1 /*
   2  * CDDL HEADER START
   3  *
   4  * The contents of this file are subject to the terms of the
   5  * Common Development and Distribution License (the "License").
   6  * You may not use this file except in compliance with the License.
   7  *
   8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
   9  * or http://www.opensolaris.org/os/licensing.
  10  * See the License for the specific language governing permissions
  11  * and limitations under the License.
  12  *
  13  * When distributing Covered Code, include this CDDL HEADER in each
  14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
  15  * If applicable, add the following below this CDDL HEADER, with the
  16  * fields enclosed by brackets "[]" replaced with your own identifying
  17  * information: Portions Copyright [yyyy] [name of copyright owner]
  18  *
  19  * CDDL HEADER END
  20  */
  21 /*
  22  * Copyright 2011 Nexenta Systems, Inc.  All rights reserved.
  23  */
  24 /*
  25  * Copyright 2005 Sun Microsystems, Inc.  All rights reserved.
  26  * Use is subject to license terms.
  27  */
  28 
  29 #include "libm.h"               /* __k_atan2 */
  30 #include "complex_wrapper.h"
  31 
  32 /*
  33  * double __k_atan2(double y, double x, double *e)
  34  *
  35  * Compute atan2 with error terms.
  36  *
  37  * Important formula:
  38  *                  3       5
  39  *                 x       x
  40  * atan(x) = x - ----- + ----- - ...    (for x <= 1)
  41  *                 3       5
  42  *
  43  *           pi     1     1
  44  *         = --- - --- + --- - ...      (for x > 1)
  45  *                         3
  46  *            2     x    3x
  47  *
  48  * Arg(x + y i) = sign(y) * atan2(|y|, x)
  49  *              = sign(y) * atan(|y|/x)           (for x > 0)
  50  *                sign(y) * (PI - atan(|y|/|x|))  (for x < 0)
  51  * Thus if x >> y (IEEE double: EXP(x) - EXP(y) >= 60):
  52  *      1. (x > 0): atan2(y,x) ~ y/x
  53  *      2. (x < 0): atan2(y,x) ~ sign(y) (PI - |y/x|))
  54  * Otherwise if x << y:
  55  *      atan2(y,x) ~ sign(y)*PI/2 - x/y
  56  *
  57  * __k_atan2 call static functions mx_poly, mx_atan
  58  */
  59 
  60 /*
  61  * (void) mx_poly (double *z, double *a, double *e, int n)
  62  * return
  63  *      e = a  + z*(a  + z*(a  + ... z*(a  + e)...))
  64  *           0       2       4           2n
  65  * Note:
  66  * 1.   e and coefficient ai are represented by two double numbers.
  67  *      For e, the first one contain the leading 24 bits rounded, and the
  68  *      second one contain the remaining 53 bits (total 77 bits accuracy).
  69  *      For ai, the first one contian the leading 53 bits rounded, and the
  70  *      second is the remaining 53 bits (total 106 bits accuracy).
  71  * 2.   z is an array of three doubles.
  72  *      z[0] :  the rounded value of Z (the intended value of z)
  73  *      z[1] :  the leading 24 bits of Z rounded
  74  *      z[2] :  the remaining 53 bits of Z
  75  *              Note that z[0] = z[1]+z[2] rounded.
  76  *
  77  */
  78 
  79 static void
  80 mx_poly(const double *z, const double *a, double *e, int n) {
  81         double r, s, t, p_h, p_l, z_h, z_l, p;
  82         int i;
  83 
  84         n = n + n;
  85         p = e[0] + a[n];
  86         p_l = a[n + 1];
  87         p_h = (double) ((float) p);
  88         p   = a[n - 2] + z[0] * p;
  89         z_h = z[1]; z_l = z[2];
  90         p_l += e[0] - (p_h - a[n]);
  91 
  92         for (i = n - 2; i >= 2; i -= 2) {
  93         /* compute p = ai + z * p */
  94                 t   = z_h * p_h;
  95                 s   = z[0] * p_l + p_h * z_l;
  96                 p_h = (double) ((float) p);
  97                 s  += a[i + 1];
  98                 r   = t - (p_h - a[i]);
  99                 p   = a[i - 2] + z[0] * p;
 100                 p_l = r + s;
 101         }
 102         e[0] = (double)((float) p);
 103         t   = z_h * p_h;
 104         s   = z[0] * p_l + p_h * z_l;
 105         r   = t - (e[0] - a[0]);
 106         e[1] = r + s;
 107 }
 108 
 109 /*
 110  * Table of constants for atan from 0.125 to 8
 111  *      0.125 -- 0x3fc00000  --- (increment at bit 16)
 112  *               0x3fc10000
 113  *               0x3fc20000
 114  *      ...     ...
