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Text File | 1991-06-16 | 45KB | 1,705 lines

/* Parser.c (C) 1990, Mark C. Peterson, CompuServe [70441,3353] All rights reserved. Code may be used in any program provided the author is credited either during program execution or in the documentation. Source code may be distributed only in combination with public domain or shareware source code. Source code may be modified provided the copyright notice and this message is left unchanged and all modifications are clearly documented. I would appreciate a copy of any work which incorporates this code, however this is optional. Mark C. Peterson 405-C Queen St. Suite #181 Southington, CT 06489 (203) 276-9721 */ #include <string.h> #include <ctype.h> #include <stdio.h> #include <stdlib.h> #include <float.h> /* TIW 04-22-91 */ #include "mpmath.h" extern far_strlen( char far *); /* TIW 03-31-91 */ extern far_strnicmp(char far *, char far *,int); /* TIW 03-31-91 */ void findpath(char *filename, char *fullpathname); void far *farmemalloc(long bytestoalloc); void farmemfree(void far *farptr); int stopmsg(int,unsigned char far *); #ifdef WATCH_MP double x1, y1, x2, y2; #endif MATH_TYPE MathType = D_MATH; /* moved struct lcomplex and union ARg to mpmath.h -6-20-90 TIW */ /* PB 910417 added MAX_OPS and MAX_ARGS defines */ #define MAX_ARGS 100 struct ConstArg { char *s; int len; union Arg a; }; #define MAX_OPS 250 struct PEND_OP { void (far *f)(void); int p; }; /* PB 901103 made some of the following static for safety */ static struct PEND_OP far *o; static void parser_allocate(void); static void free_workarea(); union Arg *Arg1, *Arg2; /* PB 910417 removed unused "a" array */ static union Arg s[20], far * far *Store, far * far *Load; static int StoPtr, LodPtr, OpPtr; static void (far * far *f)(void) = (void(far * far *)(void))0; static unsigned n, ErrPtr, posp, vsp, NextOp, LastOp, InitN; static int paren, SyntaxErr, ExpectingArg; static struct ConstArg far *v = (struct ConstArg far *)0; static int InitLodPtr, InitStoPtr, InitOpPtr, LastInitOp; static int Delta16; double fgLimit; /* TIW 05-04-91 */ static double fg; static int ShiftBack; /* TIW 06-18-90 */ extern int bitshift; extern int bitshiftless1; extern long multiply(long x, long y, int bitshift); extern long divide(long x, long y, int bitshift); extern int symmetry; /* symmetry flag for calcmand() */ extern double param[]; extern int debugflag; /* BDT for debugging */ extern char boxx[8192]; /* PB 4-9-91, good place for the formula string */ extern int row, col, overflow, cpu, fpu; extern struct complex old, new; extern double far *dx0, far *dy0; extern long far *lx0, far *ly0; /* BDT moved these to FAR */ #ifndef TESTING_MATH extern double far *dx1, far *dy1; extern long far *lx1, far *ly1; #define dShiftx dx1[row] #define dShifty dy1[col] #define lShiftx lx1[row] #define lShifty ly1[col] #else #define dShiftx 0.0 #define dShifty 0.0 #define lShiftx 0L #define lShifty 0L #endif extern struct lcomplex lold, lnew; extern char FormName[]; extern void far *typespecific_workarea; #define LastSqr v[4].a static char far * far ErrStrings[] = { /* TIW 03-31-91 added far */ "Should be an Argument", "Should be an Operator", "')' needs a matching '('", "Need more ')'", "Undefined Operator", "Undefined Function", "More than one ','", "Table overflow" }; unsigned SkipWhiteSpace(char *Str) { unsigned n, Done; for(Done = n = 0; !Done; n++) { switch(Str[n]) { case ' ': case '\t': case '\n': case '\r': break; default: Done = 1; } } return(n - 1); } void dStkAbs(void) { Arg1->d.x = fabs(Arg1->d.x); Arg1->d.y = fabs(Arg1->d.y); } void mStkAbs(void) { if(Arg1->m.x.Exp < 0) Arg1->m.x.Exp = -Arg1->m.x.Exp; if(Arg1->m.y.Exp < 0) Arg1->m.y.Exp = -Arg1->m.y.Exp; } void lStkAbs(void) { Arg1->l.x = labs(Arg1->l.x); Arg1->l.y = labs(Arg1->l.y); } void (*StkAbs)(void) = dStkAbs; void dStkSqr(void) { LastSqr.d.x = Arg1->d.x * Arg1->d.x; LastSqr.d.y = Arg1->d.y * Arg1->d.y; Arg1->d.y = Arg1->d.x * Arg1->d.y * 2.0; Arg1->d.x = LastSqr.d.x - LastSqr.d.y; LastSqr.d.x += LastSqr.d.y; LastSqr.d.y = 0; } void mStkSqr(void) { LastSqr.m.x = *MPmul(Arg1->m.x, Arg1->m.x); LastSqr.m.y = *MPmul(Arg1->m.y, Arg1->m.y); Arg1->m.y = *MPmul(Arg1->m.x, Arg1->m.y); Arg1->m.y.Exp++; Arg1->m.x = *MPsub(LastSqr.m.x, LastSqr.m.y); LastSqr.m.x = *MPadd(LastSqr.m.x, LastSqr.m.y); LastSqr.m.y.Mant = (long)(LastSqr.m.y.Exp = 0); } void lStkSqr(void) { LastSqr.l.x = multiply(Arg1->l.x, Arg1->l.x, bitshift); LastSqr.l.y = multiply(Arg1->l.y, Arg1->l.y, bitshift); Arg1->l.y = multiply(Arg1->l.x, Arg1->l.y, bitshift) << 1; Arg1->l.x = LastSqr.l.x - LastSqr.l.y; LastSqr.l.x += LastSqr.l.y; LastSqr.l.y = 0L; } void (*StkSqr)(void) = dStkSqr; void dStkAdd(void) { Arg2->d.x += Arg1->d.x; Arg2->d.y += Arg1->d.y; Arg1--; Arg2--; } void mStkAdd(void) { Arg2->m = MPCadd(Arg2->m, Arg1->m); Arg1--; Arg2--; } void lStkAdd(void) { Arg2->l.x += Arg1->l.x; Arg2->l.y += Arg1->l.y; Arg1--; Arg2--; } void (*StkAdd)(void) = dStkAdd; void dStkSub(void) { Arg2->d.x -= Arg1->d.x; Arg2->d.y -= Arg1->d.y; Arg1--; Arg2--; } void mStkSub(void) { Arg2->m = MPCsub(Arg2->m, Arg1->m); Arg1--; Arg2--; } void lStkSub(void) { Arg2->l.x -= Arg1->l.x; Arg2->l.y -= Arg1->l.y; Arg1--; Arg2--; } void (*StkSub)(void) = dStkSub; void dStkConj(void) { Arg1->d.y = -Arg1->d.y; } void mStkConj(void) { Arg1->m.y.Exp ^= 0x8000; } void lStkConj(void) { Arg1->l.y = -Arg1->l.y; } void (*StkConj)(void) = dStkConj; void dStkReal(void) { Arg1->d.y = 0.0; } void mStkReal(void) { Arg1->m.y.Mant = (long)(Arg1->m.y.Exp = 0); } void lStkReal(void) { Arg1->l.y = 0l; } void (*StkReal)(void) = dStkReal; void dStkImag(void) { Arg1->d.x = Arg1->d.y; Arg1->d.y = 0.0; } void mStkImag(void) { Arg1->m.x = Arg1->m.y; Arg1->m.y.Mant = (long)(Arg1->m.y.Exp = 0); } void lStkImag(void) { Arg1->l.x = Arg1->l.y; Arg1->l.y = 0l; } void (*StkImag)(void) = dStkImag; void dStkNeg(void) { Arg1->d.x = -Arg1->d.x; Arg1->d.y = -Arg1->d.y; } void mStkNeg(void) { Arg1->m.x.Exp ^= 0x8000; Arg1->m.y.Exp ^= 0x8000; } void lStkNeg(void) { Arg1->l.x = -Arg1->l.x; Arg1->l.y = -Arg1->l.y; } void (*StkNeg)(void) = dStkNeg; void dStkMul(void) { FPUcplxmul(&Arg2->d, &Arg1->d, &Arg2->d); Arg1--; Arg2--; } void mStkMul(void) { Arg2->m = MPCmul(Arg2->m, Arg1->m); Arg1--; Arg2--; } void lStkMul(void) { long x, y; x = multiply(Arg2->l.x, Arg1->l.x, bitshift) - multiply(Arg2->l.y, Arg1->l.y, bitshift); y = multiply(Arg2->l.y, Arg1->l.x, bitshift) + multiply(Arg2->l.x, Arg1->l.y, bitshift); Arg2->l.x = x; Arg2->l.y = y; Arg1--; Arg2--; } void (*StkMul)(void) = dStkMul; void dStkDiv(void) { FPUcplxdiv(&Arg2->d, &Arg1->d, &Arg2->d); Arg1--; Arg2--; } void mStkDiv(void) { Arg2->m = MPCdiv(Arg2->m, Arg1->m); Arg1--; Arg2--; } void lStkDiv(void) { long x, y, mod, x2, y2; mod = multiply(Arg1->l.x, Arg1->l.x, bitshift) + multiply(Arg1->l.y, Arg1->l.y, bitshift); x = divide(Arg1->l.x, mod, bitshift); y = -divide(Arg1->l.y, mod, bitshift); /* pb 900617 changed next 4 lines to use x2,y2 instead of x,y */ x2 = multiply(Arg2->l.x, x, bitshift) - multiply(Arg2->l.y, y, bitshift); y2 = multiply(Arg2->l.y, x, bitshift) + multiply(Arg2->l.x, y, bitshift); Arg2->l.x = x2; Arg2->l.y = y2; Arg1--; Arg2--; } void (*StkDiv)(void) = dStkDiv; void StkSto(void) { *Store[StoPtr++] = *Arg1; } void StkLod(void) { Arg1++; Arg2++; *Arg1 = *Load[LodPtr++]; } void dStkMod(void) { Arg1->d.x = (Arg1->d.x * Arg1->d.x) + (Arg1->d.y * Arg1->d.y); Arg1->d.y = 0.0; } void mStkMod(void) { Arg1->m.x = MPCmod(Arg1->m); Arg1->m.y.Mant = (long)(Arg1->m.y.Exp = 0); } void lStkMod(void) { Arg1->l.x = multiply(Arg2->l.x, Arg1->l.x, bitshift) + multiply(Arg2->l.y, Arg1->l.y, bitshift); if(Arg1->l.x < 0) overflow = 1; Arg1->l.y = 0L; } void (*StkMod)(void) = dStkMod; void StkClr(void) { s[0] = *Arg1; Arg1 = &s[0]; Arg2 = Arg1; Arg2--; } /* MCP 4-9-91, Added Flip() */ void dStkFlip(void) { double t; t = Arg1->d.x; Arg1->d.x = Arg1->d.y; Arg1->d.y = t; } void mStkFlip(void) { struct MP t; t = Arg1->m.x; Arg1->m.x = Arg1->m.y; Arg1->m.y = t; } void lStkFlip(void) { long t; t = Arg1->l.x; Arg1->l.x = Arg1->l.y; Arg1->l.y = t; } void (*StkFlip)(void) = dStkFlip; void dStkSin(void) { double sinx, cosx, sinhy, coshy; FPUsincos(&Arg1->d.x, &sinx, &cosx); FPUsinhcosh(&Arg1->d.y, &sinhy, &coshy); Arg1->d.x = sinx*coshy; Arg1->d.y = cosx*sinhy; } void mStkSin(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkSin(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkSin(void) { long