MultiSource/Benchmarks/Ptrdist/bc/libmath.b - third_party/llvm-test-suite - Git at Google

 /* libmath.b for bc for minix.  */

 /*  This file is part of bc written for MINIX.
     Copyright (C) 1991, 1992 Free Software Foundation, Inc.

     This program is free software; you can redistribute it and/or modify
     it under the terms of the GNU General Public License as published by
     the Free Software Foundation; either version 2 of the License , or
     (at your option) any later version.

     This program is distributed in the hope that it will be useful,
     but WITHOUT ANY WARRANTY; without even the implied warranty of
     MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
     GNU General Public License for more details.

     You should have received a copy of the GNU General Public License
     along with this program; see the file COPYING.  If not, write to
     the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.

     You may contact the author by:
        e-mail:  phil@cs.wwu.edu
       us-mail:  Philip A. Nelson
                 Computer Science Department, 9062
                 Western Washington University
                 Bellingham, WA 98226-9062

 *************************************************************************/


 scale = 20

 /* Uses the fact that e^x = (e^(x/2))^2
    When x is small enough, we use the series:
      e^x = 1 + x + x^2/2! + x^3/3! + ...
 */

 define e(x) {
   auto  a, d, e, f, i, m, v, z

   /* Check the sign of x. */
   if (x<0) {
     m = 1
     x = -x
   }

   /* Precondition x. */
   z = scale;
   scale = 4 + z + .44*x;
   while (x > 1) {
     f += 1;
     x /= 2;
   }

   /* Initialize the variables. */
   v = 1+x
   a = x
   d = 1

   for (i=2; 1; i++) {
     e = (a *= x) / (d *= i)
     if (e == 0) {
       if (f>0) while (f--)  v = v*v;
       scale = z
       if (m) return (1/v);
       return (v/1);
     }
     v += e
   }
 }

 /* Natural log. Uses the fact that ln(x^2) = 2*ln(x)
     The series used is:
        ln(x) = 2(a+a^3/3+a^5/5+...) where a=(x-1)/(x+1)
 */

 define l(x) {
   auto e, f, i, m, n, v, z

   /* return something for the special case. */
   if (x <= 0) return (1 - 10^scale)

   /* Precondition x to make .5 < x < 2.0. */
   z = scale;
   scale += 4;
   f = 2;
   i=0
   while (x >= 2) {  /* for large numbers */
     f *= 2;
     x = sqrt(x);
   }
   while (x <= .5) {  /* for small numbers */
     f *= 2;
     x = sqrt(x);
   }

   /* Set up the loop. */
   v = n = (x-1)/(x+1)
   m = n*n

   /* Sum the series. */
   for (i=3; 1; i+=2) {
     e = (n *= m) / i
     if (e == 0) {
       v = f*v
       scale = z
       return (v/1)
     }
     v += e
   }
 }

 /* Sin(x)  uses the standard series:
    sin(x) = x - x^3/3! + x^5/5! - x^7/7! ... */

 define s(x) {
   auto  e, i, m, n, s, v, z

   /* precondition x. */
   z = scale
   scale = 1.1*z + 1;
   v = a(1)
   if (x < 0) {
     m = 1;
     x = -x;
   }
   scale = 0
   n = (x / v + 2 )/4
   x = x - 4*n*v
   if (n%2) x = -x

   /* Do the loop. */
   scale = z + 2;
   v = e = x
   s = -x*x
   for (i=3; 1; i+=2) {
     e *= s/(i*(i-1))
     if (e == 0) {
       scale = z
       if (m) return (-v/1);
       return (v/1);
     }
     v += e
   }
 }

 /* Cosine : cos(x) = sin(x+pi/2) */
 define c(x) {
   auto v;
   scale += 1;
   v = s(x+a(1)*2);
   scale -= 1;
   return (v/1);
 }

 /* Arctan: Using the formula:
      atan(x) = atan(c) + atan((x-c)/(1+xc)) for a small c (.2 here)
    For under .2, use the series:
      atan(x) = x - x^3/3 + x^5/5 - x^7/7 + ...   */

 define a(x) {
   auto a, e, f, i, m, n, s, v, z

   /* Special case and for fast answers */
   if (x==1) {
     if (scale <= 25) return (.7853981633974483096156608/1)
     if (scale <= 40) return (.7853981633974483096156608458198757210492/1)
     if (scale <= 60) \
       return (.785398163397448309615660845819875721049292349843776455243736/1)
   }
   if (x==.2) {
     if (scale <= 25) return (.1973955598498807583700497/1)
     if (scale <= 40) return (.1973955598498807583700497651947902934475/1)
     if (scale <= 60) \
       return (.197395559849880758370049765194790293447585103787852101517688/1)
   }

