gnulib/import/isnan.c - binutils-gdb - Git at Google

 /* Test for NaN that does not need libm.
    Copyright (C) 2007-2021 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 3 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.  If not, see <https://www.gnu.org/licenses/>.  */

 /* Written by Bruno Haible <bruno@clisp.org>, 2007.  */

 #include <config.h>

 /* Specification.  */
 #ifdef USE_LONG_DOUBLE
 /* Specification found in math.h or isnanl-nolibm.h.  */
 extern int rpl_isnanl (long double x) _GL_ATTRIBUTE_CONST;
 #elif ! defined USE_FLOAT
 /* Specification found in math.h or isnand-nolibm.h.  */
 extern int rpl_isnand (double x);
 #else /* defined USE_FLOAT */
 /* Specification found in math.h or isnanf-nolibm.h.  */
 extern int rpl_isnanf (float x);
 #endif

 #include <float.h>
 #include <string.h>

 #include "float+.h"

 #ifdef USE_LONG_DOUBLE
 # define FUNC rpl_isnanl
 # define DOUBLE long double
 # define MAX_EXP LDBL_MAX_EXP
 # define MIN_EXP LDBL_MIN_EXP
 # if defined LDBL_EXPBIT0_WORD && defined LDBL_EXPBIT0_BIT
 #  define KNOWN_EXPBIT0_LOCATION
 #  define EXPBIT0_WORD LDBL_EXPBIT0_WORD
 #  define EXPBIT0_BIT LDBL_EXPBIT0_BIT
 # endif
 # define SIZE SIZEOF_LDBL
 # define L_(literal) literal##L
 #elif ! defined USE_FLOAT
 # define FUNC rpl_isnand
 # define DOUBLE double
 # define MAX_EXP DBL_MAX_EXP
 # define MIN_EXP DBL_MIN_EXP
 # if defined DBL_EXPBIT0_WORD && defined DBL_EXPBIT0_BIT
 #  define KNOWN_EXPBIT0_LOCATION
 #  define EXPBIT0_WORD DBL_EXPBIT0_WORD
 #  define EXPBIT0_BIT DBL_EXPBIT0_BIT
 # endif
 # define SIZE SIZEOF_DBL
 # define L_(literal) literal
 #else /* defined USE_FLOAT */
 # define FUNC rpl_isnanf
 # define DOUBLE float
 # define MAX_EXP FLT_MAX_EXP
 # define MIN_EXP FLT_MIN_EXP
 # if defined FLT_EXPBIT0_WORD && defined FLT_EXPBIT0_BIT
 #  define KNOWN_EXPBIT0_LOCATION
 #  define EXPBIT0_WORD FLT_EXPBIT0_WORD
 #  define EXPBIT0_BIT FLT_EXPBIT0_BIT
 # endif
 # define SIZE SIZEOF_FLT
 # define L_(literal) literal##f
 #endif

 #define EXP_MASK ((MAX_EXP - MIN_EXP) | 7)

 #define NWORDS \
   ((sizeof (DOUBLE) + sizeof (unsigned int) - 1) / sizeof (unsigned int))
 typedef union { DOUBLE value; unsigned int word[NWORDS]; } memory_double;

 /* Most hosts nowadays use IEEE floating point, so they use IEC 60559
    representations, have infinities and NaNs, and do not trap on
    exceptions.  Define IEEE_FLOATING_POINT if this host is one of the
    typical ones.  The C11 macro __STDC_IEC_559__ is close to what is
    wanted here, but is not quite right because this file does not require
    all the features of C11 Annex F (and does not require C11 at all,
    for that matter).  */

 #define IEEE_FLOATING_POINT (FLT_RADIX == 2 && FLT_MANT_DIG == 24 \
                              && FLT_MIN_EXP == -125 && FLT_MAX_EXP == 128)

 int
 FUNC (DOUBLE x)
 {
 #if defined KNOWN_EXPBIT0_LOCATION && IEEE_FLOATING_POINT
 # if defined USE_LONG_DOUBLE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_)) && !HAVE_SAME_LONG_DOUBLE_AS_DOUBLE
   /* Special CPU dependent code is needed to treat bit patterns outside the
      IEEE 754 specification (such as Pseudo-NaNs, Pseudo-Infinities,
      Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals) as NaNs.
      These bit patterns are:
        - exponent = 0x0001..0x7FFF, mantissa bit 63 = 0,
        - exponent = 0x0000, mantissa bit 63 = 1.
      The NaN bit pattern is:
        - exponent = 0x7FFF, mantissa >= 0x8000000000000001.  */
   memory_double m;
   unsigned int exponent;