 115  *               0x401f0000
 116  *      8.000 -- 0x40200000      (total: 97)
 117  * By K.C. Ng, March 9, 1989
 118  */
 119 
 120 static const double TBL_atan_hi[] = {
 121 1.243549945467614382e-01, 1.320397616146387620e-01, 1.397088742891636204e-01,
 122 1.473614810886516302e-01, 1.549967419239409727e-01, 1.626138285979485676e-01,
 123 1.702119252854744080e-01, 1.777902289926760471e-01, 1.853479499956947607e-01,
 124 1.928843122579746439e-01, 2.003985538258785115e-01, 2.078899272022629863e-01,
 125 2.153576996977380476e-01, 2.228011537593945213e-01, 2.302195872768437179e-01,
 126 2.376123138654712419e-01, 2.449786631268641435e-01, 2.596296294082575118e-01,
 127 2.741674511196587893e-01, 2.885873618940774099e-01, 3.028848683749714166e-01,
 128 3.170557532091470287e-01, 3.310960767041321029e-01, 3.450021772071051318e-01,
 129 3.587706702705721895e-01, 3.723984466767542023e-01, 3.858826693980737521e-01,
 130 3.992207695752525431e-01, 4.124104415973872673e-01, 4.254496373700422662e-01,
 131 4.383365598579578304e-01, 4.510696559885234436e-01, 4.636476090008060935e-01,
 132 4.883339510564055352e-01, 5.123894603107377321e-01, 5.358112379604637043e-01,
 133 5.585993153435624414e-01, 5.807563535676704136e-01, 6.022873461349641522e-01,
 134 6.231993299340659043e-01, 6.435011087932843710e-01, 6.632029927060932861e-01,
 135 6.823165548747480713e-01, 7.008544078844501923e-01, 7.188299996216245269e-01,
 136 7.362574289814280970e-01, 7.531512809621944138e-01, 7.695264804056582975e-01,
 137 7.853981633974482790e-01, 8.156919233162234217e-01, 8.441539861131710509e-01,
 138 8.709034570756529758e-01, 8.960553845713439269e-01, 9.197196053504168578e-01,
 139 9.420000403794636101e-01, 9.629943306809362058e-01, 9.827937232473290541e-01,
 140 1.001483135694234639e+00, 1.019141344266349725e+00, 1.035841253008800145e+00,
 141 1.051650212548373764e+00, 1.066630365315743623e+00, 1.080839000541168327e+00,
 142 1.094328907321189925e+00, 1.107148717794090409e+00, 1.130953743979160375e+00,
 143 1.152571997215667610e+00, 1.172273881128476303e+00, 1.190289949682531656e+00,
 144 1.206817370285252489e+00, 1.222025323210989667e+00, 1.236059489478081863e+00,
 145 1.249045772398254428e+00, 1.261093382252440387e+00, 1.272297395208717319e+00,
 146 1.282740879744270757e+00, 1.292496667789785336e+00, 1.301628834009196156e+00,
 147 1.310193935047555547e+00, 1.318242051016837113e+00, 1.325817663668032553e+00,
 148 1.339705659598999565e+00, 1.352127380920954636e+00, 1.363300100359693845e+00,
 149 1.373400766945015894e+00, 1.382574821490125894e+00, 1.390942827002418447e+00,
 150 1.398605512271957618e+00, 1.405647649380269870e+00, 1.412141064608495311e+00,
 151 1.418146998399631542e+00, 1.423717971406494032e+00, 1.428899272190732761e+00,
 152 1.433730152484709031e+00, 1.438244794498222623e+00, 1.442473099109101931e+00,
 153 1.446441332248135092e+00,
 154 };
 155 
 156 static const double TBL_atan_lo[] = {
 157 -3.125324142453938311e-18, -1.276925400709959526e-17, 2.479758919089733066e-17,
 158 5.409599147666297957e-18, 9.585415594114323829e-18, 7.784470643106252464e-18,
 159 -3.541164079802125137e-18, 2.372599351477449041e-17, 4.180692268843078977e-18,