x, y, sinx, cosx, sinhy, coshy; x = Arg1->l.x >> Delta16; y = Arg1->l.y >> Delta16; SinCos086(x, &sinx, &cosx); SinhCosh086(y, &sinhy, &coshy); Arg1->l.x = multiply(sinx, coshy, ShiftBack); /* TIW 06-18-90 */ Arg1->l.y = multiply(cosx, sinhy, ShiftBack); /* TIW 06-18-90 */ } void (*StkSin)(void) = dStkSin; /* The following functions are supported by both the parser and for fn variable replacement. TIW 04-22-91 */ void dStkTan(void) { double sinx, cosx, sinhy, coshy, denom; Arg1->d.x *= 2; Arg1->d.y *= 2; FPUsincos(&Arg1->d.x, &sinx, &cosx); FPUsinhcosh(&Arg1->d.y, &sinhy, &coshy); denom = cosx + coshy; if(fabs(denom) <= DBL_MIN) return; Arg1->d.x = sinx/denom; Arg1->d.y = sinhy/denom; } void mStkTan(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkTan(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkTan(void) { long x, y, sinx, cosx, sinhy, coshy, denom; x = Arg1->l.x >> (Delta16-1); y = Arg1->l.y >> (Delta16-1); SinCos086(x, &sinx, &cosx); SinhCosh086(y, &sinhy, &coshy); denom = cosx + coshy; if(denom == 0) return; Arg1->l.x = divide(sinx,denom,bitshift); Arg1->l.y = divide(sinhy,denom,bitshift); } void (*StkTan)(void) = dStkTan; void dStkTanh(void) { double siny, cosy, sinhx, coshx, denom; Arg1->d.x *= 2; Arg1->d.y *= 2; FPUsincos(&Arg1->d.y, &siny, &cosy); FPUsinhcosh(&Arg1->d.x, &sinhx, &coshx); denom = coshx + cosy; if(fabs(denom) <= DBL_MIN) return; Arg1->d.x = sinhx/denom; Arg1->d.y = siny/denom; } void mStkTanh(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkTanh(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkTanh(void) { long x, y, siny, cosy, sinhx, coshx, denom; x = Arg1->l.x >> (Delta16-1); y = Arg1->l.y >> (Delta16-1); SinCos086(y, &siny, &cosy); SinhCosh086(x, &sinhx, &coshx); denom = coshx + cosy; if(denom == 0) return; Arg1->l.x = divide(sinhx,denom,bitshift); Arg1->l.y = divide(siny,denom,bitshift); } void (*StkTanh)(void) = dStkTanh; void dStkCoTan(void) { double sinx, cosx, sinhy, coshy, denom; Arg1->d.x *= 2; Arg1->d.y *= 2; FPUsincos(&Arg1->d.x, &sinx, &cosx); FPUsinhcosh(&Arg1->d.y, &sinhy, &coshy); denom = coshy - cosx; if(fabs(denom) <= DBL_MIN) return; Arg1->d.x = sinx/denom; Arg1->d.y = -sinhy/denom; } void mStkCoTan(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkCoTan(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkCoTan(void) { long x, y, sinx, cosx, sinhy, coshy, denom; x = Arg1->l.x >> (Delta16-1); y = Arg1->l.y >> (Delta16-1); SinCos086(x, &sinx, &cosx); SinhCosh086(y, &sinhy, &coshy); denom = coshy - cosx; if(denom == 0) return; Arg1->l.x = divide(sinx,denom,bitshift); Arg1->l.y = -divide(sinhy,denom,bitshift); } void (*StkCoTan)(void) = dStkCoTan; void dStkCoTanh(void) { double siny, cosy, sinhx, coshx, denom; Arg1->d.x *= 2; Arg1->d.y *= 2; FPUsincos(&Arg1->d.y, &siny, &cosy); FPUsinhcosh(&Arg1->d.x, &sinhx, &coshx); denom = coshx - cosy; if(fabs(denom) <= DBL_MIN) return; Arg1->d.x = sinhx/denom; Arg1->d.y = -siny/denom; } void mStkCoTanh(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkCoTanh(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkCoTanh(void) { long x, y, siny, cosy, sinhx, coshx, denom; x = Arg1->l.x >> (Delta16-1); y = Arg1->l.y >> (Delta16-1); SinCos086(y, &siny, &cosy); SinhCosh086(x, &sinhx, &coshx); denom = coshx - cosy; if(denom == 0) return; Arg1->l.x = divide(sinhx,denom,bitshift); Arg1->l.y = -divide(siny,denom,bitshift); } void (*StkCoTanh)(void) = dStkCoTanh; /* The following functions are not directly used by the parser - support for the parser was not provided because the existing parser language represents these quite easily. They are used for fn variable support in miscres.c but are placed here because they follow the pattern of the other parser functions. TIW 04-22-91 */ void dStkRecip(void) { double mod; mod =Arg1->d.x * Arg1->d.x + Arg1->d.y * Arg1->d.y; if(mod <= DBL_MIN) return; Arg1->d.x = Arg1->d.x/mod; Arg1->d.y = -Arg1->d.y/mod; } void mStkRecip(void) { struct MP mod; mod = *MPadd(*MPmul(Arg1->m.x, Arg1->m.x),*MPmul(Arg1->m.y, Arg1->m.y)); if(mod.Mant <= 0L) return; Arg1->m.x = *MPdiv(Arg1->m.x,mod); Arg1->m.y = *MPdiv(Arg1->m.y,mod); Arg1->m.y.Exp ^= 0x8000; } void