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/*
 * IBM Accurate Mathematical Library
 * written by International Business Machines Corp.
 * Copyright (C) 2001, 2011 Free Software Foundation
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU Lesser General Public License as published by
 * the Free Software Foundation; either version 2.1 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 Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public License
 * along with this program; if not, see <http://www.gnu.org/licenses/>.
 */
/************************************************************************/
/*  MODULE_NAME: atnat2.c                                               */
/*                                                                      */
/*  FUNCTIONS: uatan2                                                   */
/*             atan2Mp                                                  */
/*             signArctan2                                              */
/*             normalized                                               */
/*                                                                      */
/*  FILES NEEDED: dla.h endian.h mpa.h mydefs.h atnat2.h                */
/*                mpatan.c mpatan2.c mpsqrt.c                           */
/*                uatan.tbl                                             */
/*                                                                      */
/* An ultimate atan2() routine. Given two IEEE double machine numbers y,*/
/* x it computes the correctly rounded (to nearest) value of atan2(y,x).*/
/*                                                                      */
/* Assumption: Machine arithmetic operations are performed in           */
/* round to nearest mode of IEEE 754 standard.                          */
/*                                                                      */
/************************************************************************/

#include <dla.h>
#include "mpa.h"
#include "MathLib.h"
#include "uatan.tbl"
#include "atnat2.h"
#include "math_private.h"

#ifndef SECTION
# define SECTION
#endif

/************************************************************************/
/* An ultimate atan2 routine. Given two IEEE double machine numbers y,x */
/* it computes the correctly rounded (to nearest) value of atan2(y,x).  */
/* Assumption: Machine arithmetic operations are performed in           */
/* round to nearest mode of IEEE 754 standard.                          */
/************************************************************************/
static double atan2Mp(double ,double ,const int[]);
  /* Fix the sign and return after stage 1 or stage 2 */
static double signArctan2(double y,double z)
{
  return __copysign(z, y);
}
static double normalized(double ,double,double ,double);
void __mpatan2(mp_no *,mp_no *,mp_no *,int);

double
SECTION
__ieee754_atan2(double y,double x) {

  int i,de,ux,dx,uy,dy;
#if 0
  int p;
#endif
  static const int pr[MM]={6,8,10,20,32};
  double ax,ay,u,du,u9,ua,v,vv,dv,t1,t2,t3,t7,t8,
	 z,zz,cor,s1,ss1,s2,ss2;
#ifndef DLA_FMS
  double t4,t5,t6;
#endif
#if 0
  double z1,z2;
#endif
  number num;
#if 0
  mp_no mperr,mpt1,mpx,mpy,mpz,mpz1,mpz2;
#endif

  static const int ep= 59768832,   /*  57*16**5   */
		   em=-59768832;   /* -57*16**5   */

  /* x=NaN or y=NaN */
  num.d = x;  ux = num.i[HIGH_HALF];  dx = num.i[LOW_HALF];
  if   ((ux&0x7ff00000)    ==0x7ff00000) {
    if (((ux&0x000fffff)|dx)!=0x00000000) return x+x; }
  num.d = y;  uy = num.i[HIGH_HALF];  dy = num.i[LOW_HALF];
  if   ((uy&0x7ff00000)    ==0x7ff00000) {
    if (((uy&0x000fffff)|dy)!=0x00000000) return y+y; }

  /* y=+-0 */
  if      (uy==0x00000000) {
    if    (dy==0x00000000) {
      if  ((ux&0x80000000)==0x00000000)  return ZERO;
      else                               return opi.d; } }
  else if (uy==0x80000000) {
    if    (dy==0x00000000) {
      if  ((ux&0x80000000)==0x00000000)  return MZERO;
      else                               return mopi.d;} }

  /* x=+-0 */
  if (x==ZERO) {
    if ((uy&0x80000000)==0x00000000)     return hpi.d;
    else                                 return mhpi.d; }

  /* x=+-INF */
  if          (ux==0x7ff00000) {
    if        (dx==0x00000000) {
      if      (uy==0x7ff00000) {
	if    (dy==0x00000000)  return qpi.d; }
      else if (uy==0xfff00000) {
	if    (dy==0x00000000)  return mqpi.d; }
      else {
	if    ((uy&0x80000000)==0x00000000)  return ZERO;
	else                                 return MZERO; }
    }
  }
  else if     (ux==0xfff00000) {
    if        (dx==0x00000000) {
      if      (uy==0x7ff00000) {
	if    (dy==0x00000000)  return tqpi.d; }
      else if (uy==0xfff00000) {
	if    (dy==0x00000000)  return mtqpi.d; }
      else                     {
	if    ((uy&0x80000000)==0x00000000)  return opi.d;
	else                                 return mopi.d; }
    }
  }