 160 2.034098543938166622e-17, 3.139954287184449286e-18, 7.333160666520898500e-18,
 161 4.738160130078732886e-19, -5.498822172446843173e-18, 1.231340452914270316e-17,
 162 1.058231431371112987e-17, 1.069875561873445139e-17, 1.923875492461530410e-17,
 163 8.261353575163771936e-18, -1.428369957377257085e-17, -1.101082790300136900e-17,
 164 -1.893928924292642146e-17, -7.952610375793798701e-18, -2.293880475557830393e-17,
 165 3.088733564861919217e-17, 1.961231150484565340e-17, 2.378822732491940868e-17,
 166 2.246598105617042065e-17, 3.963462895355093301e-17, 2.331553074189288466e-17,
 167 -2.494277030626540909e-17, 3.280735600183735558e-17, 2.269877745296168709e-17,
 168 -1.137323618932958456e-17, -2.546278147285580353e-17, -4.063795683482557497e-18,
 169 -5.455630548591626394e-18, -1.441464378193066908e-17, 2.950430737228402307e-17,
 170 2.672403885140095079e-17, 1.583478505144428617e-17, -3.076054864429649001e-17,
 171 6.943223671560007740e-18, -1.987626234335816123e-17, -2.147838844445698302e-17,
 172 3.473937648299456719e-17, -2.425693465918206812e-17, -3.704991905602721293e-17,
 173 3.061616997868383018e-17, -1.071456562778743077e-17, -4.841337011934916763e-17,
 174 -2.269823590747287052e-17, 2.923876285774304890e-17, -4.057439412852767923e-17,
 175 5.460837485846687627e-17, -3.986660595210752445e-18, 1.390331103123099845e-17,
 176 9.438308023545392000e-17, 1.000401886936679889e-17, 3.194313981784503706e-17,
 177 -9.650564731467513515e-17, -5.956589637160374564e-17, -1.567632251135907253e-17,
 178 -5.490676155022364226e-18, 9.404471373566379412e-17, 7.123833804538446299e-17,
 179 -9.159738508900378819e-17, 8.385188614028674371e-17, 7.683333629842068806e-17,
 180 4.172467638861439118e-17, -2.979162864892849274e-17, 7.879752739459421280e-17,
 181 -2.196203799612310905e-18, 3.242139621534960503e-17, 2.245875015034507026e-17,
 182 -9.283188754266129476e-18, -6.830804768926660334e-17, -1.236918499824626670e-17,
 183 8.745413734780278834e-17, -6.319394031144676258e-17, -8.824429373951136321e-17,
 184 -2.599011860304134377e-17, 2.147674250751150961e-17, 1.093246171526936217e-16,
 185 -3.307710355769516504e-17, -3.561490438648230100e-17, -9.843712133488842595e-17,
 186 -2.324061182591627982e-17, -8.922630138234492386e-17, -9.573807110557223276e-17,
 187 -8.263883782511013632e-17, 8.721870922223967507e-17, -6.457134743238754385e-17,
 188 -4.396204466767636187e-17, -2.493019910264565554e-17, -1.105119435430315713e-16,
 189 9.211323971545051565e-17,
 190 };
 191 
 192 /*
 193  * mx_atan(x,err)
 194  * Table look-up algorithm
 195  * By K.C. Ng, March 9, 1989
 196  *
 197  * Algorithm.
 198  *
 199  * The algorithm is based on atan(x)=atan(y)+atan((x-y)/(1+x*y)).
 200  * We use poly1(x) to approximate atan(x) for x in [0,1/8] with
 201  * error (relative)
 202  *      |(atan(x)-poly1(x))/x|<= 2^-83.41
 203  *
 204  * and use poly2(x) to approximate atan(x) for x in [0,1/65] with
 205  * error
 206  *      |atan(x)-poly2(x)|<= 2^-86.8
 207  *
 208  * Here poly1 and poly2 are odd polynomial with the following form:
 209  *              x + x^3*(a1+x^2*(a2+...))
