path: root/src/include/i386/__math.h

/* Inline math functions for i387.
   Copyright (C) 1995, 1996, 1997, 1998 Free Software Foundation, Inc.
   This file is part of the GNU C Library.
   Contributed by John C. Bowman <bowman@math.ualberta.ca>, 1995.

   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.  */


#ifndef __GLIBC__
#ifdef __cplusplus
# define __MATH_INLINE __inline
#else
# define __MATH_INLINE extern __inline
#endif

#ifndef ____MATH_H
#define ____MATH_H


#if defined __USE_ISOC9X && defined __GNUC__ && __GNUC__ >= 2
/* ISO C 9X defines some macros to perform unordered comparisons.  The
   ix87 FPU supports this with special opcodes and we should use them.
   These must not be inline functions since we have to be able to handle
   all floating-point types.  */
# ifdef __i686__
/* For the PentiumPro and more recent processors we can provide
   better code.  */
#  define isgreater(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucomip %%st(1), %%st; seta %%al"			      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st");	      \
	__result; })
#  define isgreaterequal(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucomip %%st(1), %%st; setae %%al"			      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st");	      \
	__result; })

#  define isless(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucomip %%st(1), %%st; seta %%al"			      \
		 : "=a" (__result) : "u" (x), "t" (y) : "cc", "st");	      \
	__result; })

#  define islessequal(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucomip %%st(1), %%st; setae %%al"			      \
		 : "=a" (__result) : "u" (x), "t" (y) : "cc", "st");	      \
	__result; })

#  define islessgreater(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucomip %%st(1), %%st; setne %%al"			      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st");	      \
	__result; })

#  define isunordered(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucomip %%st(1), %%st; setp %%al"			      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st");	      \
	__result; })
# else
/* This is the dumb, portable code for i386 and above.  */
#  define isgreater(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucompp; fnstsw; testb $0x45, %%ah; setz %%al"	      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st", "st(1)"); \
	__result; })

#  define isgreaterequal(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucompp; fnstsw; testb $0x05, %%ah; setz %%al"	      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st", "st(1)"); \
	__result; })

#  define isless(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucompp; fnstsw; testb $0x45, %%ah; setz %%al"	      \
		 : "=a" (__result) : "u" (x), "t" (y) : "cc", "st", "st(1)"); \
	__result; })

#  define islessequal(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucompp; fnstsw; testb $0x05, %%ah; setz %%al"	      \
		 : "=a" (__result) : "u" (x), "t" (y) : "cc", "st", "st(1)"); \
	__result; })

#  define islessgreater(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucompp; fnstsw; testb $0x44, %%ah; setz %%al"	      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st", "st(1)"); \
	__result; })

#  define isunordered(x, y) \
     ({ register char __result;						      \
	__asm__ ("fucompp; fnstsw; sahf; setp %%al"			      \
		 : "=a" (__result) : "u" (y), "t" (x) : "cc", "st", "st(1)"); \
	__result; })
# endif				/* __i686__ */

/* Test for negative number.  Used in the signbit() macro.  */
__MATH_INLINE int __signbitf(float __x)
{
    union {
	float __f;
	int __i;
    } __u = {
  __f:__x};
    return __u.__i < 0;
}

__MATH_INLINE int __signbit(double __x)
{
    union {
	double __d;
	int __i[2];
    } __u = {
  __d:__x};
    return __u.__i[1] < 0;
}

__MATH_INLINE int __signbitl(long double __x)
{
    union {
	long double __l;
	int __i[3];
    } __u = {
  __l:__x};
    return (__u.__i[2] & 0x8000) != 0;
}
#endif


/* The gcc, version 2.7 or below, has problems with all this inlining
   code.  So disable it for this version of the compiler.  */
#if defined __GNUC__ && (__GNUC__ > 2 || (__GNUC__ == 2 && __GNUC_MINOR__ > 7))

#if ((!defined __NO_MATH_INLINES || defined __LIBC_INTERNAL_MATH_INLINES) \
     && defined __OPTIMIZE__)