  /* y=+-INF */
  if      (uy==0x7ff00000) {
    if    (dy==0x00000000)  return hpi.d; }
  else if (uy==0xfff00000) {
    if    (dy==0x00000000)  return mhpi.d; }

  /* either x/y or y/x is very close to zero */
  ax = (x<ZERO) ? -x : x;    ay = (y<ZERO) ? -y : y;
  de = (uy & 0x7ff00000) - (ux & 0x7ff00000);
  if      (de>=ep)  { return ((y>ZERO) ? hpi.d : mhpi.d); }
  else if (de<=em)  {
    if    (x>ZERO)  {
      if  ((z=ay/ax)<TWOM1022)  return normalized(ax,ay,y,z);
      else                      return signArctan2(y,z); }
    else            { return ((y>ZERO) ? opi.d : mopi.d); } }

  /* if either x or y is extremely close to zero, scale abs(x), abs(y). */
  if (ax<twom500.d || ay<twom500.d) { ax*=two500.d;  ay*=two500.d; }

  /* x,y which are neither special nor extreme */
  if (ay<ax) {
    u=ay/ax;
    EMULV(ax,u,v,vv,t1,t2,t3,t4,t5)
    du=((ay-v)-vv)/ax; }
  else {
    u=ax/ay;
    EMULV(ay,u,v,vv,t1,t2,t3,t4,t5)
    du=((ax-v)-vv)/ay; }

  if (x>ZERO) {

    /* (i)   x>0, abs(y)< abs(x):  atan(ay/ax) */
    if (ay<ax) {
      if (u<inv16.d) {
	v=u*u;  zz=du+u*v*(d3.d+v*(d5.d+v*(d7.d+v*(d9.d+v*(d11.d+v*d13.d)))));
	if ((z=u+(zz-u1.d*u)) == u+(zz+u1.d*u))  return signArctan2(y,z);

	MUL2(u,du,u,du,v,vv,t1,t2,t3,t4,t5,t6,t7,t8)
	s1=v*(f11.d+v*(f13.d+v*(f15.d+v*(f17.d+v*f19.d))));
	ADD2(f9.d,ff9.d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f7.d,ff7.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f5.d,ff5.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f3.d,ff3.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	MUL2(u,du,s1,ss1,s2,ss2,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(u,du,s2,ss2,s1,ss1,t1,t2)
	if ((z=s1+(ss1-u5.d*s1)) == s1+(ss1+u5.d*s1))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
      else {
	i=(TWO52+TWO8*u)-TWO52;  i-=16;
	t3=u-cij[i][0].d;
	EADD(t3,du,v,dv)
	t1=cij[i][1].d;  t2=cij[i][2].d;
	zz=v*t2+(dv*t2+v*v*(cij[i][3].d+v*(cij[i][4].d+
			 v*(cij[i][5].d+v* cij[i][6].d))));
	if (i<112) {
	  if (i<48)  u9=u91.d;    /* u < 1/4        */
	  else       u9=u92.d; }  /* 1/4 <= u < 1/2 */
	else {
	  if (i<176) u9=u93.d;    /* 1/2 <= u < 3/4 */
	  else       u9=u94.d; }  /* 3/4 <= u <= 1  */
	if ((z=t1+(zz-u9*t1)) == t1+(zz+u9*t1))  return signArctan2(y,z);

	t1=u-hij[i][0].d;
	EADD(t1,du,v,vv)
	s1=v*(hij[i][11].d+v*(hij[i][12].d+v*(hij[i][13].d+
	   v*(hij[i][14].d+v* hij[i][15].d))));
	ADD2(hij[i][9].d,hij[i][10].d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][7].d,hij[i][8].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][5].d,hij[i][6].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][3].d,hij[i][4].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][1].d,hij[i][2].d,s1,ss1,s2,ss2,t1,t2)
	if ((z=s2+(ss2-ub.d*s2)) == s2+(ss2+ub.d*s2))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
    }

    /* (ii)  x>0, abs(x)<=abs(y):  pi/2-atan(ax/ay) */
    else {
      if (u<inv16.d) {
	v=u*u;
	zz=u*v*(d3.d+v*(d5.d+v*(d7.d+v*(d9.d+v*(d11.d+v*d13.d)))));
	ESUB(hpi.d,u,t2,cor)
	t3=((hpi1.d+cor)-du)-zz;
	if ((z=t2+(t3-u2.d)) == t2+(t3+u2.d))  return signArctan2(y,z);