 210  *
 211  * (0). Purge off Inf and NaN and 0
 212  * (1). Reduce x to positive by atan(x) = -atan(-x).
 213  * (2). For x <= 1/8, use
 214  *      (2.1) if x < 2^(-prec/2), atan(x) =  x  with inexact flag raised
 215  *      (2.2) Otherwise
 216  *              atan(x) = poly1(x)
 217  * (3). For x >= 8 then (prec = 78)
 218  *      (3.1) if x >= 2^prec,     atan(x) = atan(inf) - pio2lo
 219  *      (3.2) if x >= 2^(prec/3), atan(x) = atan(inf) - 1/x
 220  *      (3.3) if x >  65,         atan(x) = atan(inf) - poly2(1/x)
 221  *      (3.4) Otherwise,          atan(x) = atan(inf) - poly1(1/x)
 222  *
 223  * (4). Now x is in (0.125, 8)
 224  *      Find y that match x to 4.5 bit after binary (easy).
 225  *      If iy is the high word of y, then
 226  *              single : j = (iy - 0x3e000000) >> 19
 227  *              double : j = (iy - 0x3fc00000) >> 16
 228  *              quad   : j = (iy - 0x3ffc0000) >> 12
 229  *
 230  *      Let s = (x-y)/(1+x*y). Then
 231  *      atan(x) = atan(y) + poly1(s)
 232  *              = _TBL_atan_hi[j] + (_TBL_atan_lo[j] + poly2(s) )
 233  *
 234  *      Note. |s| <= 1.5384615385e-02 = 1/65. Maxium occurs at x = 1.03125
 235  *
 236  */
 237 
 238 #define P1 p[2]
 239 #define P4 p[8]
 240 #define P5 p[9]
 241 #define P6 p[10]
 242 #define P7 p[11]
 243 #define P8 p[12]
 244 #define P9 p[13]
 245 static const double p[] = {
 246         1.0,
 247         0.0,
 248         -3.33333333333333314830e-01,    /* p1   = BFD55555 55555555 */
 249         -1.85030852238476921863e-17,    /* p1_l = BC755525 9783A49C */
 250         2.00000000000000011102e-01,     /* p2   = 3FC99999 9999999A */
 251         -1.27263196576150347368e-17,    /* p2_l = BC6D584B 0D874007 */
 252         -1.42857142857141405923e-01,    /* p3   = BFC24924 9249245E */
 253         -1.34258204847170493327e-17,    /* p3_l = BC6EF534 A112500D */
 254         1.11111111110486909803e-01,     /* p4   = 3FBC71C7 1C71176A */
 255         -9.09090907557387889470e-02,    /* p5   = BFB745D1 73B47A7D */
 256         7.69230541541713053189e-02,     /* p6   = 3FB3B13A B1E68DE6 */
 257         -6.66645815401964159097e-02,    /* p7   = BFB110EE 1584446A */
 258         5.87081768778560317279e-02,     /* p8   = 3FAE0EFF 87657733 */
 259         -4.90818147456113240690e-02,    /* p9   = BFA92140 6A524B5C */
 260 };
 261 #define Q1 q[2]
 262 #define Q3 q[6]
 263 #define Q4 q[7]
 264 #define Q5 q[8]
 265 static const double q[] = {
 266         1.0,
 267         0.0,
 268         -3.33333333333333314830e-01,    /* q1   = BFD55555 55555555 */
 269         -1.85022941571278638733e-17,    /* q1_l = BC7554E9 D20EFA66 */
 270         1.99999999999999927836e-01,     /* q2   = 3FC99999 99999997 */
 271         -1.28782564407438833398e-17,    /* q2_l = BC6DB1FB 17217417 */
 272         -1.42857142855492280642e-01,    /* q3   = BFC24924 92483C46 */
 273         1.11111097130183356096e-01,     /* q4   = 3FBC71C6 E06595CC */
 274         -9.08553303569109294013e-02,    /* q5   = BFB7424B 808CDA76 */
 275 };
 276 static const double
 277 one = 1.0,
 278 pio2hi = 1.570796326794896558e+00,
 279 pio2lo = 6.123233995736765886e-17;
 280 
 281 static double
 282 mx_atan(double x, double *err) {
 283         double y, z, r, s, t, w, s_h, s_l, x_h, x_l, zz[3], ee[2], z_h,
 284                 z_l, r_h, r_l, u, v;
 285         int ix, iy, sign, j;
 286 
 287         ix = ((int *) &x)[HIWORD];
 288         sign = ix & 0x80000000;
 289         ix ^= sign;
 290 
 291         /* for |x| < 1/8 */
 292         if (ix < 0x3fc00000) {
 293                 if (ix < 0x3f300000) {       /* when |x| < 2**-12 */
 294                         if (ix < 0x3d800000) {       /* if |x| < 2**-39 */
 295                                 *err = (double) ((int) x);
 296                                 return (x);
 297                         }