lStkRecip(void) { long mod; mod = multiply(Arg1->l.x,Arg1->l.x,bitshift) + multiply(Arg1->l.y,Arg1->l.y,bitshift); if(mod<=0L) return; Arg1->l.x = divide(Arg1->l.x,mod,bitshift); Arg1->l.y = -divide(Arg1->l.y,mod,bitshift); } void StkIdent(void) { /* do nothing - the function Z */ } /* End TIW 04-22-91 */ void dStkSinh(void) { double siny, cosy, sinhx, coshx; FPUsincos(&Arg1->d.y, &siny, &cosy); FPUsinhcosh(&Arg1->d.x, &sinhx, &coshx); Arg1->d.x = sinhx*cosy; Arg1->d.y = coshx*siny; } void mStkSinh(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkSinh(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkSinh(void) { long x, y, sinhx, coshx, siny, cosy; x = Arg1->l.x >> Delta16; y = Arg1->l.y >> Delta16; SinCos086(y, &siny, &cosy); SinhCosh086(x, &sinhx, &coshx); Arg1->l.x = multiply(cosy, sinhx, ShiftBack); /* TIW 06-18-90 */ Arg1->l.y = multiply(siny, coshx, ShiftBack); /* TIW 06-18-90 */ } void (*StkSinh)(void) = dStkSinh; void dStkCos(void) { double sinx, cosx, sinhy, coshy; FPUsincos(&Arg1->d.x, &sinx, &cosx); FPUsinhcosh(&Arg1->d.y, &sinhy, &coshy); Arg1->d.x = cosx*coshy; Arg1->d.y = -sinx*sinhy; /* TIW 04-25-91 sign */ } void mStkCos(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkCos(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkCos(void) { long x, y, sinx, cosx, sinhy, coshy; x = Arg1->l.x >> Delta16; y = Arg1->l.y >> Delta16; SinCos086(x, &sinx, &cosx); SinhCosh086(y, &sinhy, &coshy); Arg1->l.x = multiply(cosx, coshy, ShiftBack); /* TIW 06-18-90 */ Arg1->l.y = -multiply(sinx, sinhy, ShiftBack); /* TIW 04-25-91 sign */ } void (*StkCos)(void) = dStkCos; /* Bogus version of cos, to replicate bug which was in regular cos till v16: */ void dStkCosXX(void) { dStkCos(); Arg1->d.y = -Arg1->d.y; } void mStkCosXX(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkCosXX(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkCosXX(void) { lStkCos(); Arg1->l.y = -Arg1->l.y; } void (*StkCosXX)(void) = dStkCosXX; void dStkCosh(void) { double siny, cosy, sinhx, coshx; FPUsincos(&Arg1->d.y, &siny, &cosy); FPUsinhcosh(&Arg1->d.x, &sinhx, &coshx); Arg1->d.x = coshx*cosy; Arg1->d.y = sinhx*siny; } void mStkCosh(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkCosh(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkCosh(void) { long x, y, sinhx, coshx, siny, cosy; x = Arg1->l.x >> Delta16; y = Arg1->l.y >> Delta16; SinCos086(y, &siny, &cosy); SinhCosh086(x, &sinhx, &coshx); Arg1->l.x = multiply(cosy, coshx, ShiftBack); /* TIW 06-18-90 */ Arg1->l.y = multiply(siny, sinhx, ShiftBack); /* TIW 06-18-90 */ } void (*StkCosh)(void) = dStkCosh; void dStkLT(void) { Arg2->d.x = (double)(Arg2->d.x < Arg1->d.x); Arg2->d.y = 0.0; Arg1--; Arg2--; } void mStkLT(void) { Arg2->m.x = *fg2MP((long)(MPcmp(Arg2->m.x, Arg1->m.x) == -1), 0); Arg2->m.y.Mant = (long)(Arg2->m.y.Exp = 0); Arg1--; Arg2--; } void lStkLT(void) { Arg2->l.x = Arg2->l.x < Arg1->l.x; Arg2->l.y = 0l; Arg1--; Arg2--; } void (*StkLT)(void) = dStkLT; void dStkLTE(void) { Arg2->d.x = (double)(Arg2->d.x <= Arg1->d.x); Arg2->d.y = 0.0; Arg1--; Arg2--; } void mStkLTE(void) { int comp; comp = MPcmp(Arg2->m.x, Arg1->m.x); Arg2->m.x = *fg2MP((long)(comp == -1 || comp == 0), 0); Arg2->m.y.Mant = (long)(Arg2->m.y.Exp = 0); Arg1--; Arg2--; } void lStkLTE(void) { Arg2->l.x = Arg2->l.x <= Arg1->l.x; Arg2->l.y = 0l; Arg1--; Arg2--; } void (*StkLTE)(void) = dStkLTE; void dStkLog(void) { FPUcplxlog(&Arg1->d, &Arg1->d); } void mStkLog(void) { Arg1->d = MPC2cmplx(Arg1->m); dStkLog(); Arg1->m = cmplx2MPC(Arg1->d); } void lStkLog(void) { struct complex x; x.x = (double)Arg1->l.x / fg; x.y = (double)Arg1->l.y / fg; FPUcplxlog(&x, &x); if(fabs(x.x) < fgLimit && fabs(x.y) < fgLimit) { Arg1->l.x = (long)(x.x * fg); Arg1->l.y = (long)(x.y * fg); } else overflow = 1; } void (*StkLog)(void) = dStkLog; void FPUcplxexp(struct complex *x, struct complex *z) { double e2x, siny, cosy; if(fpu == 387) FPUcplxexp387(x, z); else { e2x = exp(x->x); FPUsincos(&x->y, &siny, &cosy); z->x = e2x * cosy; z->y = e2x * siny; } } void dStkExp(void) { FPUcplxexp(&Arg1->d, &Arg1->d); } void mStkExp(void) { Arg1->d = MPC2cmplx(Arg1->m); FPUcplxexp(&Arg1->d, &Arg1->d); Arg1->m = cmplx2MPC(Arg1->d); } void