e_jn.c - platform/external/fdlibm - Git at Google


 /* @(#)e_jn.c 1.4 95/01/18 */
 /*
  * ====================================================
  * 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.
  * ====================================================
  */

 /*
  * __ieee754_jn(n, x), __ieee754_yn(n, x)
  * floating point Bessel's function of the 1st and 2nd kind
  * of order n
  *
  * Special cases:
  *	y0(0)=ieee_y1(0)=ieee_yn(n,0) = -inf with division by zero signal;
  *	y0(-ve)=ieee_y1(-ve)=ieee_yn(n,-ve) are NaN with invalid signal.
  * Note 2. About ieee_jn(n,x), ieee_yn(n,x)
  *	For n=0, ieee_j0(x) is called,
  *	for n=1, ieee_j1(x) is called,
  *	for n<x, forward recursion us used starting
  *	from values of ieee_j0(x) and ieee_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.
  *
  */

 #include "fdlibm.h"

 #ifdef __STDC__
 static const double
 #else
 static double
 #endif
 invsqrtpi=  5.64189583547756279280e-01, /* 0x3FE20DD7, 0x50429B6D */
 two   =  2.00000000000000000000e+00, /* 0x40000000, 0x00000000 */
 one   =  1.00000000000000000000e+00; /* 0x3FF00000, 0x00000000 */

 static double zero  =  0.00000000000000000000e+00;

 #ifdef __STDC__
 	double __ieee754_jn(int n, double x)
 #else
 	double __ieee754_jn(n,x)
 	int n; double x;
 #endif
 {
 	int i,hx,ix,lx, sgn;
 	double a, b, temp, di;
 	double z, w;

     /* J(-n,x) = (-1)^n * J(n, x), J(n, -x) = (-1)^n * J(n, x)
      * Thus, J(-n,x) = J(n,-x)
      */
 	hx = __HI(x);
 	ix = 0x7fffffff&hx;
 	lx = __LO(x);
     /* if J(n,NaN) is NaN */
 	if((ix|((unsigned)(lx|-lx))>>31)>0x7ff00000) return x+x;
 	if(n<0){
 		n = -n;
 		x = -x;
 		hx ^= 0x80000000;
 	}
 	if(n==0) return(__ieee754_j0(x));
 	if(n==1) return(__ieee754_j1(x));
 	sgn = (n&1)&(hx>>31);	/* even n -- 0, odd n -- sign(x) */
 	x = ieee_fabs(x);
 	if((ix|lx)==0||ix>=0x7ff00000) 	/* if x is 0 or inf */
 	    b = zero;
 	else if((double)n<=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) = ieee_cos(x-(2n+1)*pi/4)*ieee_sqrt(2/x*pi)
      *	    Yn(x) = ieee_sin(x-(2n+1)*pi/4)*ieee_sqrt(2/x*pi)
      *	    Let s=ieee_sin(x), c=ieee_cos(x),
      *		xn=x-(2n+1)*pi/4, sqt2 = ieee_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
      */
 		switch(n&3) {
 		    case 0: temp =  ieee_cos(x)+ieee_sin(x); break;
 		    case 1: temp = -ieee_cos(x)+ieee_sin(x); break;
 		    case 2: temp = -ieee_cos(x)-ieee_sin(x); break;
 		    case 3: temp =  ieee_cos(x)-ieee_sin(x); break;
 		}
 		b = invsqrtpi*temp/ieee_sqrt(x);
 	    } else {
 	        a = __ieee754_j0(x);
 	        b = __ieee754_j1(x);
 	        for(i=1;i<n;i++){
 		    temp = b;
 		    b = b*((double)(i+i)/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(n>33)	/* underflow */
 		    b = zero;
 		else {
 		    temp = x*0.5; b = temp;
 		    for (a=one,i=2;i<=n;i++) {
 			a *= (double)i;		/* a = n! */
 			b *= temp;		/* b = (x/2)^n */
 		    }
 		    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 */
 		double t,v;
 		double q0,q1,h,tmp; int k,m;
 		w  = (n+n)/(double)x; h = 2.0/(double)x;
 		q0 = w;  z = w+h; q1 = w*z - 1.0; k=1;
 		while(q1<1.0e9) {
 			k += 1; z += h;
 			tmp = z*q1 - q0;
 			q0 = q1;
 			q1 = tmp;
 		}
 		m = n+n;
 		for(t=zero, i = 2*(n+k); i>=m; i -= 2) t = one/(i/x-t);
 		a = t;
 		b = one;
 		/*  estimate ieee_log((2/x)^n*n!) = n*ieee_log(2/x)+n*ln(n)
 		 *  Hence, if n*(ieee_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 = n;
 		v = two/x;
 		tmp = tmp*__ieee754_log(ieee_fabs(v*tmp));
 		if(tmp<7.09782712893383973096e+02) {
 	    	    for(i=n-1,di=(double)(i+i);i>0;i--){
 		        temp = b;
 			b *= di;
 			b  = b/x - a;
 		        a = temp;
 			di -= two;
 	     	    }
 		} else {
 	    	    for(i=n-1,di=(double)(i+i);i>0;i--){
 		        temp = b;
 			b *= di;
 			b  = b/x - a;
 		        a = temp;
 			di -= two;
 		    /* scale b to avoid spurious overflow */
 			if(b>1e100) {
 			    a /= b;
 			    t /= b;
 			    b  = one;
 			}
 	     	    }
 		}
 	    	b = (t*__ieee754_j0(x)/b);
 	    }
 	}
 	if(sgn==1) return -b; else return b;
 }