	MUL2(u,du,u,du,v,vv,t1,t2,t3,t4,t5,t6,t7,t8)
	s1=v*(f11.d+v*(f13.d+v*(f15.d+v*(f17.d+v*f19.d))));
	ADD2(f9.d,ff9.d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f7.d,ff7.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f5.d,ff5.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f3.d,ff3.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	MUL2(u,du,s1,ss1,s2,ss2,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(u,du,s2,ss2,s1,ss1,t1,t2)
	SUB2(hpi.d,hpi1.d,s1,ss1,s2,ss2,t1,t2)
	if ((z=s2+(ss2-u6.d)) == s2+(ss2+u6.d))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
      else {
	i=(TWO52+TWO8*u)-TWO52;  i-=16;
	v=(u-cij[i][0].d)+du;
	zz=hpi1.d-v*(cij[i][2].d+v*(cij[i][3].d+v*(cij[i][4].d+
				 v*(cij[i][5].d+v* cij[i][6].d))));
	t1=hpi.d-cij[i][1].d;
	if (i<112)  ua=ua1.d;  /* w <  1/2 */
	else        ua=ua2.d;  /* w >= 1/2 */
	if ((z=t1+(zz-ua)) == t1+(zz+ua))  return signArctan2(y,z);

	t1=u-hij[i][0].d;
	EADD(t1,du,v,vv)
	s1=v*(hij[i][11].d+v*(hij[i][12].d+v*(hij[i][13].d+
	   v*(hij[i][14].d+v* hij[i][15].d))));
	ADD2(hij[i][9].d,hij[i][10].d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][7].d,hij[i][8].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][5].d,hij[i][6].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][3].d,hij[i][4].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][1].d,hij[i][2].d,s1,ss1,s2,ss2,t1,t2)
	SUB2(hpi.d,hpi1.d,s2,ss2,s1,ss1,t1,t2)
	if ((z=s1+(ss1-uc.d)) == s1+(ss1+uc.d))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
    }
  }
  else {

    /* (iii) x<0, abs(x)< abs(y):  pi/2+atan(ax/ay) */
    if (ax<ay) {
      if (u<inv16.d) {
	v=u*u;
	zz=u*v*(d3.d+v*(d5.d+v*(d7.d+v*(d9.d+v*(d11.d+v*d13.d)))));
	EADD(hpi.d,u,t2,cor)
	t3=((hpi1.d+cor)+du)+zz;
	if ((z=t2+(t3-u3.d)) == t2+(t3+u3.d))  return signArctan2(y,z);

	MUL2(u,du,u,du,v,vv,t1,t2,t3,t4,t5,t6,t7,t8)
	s1=v*(f11.d+v*(f13.d+v*(f15.d+v*(f17.d+v*f19.d))));
	ADD2(f9.d,ff9.d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f7.d,ff7.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f5.d,ff5.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f3.d,ff3.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	MUL2(u,du,s1,ss1,s2,ss2,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(u,du,s2,ss2,s1,ss1,t1,t2)
	ADD2(hpi.d,hpi1.d,s1,ss1,s2,ss2,t1,t2)
	if ((z=s2+(ss2-u7.d)) == s2+(ss2+u7.d))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
      else {
	i=(TWO52+TWO8*u)-TWO52;  i-=16;
	v=(u-cij[i][0].d)+du;
	zz=hpi1.d+v*(cij[i][2].d+v*(cij[i][3].d+v*(cij[i][4].d+
				 v*(cij[i][5].d+v* cij[i][6].d))));
	t1=hpi.d+cij[i][1].d;
	if (i<112)  ua=ua1.d;  /* w <  1/2 */
	else        ua=ua2.d;  /* w >= 1/2 */
	if ((z=t1+(zz-ua)) == t1+(zz+ua))  return signArctan2(y,z);

	t1=u-hij[i][0].d;
	EADD(t1,du,v,vv)
	s1=v*(hij[i][11].d+v*(hij[i][12].d+v*(hij[i][13].d+
	   v*(hij[i][14].d+v* hij[i][15].d))));
	ADD2(hij[i][9].d,hij[i][10].d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][7].d,hij[i][8].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][5].d,hij[i][6].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][3].d,hij[i][4].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][1].d,hij[i][2].d,s1,ss1,s2,ss2,t1,t2)
	ADD2(hpi.d,hpi1.d,s2,ss2,s1,ss1,t1,t2)
	if ((z=s1+(ss1-uc.d)) == s1+(ss1+uc.d))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
    }

