/* Math functions for i387. Copyright (C) 1995, 1996, 1997 Free Software Foundation, Inc. This file is part of the GNU C Library. Contributed by John C. Bowman , 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. */ #include #include double atan (double __x); double atan2 (double __y, double __x); double ceil (double __x); double cos (double __x); double fabs (double __x); double floor (double __x); long _ftol (double fl); double log (double __x); double __log2 (double __x); double pow (double __x, double __y); double sin (double __x); double sqrt (double __x); double tan (double __x); div_t div(int num, int denom); int mod(int num, int denom); double atan (double __x) { register double __value; __asm __volatile__ ("fld1\n\t" "fpatan" : "=t" (__value) : "0" (__x)); return __value; } double atan2 (double __y, double __x) { register double __value; __asm __volatile__ ("fpatan\n\t" "fld %%st(0)" : "=t" (__value) : "0" (__x), "u" (__y)); return __value; } double ceil (double __x) { register double __value; __volatile unsigned short int __cw, __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; } double cos (double __x) { register double __value; __asm __volatile__ ("fcos" : "=t" (__value): "0" (__x)); return __value; } double fabs (double __x) { register double __value; __asm __volatile__ ("fabs" : "=t" (__value) : "0" (__x)); return __value; } double floor (double __x) { register double __value; __volatile unsigned short int __cw, __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; } long _ftol (double fl) { return (long)fl; } double log (double __x) { register double __value; __asm __volatile__ ("fldln2\n\t" "fxch\n\t" "fyl2x" : "=t" (__value) : "0" (__x)); return __value; } double __log2 (double __x) { register double __value; __asm __volatile__ ("fld1\n\t" "fxch\n\t" "fyl2x" : "=t" (__value) : "0" (__x)); return __value; } double pow (double __x, double __y) { register double __value, __exponent; long __p = (long) __y; if (__x == 0.0 && __y > 0.0) return 0.0; if (__y == (double) __p) { 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__ ("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" (__log2 (__x)), "1" (__y)); __value += 1.0; __asm __volatile__ ("fscale" : "=t" (__value) : "0" (__value), "u" (__exponent)); return __value; } double sin (double __x) { register double __value; __asm __volatile__ ("fsin" : "=t" (__value) : "0" (__x)); return __value; } double sqrt (double __x) { register double __value; __asm __volatile__ ("fsqrt" : "=t" (__value) : "0" (__x)); return __value; } double tan (double __x) { register double __value; register double __value2 __attribute__ ((unused)); __asm __volatile__ ("fptan" : "=t" (__value2), "=u" (__value) : "0" (__x)); return __value; } div_t div(int num, int denom) { div_t r; if (num > 0 && denom < 0) { num = -num; denom = -denom; } r.quot = num / denom; r.rem = num % denom; if (num < 0 && denom > 0) { if (r.rem > 0) { r.quot++; r.rem -= denom; } } return r; } int mod(int num, int denom) { div_t dvt = div(num, denom); return dvt.rem; } //FIXME! Is there a better algorithm. like FT_MulDiv INT STDCALL EngMulDiv( INT nMultiplicand, INT nMultiplier, INT nDivisor) { #if SIZEOF_LONG_LONG >= 8 long long ret; if (!nDivisor) return -1; /* We want to deal with a positive divisor to simplify the logic. */ if (nDivisor < 0) { nMultiplicand = - nMultiplicand; nDivisor = -nDivisor; } /* If the result is positive, we "add" to round. else, we subtract to round. */ if ( ( (nMultiplicand < 0) && (nMultiplier < 0) ) || ( (nMultiplicand >= 0) && (nMultiplier >= 0) ) ) ret = (((long long)nMultiplicand * nMultiplier) + (nDivisor/2)) / nDivisor; else ret = (((long long)nMultiplicand * nMultiplier) - (nDivisor/2)) / nDivisor; if ((ret > 2147483647) || (ret < -2147483647)) return -1; return ret; #else if (!nDivisor) return -1; /* We want to deal with a positive divisor to simplify the logic. */ if (nDivisor < 0) { nMultiplicand = - nMultiplicand; nDivisor = -nDivisor; } /* If the result is positive, we "add" to round. else, we subtract to round. */ if ( ( (nMultiplicand < 0) && (nMultiplier < 0) ) || ( (nMultiplicand >= 0) && (nMultiplier >= 0) ) ) return ((nMultiplicand * nMultiplier) + (nDivisor/2)) / nDivisor; return ((nMultiplicand * nMultiplier) - (nDivisor/2)) / nDivisor; #endif }