lStkExp(void) { struct complex x; x.x = (double)Arg1->l.x / fg; x.y = (double)Arg1->l.y / fg; FPUcplxexp(&x, &x); if(fabs(x.x) < fgLimit && fabs(x.y) < fgLimit) { Arg1->l.x = (long)(x.x * fg); Arg1->l.y = (long)(x.y * fg); } else overflow = 1; } void (*StkExp)(void) = dStkExp; void dStkPwr(void) { Arg2->d = ComplexPower(Arg2->d, Arg1->d); Arg1--; Arg2--; } void mStkPwr(void) { struct complex x, y; x = MPC2cmplx(Arg2->m); y = MPC2cmplx(Arg1->m); x = ComplexPower(x, y); Arg2->m = cmplx2MPC(x); Arg1--; Arg2--; } void lStkPwr(void) { struct complex x, y; x.x = (double)Arg2->l.x / fg; x.y = (double)Arg2->l.y / fg; y.x = (double)Arg1->l.x / fg; y.y = (double)Arg1->l.y / fg; x = ComplexPower(x, y); if(fabs(x.x) < fgLimit && fabs(x.y) < fgLimit) { Arg2->l.x = (long)(x.x * fg); Arg2->l.y = (long)(x.y * fg); } else overflow = 1; Arg1--; Arg2--; } void (*StkPwr)(void) = dStkPwr; void EndInit(void) { LastInitOp = OpPtr; } struct ConstArg far *isconst(char *Str, int Len) { struct complex z; unsigned n, j; for(n = 0; n < vsp; n++) { if(v[n].len == Len) { if(!strnicmp(v[n].s, Str, Len)) return(&v[n]); } } v[vsp].s = Str; v[vsp].len = Len; v[vsp].a.d.x = v[vsp].a.d.y = 0.0; if(isdigit(Str[0]) || Str[0] == '.') { if(o[posp-1].f == StkNeg) { posp--; Str = Str - 1; InitN--; } for(n = 1; isdigit(Str[n]) || Str[n] == '.'; n++); if(Str[n] == ',') { j = n + SkipWhiteSpace(&Str[n+1]) + 1; if(isdigit(Str[j]) || (Str[j] == '-' && isdigit(Str[j+1]))) { z.y = atof(&Str[j]); for(; isdigit(Str[j]) || Str[j] == '.' || Str[j] == '-'; j++); v[vsp].len = j; } else z.y = 0.0; } else z.y = 0.0; z.x = atof(Str); switch(MathType) { case D_MATH: v[vsp].a.d = z; break; case M_MATH: v[vsp].a.m = cmplx2MPC(z); break; case L_MATH: v[vsp].a.l.x = (long)(z.x * fg); v[vsp].a.l.y = (long)(z.y * fg); break; } v[vsp].s = Str; } return(&v[vsp++]); } struct FNCT_LIST { char far *s; /* TIW 03-31-91 added far */ void (**ptr)(void); }; /* TIW 03-30-91 START */ extern unsigned char trigndx[]; extern void (*ltrig0)(); extern void (*ltrig1)(); extern void (*ltrig2)(); extern void (*ltrig3)(); extern void (*dtrig0)(); extern void (*dtrig1)(); extern void (*dtrig2)(); extern void (*dtrig3)(); extern void (*mtrig0)(); extern void (*mtrig1)(); extern void (*mtrig2)(); extern void (*mtrig3)(); void (*StkTrig0)() = dStkSin; void (*StkTrig1)() = dStkSqr; void (*StkTrig2)() = dStkSinh; void (*StkTrig3)() = dStkCosh; char maxfn = 0; /* TIW 03-30-91 STOP */ struct FNCT_LIST far FnctList[] = { /* TIW 03-31-91 added far */ "sin", &StkSin, "sinh", &StkSinh, "cos", &StkCos, "cosh", &StkCosh, "sqr", &StkSqr, "log", &StkLog, "exp", &StkExp, "abs", &StkAbs, "conj", &StkConj, "real", &StkReal, "imag", &StkImag, "fn1", &StkTrig0, /* TIW 03-30-91 */ "fn2", &StkTrig1, /* TIW 03-30-91 */ "fn3", &StkTrig2, /* TIW 03-30-91 */ "fn4", &StkTrig3, /* TIW 03-30-91 */ "flip", &StkFlip, /* MCP 4-9-91 */ "tan", &StkTan, /* TIW 04-22-91 */ "tanh", &StkTanh, /* TIW 04-22-91 */ "cotan", &StkCoTan, /* TIW 04-24-91 */ "cotanh", &StkCoTanh,/* TIW 04-24-91 */ "cosxx",&StkCosXX, /* PB 04-28-91 */ }; void NotAFnct(void) { } void FnctNotFound(void) { } /* determine if s names a function and if so which one */ /* TIW 04-22-91 */ whichfn(char *s, int len) { int out; if(len != 3) out = 0; else if(strnicmp(s,"fn",2)) out = 0; else out = atoi(s+2); if(out < 1 || out > 4) out = 0; return(out); } void (far *isfunct(char *Str, int Len))(void) { unsigned n; int functnum; /* TIW 04-22-91 */ n = SkipWhiteSpace(&Str[Len]); if(Str[Len+n] == '(') { for(n = 0; n < sizeof(FnctList) / sizeof(struct FNCT_LIST); n++) { if(far_strlen(FnctList[n].s) == Len) { /* TIW 03-31-91 added far */ if(!far_strnicmp(FnctList[n].s, Str, Len)) { /* TIW 03-31-91 added far */ /* count function variables */ if(functnum = whichfn(Str, Len)) /* TIW 04-22-91 */ if(functnum > maxfn) /* TIW 04-22-91 */ maxfn = functnum; /* TIW 04-22-91 */ return(*FnctList[n].ptr); } } } return(FnctNotFound); } return(NotAFnct); } void RecSortPrec(void) { int ThisOp = NextOp++; while(o[ThisOp].p > o[NextOp].p && NextOp < posp) RecSortPrec(); f[OpPtr++] = o[ThisOp].f; } static char *Constants[] = { "pixel", "p1", "p2", "z", "LastSqr", }; struct SYMETRY { char *s; int n; } SymStr[] = { "NOSYM", 