libquadmath/math/clog10q.c - gcc - Git at Google

 /* Compute complex base 10 logarithm for complex __float128.
    Copyright (C) 1997-2012 Free Software Foundation, Inc.
    This file is part of the GNU C Library.
    Contributed by Ulrich Drepper <drepper@cygnus.com>, 1997.

    The GNU C Library 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.

    The GNU C Library 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 the GNU C Library; if not, see
    <http://www.gnu.org/licenses/>.  */

 #include "quadmath-imp.h"


 /* log_10 (2).  */
 #define M_LOG10_2q 0.3010299956639811952137388947244930267682Q


 __complex128
 clog10q (__complex128 x)
 {
   __complex128 result;
   int rcls = fpclassifyq (__real__ x);
   int icls = fpclassifyq (__imag__ x);

   if (__builtin_expect (rcls == QUADFP_ZERO && icls == QUADFP_ZERO, 0))
     {
       /* Real and imaginary part are 0.0.  */
       __imag__ result = signbitq (__real__ x) ? M_PIq : 0.0Q;
       __imag__ result = copysignq (__imag__ result, __imag__ x);
       /* Yes, the following line raises an exception.  */
       __real__ result = -1.0Q / fabsq (__real__ x);
     }
   else if (__builtin_expect (rcls != QUADFP_NAN && icls != QUADFP_NAN, 1))
     {
       /* Neither real nor imaginary part is NaN.  */
       __float128 absx = fabsq (__real__ x), absy = fabsq (__imag__ x);
       int scale = 0;

       if (absx < absy)
 	{
 	  __float128 t = absx;
 	  absx = absy;
 	  absy = t;
 	}

       if (absx > FLT128_MAX / 2.0Q)
 	{
 	  scale = -1;
 	  absx = scalbnq (absx, scale);
 	  absy = (absy >= FLT128_MIN * 2.0Q ? scalbnq (absy, scale) : 0.0Q);
 	}
       else if (absx < FLT128_MIN && absy < FLT128_MIN)
 	{
 	  scale = FLT128_MANT_DIG;
 	  absx = scalbnq (absx, scale);
 	  absy = scalbnq (absy, scale);
 	}

       if (absx == 1.0Q && scale == 0)
 	{
 	  __float128 absy2 = absy * absy;
 	  if (absy2 <= FLT128_MIN * 2.0Q * M_LN10q)
 	    __real__ result
 	      = (absy2 / 2.0Q - absy2 * absy2 / 4.0Q) * M_LOG10Eq;
 	  else
 	    __real__ result = log1pq (absy2) * (M_LOG10Eq / 2.0Q);
 	}
       else if (absx > 1.0Q && absx < 2.0Q && absy < 1.0Q && scale == 0)
 	{
 	  __float128 d2m1 = (absx - 1.0Q) * (absx + 1.0Q);
 	  if (absy >= FLT128_EPSILON)
 	    d2m1 += absy * absy;
 	  __real__ result = log1pq (d2m1) * (M_LOG10Eq / 2.0Q);
 	}
       else if (absx < 1.0Q
 	       && absx >= 0.75Q
 	       && absy < FLT128_EPSILON / 2.0Q
 	       && scale == 0)
 	{
 	  __float128 d2m1 = (absx - 1.0Q) * (absx + 1.0Q);
 	  __real__ result = log1pq (d2m1) * (M_LOG10Eq / 2.0Q);
 	}
       else if (absx < 1.0Q && (absx >= 0.75Q || absy >= 0.5Q) && scale == 0)
 	{
 	  __float128 d2m1 = __quadmath_x2y2m1q (absx, absy);
 	  __real__ result = log1pq (d2m1) * (M_LOG10Eq / 2.0Q);
 	}
       else
 	{
 	  __float128 d = hypotq (absx, absy);
 	  __real__ result = log10q (d) - scale * M_LOG10_2q;
 	}

       __imag__ result = M_LOG10Eq * atan2q (__imag__ x, __real__ x);
     }
   else
     {
       __imag__ result = nanq ("");
       if (rcls == QUADFP_INFINITE || icls == QUADFP_INFINITE)
 	/* Real or imaginary part is infinite.  */
 	__real__ result = HUGE_VALQ;
       else
 	__real__ result = nanq ("");
     }

   return result;
 }
	/* Compute complex base 10 logarithm for complex __float128.
	Copyright (C) 1997-2012 Free Software Foundation, Inc.
	This file is part of the GNU C Library.
	Contributed by Ulrich Drepper <drepper@cygnus.com>, 1997.