/* A macro to define float, double, and long double versions of various
   math functions for the ix87 FPU.  FUNC is the function name (which will
   be suffixed with f and l for the float and long double version,
   respectively).  OP is the name of the FPU operation.  */

#if defined __USE_MISC || defined __USE_ISOC9X
# define __inline_mathop(func, op) \
  __inline_mathop_ (double, func, op)					      \
  __inline_mathop_ (float, __CONCAT(func,f), op)			      \
  __inline_mathop_ (long double, __CONCAT(func,l), op)
#else
# define __inline_mathop(func, op) \
  __inline_mathop_ (double, func, op)
#endif

#define __inline_mathop_(float_type, func, op) \
  __inline_mathop_decl_ (float_type, func, op, "0" (__x))


#if defined __USE_MISC || defined __USE_ISOC9X
# define __inline_mathop_decl(func, op, params...) \
  __inline_mathop_decl_ (double, func, op, params)			      \
  __inline_mathop_decl_ (float, __CONCAT(func,f), op, params)		      \
  __inline_mathop_decl_ (long double, __CONCAT(func,l), op, params)
#else
# define __inline_mathop_decl(func, op, params...) \
  __inline_mathop_decl_ (double, func, op, params)
#endif

#define __inline_mathop_decl_(float_type, func, op, params...) \
  __MATH_INLINE float_type func (float_type);				      \
  __MATH_INLINE float_type func (float_type __x)			      \
  {									      \
    register float_type __result;					      \
    __asm __volatile__ (op : "=t" (__result) : params);			      \
    return __result;							      \
  }


#if defined __USE_MISC || defined __USE_ISOC9X
# define __inline_mathcode(func, arg, code) \
  __inline_mathcode_ (double, func, arg, code)				      \
  __inline_mathcode_ (float, __CONCAT(func,f), arg, code)		      \
  __inline_mathcode_ (long double, __CONCAT(func,l), arg, code)
# define __inline_mathcode2(func, arg1, arg2, code) \
  __inline_mathcode2_ (double, func, arg1, arg2, code)			      \
  __inline_mathcode2_ (float, __CONCAT(func,f), arg1, arg2, code)	      \
  __inline_mathcode2_ (long double, __CONCAT(func,l), arg1, arg2, code)
# define __inline_mathcode3(func, arg1, arg2, arg3, code) \
  __inline_mathcode3_ (double, func, arg1, arg2, arg3, code)		      \
  __inline_mathcode3_ (float, __CONCAT(func,f), arg1, arg2, arg3, code)	      \
  __inline_mathcode3_ (long double, __CONCAT(func,l), arg1, arg2, arg3, code)
#else
# define __inline_mathcode(func, arg, code) \
  __inline_mathcode_ (double, func, (arg), code)
# define __inline_mathcode2(func, arg1, arg2, code) \
  __inline_mathcode2_ (double, func, arg1, arg2, code)
# define __inline_mathcode3(func, arg1, arg2, arg3, code) \
  __inline_mathcode3_ (double, func, arg1, arg2, arg3, code)
#endif

#define __inline_mathcode_(float_type, func, arg, code) \
  __MATH_INLINE float_type func (float_type);				      \
  __MATH_INLINE float_type func (float_type arg)			      \
  {									      \
    code;								      \
  }

#define __inline_mathcode2_(float_type, func, arg1, arg2, code) \
  __MATH_INLINE float_type func (float_type, float_type);		      \
  __MATH_INLINE float_type func (float_type arg1, float_type arg2)	      \
  {									      \
    code;								      \
  }

#define __inline_mathcode3_(float_type, func, arg1, arg2, arg3, code) \
  __MATH_INLINE float_type func (float_type, float_type, float_type);	      \
  __MATH_INLINE float_type func (float_type arg1, float_type arg2,	      \
				 float_type arg3)			      \
  {									      \
    code;								      \
  }
#endif


#if !defined __NO_MATH_INLINES && defined __OPTIMIZE__
/* Miscellaneous functions */