   m.value = x;
   exponent = (m.word[EXPBIT0_WORD] >> EXPBIT0_BIT) & EXP_MASK;
 #  ifdef WORDS_BIGENDIAN
   /* Big endian: EXPBIT0_WORD = 0, EXPBIT0_BIT = 16.  */
   if (exponent == 0)
     return 1 & (m.word[0] >> 15);
   else if (exponent == EXP_MASK)
     return (((m.word[0] ^ 0x8000U) << 16) | m.word[1] | (m.word[2] >> 16)) != 0;
   else
     return 1 & ~(m.word[0] >> 15);
 #  else
   /* Little endian: EXPBIT0_WORD = 2, EXPBIT0_BIT = 0.  */
   if (exponent == 0)
     return (m.word[1] >> 31);
   else if (exponent == EXP_MASK)
     return ((m.word[1] ^ 0x80000000U) | m.word[0]) != 0;
   else
     return (m.word[1] >> 31) ^ 1;
 #  endif
 # else
   /* Be careful to not do any floating-point operation on x, such as x == x,
      because x may be a signaling NaN.  */
 #  if defined __SUNPRO_C || defined __ICC || defined _MSC_VER \
       || defined __DECC || defined __TINYC__ \
       || (defined __sgi && !defined __GNUC__)
   /* The Sun C 5.0, Intel ICC 10.0, Microsoft Visual C/C++ 9.0, Compaq (ex-DEC)
      6.4, and TinyCC compilers don't recognize the initializers as constant
      expressions.  The Compaq compiler also fails when constant-folding
      0.0 / 0.0 even when constant-folding is not required.  The Microsoft
      Visual C/C++ compiler also fails when constant-folding 1.0 / 0.0 even
      when constant-folding is not required. The SGI MIPSpro C compiler
      complains about "floating-point operation result is out of range".  */
   static DOUBLE zero = L_(0.0);
   memory_double nan;
   DOUBLE plus_inf = L_(1.0) / zero;
   DOUBLE minus_inf = -L_(1.0) / zero;
   nan.value = zero / zero;
 #  else
   static memory_double nan = { L_(0.0) / L_(0.0) };
   static DOUBLE plus_inf = L_(1.0) / L_(0.0);
   static DOUBLE minus_inf = -L_(1.0) / L_(0.0);
 #  endif
   {
     memory_double m;

     /* A NaN can be recognized through its exponent.  But exclude +Infinity and
        -Infinity, which have the same exponent.  */
     m.value = x;
     if (((m.word[EXPBIT0_WORD] ^ nan.word[EXPBIT0_WORD])
          & (EXP_MASK << EXPBIT0_BIT))
         == 0)
       return (memcmp (&m.value, &plus_inf, SIZE) != 0
               && memcmp (&m.value, &minus_inf, SIZE) != 0);
     else
       return 0;
   }
 # endif
 #else
   /* The configuration did not find sufficient information, or does
      not use IEEE floating point.  Give up about the signaling NaNs;
      handle only the quiet NaNs.  */
   if (x == x)
     {
 # if defined USE_LONG_DOUBLE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_)) && !HAVE_SAME_LONG_DOUBLE_AS_DOUBLE
       /* Detect any special bit patterns that pass ==; see comment above.  */
       memory_double m1;
       memory_double m2;

       memset (&m1.value, 0, SIZE);
       memset (&m2.value, 0, SIZE);
       m1.value = x;
       m2.value = x + (x ? 0.0L : -0.0L);
       if (memcmp (&m1.value, &m2.value, SIZE) != 0)
         return 1;
 # endif
       return 0;
     }
   else
     return 1;
 #endif
 }
	/* Test for NaN that does not need libm.
	Copyright (C) 2007-2021 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 3 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. If not, see <https://www.gnu.org/licenses/>. */

