/* * REMOVED FORMAL PARAMETERS FROM FUNCTION DEFINITIONS (1/4/92) */ #ifndef MPMATH_H #define MPMATH_H #ifndef _CMPLX_DEFINED #include "cmplx.h" #endif #ifdef XFRACT #define far #endif extern int DivideOverflow; /* Mark Peterson's expanded floating point operators. Automatically uses either the 8086 or 80386 processor type specified in global 'cpu'. If the operation results in an overflow (result < 2**(2**14), or division by zero) the global 'MPoverflow' is set to one. */ /*** Formula Declarations ***/ #define fDiv(x, y, z) (void)((*(long*)&z) = RegDivFloat(*(long*)&x, *(long*)&y)) #define fMul16(x, y, z) (void)((*(long*)&z) = r16Mul(*(long*)&x, *(long*)&y)) #define fShift(x, Shift, z) (void)((*(long*)&z) = \ RegSftFloat(*(long*)&x, Shift)) #define Fg2Float(x, f, z) (void)((*(long*)&z) = RegFg2Float(x, f)) #define Float2Fg(x, f) RegFloat2Fg(*(long*)&x, f) #define fLog14(x, z) (void)((*(long*)&z) = \ RegFg2Float(LogFloat14(*(long*)&x), 16)) #define fExp14(x, z) (void)((*(long*)&z) = ExpFloat14(*(long*)&x)); #define fSqrt14(x, z) fLog14(x, z); fShift(z, -1, z); fExp14(z, z) /* the following are declared 4 dimensional as an experiment */ /* changing declarations to _CMPLX */ /* to 2D */ union Arg { _CMPLX d; /* _DHCMPLX dh; _LHCMPLX lh; */ }; struct ConstArg { char *s; int len; union Arg a; }; extern union Arg *Arg1,*Arg2; extern void dStkSin(void),dStkCos(void),dStkSinh(void),dStkCosh(void),dStkLog(void),dStkExp(void),dStkSqr(void); extern void (*dtrig0)(void); extern void (*dtrig1)(void); extern void (*dtrig2)(void); extern void (*dtrig3)(void); /* -------------------------------------------------------------------- */ /* The following #defines allow the complex transcendental functions */ /* in parser.c to be used here thus avoiding duplicated code. */ /* -------------------------------------------------------------------- */ #ifndef XFRACT #define CMPLXmod(z) (sqr((z).x)+sqr((z).y)) #define CMPLXconj(z) ((z).y = -((z).y)) #endif /* XFRACT */ #define CMPLXtrig0(arg,out) Arg1->d = (arg); dtrig0(); (out)=Arg1->d #define CMPLXtrig1(arg,out) Arg1->d = (arg); dtrig1(); (out)=Arg1->d #define CMPLXtrig2(arg,out) Arg1->d = (arg); dtrig2(); (out)=Arg1->d #define CMPLXtrig3(arg,out) Arg1->d = (arg); dtrig3(); (out)=Arg1->d #define CMPLXsin(arg,out) Arg1->d = (arg); dStkSin(); (out) = Arg1->d #define CMPLXcos(arg,out) Arg1->d = (arg); dStkCos(); (out) = Arg1->d #define CMPLXsinh(arg,out) Arg1->d = (arg); dStkSinh(); (out) = Arg1->d #define CMPLXcosh(arg,out) Arg1->d = (arg); dStkCosh(); (out) = Arg1->d #define CMPLXlog(arg,out) Arg1->d = (arg); dStkLog(); (out) = Arg1->d #define CMPLXexp(arg,out) FPUcplxexp(&(arg), &(out)) /* #define CMPLXsqr(arg,out) Arg1->d = (arg); dStkSqr(); (out) = Arg1->d */ #define CMPLXsqr(arg,out) \ (out).x = sqr((arg).x) - sqr((arg).y);\ (out).y = ((arg).x+(arg).x) * (arg).y #define CMPLXsqr_old(out) \ (out).y = (old.x+old.x) * old.y;\ (out).x = tempsqrx - tempsqry #define CMPLXpwr(arg1,arg2,out) (out)= ComplexPower((arg1), (arg2)) #define CMPLXmult1(arg1,arg2,out) Arg2->d = (arg1); Arg1->d = (arg2);\ dStkMul(); Arg1++; Arg2++; (out) = Arg2->d #define CMPLXmult(arg1,arg2,out) \ {\ _CMPLX TmP;\ TmP.x = (arg1).x*(arg2).x - (arg1).y*(arg2).y;\ TmP.y = (arg1).x*(arg2).y + (arg1).y*(arg2).x;\ (out) = TmP;\ } #define CMPLXadd(arg1,arg2,out) \ (out).x = (arg1).x + (arg2).x; (out).y = (arg1).y + (arg2).y #define CMPLXsub(arg1,arg2,out) \ (out).x = (arg1).x - (arg2).x; (out).y = (arg1).y - (arg2).y #define CMPLXtimesreal(arg,real,out) \ (out).x = (arg).x*(real);\ (out).y = (arg).y*(real) #define CMPLXrecip(arg,out) \ { double denom; denom = sqr((arg).x) + sqr((arg).y);\ if(denom==0.0) {(out).x = 1.0e10;(out).y = 1.0e10;}else\ { (out).x = (arg).x/denom;\ (out).y = -(arg).y/denom;}} #endif