 #ifdef __STDC__
 	double __ieee754_yn(int n, double x)
 #else
 	double __ieee754_yn(n,x)
 	int n; double x;
 #endif
 {
 	int i,hx,ix,lx;
 	int sign;
 	double a, b, temp;

 	hx = __HI(x);
 	ix = 0x7fffffff&hx;
 	lx = __LO(x);
     /* if Y(n,NaN) is NaN */
 	if((ix|((unsigned)(lx|-lx))>>31)>0x7ff00000) return x+x;
 	if((ix|lx)==0) return -one/zero;
 	if(hx<0) return zero/zero;
 	sign = 1;
 	if(n<0){
 		n = -n;
 		sign = 1 - ((n&1)<<1);
 	}
 	if(n==0) return(__ieee754_y0(x));
 	if(n==1) return(sign*__ieee754_y1(x));
 	if(ix==0x7ff00000) return zero;
 	if(ix>=0x52D00000) { /* x > 2**302 */
     /* (x >> n**2)
      *	    Jn(x) = ieee_cos(x-(2n+1)*pi/4)*ieee_sqrt(2/x*pi)
      *	    Yn(x) = ieee_sin(x-(2n+1)*pi/4)*ieee_sqrt(2/x*pi)
      *	    Let s=ieee_sin(x), c=ieee_cos(x),
      *		xn=x-(2n+1)*pi/4, sqt2 = ieee_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
      */
 		switch(n&3) {
 		    case 0: temp =  ieee_sin(x)-ieee_cos(x); break;
 		    case 1: temp = -ieee_sin(x)-ieee_cos(x); break;
 		    case 2: temp = -ieee_sin(x)+ieee_cos(x); break;
 		    case 3: temp =  ieee_sin(x)+ieee_cos(x); break;
 		}
 		b = invsqrtpi*temp/ieee_sqrt(x);
 	} else {
 	    a = __ieee754_y0(x);
 	    b = __ieee754_y1(x);
 	/* quit if b is -inf */
 	    for(i=1;i<n&&(__HI(b) != 0xfff00000);i++){
 		temp = b;
 		b = ((double)(i+i)/x)*b - a;
 		a = temp;
 	    }
 	}
 	if(sign>0) return b; else return -b;
 }

	/* @(#)e_jn.c 1.4 95/01/18 */
	/*
	* ====================================================
	* 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.
	* ====================================================
	*/

	/*
	* __ieee754_jn(n, x), __ieee754_yn(n, x)
	* floating point Bessel's function of the 1st and 2nd kind
	* of order n
	*
	* Special cases:
	* y0(0)=ieee_y1(0)=ieee_yn(n,0) = -inf with division by zero signal;
	* y0(-ve)=ieee_y1(-ve)=ieee_yn(n,-ve) are NaN with invalid signal.
	* Note 2. About ieee_jn(n,x), ieee_yn(n,x)
	* For n=0, ieee_j0(x) is called,
	* for n=1, ieee_j1(x) is called,
	* for n<x, forward recursion us used starting
	* from values of ieee_j0(x) and ieee_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.
	*
	*/

	#include "fdlibm.h"

	#ifdef __STDC__
	static const double
	#else
	static double
	#endif
	invsqrtpi= 5.64189583547756279280e-01, /* 0x3FE20DD7, 0x50429B6D */
	two = 2.00000000000000000000e+00, /* 0x40000000, 0x00000000 */
	one = 1.00000000000000000000e+00; /* 0x3FF00000, 0x00000000 */

	static double zero = 0.00000000000000000000e+00;

	#ifdef __STDC__
	double __ieee754_jn(int n, double x)
	#else
	double __ieee754_jn(n,x)
	int n; double x;
	#endif
	{
	int i,hx,ix,lx, sgn;
	double a, b, temp, di;
	double z, w;

