| /* origin: FreeBSD /usr/src/lib/msun/src/e_jn.c */ |
| /* |
| * ==================================================== |
| * Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved. |
| * |
| * Developed at SunSoft, a Sun Microsystems, Inc. business. |
| * Permission to use, copy, modify, and distribute this |
| * software is freely granted, provided that this notice |
| * is preserved. |
| * ==================================================== |
| */ |
| /* |
| * jn(n, x), yn(n, x) |
| * floating point Bessel's function of the 1st and 2nd kind |
| * of order n |
| * |
| * Special cases: |
| * y0(0)=y1(0)=yn(n,0) = -inf with division by zero signal; |
| * y0(-ve)=y1(-ve)=yn(n,-ve) are NaN with invalid signal. |
| * Note 2. About jn(n,x), yn(n,x) |
| * For n=0, j0(x) is called, |
| * for n=1, j1(x) is called, |
| * for n<=x, forward recursion is used starting |
| * from values of j0(x) and j1(x). |
| * for n>x, a continued fraction approximation to |
| * j(n,x)/j(n-1,x) is evaluated and then backward |
| * recursion is used starting from a supposed value |
| * for j(n,x). The resulting value of j(0,x) is |
| * compared with the actual value to correct the |
| * supposed value of j(n,x). |
| * |
| * yn(n,x) is similar in all respects, except |
| * that forward recursion is used for all |
| * values of n>1. |
| */ |
| |
| use super::{cos, fabs, get_high_word, get_low_word, j0, j1, log, sin, sqrt, y0, y1}; |
| |
| const INVSQRTPI: f64 = 5.64189583547756279280e-01; /* 0x3FE20DD7, 0x50429B6D */ |
| |
| pub fn jn(n: i32, mut x: f64) -> f64 { |
| let mut ix: u32; |
| let lx: u32; |
| let nm1: i32; |
| let mut i: i32; |
| let mut sign: bool; |
| let mut a: f64; |
| let mut b: f64; |
| let mut temp: f64; |
| |
| ix = get_high_word(x); |
| lx = get_low_word(x); |
| sign = (ix >> 31) != 0; |
| ix &= 0x7fffffff; |
| |
| // -lx == !lx + 1 |
| if (ix | (lx | ((!lx).wrapping_add(1))) >> 31) > 0x7ff00000 { |
| /* nan */ |
| return x; |
| } |
| |
| /* J(-n,x) = (-1)^n * J(n, x), J(n, -x) = (-1)^n * J(n, x) |
| * Thus, J(-n,x) = J(n,-x) |
| */ |
| /* nm1 = |n|-1 is used instead of |n| to handle n==INT_MIN */ |
| if n == 0 { |
| return j0(x); |
| } |
| if n < 0 { |
| nm1 = -(n + 1); |
| x = -x; |
| sign = !sign; |
| } else { |
| nm1 = n - 1; |
| } |
| if nm1 == 0 { |
| return j1(x); |
| } |
| |
| sign &= (n & 1) != 0; /* even n: 0, odd n: signbit(x) */ |
| x = fabs(x); |
| if (ix | lx) == 0 || ix == 0x7ff00000 { |
| /* if x is 0 or inf */ |
| b = 0.0; |
| } else if (nm1 as f64) < x { |
| /* Safe to use J(n+1,x)=2n/x *J(n,x)-J(n-1,x) */ |
| if ix >= 0x52d00000 { |
| /* x > 2**302 */ |
| /* (x >> n**2) |
| * Jn(x) = cos(x-(2n+1)*pi/4)*sqrt(2/x*pi) |
| * Yn(x) = sin(x-(2n+1)*pi/4)*sqrt(2/x*pi) |
| * Let s=sin(x), c=cos(x), |
| * xn=x-(2n+1)*pi/4, sqt2 = sqrt(2),then |
| * |
| * n sin(xn)*sqt2 cos(xn)*sqt2 |
| * ---------------------------------- |
| * 0 s-c c+s |
| * 1 -s-c -c+s |
| * 2 -s+c -c-s |
| * 3 s+c c-s |
| */ |
| temp = match nm1 & 3 { |
| 0 => -cos(x) + sin(x), |
| 1 => -cos(x) - sin(x), |
| 2 => cos(x) - sin(x), |
| 3 | _ => cos(x) + sin(x), |
| }; |
| b = INVSQRTPI * temp / sqrt(x); |
| } else { |
| a = j0(x); |
| b = j1(x); |
| i = 0; |
| while i < nm1 { |
| i += 1; |
| temp = b; |
| b = b * (2.0 * (i as f64) / x) - a; /* avoid underflow */ |
| a = temp; |
| } |
| } |
| } else { |
| if ix < 0x3e100000 { |
| /* x < 2**-29 */ |
| /* x is tiny, return the first Taylor expansion of J(n,x) |
| * J(n,x) = 1/n!*(x/2)^n - ... |
| */ |
| if nm1 > 32 { |
| /* underflow */ |
| b = 0.0; |
| } else { |
| temp = x * 0.5; |
| b = temp; |
| a = 1.0; |
| i = 2; |
| while i <= nm1 + 1 { |
| a *= i as f64; /* a = n! */ |
| b *= temp; /* b = (x/2)^n */ |
| i += 1; |
| } |
| b = b / a; |
| } |
| } else { |
| /* use backward recurrence */ |
| /* x x^2 x^2 |
| * J(n,x)/J(n-1,x) = ---- ------ ------ ..... |
| * 2n - 2(n+1) - 2(n+2) |
| * |
| * 1 1 1 |
