+01
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xatan_p2 := -7.500855792314704667340e+01
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xatan_p3 := -1.228866684490136173410e+02
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xatan_p4 := -6.485021904942025371773e+01
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xatan_q0 := 2.485846490142306297962e+01
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xatan_q1 := 1.650270098316988542046e+02
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xatan_q2 := 4.328810604912902668951e+02
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xatan_q3 := 4.853903996359136964868e+02
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xatan_q4 := 1.945506571482613964425e+02
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mut z := x * x
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z = z * ((((xatan_p0 * z + xatan_p1) * z + xatan_p2) * z + xatan_p3) * z + xatan_p4) / (((((z +
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xatan_q0) * z + xatan_q1) * z + xatan_q2) * z + xatan_q3) * z + xatan_q4)
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z = x * z + x
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return z
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}
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// satan reduces its argument (known to be positive)
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// to the range [0, 0.66] and calls xatan.
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[inline]
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fn satan(x f64) f64 {
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if x <= 0.66 {
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return xatan(x)
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}
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if x > math.tan3pio8 {
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return pi / 2.0 - xatan(1.0 / x) + f64(math.morebits)
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}
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return pi / 4 + xatan((x - 1.0) / (x + 1.0)) + 0.5 * f64(math.morebits)
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}
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// atan returns the arctangent, in radians, of x.
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//
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// special cases are:
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// atan(±0) = ±0
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// atan(±inf) = ±pi/2.0
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pub fn atan(x f64) f64 {
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if x == 0 {
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return x
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}
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if x > 0 {
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return satan(x)
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}
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return -satan(-x)
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}
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// atan2 returns the arc tangent of y/x, using
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// the signs of the two to determine the quadrant
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// of the return value.
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//
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// special cases are (in order):
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// atan2(y, nan) = nan
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// atan2(nan, x) = nan
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// atan2(+0, x>=0) = +0
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// atan2(-0, x>=0) = -0
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// atan2(+0, x<=-0) = +pi
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// atan2(-0, x<=-0) = -pi
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// atan2(y>0, 0) = +pi/2.0
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// atan2(y<0, 0) = -pi/2.0
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// atan2(+inf, +inf) = +pi/4
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// atan2(-inf, +inf) = -pi/4
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// atan2(+inf, -inf) = 3pi/4
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// atan2(-inf, -inf) = -3pi/4
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// atan2(y, +inf) = 0
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// atan2(y>0, -inf) = +pi
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// atan2(y<0, -inf) = -pi
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// atan2(+inf, x) = +pi/2.0
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// atan2(-inf, x) = -pi/2.0
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pub fn atan2(y f64, x f64) f64 {
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// special cases
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if is_nan(y) || is_nan(x) {
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return nan()
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}
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if y == 0.0 {
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if x >= 0 && !signbit(x) {
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return copysign(0, y)
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}
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return copysign(pi, y)
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}
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if x == 0.0 {
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return copysign(pi / 2.0, y)
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}
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if is_inf(x, 0) {
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if is_inf(x, 1) {
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if is_inf(y, 0) {
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return copysign(pi / 4, y)
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}
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return copysign(0, y)
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}
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if is_inf(y, 0) {
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return copysign(3.0 * pi / 4.0, y)
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}
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return copysign(pi, y)
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}
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if is_inf(y, 0) {
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return copysign(pi / 2.0, y)
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}
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// Call atan and determine the quadrant.
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q := atan(y / x)
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if x < 0 {
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if q <= 0 {
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return q + pi
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}
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return q - pi
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}
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return q
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}
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/*
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Floating-point arcsine and arccosine.
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They are implemented by computing the arctangent
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after appropriate range reduction.
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*/
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// asin returns the arcsine, in radians, of x.
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//
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// special cases are:
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// asin(±0) = ±0
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// asin(x) = nan if x < -1 or x > 1
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pub fn asin(x_ f64) f64 {
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mut x := x_
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if x == 0.0 {
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return x // special case
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}
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mut sign := false
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if x < 0.0 {
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x = -x
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sign = true
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}
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if x > 1.0 {
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return nan() // special case
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}
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mut temp := sqrt(1.0 - x * x)
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if x > 0.7 {
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temp = pi / 2.0 - satan(temp / x)
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} else {
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temp = satan(x / temp)
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}
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if sign {
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temp = -temp
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}
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return temp
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}
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// acos returns the arccosine, in radians, of x.
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//
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// special case is:
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// acos(x) = nan if x < -1 or x > 1
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[inline]
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pub fn acos(x f64) f64 {
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if (x < -1.0) || (x > 1.0) {
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return nan()
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}
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if x == 0.0 {
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return nan()
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}
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if x > 0.5 {
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return f64(2.0) * asin(sqrt(0.5 - 0.5 * x))
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}
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mut z := pi / f64(4.0) - asin(x)
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z = z + math.morebits
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z = z + pi / f64(4.0)
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return z
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}
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