 298                         z = x * x;
 299                         t = x * z * (q[2] + z * (q[4] + z * q[6]));
 300                         r = x + t;
 301                         *err = t - (r - x);
 302                         return (r);
 303                 }
 304                 z = x * x;
 305 
 306                 /* use double precision at p4 and on */
 307                 ee[0] = z *
 308                         (P4 + z *
 309                         (P5 + z * (P6 + z * (P7 + z * (P8 + z * P9)))));
 310 
 311                 x_h = (double) ((float) x);
 312                 z_h = (double) ((float) z);
 313                 x_l = x - x_h;
 314                 z_l = (x_h * x_h - z_h);
 315                 zz[0] = z;
 316                 zz[1] = z_h;
 317                 zz[2] = z_l + x_l * (x + x_h);
 318 
 319                 /*
 320                  * compute (1+z*(p1+z*(p2+z*(p3+e)))) by call
 321                  * mx_poly
 322                  */
 323 
 324                 mx_poly(zz, p, ee, 3);
 325 
 326                 /* finally x*(1+z*(p1+...)) */
 327                 r = x_h * ee[0];
 328                 t = x * ee[1] + x_l * ee[0];
 329                 s = t + r;
 330                 *err = t - (s - r);
 331                 return (s);
 332         }
 333         /* for |x| >= 8.0 */
 334         if (ix >= 0x40200000) {      /* x >=  8 */
 335                 x = fabs(x);
 336                 if (ix >= 0x42600000) {      /* x >=  2**39 */
 337                         if (ix >= 0x44c00000) {      /* x >=  2**77 */
 338                                 y = -pio2lo;
 339                         } else
 340                                 y = one / x - pio2lo;
 341                         if (sign == 0) {
 342                                 t = pio2hi - y;
 343                                 *err = -(y - (pio2hi - t));
 344                         } else {
 345                                 t = y - pio2hi;
 346                                 *err = y - (pio2hi + t);
 347                         }
 348                         return (t);
 349                 } else {
 350                         /* compute r = 1/x */
 351                         r = one / x;
 352                         z = r * r;
 353                         if (ix < 0x40504000) {       /* 8 <  x <  65 */
 354 
 355                                 /* use double precision at p4 and on */
 356                                 ee[0] = z *
 357                                         (P4 + z *
 358                                         (P5 + z *
 359                                         (P6 + z * (P7 + z * (P8 + z * P9)))));
 360                                 x_h = (double) ((float) x);
 361                                 r_h = (double) ((float) r);
 362                                 z_h = (double) ((float) z);
 363                                 r_l = r * ((x_h - x) * r_h - (x_h * r_h - one));
 364                                 z_l = (r_h * r_h - z_h);
 365                                 zz[0] = z;
 366                                 zz[1] = z_h;
 367                                 zz[2] = z_l + r_l * (r + r_h);
 368                                 /*
 369                                  * compute (1+z*(p1+z*(p2+z*(p3+e)))) by call
 370                                  * mx_poly
 371                                  */
 372                                 mx_poly(zz, p, ee, 3);
 373                         } else { /* x < 65 < 2**39 */
 374                                 /* use double precision at q3 and on */
 375                                 ee[0] = z * (Q3 + z * (Q4 + z * Q5));
 376                                 x_h = (double) ((float) x);
 377                                 r_h = (double) ((float) r);
 378                                 z_h = (double) ((float) z);
