(M_*l): Extend long double constants to be usable for 128 bit floats.

[thirdparty/glibc.git] / math / math.h

/* Declarations for math functions.
   Copyright (C) 1991, 92, 93, 95, 96, 97, 98 Free Software Foundation, Inc.
   This file is part of the GNU C Library.

   The GNU C Library is free software; you can redistribute it and/or
   modify it under the terms of the GNU Library General Public License as
   published by the Free Software Foundation; either version 2 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
   Library General Public License for more details.

   You should have received a copy of the GNU Library General Public
   License along with the GNU C Library; see the file COPYING.LIB.  If not,
   write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
   Boston, MA 02111-1307, USA.  */

/*
 *      ISO C Standard: 4.5 MATHEMATICS <math.h>
 */

#ifndef _MATH_H
#define _MATH_H 1

#include <features.h>

__BEGIN_DECLS

/* Get machine-dependent HUGE_VAL value (returned on overflow).
   On all IEEE754 machines, this is +Infinity.  */
#include <bits/huge_val.h>

/* Get machine-dependent NAN value (returned for some domain errors).  */
#ifdef   __USE_GNU
# include <bits/nan.h>
#endif


/* The file <bits/mathcalls.h> contains the prototypes for all the
   actual math functions.  These macros are used for those prototypes,
   so we can easily declare each function as both `name' and `__name',
   and can declare the float versions `namef' and `__namef'.  */

#define __MATHCALL(function,suffix, args)       \
  __MATHDECL (_Mdouble_,function,suffix, args)
#define __MATHDECL(type, function,suffix, args) \
  __MATHDECL_1(type, function,suffix, args); \
  __MATHDECL_1(type, __CONCAT(__,function),suffix, args)
#define __MATHCALLX(function,suffix, args, attrib)      \
  __MATHDECLX (_Mdouble_,function,suffix, args, attrib)
#define __MATHDECLX(type, function,suffix, args, attrib) \
  __MATHDECL_1(type, function,suffix, args) __attribute__ (attrib); \
  __MATHDECL_1(type, __CONCAT(__,function),suffix, args) __attribute__ (attrib)
#define __MATHDECL_1(type, function,suffix, args) \
  extern type __MATH_PRECNAME(function,suffix) args

#define _Mdouble_               double
#define __MATH_PRECNAME(name,r) __CONCAT(name,r)
#include <bits/mathcalls.h>
#undef  _Mdouble_
#undef  __MATH_PRECNAME

#if defined __USE_MISC || defined __USE_ISOC9X


/* Include the file of declarations again, this time using `float'
   instead of `double' and appending f to each function name.  */

# ifndef _Mfloat_
#  define _Mfloat_              float
# endif
# define _Mdouble_              _Mfloat_
# ifdef __STDC__
#  define __MATH_PRECNAME(name,r) name##f##r
# else
#  define __MATH_PRECNAME(name,r) name/**/f/**/r
# endif
# include <bits/mathcalls.h>
# undef _Mdouble_
# undef __MATH_PRECNAME

# if __STDC__ - 0 || __GNUC__ - 0
/* Include the file of declarations again, this time using `long double'
   instead of `double' and appending l to each function name.  */

#  ifndef _Mlong_double_
#   define _Mlong_double_       long double
#  endif
#  define _Mdouble_             _Mlong_double_
#  ifdef __STDC__
#   define __MATH_PRECNAME(name,r) name##l##r
#  else
#   define __MATH_PRECNAME(name,r) name/**/l/**/r
#  endif
#  include <bits/mathcalls.h>
#  undef _Mdouble_
#  undef __MATH_PRECNAME

# endif /* __STDC__ || __GNUC__ */

#endif  /* Use misc or ISO C 9X.  */
#undef  __MATHDECL_1
#undef  __MATHDECL
#undef  __MATHCALL


#if defined __USE_MISC || defined __USE_XOPEN || defined __USE_ISOC9X
/* This variable is used by `gamma' and `lgamma'.  */
extern int signgam;
#endif


/* ISO C 9X defines some generic macros which work on any data type.  */
#if __USE_ISOC9X

/* Get the architecture specific values describing the floating-point
   evaluation.  The following symbols will get defined:

    float_t     floating-point type at least as wide as `float' used
                to evaluate `float' expressions
    double_t    floating-point type at least as wide as `double' used
                to evaluate `double' expressions

    FLT_EVAL_METHOD
                Defined to
                  0     if `float_t' is `float' and `double_t' is `double'
                  1     if `float_t' and `double_t' are `double'
                  2     if `float_t' and `double_t' are `long double'
                  else  `float_t' and `double_t' are unspecified

    INFINITY    representation of the infinity value of type `float'

    FP_FAST_FMA
    FP_FAST_FMAF
    FP_FAST_FMAL
                If defined it indicates that the the `fma' function
                generally executes about as fast as a multiply and an add.
                This macro is defined only iff the `fma' function is
                implemented directly with a hardware multiply-add instructions.