	The GNU C Library 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.

	The GNU C Library 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 the GNU C Library; if not, see
	<http://www.gnu.org/licenses/>. */

	#include "quadmath-imp.h"


	/* log_10 (2). */
	#define M_LOG10_2q 0.3010299956639811952137388947244930267682Q


	__complex128
	clog10q (__complex128 x)
	{
	__complex128 result;
	int rcls = fpclassifyq (__real__ x);
	int icls = fpclassifyq (__imag__ x);

	if (__builtin_expect (rcls == QUADFP_ZERO && icls == QUADFP_ZERO, 0))
	{
	/* Real and imaginary part are 0.0. */
	__imag__ result = signbitq (__real__ x) ? M_PIq : 0.0Q;
	__imag__ result = copysignq (__imag__ result, __imag__ x);
	/* Yes, the following line raises an exception. */
	__real__ result = -1.0Q / fabsq (__real__ x);
	}
	else if (__builtin_expect (rcls != QUADFP_NAN && icls != QUADFP_NAN, 1))
	{
	/* Neither real nor imaginary part is NaN. */
	__float128 absx = fabsq (__real__ x), absy = fabsq (__imag__ x);
	int scale = 0;

	if (absx < absy)
	{
	__float128 t = absx;
	absx = absy;
	absy = t;
	}

	if (absx > FLT128_MAX / 2.0Q)
	{
	scale = -1;
	absx = scalbnq (absx, scale);
	absy = (absy >= FLT128_MIN * 2.0Q ? scalbnq (absy, scale) : 0.0Q);
	}
	else if (absx < FLT128_MIN && absy < FLT128_MIN)
	{
	scale = FLT128_MANT_DIG;
	absx = scalbnq (absx, scale);
	absy = scalbnq (absy, scale);
	}

	if (absx == 1.0Q && scale == 0)
	{
	__float128 absy2 = absy * absy;
	if (absy2 <= FLT128_MIN * 2.0Q * M_LN10q)
	__real__ result
	= (absy2 / 2.0Q - absy2 * absy2 / 4.0Q) * M_LOG10Eq;
	else
	__real__ result = log1pq (absy2) * (M_LOG10Eq / 2.0Q);
	}
	else if (absx > 1.0Q && absx < 2.0Q && absy < 1.0Q && scale == 0)
	{
	__float128 d2m1 = (absx - 1.0Q) * (absx + 1.0Q);
	if (absy >= FLT128_EPSILON)
	d2m1 += absy * absy;
	__real__ result = log1pq (d2m1) * (M_LOG10Eq / 2.0Q);
	}
	else if (absx < 1.0Q
	&& absx >= 0.75Q
	&& absy < FLT128_EPSILON / 2.0Q
	&& scale == 0)
	{
	__float128 d2m1 = (absx - 1.0Q) * (absx + 1.0Q);
	__real__ result = log1pq (d2m1) * (M_LOG10Eq / 2.0Q);
	}
	else if (absx < 1.0Q && (absx >= 0.75Q \|\| absy >= 0.5Q) && scale == 0)
	{
	__float128 d2m1 = __quadmath_x2y2m1q (absx, absy);
	__real__ result = log1pq (d2m1) * (M_LOG10Eq / 2.0Q);
	}
	else
	{
	__float128 d = hypotq (absx, absy);
	__real__ result = log10q (d) - scale * M_LOG10_2q;
	}

	__imag__ result = M_LOG10Eq * atan2q (__imag__ x, __real__ x);
	}
	else
	{
	__imag__ result = nanq ("");
	if (rcls == QUADFP_INFINITE \|\| icls == QUADFP_INFINITE)
	/* Real or imaginary part is infinite. */
	__real__ result = HUGE_VALQ;
	else
	__real__ result = nanq ("");
	}

	return result;
	}