    /* (iv)  x<0, abs(y)<=abs(x):  pi-atan(ax/ay) */
    else {
      if (u<inv16.d) {
	v=u*u;
	zz=u*v*(d3.d+v*(d5.d+v*(d7.d+v*(d9.d+v*(d11.d+v*d13.d)))));
	ESUB(opi.d,u,t2,cor)
	t3=((opi1.d+cor)-du)-zz;
	if ((z=t2+(t3-u4.d)) == t2+(t3+u4.d))  return signArctan2(y,z);

	MUL2(u,du,u,du,v,vv,t1,t2,t3,t4,t5,t6,t7,t8)
	s1=v*(f11.d+v*(f13.d+v*(f15.d+v*(f17.d+v*f19.d))));
	ADD2(f9.d,ff9.d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f7.d,ff7.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f5.d,ff5.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(f3.d,ff3.d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	MUL2(u,du,s1,ss1,s2,ss2,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(u,du,s2,ss2,s1,ss1,t1,t2)
	SUB2(opi.d,opi1.d,s1,ss1,s2,ss2,t1,t2)
	if ((z=s2+(ss2-u8.d)) == s2+(ss2+u8.d))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
      else {
	i=(TWO52+TWO8*u)-TWO52;  i-=16;
	v=(u-cij[i][0].d)+du;
	zz=opi1.d-v*(cij[i][2].d+v*(cij[i][3].d+v*(cij[i][4].d+
				 v*(cij[i][5].d+v* cij[i][6].d))));
	t1=opi.d-cij[i][1].d;
	if (i<112)  ua=ua1.d;  /* w <  1/2 */
	else        ua=ua2.d;  /* w >= 1/2 */
	if ((z=t1+(zz-ua)) == t1+(zz+ua))  return signArctan2(y,z);

	t1=u-hij[i][0].d;
	EADD(t1,du,v,vv)
	s1=v*(hij[i][11].d+v*(hij[i][12].d+v*(hij[i][13].d+
	   v*(hij[i][14].d+v* hij[i][15].d))));
	ADD2(hij[i][9].d,hij[i][10].d,s1,ZERO,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][7].d,hij[i][8].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][5].d,hij[i][6].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][3].d,hij[i][4].d,s1,ss1,s2,ss2,t1,t2)
	MUL2(v,vv,s2,ss2,s1,ss1,t1,t2,t3,t4,t5,t6,t7,t8)
	ADD2(hij[i][1].d,hij[i][2].d,s1,ss1,s2,ss2,t1,t2)
	SUB2(opi.d,opi1.d,s2,ss2,s1,ss1,t1,t2)
	if ((z=s1+(ss1-uc.d)) == s1+(ss1+uc.d))  return signArctan2(y,z);
	return atan2Mp(x,y,pr);
      }
    }
  }
}
#ifndef __ieee754_atan2
strong_alias (__ieee754_atan2, __atan2_finite)
#endif

  /* Treat the Denormalized case */
static double
SECTION
normalized(double ax,double ay,double y, double z)
    { int p;
      mp_no mpx,mpy,mpz,mperr,mpz2,mpt1;
  p=6;
  __dbl_mp(ax,&mpx,p);  __dbl_mp(ay,&mpy,p);  __dvd(&mpy,&mpx,&mpz,p);
  __dbl_mp(ue.d,&mpt1,p);   __mul(&mpz,&mpt1,&mperr,p);
  __sub(&mpz,&mperr,&mpz2,p);  __mp_dbl(&mpz2,&z,p);
  return signArctan2(y,z);
}
  /* Stage 3: Perform a multi-Precision computation */
static double
SECTION
atan2Mp(double x,double y,const int pr[])
{
  double z1,z2;
  int i,p;
  mp_no mpx,mpy,mpz,mpz1,mpz2,mperr,mpt1;
  for (i=0; i<MM; i++) {
    p = pr[i];
    __dbl_mp(x,&mpx,p);  __dbl_mp(y,&mpy,p);
    __mpatan2(&mpy,&mpx,&mpz,p);
    __dbl_mp(ud[i].d,&mpt1,p);   __mul(&mpz,&mpt1,&mperr,p);
    __add(&mpz,&mperr,&mpz1,p);  __sub(&mpz,&mperr,&mpz2,p);
    __mp_dbl(&mpz1,&z1,p);       __mp_dbl(&mpz2,&z2,p);
    if (z1==z2)   return z1;
  }
  return z1; /*if unpossible to do exact computing */
}