    FP_ILOGB0   Expands to a value returned by `ilogb (0.0)'.
    FP_ILOGBNAN Expands to a value returned by `ilogb (NAN)'.

    DECIMAL_DIG Number of decimal digits supported by conversion between
                decimal and all internal floating-point formats.

*/
# include <bits/mathdef.h>

/* All floating-point numbers can be put in one of these categories.  */
enum
  {
    FP_NAN,
# define FP_NAN FP_NAN
    FP_INFINITE,
# define FP_INFINITE FP_INFINITE
    FP_ZERO,
# define FP_ZERO FP_ZERO
    FP_SUBNORMAL,
# define FP_SUBNORMAL FP_SUBNORMAL
    FP_NORMAL
# define FP_NORMAL FP_NORMAL
  };

/* Return number of classification appropriate for X.  */
# define fpclassify(x) \
     (sizeof (x) == sizeof (float) ?                                          \
        __fpclassifyf (x)                                                     \
      : sizeof (x) == sizeof (double) ?                                       \
        __fpclassify (x) : __fpclassifyl (x))

/* Return nonzero value if sign of X is negative.  */
# define signbit(x) \
     (sizeof (x) == sizeof (float) ?                                          \
        __signbitf (x)                                                        \
      : sizeof (x) == sizeof (double) ?                                       \
        __signbit (x) : __signbitl (x))

/* Return nonzero value if X is not +-Inf or NaN.  */
# define isfinite(x) \
     (sizeof (x) == sizeof (float) ?                                          \
        __finitef (x)                                                         \
      : sizeof (x) == sizeof (double) ?                                       \
        __finite (x) : __finitel (x))

/* Return nonzero value if X is neither zero, subnormal, Inf, nor NaN.  */
# define isnormal(x) (fpclassify (x) == FP_NORMAL)

/* Return nonzero value if X is a NaN.  We could use `fpclassify' but
   we already have this functions `__isnan' and it is faster.  */
# define isnan(x) \
     (sizeof (x) == sizeof (float) ?                                          \
        __isnanf (x)                                                          \
      : sizeof (x) == sizeof (double) ?                                       \
        __isnan (x) : __isnanl (x))

#endif /* Use ISO C 9X.  */

#ifdef  __USE_MISC
/* Support for various different standard error handling behaviors.  */

typedef enum { _IEEE_ = -1, _SVID_, _XOPEN_, _POSIX_ } _LIB_VERSION_TYPE;

/* This variable can be changed at run-time to any of the values above to
   affect floating point error handling behavior (it may also be necessary
   to change the hardware FPU exception settings).  */
extern _LIB_VERSION_TYPE _LIB_VERSION;
#endif


#ifdef __USE_SVID
/* In SVID error handling, `matherr' is called with this description
   of the exceptional condition.

   We have a problem when using C++ since `exception' is a reserved
   name in C++.  */
# ifdef __cplusplus
struct __exception
# else
struct exception
# endif
  {
    int type;
    char *name;
    double arg1;
    double arg2;
    double retval;
  };

# ifdef __cplusplus
extern int __matherr __P ((struct __exception *__exc));
extern int matherr __P ((struct __exception *__exc));
# else
extern int __matherr __P ((struct exception *__exc));
extern int matherr __P ((struct exception *__exc));
# endif

# define X_TLOSS        1.41484755040568800000e+16

/* Types of exceptions in the `type' field.  */
# define DOMAIN         1
# define SING           2
# define OVERFLOW       3
# define UNDERFLOW      4
# define TLOSS          5
# define PLOSS          6

/* SVID mode specifies returning this large value instead of infinity.  */
# define HUGE           FLT_MAX
# include <float.h>             /* Defines FLT_MAX.  */

#else   /* !SVID */

# ifdef __USE_XOPEN
/* X/Open wants another strange constant.  */
#  define MAXFLOAT      FLT_MAX
#  include <float.h>
# endif