__inline_mathcode(__sgn, __x,
		  return __x == 0.0 ? 0.0 : (__x > 0.0 ? 1.0 : -1.0))
    __inline_mathcode(__pow2, __x,
		      register long double __value;
		      register long double __exponent;
		      __extension__ long long int __p = (long long int)__x;
		      if (__x == (long double) __p)
		      {
__asm __volatile__("fscale": "=t"(__value):"0"(1.0), "u"(__x));
		      return
		      __value;}
__asm __volatile__("fld	%%st(0)\n\t" "frndint			# int(x)\n\t" "fxch\n\t" "fsub	%%st(1)		# fract(x)\n\t" "f2xm1			# 2^(fract(x)) - 1\n\t": "=t"(__value), "=u"(__exponent): "0"(__x)); __value += 1.0; __asm __volatile__("fscale": "=t"(__value):"0"(__value), "u"(__exponent));
		      return
		      __value)
#define __sincos_code \
  register long double __cosr;						      \
  register long double __sinr;						      \
  __asm __volatile__							      \
    ("fsincos\n\t"							      \
     "fnstsw	%%ax\n\t"						      \
     "testl	$0x400, %%eax\n\t"					      \
     "jz	1f\n\t"							      \
     "fldpi\n\t"							      \
     "fadd	%%st(0)\n\t"						      \
     "fxch	%%st(1)\n\t"						      \
     "2: fprem1\n\t"							      \
     "fnstsw	%%ax\n\t"						      \
     "testl	$0x400, %%eax\n\t"					      \
     "jnz	2b\n\t"							      \
     "fstp	%%st(1)\n\t"						      \
     "fsincos\n\t"							      \
     "1:"								      \
     : "=t" (__cosr), "=u" (__sinr) : "0" (__x));			      \
  *__sinx = __sinr;							      \
  *__cosx = __cosr

    __MATH_INLINE void __sincos(double __x, double *__sinx,
				double *__cosx);
__MATH_INLINE void __sincos(double __x, double *__sinx, double *__cosx)
{
    __sincos_code;
}

__MATH_INLINE void __sincosf(float __x, float *__sinx, float *__cosx);
__MATH_INLINE void __sincosf(float __x, float *__sinx, float *__cosx)
{
    __sincos_code;
}

__MATH_INLINE void __sincosl(long double __x, long double *__sinx,
			     long double *__cosx);
__MATH_INLINE void
__sincosl(long double __x, long double *__sinx, long double *__cosx)
{
    __sincos_code;
}


/* Optimized inline implementation, sometimes with reduced precision
   and/or argument range.  */