 379                                 r_l = r * ((x_h - x) * r_h - (x_h * r_h - one));
 380                                 z_l = (r_h * r_h - z_h);
 381                                 zz[0] = z;
 382                                 zz[1] = z_h;
 383                                 zz[2] = z_l + r_l * (r + r_h);
 384                                 /*
 385                                  * compute (1+z*(q1+z*(q2+e))) by call
 386                                  * mx_poly
 387                                  */
 388                                 mx_poly(zz, q, ee, 2);
 389                         }
 390                         /* pio2 - r*(1+...) */
 391                         v = r_h * ee[0];
 392                         t = pio2lo - (r * ee[1] + r_l * ee[0]);
 393                         if (sign == 0) {
 394                                 s = pio2hi - v;
 395                                 t -= (v - (pio2hi - s));
 396                         } else {
 397                                 s = v - pio2hi;
 398                                 t = -(t - (v - (s + pio2hi)));
 399                         }
 400                         w = s + t;
 401                         *err = t - (w - s);
 402                         return (w);
 403                 }
 404         }
 405         /* now x is between 1/8 and 8 */
 406         ((int *) &x)[HIWORD] = ix;
 407         iy = (ix + 0x00008000) & 0x7fff0000;
 408         ((int *) &y)[HIWORD] = iy;
 409         ((int *) &y)[LOWORD] = 0;
 410         j = (iy - 0x3fc00000) >> 16;
 411 
 412         w = (x - y);
 413         v = 1 / (one + x * y);
 414         s = w * v;
 415         z = s * s;
 416         /* use double precision at q3 and on */
 417         ee[0] = z * (Q3 + z * (Q4 + z * Q5));
 418         s_h = (double) ((float) s);
 419         z_h = (double) ((float) z);
 420         x_h = (double) ((float) x);
 421         t = (double) ((float) (one + x * y));
 422         r = -((x_h - x) * y - (x_h * y - (t - one)));
 423         s_l = -v * (s_h * r - (w - s_h * t));
 424         z_l = (s_h * s_h - z_h);
 425         zz[0] = z;
 426         zz[1] = z_h;
 427         zz[2] = z_l + s_l * (s + s_h);
 428         /* compute (1+z*(q1+z*(q2+e))) by call mx_poly */
 429         mx_poly(zz, q, ee, 2);
 430         v = s_h * ee[0];
 431         t = TBL_atan_lo[j] + (s * ee[1] + s_l * ee[0]);
 432         u = TBL_atan_hi[j];
 433         s = u + v;
 434         t += (v - (s - u));
 435         w = s + t;
 436         *err = t - (w - s);
 437         if (sign != 0) {
 438                 w = -w;
 439                 *err = -*err;
 440         }
 441         return (w);
 442 }
 443 
 444 static const double
 445         twom768 = 6.441148769597133308e-232,    /* 2^-768 */
 446         two768  = 1.552518092300708935e+231,    /* 2^768 */
 447         pi = 3.1415926535897931159979634685,
 448         pi_lo = 1.224646799147353177e-16,
 449         pio2 = 1.570796326794896558e+00,
 450         pio2_lo = 6.123233995736765886e-17,
 451         pio4 = 0.78539816339744827899949,
 452         pio4_lo = 3.061616997868382943e-17,
 453         pi3o4 = 2.356194490192344836998,
 454         pi3o4_lo = 9.184850993605148829195e-17;
 455 
 456 double
 457 __k_atan2(double y, double x, double *w) {
 458         double t, xh, th, t1, t2, w1, w2;
 459         int ix, iy, hx, hy, lx, ly;
 460 
 461         hy = ((int *) &y)[HIWORD];
 462         ly = ((int *) &y)[LOWORD];
 463         iy = hy & ~0x80000000;
 464 
 465         hx = ((int *) &x)[HIWORD];
 466         lx = ((int *) &x)[LOWORD];
 467         ix = hx & ~0x80000000;
 468 
 469         *w = 0.0;
 470         if (ix >= 0x7ff00000 || iy >= 0x7ff00000) {       /* ignore inexact */
 471                 if (isnan(x) || isnan(y))
 472                         return (x * y);
 473                 else if (iy < 0x7ff00000) {