#endif  /* SVID */


/* Some useful constants.  */
#if defined __USE_BSD || defined __USE_UNIX98
# define M_E            2.7182818284590452354   /* e */
# define M_LOG2E        1.4426950408889634074   /* log_2 e */
# define M_LOG10E       0.43429448190325182765  /* log_10 e */
# define M_LN2          0.69314718055994530942  /* log_e 2 */
# define M_LN10         2.30258509299404568402  /* log_e 10 */
# define M_PI           3.14159265358979323846  /* pi */
# define M_PI_2         1.57079632679489661923  /* pi/2 */
# define M_PI_4         0.78539816339744830962  /* pi/4 */
# define M_1_PI         0.31830988618379067154  /* 1/pi */
# define M_2_PI         0.63661977236758134308  /* 2/pi */
# define M_2_SQRTPI     1.12837916709551257390  /* 2/sqrt(pi) */
# define M_SQRT2        1.41421356237309504880  /* sqrt(2) */
# define M_SQRT1_2      0.70710678118654752440  /* 1/sqrt(2) */
#endif

/* The above constants are not adequate for computation using `long double's.
   Therefore we provide as an extension constants with similar names as a
   GNU extension.  Provide enough digits for the 128-bit IEEE quad.  */
#ifdef __USE_GNU
# define M_El           2.7182818284590452353602874713526625L  /* e */
# define M_LOG2El       1.4426950408889634073599246810018922L  /* log_2 e */
# define M_LOG10El      0.4342944819032518276511289189166051L  /* log_10 e */
# define M_LN2l         0.6931471805599453094172321214581766L  /* log_e 2 */
# define M_LN10l        2.3025850929940456840179914546843642L  /* log_e 10 */
# define M_PIl          3.1415926535897932384626433832795029L  /* pi */
# define M_PI_2l        1.5707963267948966192313216916397514L  /* pi/2 */
# define M_PI_4l        0.7853981633974483096156608458198757L  /* pi/4 */
# define M_1_PIl        0.3183098861837906715377675267450287L  /* 1/pi */
# define M_2_PIl        0.6366197723675813430755350534900574L  /* 2/pi */
# define M_2_SQRTPIl    1.1283791670955125738961589031215452L  /* 2/sqrt(pi) */
# define M_SQRT2l       1.4142135623730950488016887242096981L  /* sqrt(2) */
# define M_SQRT1_2l     0.7071067811865475244008443621048490L  /* 1/sqrt(2) */
#endif


/* Get machine-dependent inline versions (if there are any).  */
#ifdef __OPTIMIZE__
# include <bits/mathinline.h>
#endif


#if __USE_ISOC9X
/* ISO C 9X defines some macros to compare number while taking care
   for unordered numbers.  Since many FPUs provide special
   instructions to support these operations and these tests are
   defined in <bits/mathinline.h>, we define the generic macros at
   this late point and only if they are not defined yet.  */

/* Return nonzero value if X is greater than Y.  */
# ifndef isgreater
#  define isgreater(x, y) \
  (__extension__                                                              \
   ({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);                       \
      !isunordered (__x, __y) && __x > __y; }))
# endif

/* Return nonzero value if X is greater than or equal to Y.  */
# ifndef isgreaterequal
#  define isgreaterequal(x, y) \
  (__extension__                                                              \
   ({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);                       \
      !isunordered (__x, __y) && __x >= __y; }))
# endif

/* Return nonzero value if X is less than Y.  */
# ifndef isless
#  define isless(x, y) \
  (__extension__                                                              \
   ({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);                       \
      !isunordered (__x, __y) && __x < __y; }))
# endif

/* Return nonzero value if X is less than or equal to Y.  */
# ifndef islessequal
#  define islessequal(x, y) \
  (__extension__                                                              \
   ({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);                       \
      !isunordered (__x, __y) && __x <= __y; }))
# endif

/* Return nonzero value if either X is less than Y or Y is less than X.  */
# ifndef islessgreater
#  define islessgreater(x, y) \
  (__extension__                                                              \
   ({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);                       \
      !isunordered (__x, __y) && (__x < __y || __y < __x); }))
# endif

/* Return nonzero value if arguments are unordered.  */
# ifndef isunordered
#  define isunordered(u, v) \
  (__extension__                                                              \
   ({ __typeof__(u) __u = (u); __typeof__(v) __v = (v);                       \
      fpclassify (__u) == FP_NAN || fpclassify (__v) == FP_NAN; }))
# endif

#endif

__END_DECLS


#endif /* math.h  */