	/* Written by Bruno Haible <bruno@clisp.org>, 2007. */

	#include <config.h>

	/* Specification. */
	#ifdef USE_LONG_DOUBLE
	/* Specification found in math.h or isnanl-nolibm.h. */
	extern int rpl_isnanl (long double x) _GL_ATTRIBUTE_CONST;
	#elif ! defined USE_FLOAT
	/* Specification found in math.h or isnand-nolibm.h. */
	extern int rpl_isnand (double x);
	#else /* defined USE_FLOAT */
	/* Specification found in math.h or isnanf-nolibm.h. */
	extern int rpl_isnanf (float x);
	#endif

	#include <float.h>
	#include <string.h>

	#include "float+.h"

	#ifdef USE_LONG_DOUBLE
	# define FUNC rpl_isnanl
	# define DOUBLE long double
	# define MAX_EXP LDBL_MAX_EXP
	# define MIN_EXP LDBL_MIN_EXP
	# if defined LDBL_EXPBIT0_WORD && defined LDBL_EXPBIT0_BIT
	# define KNOWN_EXPBIT0_LOCATION
	# define EXPBIT0_WORD LDBL_EXPBIT0_WORD
	# define EXPBIT0_BIT LDBL_EXPBIT0_BIT
	# endif
	# define SIZE SIZEOF_LDBL
	# define L_(literal) literal##L
	#elif ! defined USE_FLOAT
	# define FUNC rpl_isnand
	# define DOUBLE double
	# define MAX_EXP DBL_MAX_EXP
	# define MIN_EXP DBL_MIN_EXP
	# if defined DBL_EXPBIT0_WORD && defined DBL_EXPBIT0_BIT
	# define KNOWN_EXPBIT0_LOCATION
	# define EXPBIT0_WORD DBL_EXPBIT0_WORD
	# define EXPBIT0_BIT DBL_EXPBIT0_BIT
	# endif
	# define SIZE SIZEOF_DBL
	# define L_(literal) literal
	#else /* defined USE_FLOAT */
	# define FUNC rpl_isnanf
	# define DOUBLE float
	# define MAX_EXP FLT_MAX_EXP
	# define MIN_EXP FLT_MIN_EXP
	# if defined FLT_EXPBIT0_WORD && defined FLT_EXPBIT0_BIT
	# define KNOWN_EXPBIT0_LOCATION
	# define EXPBIT0_WORD FLT_EXPBIT0_WORD
	# define EXPBIT0_BIT FLT_EXPBIT0_BIT
	# endif
	# define SIZE SIZEOF_FLT
	# define L_(literal) literal##f
	#endif

	#define EXP_MASK ((MAX_EXP - MIN_EXP) \| 7)

	#define NWORDS \
	((sizeof (DOUBLE) + sizeof (unsigned int) - 1) / sizeof (unsigned int))
	typedef union { DOUBLE value; unsigned int word[NWORDS]; } memory_double;

	/* Most hosts nowadays use IEEE floating point, so they use IEC 60559
	representations, have infinities and NaNs, and do not trap on
	exceptions. Define IEEE_FLOATING_POINT if this host is one of the
	typical ones. The C11 macro __STDC_IEC_559__ is close to what is
	wanted here, but is not quite right because this file does not require
	all the features of C11 Annex F (and does not require C11 at all,
	for that matter). */

	#define IEEE_FLOATING_POINT (FLT_RADIX == 2 && FLT_MANT_DIG == 24 \
	&& FLT_MIN_EXP == -125 && FLT_MAX_EXP == 128)

	int
	FUNC (DOUBLE x)
	{
	#if defined KNOWN_EXPBIT0_LOCATION && IEEE_FLOATING_POINT
	# if defined USE_LONG_DOUBLE && ((defined __ia64 && LDBL_MANT_DIG == 64) \|\| (defined __x86_64__ \|\| defined __amd64__) \|\| (defined __i386 \|\| defined __i386__ \|\| defined _I386 \|\| defined _M_IX86 \|\| defined _X86_)) && !HAVE_SAME_LONG_DOUBLE_AS_DOUBLE
	/* Special CPU dependent code is needed to treat bit patterns outside the
	IEEE 754 specification (such as Pseudo-NaNs, Pseudo-Infinities,
	Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals) as NaNs.
	These bit patterns are:
	- exponent = 0x0001..0x7FFF, mantissa bit 63 = 0,
	- exponent = 0x0000, mantissa bit 63 = 1.
	The NaN bit pattern is:
	- exponent = 0x7FFF, mantissa >= 0x8000000000000001. */
	memory_double m;
	unsigned int exponent;

