newlib-cygwin/newlib/libm/mathfp/sf_atangent.c


/* @(#)z_atangentf.c 1.0 98/08/13 */
/******************************************************************
 * The following routines are coded directly from the algorithms
 * and coefficients given in "Software Manual for the Elementary
 * Functions" by William J. Cody, Jr. and William Waite, Prentice
 * Hall, 1980.
 ******************************************************************/
/******************************************************************
 * Arctangent
 *
 * Input:
 *   x - floating point value
 *
 * Output:
 *   arctangent of x
 *
 * Description:
 *   This routine calculates arctangents.
 *
 *****************************************************************/

#include <float.h>
#include "fdlibm.h"
#include "zmath.h"

static const float ROOT3 = 1.732050807;
static const float a[] = { 0.0, 0.523598775, 1.570796326,
                     1.047197551 };
static const float q[] = { 0.1412500740e+1 };
static const float p[] = { -0.4708325141, -0.5090958253e-1 };

float
_DEFUN (atangentf, (float, float, float, int),
        float x _AND
        float v _AND
        float u _AND
        int arctan2)
{
  float f, g, R, P, Q, A, res;
  int N;
  int branch = 0;
  int expv, expu;

  /* Preparation for calculating arctan2. */
  if (arctan2)
    {
      if (u == 0.0)
        if (v == 0.0)
          {
            errno = ERANGE;
            return (z_notanum_f.f);
          }
        else
          {
            branch = 1;
            res = __PI_OVER_TWO;
          }

      if (!branch)
        {
          int e;
          /* Get the exponent values of the inputs. */
          g = frexpf (v, &expv);
          g = frexpf (u, &expu);

          /* See if a divide will overflow. */
          e = expv - expu;
          if (e > FLT_MAX_EXP)
            {
               branch = 1;
               res = __PI_OVER_TWO;
            }

          /* Also check for underflow. */
          else if (e < FLT_MIN_EXP)
            {
               branch = 2;
               res = 0.0;
            }
         }
    }

  if (!branch)
    {
      if (arctan2)
        f = fabsf (v / u);
      else
        f = fabsf (x);

      if (f > 1.0)
        {
          f = 1.0 / f;
          N = 2;
        }
      else
        N = 0;

      if (f > (2.0 - ROOT3))
        {
          A = ROOT3 - 1.0;
          f = (((A * f - 0.5) - 0.5) + f) / (ROOT3 + f);
          N++;
        }

      /* Check for values that are too small. */
      if (-z_rooteps_f < f && f < z_rooteps_f)
        res = f;

      /* Calculate the Taylor series. */
      else
        {
          g = f * f;
          P = (p[1] * g + p[0]) * g;
          Q = g + q[0];
          R = P / Q;

          res = f + f * R;
        }

      if (N > 1)
        res = -res;

      res += a[N];
    }

  if (arctan2)
    {
      if (u < 0.0 || branch == 2)
        res = __PI - res;
      if (v < 0.0 || branch == 1)
        res = -res;
    }
  else if (x < 0.0)
    {
      res = -res;
    }

  return (res);
}
import newlib-2000-02-17 snapshot 2000-02-18 03:39:52 +08:00
			`/* @(#)z_atangentf.c 1.0 98/08/13 */`
			`/******************************************************************`
			`* The following routines are coded directly from the algorithms`
			`* and coefficients given in "Software Manual for the Elementary`
			`* Functions" by William J. Cody, Jr. and William Waite, Prentice`
			`* Hall, 1980.`
			`******************************************************************/`
			`/******************************************************************`
			`* Arctangent`
			`*`
			`* Input:`
			`* x - floating point value`
			`*`
			`* Output:`
			`* arctangent of x`
			`*`
			`* Description:`
			`* This routine calculates arctangents.`
			`*`
			`*****************************************************************/`

			`#include <float.h>`
			`#include "fdlibm.h"`
			`#include "zmath.h"`

			`static const float ROOT3 = 1.732050807;`
			`static const float a[] = { 0.0, 0.523598775, 1.570796326,`
			`1.047197551 };`
			`static const float q[] = { 0.1412500740e+1 };`
			`static const float p[] = { -0.4708325141, -0.5090958253e-1 };`

			`float`
			`_DEFUN (atangentf, (float, float, float, int),`
			`float x _AND`
			`float v _AND`
			`float u _AND`
			`int arctan2)`
			`{`
			`float f, g, R, P, Q, A, res;`
			`int N;`
			`int branch = 0;`
			`int expv, expu;`

			`/* Preparation for calculating arctan2. */`
			`if (arctan2)`
			`{`
			`if (u == 0.0)`
			`if (v == 0.0)`
			`{`
			`errno = ERANGE;`
			`return (z_notanum_f.f);`
			`}`
			`else`
			`{`
			`branch = 1;`
			`res = __PI_OVER_TWO;`
			`}`

			`if (!branch)`
			`{`
			`int e;`
			`/* Get the exponent values of the inputs. */`
			`g = frexpf (v, &expv);`
			`g = frexpf (u, &expu);`

			`/* See if a divide will overflow. */`
			`e = expv - expu;`
			`if (e > FLT_MAX_EXP)`
			`{`
			`branch = 1;`
			`res = __PI_OVER_TWO;`
			`}`

			`/* Also check for underflow. */`
			`else if (e < FLT_MIN_EXP)`
			`{`
			`branch = 2;`
			`res = 0.0;`
			`}`
			`}`
			`}`

			`if (!branch)`
			`{`
			`if (arctan2)`
			`f = fabsf (v / u);`
			`else`
			`f = fabsf (x);`

			`if (f > 1.0)`
			`{`
			`f = 1.0 / f;`
			`N = 2;`
			`}`
			`else`
			`N = 0;`

			`if (f > (2.0 - ROOT3))`
			`{`
			`A = ROOT3 - 1.0;`
			`f = (((A * f - 0.5) - 0.5) + f) / (ROOT3 + f);`
			`N++;`
			`}`

			`/* Check for values that are too small. */`
			`if (-z_rooteps_f < f && f < z_rooteps_f)`
			`res = f;`

			`/* Calculate the Taylor series. */`
			`else`
			`{`
			`g = f * f;`
			`P = (p[1] * g + p[0]) * g;`
			`Q = g + q[0];`
			`R = P / Q;`

			`res = f + f * R;`
			`}`

			`if (N > 1)`
			`res = -res;`

			`res += a[N];`
			`}`

			`if (arctan2)`
			`{`
			`if (u < 0.0 \|\| branch == 2)`
			`res = __PI - res;`
			`if (v < 0.0 \|\| branch == 1)`
			`res = -res;`
			`}`
			`else if (x < 0.0)`
			`{`
			`res = -res;`
			`}`

			`return (res);`
			`}`