#define __expm1_code \
  register long double __value;						      \
  register long double __exponent;					      \
  register long double __temp;						      \
  __asm __volatile__							      \
    ("fldl2e			# e^x - 1 = 2^(x * log2(e)) - 1\n\t"	      \
     "fmul	%%st(1)		# x * log2(e)\n\t"			      \
     "fst	%%st(1)\n\t"						      \
     "frndint			# int(x * log2(e))\n\t"			      \
     "fxch\n\t"								      \
     "fsub	%%st(1)		# fract(x * log2(e))\n\t"		      \
     "f2xm1			# 2^(fract(x * log2(e))) - 1\n\t"	      \
     "fscale			# 2^(x * log2(e)) - 2^(int(x * log2(e)))\n\t" \
     : "=t" (__value), "=u" (__exponent) : "0" (__x));			      \
  __asm __volatile__							      \
    ("fscale			# 2^int(x * log2(e))\n\t"		      \
     : "=t" (__temp) : "0" (1.0), "u" (__exponent));			      \
  __temp -= 1.0;							      \
  return __temp + __value
__inline_mathcode_(long double, __expm1l, __x, __expm1_code)
#define __exp_code \
  register long double __value;						      \
  register long double __exponent;					      \
  __asm __volatile__							      \
    ("fldl2e			# e^x = 2^(x * log2(e))\n\t"		      \
     "fmul	%%st(1)		# x * log2(e)\n\t"			      \
     "fst	%%st(1)\n\t"						      \
     "frndint			# int(x * log2(e))\n\t"			      \
     "fxch\n\t"								      \
     "fsub	%%st(1)		# fract(x * log2(e))\n\t"		      \
     "f2xm1			# 2^(fract(x * log2(e))) - 1\n\t"	      \
     : "=t" (__value), "=u" (__exponent) : "0" (__x));			      \
  __value += 1.0;							      \
  __asm __volatile__							      \
    ("fscale"								      \
     : "=t" (__value) : "0" (__value), "u" (__exponent));		      \
  return __value
__inline_mathcode(exp, __x, __exp_code) __inline_mathcode_(long double, __expl, __x, __exp_code) __inline_mathcode(tan, __x, register long double __value; register long double __value2 __attribute__ ((__unused__)); __asm __volatile__("fptan": "=t"(__value2), "=u"(__value):"0"(__x)); return __value)
#define __atan2_code \
  register long double __value;						      \
  __asm __volatile__							      \
    ("fpatan\n\t"							      \
     : "=t" (__value) : "0" (__x), "u" (__y) : "st(1)");		      \
  return __value
    __inline_mathcode2(atan2, __y, __x,
		   __atan2_code) __inline_mathcode2_(long double, __atan2l,
						     __y, __x,
						     __atan2_code)
__inline_mathcode2(fmod, __x, __y, register long double __value; __asm __volatile__("1:	fprem\n\t" "fnstsw	%%ax\n\t" "sahf\n\t" "jp	1b": "=t"(__value): "0"(__x), "u"(__y):"ax", "cc"); return __value)
    __inline_mathcode2(pow, __x, __y,
		       register long double __value;
		       register long double __exponent;
		       __extension__ long long int __p =
		       (long long int)__y; if (__x == 0.0 && __y > 0.0)
		       return 0.0; if (__y == (double) __p)
		       {
		       long double __r = 1.0;
		       if (__p == 0) return 1.0; if (__p < 0) {
		       __p = -__p; __x = 1.0 / __x;}
		       while (1) {
		       if (__p & 1)
		       __r *= __x;
		       __p >>= 1; if (__p == 0) return __r; __x *= __x;}
		       /* NOTREACHED */
		       }

__asm __volatile__("fyl2x": "=t"(__value): "0"(__x), "u"(1.0): "st(1)"); __asm __volatile__("fmul	%%st(1)		# y * log2(x)\n\t" "fst	%%st(1)\n\t" "frndint			# int(y * log2(x))\n\t" "fxch\n\t" "fsub	%%st(1)		# fract(y * log2(x))\n\t" "f2xm1			# 2^(fract(y * log2(x))) - 1\n\t": "=t"(__value), "=u"(__exponent): "0"(__y), "1"(__value)); __value += 1.0; __asm __volatile__("fscale": "=t"(__value):"0"(__value), "u"(__exponent));
		       return
		       __value)