	/* J(-n,x) = (-1)^n * J(n, x), J(n, -x) = (-1)^n * J(n, x)
	* Thus, J(-n,x) = J(n,-x)
	*/
	hx = __HI(x);
	ix = 0x7fffffff&hx;
	lx = __LO(x);
	/* if J(n,NaN) is NaN */
	if((ix\|((unsigned)(lx\|-lx))>>31)>0x7ff00000) return x+x;
	if(n<0){
	n = -n;
	x = -x;
	hx ^= 0x80000000;
	}
	if(n==0) return(__ieee754_j0(x));
	if(n==1) return(__ieee754_j1(x));
	sgn = (n&1)&(hx>>31); /* even n -- 0, odd n -- sign(x) */
	x = ieee_fabs(x);
	if((ix\|lx)==0\|\|ix>=0x7ff00000) /* if x is 0 or inf */
	b = zero;
	else if((double)n<=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) = ieee_cos(x-(2n+1)pi/4)ieee_sqrt(2/x*pi)
	* Yn(x) = ieee_sin(x-(2n+1)pi/4)ieee_sqrt(2/x*pi)
	* Let s=ieee_sin(x), c=ieee_cos(x),
	* xn=x-(2n+1)*pi/4, sqt2 = ieee_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
	*/
	switch(n&3) {
	case 0: temp = ieee_cos(x)+ieee_sin(x); break;
	case 1: temp = -ieee_cos(x)+ieee_sin(x); break;
	case 2: temp = -ieee_cos(x)-ieee_sin(x); break;
	case 3: temp = ieee_cos(x)-ieee_sin(x); break;
	}
	b = invsqrtpi*temp/ieee_sqrt(x);
	} else {
	a = __ieee754_j0(x);
	b = __ieee754_j1(x);
	for(i=1;i<n;i++){
	temp = b;
	b = b((double)(i+i)/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(n>33) /* underflow */
	b = zero;
	else {
	temp = x*0.5; b = temp;
	for (a=one,i=2;i<=n;i++) {
	a = (double)i; / a = n! */
	b = temp; / b = (x/2)^n */
	}
	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+kh)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 */
	double t,v;
	double q0,q1,h,tmp; int k,m;
	w = (n+n)/(double)x; h = 2.0/(double)x;
	q0 = w; z = w+h; q1 = w*z - 1.0; k=1;
	while(q1<1.0e9) {
	k += 1; z += h;
	tmp = z*q1 - q0;
	q0 = q1;
	q1 = tmp;
	}
	m = n+n;
	for(t=zero, i = 2*(n+k); i>=m; i -= 2) t = one/(i/x-t);
	a = t;
	b = one;
	/* estimate ieee_log((2/x)^nn!) = nieee_log(2/x)+n*ln(n)
	* Hence, if n*(ieee_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 = n;
	v = two/x;
	tmp = tmp__ieee754_log(ieee_fabs(vtmp));
	if(tmp<7.09782712893383973096e+02) {
	for(i=n-1,di=(double)(i+i);i>0;i--){
	temp = b;
	b *= di;
	b = b/x - a;
	a = temp;
	di -= two;
	}
	} else {
	for(i=n-1,di=(double)(i+i);i>0;i--){
	temp = b;
	b *= di;
	b = b/x - a;
	a = temp;
	di -= two;
	/* scale b to avoid spurious overflow */
	if(b>1e100) {
	a /= b;
	t /= b;
	b = one;
	}
	}
	}
	b = (t*__ieee754_j0(x)/b);
	}
	}
	if(sgn==1) return -b; else return b;
	}

	#ifdef __STDC__
	double __ieee754_yn(int n, double x)
	#else
	double __ieee754_yn(n,x)
	int n; double x;
	#endif
	{
	int i,hx,ix,lx;
	int sign;
	double a, b, temp;

	hx = __HI(x);
	ix = 0x7fffffff&hx;
	lx = __LO(x);
	/* if Y(n,NaN) is NaN */
	if((ix\|((unsigned)(lx\|-lx))>>31)>0x7ff00000) return x+x;
	if((ix\|lx)==0) return -one/zero;
	if(hx<0) return zero/zero;
	sign = 1;
	if(n<0){
	n = -n;
	sign = 1 - ((n&1)<<1);
	}
	if(n==0) return(__ieee754_y0(x));
	if(n==1) return(sign*__ieee754_y1(x));
	if(ix==0x7ff00000) return zero;
	if(ix>=0x52D00000) { /* x > 2*302 /
	/* (x >> n**2)
	* Jn(x) = ieee_cos(x-(2n+1)pi/4)ieee_sqrt(2/x*pi)
	* Yn(x) = ieee_sin(x-(2n+1)pi/4)ieee_sqrt(2/x*pi)
	* Let s=ieee_sin(x), c=ieee_cos(x),
	* xn=x-(2n+1)*pi/4, sqt2 = ieee_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
	*/
	switch(n&3) {
	case 0: temp = ieee_sin(x)-ieee_cos(x); break;
	case 1: temp = -ieee_sin(x)-ieee_cos(x); break;
	case 2: temp = -ieee_sin(x)+ieee_cos(x); break;
	case 3: temp = ieee_sin(x)+ieee_cos(x); break;
	}
	b = invsqrtpi*temp/ieee_sqrt(x);
	} else {
	a = __ieee754_y0(x);
	b = __ieee754_y1(x);
	/* quit if b is -inf */
	for(i=1;i<n&&(__HI(b) != 0xfff00000);i++){
	temp = b;
	b = ((double)(i+i)/x)*b - a;
	a = temp;
	}
	}
	if(sign>0) return b; else return -b;
	}