 474                         if (hx >= 0) {       /* ATAN2(+-finite, +inf) is +-0 */
 475                                 *w *= y;
 476                                 return (*w);
 477                         } else {        /* ATAN2(+-finite, -inf) is +-pi */
 478                                 *w = copysign(pi_lo, y);
 479                                 return (copysign(pi, y));
 480                         }
 481                 } else if (ix < 0x7ff00000) {
 482                                         /* ATAN2(+-inf, finite) is +-pi/2 */
 483                         *w = (hy >= 0)? pio2_lo : -pio2_lo;
 484                         return ((hy >= 0)? pio2 : -pio2);
 485                 } else if (hx > 0) { /* ATAN2(+-INF,+INF) = +-pi/4 */
 486                         *w = (hy >= 0)? pio4_lo : -pio4_lo;
 487                         return ((hy >= 0)? pio4 : -pio4);
 488                 } else {                /* ATAN2(+-INF,-INF) = +-3pi/4 */
 489                         *w = (hy >= 0)? pi3o4_lo : -pi3o4_lo;
 490                         return ((hy >= 0)? pi3o4 : -pi3o4);
 491                 }
 492         } else if ((ix | lx) == 0 || (iy | ly) == 0) {
 493                 if ((iy | ly) == 0) {
 494                         if (hx >= 0) /* ATAN2(+-0, +(0 <= x <= inf)) is +-0 */
 495                                 return (y);
 496                         else {  /* ATAN2(+-0, -(0 <= x <= inf)) is +-pi */
 497                                 *w = (hy >= 0)? pi_lo : -pi_lo;
 498                                 return ((hy >= 0)? pi : -pi);
 499                         }
 500                 } else { /* ATAN2(+-(anything but 0 and NaN), 0) is +-pi/2 */
 501                         *w = (hy >= 0)? pio2_lo : -pio2_lo;
 502                         return ((hy >= 0)? pio2 : -pio2);
 503                 }
 504         } else if (iy - ix > 0x06400000) { /* |x/y| < 2 ** -100 */
 505                 *w = (hy >= 0)? pio2_lo : -pio2_lo;
 506                 return ((hy >= 0)? pio2 : -pio2);
 507         } else if (ix - iy > 0x06400000) { /* |y/x| < 2 ** -100 */
 508                 if (hx < 0) {
 509                         *w = (hy >= 0)? pi_lo : -pi_lo;
 510                         return ((hy >= 0)? pi : -pi);
 511                 } else {
 512                         t = y / x;
 513                         th = t;
 514                         ((int *) &th)[LOWORD] &= 0xf8000000;
 515                         xh = x;
 516                         ((int *) &xh)[LOWORD] &= 0xf8000000;
 517                         t1 = (x - xh) * t + xh * (t - th);
 518                         t2 = y - xh * th;
 519                         *w = (t2 - t1) / x;
 520                         return (t);
 521                 }
 522         } else {
 523                 if (ix >= 0x5f300000) {
 524                         x *= twom768;
 525                         y *= twom768;
 526                 } else if (ix < 0x23d00000) {
 527                         x *= two768;
 528                         y *= two768;
 529                 }
 530                 y = fabs(y);
 531                 x = fabs(x);
 532                 t = y / x;
 533                 th = t;
 534                 ((int *) &th)[LOWORD] &= 0xf8000000;
 535                 xh = x;
 536                 ((int *) &xh)[LOWORD] &= 0xf8000000;
 537                 t1 = (x - xh) * t + xh * (t - th);
 538                 t2 = y - xh * th;
 539                 w1 = mx_atan(t, &w2);
 540                 w2 += (t2 - t1) / (x + y * t);
 541                 if (hx < 0) {
 542                         t1 = pi - w1;
 543                         t2 = pi - t1;
 544                         w2 = (pi_lo - w2) - (w1 - t2);
 545                         w1 = t1;
 546                 }
 547                 *w = (hy >= 0)? w2 : -w2;
 548                 return ((hy >= 0)? w1 : -w1);
 549         }
 550 }