   /* Negative x? */
   if (x<0) {
     m = 1;
     x = -x;
   }

   /* Save the scale. */
   z = scale;

   /* Note: a and f are known to be zero due to being auto vars. */
   /* Calculate atan of a known number. */
   if (x > .2)  {
     scale = z+4;
     a = a(.2);
   }

   /* Precondition x. */
   scale = z+2;
   while (x > .2) {
     f += 1;
     x = (x-.2) / (1+x*.2);
   }

   /* Initialize the series. */
   v = n = x;
   s = -x*x;

   /* Calculate the series. */
   for (i=3; 1; i+=2) {
     e = (n *= s) / i;
     if (e == 0) {
       scale = z;
       if (m) return ((f*a+v)/-1);
       return ((f*a+v)/1);
     }
     v += e
   }
 }


 /* Bessel function of integer order.  Uses the following:
    j(-n,x) = (-1)^n*j(n,x)
    j(n,x) = x^n/(2^n*n!) * (1 - x^2/(2^2*1!*(n+1)) + x^4/(2^4*2!*(n+1)*(n+2))
             - x^6/(2^6*3!*(n+1)*(n+2)*(n+3)) .... )
 */
 define j(n,x) {
   auto a, d, e, f, i, m, s, v, z

   /* Make n an integer and check for negative n. */
   z = scale;
   scale = 0;
   n = n/1;
   if (n<0) {
     n = -n;
     if (n%2 == 1) m = 1;
   }

   /* Compute the factor of x^n/(2^n*n!) */
   f = 1;
   for (i=2; i<=n; i++) f = f*i;
   scale = 1.5*z;
   f = x^n / 2^n / f;

   /* Initialize the loop .*/
   v = e = 1;
   s = -x*x/4
   scale = 1.5*z

   /* The Loop.... */
   for (i=1; 1; i++) {
     e =  e * s / i / (n+i);
     if (e == 0) {
        scale = z
        if (m) return (-f*v/1);
        return (f*v/1);
     }
     v += e;
   }
 }
	/* libmath.b for bc for minix. */

	/* This file is part of bc written for MINIX.
	Copyright (C) 1991, 1992 Free Software Foundation, Inc.

	This program is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 2 of the License , or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program; see the file COPYING. If not, write to
	the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.

	You may contact the author by:
	e-mail: phil@cs.wwu.edu
	us-mail: Philip A. Nelson
	Computer Science Department, 9062
	Western Washington University
	Bellingham, WA 98226-9062

	*************************************************************************/


	scale = 20

	/* Uses the fact that e^x = (e^(x/2))^2
	When x is small enough, we use the series:
	e^x = 1 + x + x^2/2! + x^3/3! + ...
	*/

	define e(x) {
	auto a, d, e, f, i, m, v, z

	/* Check the sign of x. */
	if (x<0) {
	m = 1
	x = -x
	}

	/* Precondition x. */
	z = scale;
	scale = 4 + z + .44*x;
	while (x > 1) {
	f += 1;
	x /= 2;
	}

	/* Initialize the variables. */
	v = 1+x
	a = x
	d = 1

	for (i=2; 1; i++) {
	e = (a = x) / (d = i)
	if (e == 0) {
	if (f>0) while (f--) v = v*v;
	scale = z
	if (m) return (1/v);
	return (v/1);
	}
	v += e
	}
	}

	/* Natural log. Uses the fact that ln(x^2) = 2*ln(x)
	The series used is:
	ln(x) = 2(a+a^3/3+a^5/5+...) where a=(x-1)/(x+1)
	*/

	define l(x) {
	auto e, f, i, m, n, v, z

	/* return something for the special case. */
	if (x <= 0) return (1 - 10^scale)

	/* Precondition x to make .5 < x < 2.0. */
	z = scale;
	scale += 4;
	f = 2;
	i=0
	while (x >= 2) { /* for large numbers */
	f *= 2;
	x = sqrt(x);
	}
	while (x <= .5) { /* for small numbers */
	f *= 2;
	x = sqrt(x);
	}