    __inline_mathop(sqrt, "fsqrt")
	__inline_mathop_(long double, __sqrtl, "fsqrt")
#if defined __GNUC__ && (__GNUC__ > 2 || __GNUC__ == 2 && __GNUC_MINOR__ >= 8)
    __inline_mathcode_(double, fabs, __x, return __builtin_fabs(__x))
	__inline_mathcode_(float, fabsf, __x, return __builtin_fabsf(__x))
	__inline_mathcode_(long double, fabsl, __x,
			   return __builtin_fabsl(__x))
	__inline_mathcode_(long double, __fabsl, __x,
			   return __builtin_fabsl(__x))
#else
	__inline_mathop(fabs, "fabs")
	__inline_mathop_(long double, __fabsl, "fabs")
#endif
/* The argument range of this inline version is reduced.  */
     __inline_mathop(sin, "fsin")
/* The argument range of this inline version is reduced.  */
     __inline_mathop(cos, "fcos")
	__inline_mathop(atan, "fld1; fpatan")
	__inline_mathop(log, "fldln2; fxch; fyl2x")
	__inline_mathop(log10, "fldlg2; fxch; fyl2x")
	__inline_mathcode(asin, __x,
			  return __atan2l(__x,
					  __sqrtl(1.0 -
						  __x *
						  __x)))
	__inline_mathcode(acos, __x,
			  return __atan2l(__sqrtl(1.0 - __x * __x),
					  __x)) __inline_mathcode_(long
								   double,
								   __sgn1l,
								   __x,
								   return
								   __x >=
								   0.0 ?
								   1.0 :
								   -1.0)
/* The argument range of the inline version of sinhl is slightly reduced.  */
     __inline_mathcode(sinh, __x, register long double __exm1 =
		       __expm1l(__fabsl(__x));
		       return 0.5 * (__exm1 / (__exm1 + 1.0) +
				     __exm1) *
		       __sgn1l(__x)) __inline_mathcode(cosh, __x,
						       register long double
						       __ex = __expl(__x);
						       return 0.5 * (__ex +
								     1.0 /
								     __ex))
__inline_mathcode(tanh, __x, register long double __exm1 = __expm1l(-__fabsl(__x + __x)); return __exm1 / (__exm1 + 2.0) * __sgn1l(-__x)) __inline_mathcode(floor, __x, register long double __value; __volatile unsigned short int __cw; __volatile unsigned short int __cwtmp; __asm __volatile("fnstcw %0":"=m"(__cw)); __cwtmp = (__cw & 0xf3ff) | 0x0400;
																				/* rounding down */
__asm __volatile("fldcw %0": : "m"(__cwtmp)); __asm __volatile("frndint": "=t"(__value): "0"(__x)); __asm __volatile("fldcw %0": :				"m"(__cw)); return __value)
__inline_mathcode(ceil, __x, register long double __value; __volatile unsigned short int __cw; __volatile unsigned short int __cwtmp; __asm __volatile("fnstcw %0":"=m"(__cw)); __cwtmp = (__cw & 0xf3ff) | 0x0800;
							/* rounding up */
__asm __volatile("fldcw %0": : "m"(__cwtmp)); __asm __volatile("frndint": "=t"(__value): "0"(__x)); __asm __volatile("fldcw %0": :"m"(__cw));
		      return
		      __value)
#define __ldexp_code \
  register long double __value;						      \
  __asm __volatile__							      \
    ("fscale"								      \
     : "=t" (__value) : "0" (__x), "u" ((long double) __y));		      \
  return __value
__MATH_INLINE double ldexp(double __x, int __y);
__MATH_INLINE double ldexp(double __x, int __y)
{
    __ldexp_code;
}


/* Optimized versions for some non-standardized functions.  */
#if defined __USE_ISOC9X || defined __USE_MISC

__inline_mathcode(expm1, __x, __expm1_code)
/* We cannot rely on M_SQRT being defined.  So we do it for ourself
   here.  */
# define __M_SQRT2	1.41421356237309504880L	/* sqrt(2) */
    __inline_mathcode(log1p, __x,
		      register long double __value;
		      if (__fabsl(__x) >= 1.0 - 0.5 * __M_SQRT2)
		      __value = logl(1.0 + __x);
		      else
__asm __volatile__("fldln2\n\t" "fxch\n\t" "fyl2xp1": "=t"(__value):"0"(__x));
		      return
		      __value)