| * (for large x) = ---- ------ ------ ..... |
| * 2n 2(n+1) 2(n+2) |
| * -- - ------ - ------ - |
| * x x x |
| * |
| * Let w = 2n/x and h=2/x, then the above quotient |
| * is equal to the continued fraction: |
| * 1 |
| * = ----------------------- |
| * 1 |
| * w - ----------------- |
| * 1 |
| * w+h - --------- |
| * w+2h - ... |
| * |
| * To determine how many terms needed, let |
| * Q(0) = w, Q(1) = w(w+h) - 1, |
| * Q(k) = (w+k*h)*Q(k-1) - Q(k-2), |
| * When Q(k) > 1e4 good for single |
| * When Q(k) > 1e9 good for double |
| * When Q(k) > 1e17 good for quadruple |
| */ |
| /* determine k */ |
| let mut t: f64; |
| let mut q0: f64; |
| let mut q1: f64; |
| let mut w: f64; |
| let h: f64; |
| let mut z: f64; |
| let mut tmp: f64; |
| let nf: f64; |
| |
| let mut k: i32; |
| |
| nf = (nm1 as f64) + 1.0; |
| w = 2.0 * nf / x; |
| h = 2.0 / x; |
| z = w + h; |
| q0 = w; |
| q1 = w * z - 1.0; |
| k = 1; |
| while q1 < 1.0e9 { |
| k += 1; |
| z += h; |
| tmp = z * q1 - q0; |
| q0 = q1; |
| q1 = tmp; |
| } |
| t = 0.0; |
| i = k; |
| while i >= 0 { |
| t = 1.0 / (2.0 * ((i as f64) + nf) / x - t); |
| i -= 1; |
| } |
| a = t; |
| b = 1.0; |
| /* estimate log((2/x)^n*n!) = n*log(2/x)+n*ln(n) |
| * Hence, if n*(log(2n/x)) > ... |
| * single 8.8722839355e+01 |
| * double 7.09782712893383973096e+02 |
| * long double 1.1356523406294143949491931077970765006170e+04 |
| * then recurrent value may overflow and the result is |
| * likely underflow to zero |
| */ |
| tmp = nf * log(fabs(w)); |
| if tmp < 7.09782712893383973096e+02 { |
| i = nm1; |
| while i > 0 { |
| temp = b; |
| b = b * (2.0 * (i as f64)) / x - a; |
| a = temp; |
| i -= 1; |
| } |
| } else { |
| i = nm1; |
| while i > 0 { |
| temp = b; |
| b = b * (2.0 * (i as f64)) / x - a; |
| a = temp; |
| /* scale b to avoid spurious overflow */ |
| let x1p500 = f64::from_bits(0x5f30000000000000); // 0x1p500 == 2^500 |
| if b > x1p500 { |
| a /= b; |
| t /= b; |
| b = 1.0; |
| } |
| i -= 1; |
| } |
| } |
| z = j0(x); |
| w = j1(x); |
| if fabs(z) >= fabs(w) { |
| b = t * z / b; |
| } else { |
| b = t * w / a; |
| } |
| } |
| } |
| |
| if sign { |
| -b |
| } else { |
| b |
| } |
| } |
| |
| pub fn yn(n: i32, x: f64) -> f64 { |
| let mut ix: u32; |
| let lx: u32; |
| let mut ib: u32; |
| let nm1: i32; |
| let mut sign: bool; |
| let mut i: i32; |
| let mut a: f64; |
| let mut b: f64; |
| let mut temp: f64; |
| |
| ix = get_high_word(x); |
| lx = get_low_word(x); |
| sign = (ix >> 31) != 0; |
| ix &= 0x7fffffff; |
| |
| // -lx == !lx + 1 |
| if (ix | (lx | ((!lx).wrapping_add(1))) >> 31) > 0x7ff00000 { |
| /* nan */ |
| return x; |
| } |
| if sign && (ix | lx) != 0 { |
| /* x < 0 */ |
| return 0.0 / 0.0; |
| } |
| if ix == 0x7ff00000 { |
| return 0.0; |
| } |
| |
| if n == 0 { |
| return y0(x); |
| } |
| if n < 0 { |
| nm1 = -(n + 1); |
| sign = (n & 1) != 0; |
| } else { |
| nm1 = n - 1; |
| sign = false; |
| } |
| if nm1 == 0 { |
| if sign { |
| return -y1(x); |
| } else { |
| return y1(x); |
| } |
| } |
| |
| if ix >= 0x52d00000 { |
| /* x > 2**302 */ |
| /* (x >> n**2) |
| * Jn(x) = cos(x-(2n+1)*pi/4)*sqrt(2/x*pi) |
| * Yn(x) = sin(x-(2n+1)*pi/4)*sqrt(2/x*pi) |
| * Let s=sin(x), c=cos(x), |
| * xn=x-(2n+1)*pi/4, sqt2 = sqrt(2),then |
| * |
| * n sin(xn)*sqt2 cos(xn)*sqt2 |
| * ---------------------------------- |
| * 0 s-c c+s |
| * 1 -s-c -c+s |
| * 2 -s+c -c-s |
| * 3 s+c c-s |
| */ |
| temp = match nm1 & 3 { |
| 0 => -sin(x) - cos(x), |
| 1 => -sin(x) + cos(x), |
| 2 => sin(x) + cos(x), |
| 3 | _ => sin(x) - cos(x), |
| }; |
| b = INVSQRTPI * temp / sqrt(x); |
| } else { |
| a = y0(x); |
| b = y1(x); |
| /* quit if b is -inf */ |
| ib = get_high_word(b); |
| i = 0; |
| while i < nm1 && ib != 0xfff00000 { |
| i += 1; |
| temp = b; |
| b = (2.0 * (i as f64) / x) * b - a; |
| ib = get_high_word(b); |
| a = temp; |
| } |
| } |
| |
| if sign { |
| -b |
| } else { |
| b |
| } |
| } |