	m.value = x;
	exponent = (m.word[EXPBIT0_WORD] >> EXPBIT0_BIT) & EXP_MASK;
	# ifdef WORDS_BIGENDIAN
	/* Big endian: EXPBIT0_WORD = 0, EXPBIT0_BIT = 16. */
	if (exponent == 0)
	return 1 & (m.word[0] >> 15);
	else if (exponent == EXP_MASK)
	return (((m.word[0] ^ 0x8000U) << 16) \| m.word[1] \| (m.word[2] >> 16)) != 0;
	else
	return 1 & ~(m.word[0] >> 15);
	# else
	/* Little endian: EXPBIT0_WORD = 2, EXPBIT0_BIT = 0. */
	if (exponent == 0)
	return (m.word[1] >> 31);
	else if (exponent == EXP_MASK)
	return ((m.word[1] ^ 0x80000000U) \| m.word[0]) != 0;
	else
	return (m.word[1] >> 31) ^ 1;
	# endif
	# else
	/* Be careful to not do any floating-point operation on x, such as x == x,
	because x may be a signaling NaN. */
	# if defined __SUNPRO_C \|\| defined __ICC \|\| defined _MSC_VER \
	\|\| defined __DECC \|\| defined __TINYC__ \
	\|\| (defined __sgi && !defined __GNUC__)
	/* The Sun C 5.0, Intel ICC 10.0, Microsoft Visual C/C++ 9.0, Compaq (ex-DEC)
	6.4, and TinyCC compilers don't recognize the initializers as constant
	expressions. The Compaq compiler also fails when constant-folding
	0.0 / 0.0 even when constant-folding is not required. The Microsoft
	Visual C/C++ compiler also fails when constant-folding 1.0 / 0.0 even
	when constant-folding is not required. The SGI MIPSpro C compiler
	complains about "floating-point operation result is out of range". */
	static DOUBLE zero = L_(0.0);
	memory_double nan;
	DOUBLE plus_inf = L_(1.0) / zero;
	DOUBLE minus_inf = -L_(1.0) / zero;
	nan.value = zero / zero;
	# else
	static memory_double nan = { L_(0.0) / L_(0.0) };
	static DOUBLE plus_inf = L_(1.0) / L_(0.0);
	static DOUBLE minus_inf = -L_(1.0) / L_(0.0);
	# endif
	{
	memory_double m;

	/* A NaN can be recognized through its exponent. But exclude +Infinity and
	-Infinity, which have the same exponent. */
	m.value = x;
	if (((m.word[EXPBIT0_WORD] ^ nan.word[EXPBIT0_WORD])
	& (EXP_MASK << EXPBIT0_BIT))
	== 0)
	return (memcmp (&m.value, &plus_inf, SIZE) != 0
	&& memcmp (&m.value, &minus_inf, SIZE) != 0);
	else
	return 0;
	}
	# endif
	#else
	/* The configuration did not find sufficient information, or does
	not use IEEE floating point. Give up about the signaling NaNs;
	handle only the quiet NaNs. */
	if (x == x)
	{
	# if defined USE_LONG_DOUBLE && ((defined __ia64 && LDBL_MANT_DIG == 64) \|\| (defined __x86_64__ \|\| defined __amd64__) \|\| (defined __i386 \|\| defined __i386__ \|\| defined _I386 \|\| defined _M_IX86 \|\| defined _X86_)) && !HAVE_SAME_LONG_DOUBLE_AS_DOUBLE
	/* Detect any special bit patterns that pass ==; see comment above. */
	memory_double m1;
	memory_double m2;

	memset (&m1.value, 0, SIZE);
	memset (&m2.value, 0, SIZE);
	m1.value = x;
	m2.value = x + (x ? 0.0L : -0.0L);
	if (memcmp (&m1.value, &m2.value, SIZE) != 0)
	return 1;
	# endif
	return 0;
	}
	else
	return 1;
	#endif
	}