/* The argument range of the inline version of asinhl is slightly reduced.  */
    __inline_mathcode(asinh, __x,
		      register long double __y = __fabsl(__x);
		      return (log1pl
			      (__y * __y /
			       (__sqrtl(__y * __y + 1.0) + 1.0) +
			       __y) *
			      __sgn1l(__x))) __inline_mathcode(acosh, __x,
							       return
							       logl(__x +
								    __sqrtl
								    (__x -
								     1.0)
								    *
								    __sqrtl
								    (__x +
								     1.0)))
    __inline_mathcode(atanh, __x, register long double __y = __fabsl(__x);
		      return -0.5 * log1pl(-(__y + __y) / (1.0 + __y)) *
		      __sgn1l(__x))
/* The argument range of the inline version of hypotl is slightly reduced.  */
__inline_mathcode2(hypot, __x, __y, return __sqrtl(__x * __x + __y * __y)) __inline_mathcode(logb, __x, register long double __value; register long double __junk; __asm __volatile__("fxtract\n\t": "=t"(__junk), "=u"(__value):"0"(__x)); return __value)
#endif
#ifdef __USE_ISOC9X
    __inline_mathop(log2, "fld1; fxch; fyl2x")
__MATH_INLINE float ldexpf(float __x, int __y);
__MATH_INLINE float ldexpf(float __x, int __y)
{
    __ldexp_code;
}

__MATH_INLINE long double ldexpl(long double __x, int __y);
__MATH_INLINE long double ldexpl(long double __x, int __y)
{
    __ldexp_code;
}

__inline_mathcode3(fma, __x, __y, __z, return (__x * __y) + __z)
    __inline_mathop(rint, "frndint")
#define __lrint_code \
  long int __lrintres;							      \
  __asm__ __volatile__							      \
    ("fistpl %0"							      \
     : "=m" (__lrintres) : "t" (__x) : "st");				      \
  return __lrintres
__MATH_INLINE long int lrintf(float __x)
{
    __lrint_code;
}

__MATH_INLINE long int lrint(double __x)
{
    __lrint_code;
}

__MATH_INLINE long int lrintl(long double __x)
{
    __lrint_code;
}

#undef __lrint_code

#define __llrint_code \
  long long int __llrintres;						      \
  __asm__ __volatile__							      \
    ("fistpll %0"							      \
     : "=m" (__llrintres) : "t" (__x) : "st");				      \
  return __llrintres
__MATH_INLINE long long int llrintf(float __x)
{
    __llrint_code;
}

__MATH_INLINE long long int llrint(double __x)
{
    __llrint_code;
}

__MATH_INLINE long long int llrintl(long double __x)
{
    __llrint_code;
}

#undef __llrint_code

#endif


#ifdef __USE_MISC

__inline_mathcode2(drem, __x, __y, register double __value; register int __clobbered; __asm __volatile__("1:	fprem1\n\t" "fstsw	%%ax\n\t" "sahf\n\t" "jp	1b": "=t"(__value), "=&a"(__clobbered): "0"(__x), "u"(__y):"cc"); return __value)
/* This function is used in the `isfinite' macro.  */
#if 0
__MATH_INLINE int __finite(double __x) __attribute__ ((__const__));
__MATH_INLINE int __finite(double __x)
{
    return (__extension__(((((union {
			      double __d;
			      int __i[2];
			      }
			     ) {
  __d:			     __x}
			    ).__i[1] | 0x800fffff) + 1) >> 31));
}
#endif

/* Miscellaneous functions */

__inline_mathcode(__coshm1, __x,
		  register long double __exm1 = __expm1l(__fabsl(__x));
		  return 0.5 * (__exm1 / (__exm1 + 1.0)) * __exm1)
    __inline_mathcode(__acosh1p, __x,
		  return log1pl(__x + __sqrtl(__x) * __sqrtl(__x + 2.0)))
#endif				/* __USE_MISC  */
/* Undefine some of the large macros which are not used anymore.  */
#undef __expm1_code
#undef __exp_code
#undef __atan2_code
#undef __sincos_code
#endif				/* __NO_MATH_INLINES  */
/* This code is used internally in the GNU libc.  */
#ifdef __LIBC_INTERNAL_MATH_INLINES
__inline_mathop(__ieee754_sqrt, "fsqrt") __inline_mathcode2(__ieee754_atan2, __y, __x, register long double __value; __asm __volatile__("fpatan\n\t": "=t"(__value): "0"(__x), "u"(__y):"st(1)"); return __value;
    )
#endif
#endif				/* __GNUC__  */
#endif
#endif