	/* Set up the loop. */
	v = n = (x-1)/(x+1)
	m = n*n

	/* Sum the series. */
	for (i=3; 1; i+=2) {
	e = (n *= m) / i
	if (e == 0) {
	v = f*v
	scale = z
	return (v/1)
	}
	v += e
	}
	}

	/* Sin(x) uses the standard series:
	sin(x) = x - x^3/3! + x^5/5! - x^7/7! ... */

	define s(x) {
	auto e, i, m, n, s, v, z

	/* precondition x. */
	z = scale
	scale = 1.1*z + 1;
	v = a(1)
	if (x < 0) {
	m = 1;
	x = -x;
	}
	scale = 0
	n = (x / v + 2 )/4
	x = x - 4nv
	if (n%2) x = -x

	/* Do the loop. */
	scale = z + 2;
	v = e = x
	s = -x*x
	for (i=3; 1; i+=2) {
	e = s/(i(i-1))
	if (e == 0) {
	scale = z
	if (m) return (-v/1);
	return (v/1);
	}
	v += e
	}
	}

	/* Cosine : cos(x) = sin(x+pi/2) */
	define c(x) {
	auto v;
	scale += 1;
	v = s(x+a(1)*2);
	scale -= 1;
	return (v/1);
	}

	/* Arctan: Using the formula:
	atan(x) = atan(c) + atan((x-c)/(1+xc)) for a small c (.2 here)
	For under .2, use the series:
	atan(x) = x - x^3/3 + x^5/5 - x^7/7 + ... */

	define a(x) {
	auto a, e, f, i, m, n, s, v, z

	/* Special case and for fast answers */
	if (x==1) {
	if (scale <= 25) return (.7853981633974483096156608/1)
	if (scale <= 40) return (.7853981633974483096156608458198757210492/1)
	if (scale <= 60) \
	return (.785398163397448309615660845819875721049292349843776455243736/1)
	}
	if (x==.2) {
	if (scale <= 25) return (.1973955598498807583700497/1)
	if (scale <= 40) return (.1973955598498807583700497651947902934475/1)
	if (scale <= 60) \
	return (.197395559849880758370049765194790293447585103787852101517688/1)
	}

	/* Negative x? */
	if (x<0) {
	m = 1;
	x = -x;
	}

	/* Save the scale. */
	z = scale;

	/* Note: a and f are known to be zero due to being auto vars. */
	/* Calculate atan of a known number. */
	if (x > .2) {
	scale = z+4;
	a = a(.2);
	}

	/* Precondition x. */
	scale = z+2;
	while (x > .2) {
	f += 1;
	x = (x-.2) / (1+x*.2);
	}

	/* Initialize the series. */
	v = n = x;
	s = -x*x;

	/* Calculate the series. */
	for (i=3; 1; i+=2) {
	e = (n *= s) / i;
	if (e == 0) {
	scale = z;
	if (m) return ((f*a+v)/-1);
	return ((f*a+v)/1);
	}
	v += e
	}
	}


	/* Bessel function of integer order. Uses the following:
	j(-n,x) = (-1)^n*j(n,x)
	j(n,x) = x^n/(2^nn!) (1 - x^2/(2^21!(n+1)) + x^4/(2^42!(n+1)*(n+2))
	- x^6/(2^63!(n+1)(n+2)(n+3)) .... )
	*/
	define j(n,x) {
	auto a, d, e, f, i, m, s, v, z

	/* Make n an integer and check for negative n. */
	z = scale;
	scale = 0;
	n = n/1;
	if (n<0) {
	n = -n;
	if (n%2 == 1) m = 1;
	}

	/* Compute the factor of x^n/(2^nn!) /
	f = 1;
	for (i=2; i<=n; i++) f = f*i;
	scale = 1.5*z;
	f = x^n / 2^n / f;

	/* Initialize the loop .*/
	v = e = 1;
	s = -x*x/4
	scale = 1.5*z

	/* The Loop.... */
	for (i=1; 1; i++) {
	e = e * s / i / (n+i);
	if (e == 0) {
	scale = z
	if (m) return (-f*v/1);
	return (f*v/1);
	}
	v += e;
	}
	}