/* Copyright (C) 1991, 1992 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., 675 Mass Ave, Cambridge, MA 02139, USA. */ #ifdef __GNUC__ #include __BEGIN_DECLS #ifdef __NO_MATH_INLINES #define __m81_u(x) __CONCAT(__,x) #else #define __m81_u(x) x #define __MATH_INLINES 1 #endif #define __inline_mathop2(func, op) \ extern __inline __CONSTVALUE double \ __m81_u(func)(double __mathop_x) __CONSTVALUE2; \ extern __inline __CONSTVALUE double \ __m81_u(func)(double __mathop_x) \ { \ double __result; \ __asm("f" __STRING(op) "%.x %1, %0" : "=f" (__result) : "f" (__mathop_x));\ return __result; \ } #define __inline_mathop(op) __inline_mathop2(op, op) __inline_mathop(acos) __inline_mathop(asin) __inline_mathop(atan) __inline_mathop(cos) __inline_mathop(sin) __inline_mathop(tan) __inline_mathop(cosh) __inline_mathop(sinh) __inline_mathop(tanh) __inline_mathop2(exp, etox) __inline_mathop2(fabs, abs) __inline_mathop(log10) __inline_mathop2(log, logn) __inline_mathop2(floor, intrz) __inline_mathop(sqrt) __inline_mathop2(__rint, int) __inline_mathop2(__expm1, etoxm1) #ifdef __USE_MISC __inline_mathop2(rint, int) __inline_mathop2(expm1, etoxm1) __inline_mathop2(log1p, lognp1) __inline_mathop(atanh) #endif extern __inline __CONSTVALUE double __m81_u(__drem)(double __x, double __y) __CONSTVALUE2; extern __inline __CONSTVALUE double __m81_u(__drem)(double __x, double __y) { double __result; __asm("frem%.x %1, %0" : "=f" (__result) : "f" (__y), "0" (__x)); return __result; } extern __inline __CONSTVALUE double __m81_u(ldexp)(double __x, int __e) __CONSTVALUE2; extern __inline __CONSTVALUE double __m81_u(ldexp)(double __x, int __e) { double __result; double __double_e = (double) __e; __asm("fscale%.x %1, %0" : "=f" (__result) : "f" (__double_e), "0" (__x)); return __result; } extern __inline __CONSTVALUE double __m81_u(fmod)(double __x, double __y) __CONSTVALUE2; extern __inline __CONSTVALUE double __m81_u(fmod)(double __x, double __y) { double __result; __asm("fmod%.x %1, %0" : "=f" (__result) : "f" (__y), "0" (__x)); return __result; } extern __inline double __m81_u(frexp)(double __value, int *__expptr); extern __inline double __m81_u(frexp)(double __value, int *__expptr) { double __mantissa, __exponent; __asm("fgetexp%.x %1, %0" : "=f" (__exponent) : "f" (__value)); __asm("fgetman%.x %1, %0" : "=f" (__mantissa) : "f" (__value)); *__expptr = (int) __exponent; return __mantissa; } extern __inline __CONSTVALUE double __m81_u(pow)(double __x, double __y) __CONSTVALUE2; extern __inline __CONSTVALUE double __m81_u(pow)(double __x, double __y) { double __result; if (__y == 0.0 || __x == 1.0) __result = 1.0; else if (__y == 1.0) __result = __x; else if (__y == 2.0) __result = __x * __x; else if (__x == 10.0) __asm("ftentox%.x %1, %0" : "=f" (__result) : "f" (__y)); else if (__x == 2.0) __asm("ftwotox%.x %1, %0" : "=f" (__result) : "f" (__y)); else if (__x < 0.0) { double __temp = __m81_u (floor) (__y); if (__y == __temp) { int i = (int) __y; __result = __m81_u (exp) (__y * __m81_u (log) (-__x)); if (i & 1) __result = -__result; } else __result = __m81_u (exp) (__y * __m81_u (log) (__x)); } else __result = __m81_u(exp)(__y * __m81_u(log)(__x)); return __result; } extern __inline __CONSTVALUE double __m81_u(ceil)(double __x) __CONSTVALUE2; extern __inline __CONSTVALUE double __m81_u(ceil)(double __x) { double __result; unsigned long int __ctrl_reg; __asm("fmove%.l fpcr, %0" : "=g" (__ctrl_reg)); /* Set rounding towards positive infinity. */ __asm("fmove%.l %0, fpcr" : /* No outputs. */ : "g" (__ctrl_reg | 0x30)); /* Convert X to an integer, using +Inf rounding. */ __asm("fint%.x %1, %0" : "=f" (__result) : "f" (__x)); /* Restore the previous rounding mode. */ __asm("fmove%.l %0, fpcr" : /* No outputs. */ : "g" (__ctrl_reg)); return __result; } extern __inline double __m81_u(modf)(double __value, double *__iptr); extern __inline double __m81_u(modf)(double __value, double *__iptr) { double __modf_int = __m81_u(floor)(__value); *__iptr = __modf_int; return __value - __modf_int; } extern __inline __CONSTVALUE int __m81_u(__isinf)(double __value) __CONSTVALUE2; extern __inline __CONSTVALUE int __m81_u(__isinf)(double __value) { /* There is no branch-condition for infinity, so we must extract and examine the condition codes manually. */ unsigned long int __fpsr; __asm("ftst%.x %1\n" "fmove%.l fpsr, %0" : "=g" (__fpsr) : "f" (__value)); return (__fpsr & (2 << (3 * 8))) ? (__value < 0 ? -1 : 1) : 0; } extern __inline __CONSTVALUE int __m81_u(__isnan)(double __value) __CONSTVALUE2; extern __inline __CONSTVALUE int __m81_u(__isnan)(double __value) { char __result; __asm("ftst%.x %1\n" "fsun %0" : "=g" (__result) : "f" (__value)); return __result; } __END_DECLS #endif /* GCC. */