0, "XAXIS_NOPARM", -1, "XAXIS", 1, "YAXIS_NOPARM", -2, "YAXIS", 2, "XYAXIS_NOPARM",-3, "XYAXIS", 3, "ORIGIN_NOPARM",-4, "ORIGIN", 4, "PI_SYM_NOPARM",-5, "PI_SYM", 5, "NOPLOT", 99, "", 0 }; int ParseStr(char *Str) { struct ConstArg far *c; int ModFlag = 999, Len, Equals = 0, Mod[20], mdstk = 0; int NewStatement; struct ERROR { int n, s; } far *e; e = (struct ERROR far *)farmemalloc(sizeof(struct ERROR) * 100L); /* PB 910417 changed "o" to be a temporary alloc, during ParseStr only */ o = (struct PEND_OP far *)farmemalloc(sizeof(struct PEND_OP) * (long)MAX_OPS); if(!e || !o || !typespecific_workarea) { static char far msg[]={"Insufficient memory to run fractal type 'formula'"}; stopmsg(0,msg); return(1); } switch(MathType) { case D_MATH: StkAdd = dStkAdd; StkSub = dStkSub; StkNeg = dStkNeg; StkMul = dStkMul; StkSin = dStkSin; StkSinh = dStkSinh; StkLT = dStkLT; StkLTE = dStkLTE; StkMod = dStkMod; StkSqr = dStkSqr; StkCos = dStkCos; StkCosh = dStkCosh; StkLog = dStkLog; StkExp = dStkExp; StkPwr = dStkPwr; StkDiv = dStkDiv; StkAbs = dStkAbs; StkReal = dStkReal; StkImag = dStkImag; StkConj = dStkConj; StkTrig0 = dtrig0; /* TIW 03-30-91 */ StkTrig1 = dtrig1; /* TIW 03-30-91 */ StkTrig2 = dtrig2; /* TIW 03-30-91 */ StkTrig3 = dtrig3; /* TIW 03-30-91 */ StkFlip = dStkFlip; StkTan = dStkTan; /* TIW 04-22-91 */ StkTanh = dStkTanh; /* TIW 04-22-91 */ StkCoTan = dStkCoTan; /* TIW 04-24-91 */ StkCoTanh = dStkCoTanh; /* TIW 04-24-91 */ StkCosXX = dStkCosXX; /* PB 04-28-91 */ break; case M_MATH: StkAdd = mStkAdd; StkSub = mStkSub; StkNeg = mStkNeg; StkMul = mStkMul; StkSin = mStkSin; StkSinh = mStkSinh; StkLT = mStkLT; StkLTE = mStkLTE; StkMod = mStkMod; StkSqr = mStkSqr; StkCos = mStkCos; StkCosh = mStkCosh; StkLog = mStkLog; StkExp = mStkExp; StkPwr = mStkPwr; StkDiv = mStkDiv; StkAbs = mStkAbs; StkReal = mStkReal; StkImag = mStkImag; StkConj = mStkConj; StkTrig0 = mtrig0; /* TIW 03-30-91 */ StkTrig1 = mtrig1; /* TIW 03-30-91 */ StkTrig2 = mtrig2; /* TIW 03-30-91 */ StkTrig3 = mtrig3; /* TIW 03-30-91 */ StkFlip = mStkFlip; StkTan = mStkTan; /* TIW 04-22-91 */ StkTanh = mStkTanh;/* TIW 04-22-91 */ StkCoTan = mStkCoTan; /* TIW 04-24-91 */ StkCoTanh = mStkCoTanh;/* TIW 04-24-91 */ StkCosXX = mStkCosXX; /* PB 04-28-91 */ break; case L_MATH: Delta16 = bitshift - 16; ShiftBack = 32 - bitshift; /* TW 06-18-90 */ StkAdd = lStkAdd; StkSub = lStkSub; StkNeg = lStkNeg; StkMul = lStkMul; StkSin = lStkSin; StkSinh = lStkSinh; StkLT = lStkLT; StkLTE = lStkLTE; StkMod = lStkMod; StkSqr = lStkSqr; StkCos = lStkCos; StkCosh = lStkCosh; StkLog = lStkLog; StkExp = lStkExp; StkPwr = lStkPwr; StkDiv = lStkDiv; StkAbs = lStkAbs; StkReal = lStkReal; StkImag = lStkImag; StkConj = lStkConj; StkTrig0 = ltrig0; /* TIW 03-30-91 */ StkTrig1 = ltrig1; /* TIW 03-30-91 */ StkTrig2 = ltrig2; /* TIW 03-30-91 */ StkTrig3 = ltrig3; /* TIW 03-30-91 */ StkFlip = lStkFlip; StkTan = lStkTan; /* TIW 04-22-91 */ StkTanh = lStkTanh; /* TIW 04-22-91 */ StkCoTan = lStkCoTan; /* TIW 04-24-91 */ StkCoTanh = lStkCoTanh; /* TIW 04-24-91 */ StkCosXX = lStkCosXX; /* PB 04-28-91 */ break; } maxfn = 0; /* TIW 03-30-91 */ for(vsp = 0; vsp < sizeof(Constants) / sizeof(char*); vsp++) { v[vsp].s = Constants[vsp]; v[vsp].len = strlen(Constants[vsp]); } switch(MathType) { case D_MATH: v[1].a.d.x = param[0]; v[1].a.d.y = param[1]; v[2].a.d.x = param[2]; v[2].a.d.y = param[3]; break; case M_MATH: v[1].a.m.x = *d2MP(param[0]); v[1].a.m.y = *d2MP(param[1]); v[2].a.m.x = *d2MP(param[2]); v[2].a.m.y = *d2MP(param[3]); break; case L_MATH: v[1].a.l.x = (long)(param[0] * fg); v[1].a.l.y = (long)(param[1] * fg); v[2].a.l.x = (long)(param[2] * fg); v[2].a.l.y = (long)(param[3] * fg); break; } LastInitOp = ErrPtr = paren = OpPtr = LodPtr = StoPtr = posp = 0; NewStatement = 1; SyntaxErr = -1; ExpectingArg = 1; for(n = 0; Str[n]; n++) { if(!Str[n]) break; InitN = n; switch(Str[n]) { case ' ': case '\t': case '\r': case '\n': break; case '(': paren++; if(!ExpectingArg) SyntaxErr = 1; break; case ')': if(paren) paren--; else SyntaxErr = 2; if(ExpectingArg) { e[ErrPtr].n = InitN; e[ErrPtr++].s = 0; } break; case '|': if(ModFlag == paren-1) { if(ExpectingArg) SyntaxErr = 0; paren--; ModFlag = Mod[--mdstk]; } else { if(!ExpectingArg) SyntaxErr = 1; Mod[mdstk++] = ModFlag; o[posp].f = StkMod; o[posp++].p = 2 - (paren + Equals)*15; ModFlag = paren++; } break; case ',': case ';': if(paren) { e[ErrPtr].n = InitN; e[ErrPtr++].s = 3; } if(!ExpectingArg) { NewStatement = 1; ExpectingArg = 1; o[posp].f = (void(far*)(void))0; o[posp++].p = 15; o[posp].f = StkClr; o[posp++].p = -30000; Equals = paren = 0; } else if(!NewStatement) SyntaxErr = 0; break; case ':': if(paren) { e[ErrPtr].n = InitN; e[ErrPtr++].s = 3; } if(ExpectingArg) SyntaxErr = 0; else ExpectingArg = 1; o[posp].f = (void(far*)(void))0; o[posp++].p = 15; o[posp].f = EndInit; o[posp++].p = -30000; Equals = paren = 0; LastInitOp = 10000; NewStatement = 1; break; case '+': if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; o[posp].f = StkAdd; o[posp++].p = 4 - (paren + Equals)*15; break; case '-': if(ExpectingArg) { o[posp].f = StkNeg; o[posp++].p = 2 - (paren + Equals)*15; } else { o[posp].f = StkSub; o[posp++].p = 4 - (paren + Equals)*15; ExpectingArg = 1; } break; case '<': if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; if(Str[n+1] == '=') { n++; o[posp].f = StkLTE; } else o[posp].f = StkLT; o[posp++].p = 6 - (paren + Equals)*15; break; case '*': if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; o[posp].f = StkMul; o[posp++].p = 3 - (paren + Equals)*15; break; case '/': if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; o[posp].f = StkDiv; o[posp++].p = 3 - (paren + Equals)*15; break; case '^': if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; o[posp].f = StkPwr; o[posp++].p = 2 - (paren + Equals)*15; break; case '=': if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; o[posp-1].f = StkSto; o[posp-1].p = 5 - (paren + Equals)*15; Store[StoPtr++] = Load[--LodPtr]; Equals++; break; default: if(isalnum(Str[n]) || Str[n] == '.') { while(isalnum(Str[n+1]) || Str[n+1] == '.') n++; if(!ExpectingArg) { SyntaxErr = 1; } NewStatement = ExpectingArg = 0; Len = (n+1)-InitN; o[posp].f = isfunct(&Str[InitN], Len); if(o[posp].f != NotAFnct) { if(o[posp].f == FnctNotFound) { e[ErrPtr].n = InitN; e[ErrPtr++].s = 5; } else o[posp++].p = 1 - (paren + Equals)*15; ExpectingArg = 1; } else { c = isconst(&Str[InitN], Len); Load[LodPtr++] = &(c->a); o[posp].f = StkLod; o[posp++].p = 1 - (paren + Equals)*15; n = InitN + c->len - 1; if(vsp >= MAX_ARGS-1) { /* PB 910417 safety test */ e[ErrPtr].n = InitN; e[ErrPtr++].s = 7; break; } } } else { if(ExpectingArg) SyntaxErr = 0; ExpectingArg = 1; e[ErrPtr].n = InitN; e[ErrPtr++].s = 4; } break; } if(SyntaxErr >= 0) { e[ErrPtr].n = InitN; e[ErrPtr++].s = SyntaxErr; SyntaxErr = -1; } if(posp >= MAX_OPS-1) { /* PB 901103 added safety test here */ e[ErrPtr].n = InitN; e[ErrPtr++].s = 7; break; } if(ErrPtr > 50) /* PB 910417 safety test */ break; } o[posp].f = (void(far*)(void))0; o[posp++].p = 16; if(paren > 0) { e[ErrPtr].n = n; e[ErrPtr++].s = 3; } if (ErrPtr) { int i, j, k, m; char msgbuf[700]; /* PB replaced printf loop by build msgbuf & stopmsg */ /* stopmsg defined to have max 9 lines, show at most first 3 errors */ msgbuf[0] = 0; for(n = 0; n < ErrPtr && n < 3; n++) { if (n) strcat(msgbuf,"\n"); sprintf(&msgbuf[strlen(msgbuf)], "Error(%d): %Fs\n ", e[n].s, /*TIW 03-31-91 added %Fs*/ ErrStrings[e[n].s]); j = 24; if ((i = e[n].n - j) < 0) { j = e[n].n; i = 0; } else { strcat(msgbuf,"..."); j += 3; } k = strlen(msgbuf); m = i + 66; while (i < m && Str[i]) { if ((msgbuf[k] = Str[i]) == '\n' || msgbuf[k] == '\t') msgbuf[k] = ' '; ++i; ++k; } if (Str[i]) { msgbuf[k++] = '.'; msgbuf[k++] = '.'; msgbuf[k++] = '.'; } msgbuf[k++] = '\n'; while (--j >= -2) msgbuf[k++] = ' '; msgbuf[k++] = '^'; msgbuf[k] = 0; } stopmsg(8,msgbuf); } if(!ErrPtr) { NextOp = 0; LastOp = posp; while(NextOp < posp) { if(o[NextOp].f) RecSortPrec(); else { NextOp++; LastOp--; } } } else posp = 0; farmemfree(o); farmemfree(e); /* PB 910417 free all arrays if error */ if (ErrPtr) free_workarea(); return(ErrPtr); } int Formula(void) { if(FormName[0] == 0 || overflow) return(1); LodPtr = InitLodPtr; StoPtr = InitStoPtr; OpPtr = InitOpPtr; Arg1 = &s[0]; Arg2 = Arg1; Arg2--; while(OpPtr < LastOp) { f[OpPtr++](); #ifdef WATCH_MP x1 = *MP2d(Arg1->m.x); y1 = *MP2d(Arg1->m.y); x2 = *MP2d(Arg2->m.x); y2 = *MP2d(Arg2->m.y); #endif } switch(MathType) { case D_MATH: old = new = v[3].a.d; return(Arg1->d.x == 0.0); case M_MATH: old = new = MPC2cmplx(v[3].a.m); return(Arg1->m.x.Exp == 0 && Arg1->m.x.Mant == 0); case L_MATH: lold = lnew = v[3].a.l; if(overflow) return(1); return(Arg1->l.x == 0L); } return(1); } int form_per_pixel(void) { if (FormName[0] == 0) return(1); overflow = LodPtr = StoPtr = OpPtr = 0; Arg1 = &s[0]; Arg2 = Arg1; Arg2--; switch(MathType) { case D_MATH: old.x = new.x = v[0].a.d.x = dx0[col]+dShiftx; old.y = new.y = v[0].a.d.y = dy0[row]+dShifty; break; case M_MATH: v[0].a.m.x = *d2MP(old.x = new.x = dx0[col]+dShiftx); v[0].a.m.y = *d2MP(old.y = new.y = dy0[row]+dShifty); break; case L_MATH: lold.x = lnew.x = v[0].a.l.x = lx0[col]+lShiftx; lold.y = lnew.y = v[0].a.l.y = ly0[row]+lShifty; break; } if(LastInitOp) LastInitOp = LastOp; while(OpPtr < LastInitOp) f[OpPtr++](); InitLodPtr = LodPtr; InitStoPtr = StoPtr; InitOpPtr = OpPtr; if(overflow) return(0); else return(1); } char *FormStr; extern char FormFileName[]; /* BDT file to find the formulas in */ extern char FormName[]; /* BDT Name of the Formula (if not null) */ char *FindFormula(char *Str) { char *FormulaStr = (char *)0; char StrBuff[201]; /* PB, to match a safety fix in parser */ /* MCP, changed to an automatic variable */ char fullfilename[100]; /* BDT Full file name */ unsigned Done; int c; FILE *File; findpath(FormFileName, fullfilename); /* BDT get full path name */ symmetry = 0; if((File = fopen(fullfilename, "rt")) != NULL) { /* BDT use variable files */ while(StrBuff[0]=0,/* TIW 04-22-91 */ fscanf(File, "%200[^ \n\t({]", StrBuff) != EOF) { if(!stricmp(StrBuff, Str) || !Str[0]) { while((c = getc(File)) != EOF) { if(c == '(') { StrBuff[0]=0; /* TIW 04-22-91 */ fscanf(File, "%200[^)]", StrBuff); for(n = 0; SymStr[n].s[0]; n++) { if(!stricmp(SymStr[n].s, StrBuff)) { symmetry = SymStr[n].n; break; } } if(!SymStr[n].s[0]) { sprintf(fullfilename,"Undefined symmetry:\n %.76s", StrBuff); stopmsg(0,fullfilename); /* PB printf -> stopmsg */ FormulaStr = (char *)0; /* PB 910511 */ Exit: fclose(File); return(FormulaStr); } } else if(c == '{') break; } /* MCP 4-9-91, Strip the comments inside the formula. Might as well allow unlimited formula lengths while we're at it. */ FormulaStr = boxx; n = Done = 0; while(!Done) { switch(c = getc(File)) { static char far msg[]={"Unexpected EOF: missing a '}'"}; case EOF: UnexpectedEOF: stopmsg(0, msg); FormulaStr = (char *)0; goto Exit; case '}': FormulaStr[n++] = 0; Done = 1; break; case ';': while((c = getc(File)) != '\n') { if(c == EOF) goto UnexpectedEOF; } FormulaStr[n++] = ','; break; case ' ': /* Also strip out the white spaces */ case '\t': break; case '\n': FormulaStr[n++] = ','; break; default: FormulaStr[n++] = c; } if (n >= 8192) { /* PB 4-9-91, added safety test */ static char far msg[]={"Definition too large, missing a '}'?"}; stopmsg(0, msg); FormulaStr = (char *)0; goto Exit; } } goto Exit; } StrBuff[0]=0; /* TIW 04-22-91 */ fscanf(File, "%200[ \n\t({]", StrBuff); if(StrBuff[strcspn(StrBuff, "({")]) { skipcomments: fscanf(File, "%200[^}]", StrBuff); if (getc(File)!= '}') goto skipcomments; } } sprintf(fullfilename, "Formula \"%s\" not found", Str); stopmsg(0,fullfilename); /* PB printf -> stopmsg */ FormulaStr = (char *)0; /* PB 910511 */ goto Exit; } sprintf(fullfilename, "Unable to open %s", FormFileName); stopmsg(0,fullfilename); /* PB printf -> stopmsg */ return((char *)0); /* PB 910511 */ } int RunForm(char *Name) { if (FormName[0] == 0) return(1); parser_allocate(); if((FormStr = FindFormula(Name)) != NULL) return(ParseStr(FormStr)); else return(1); /* PB, msg moved to FindFormula */ } int fpFormulaSetup(void) { if (fpu > 0) { MathType = D_MATH; return(!RunForm(FormName)); } else { MathType = M_MATH; return(!RunForm(FormName)); } } int intFormulaSetup(void) { MathType = L_MATH; fg = (double)(1L << bitshift); fgLimit = (double)0x7fffffffL / fg; ShiftBack = 32 - bitshift; return(!RunForm(FormName)); } /* TIW added 06-20-90 so functions can be called from fractals.c */ void init_misc() { static struct ConstArg far vv[5]; static union Arg argfirst,argsecond; if(!v) /* PB 901103 added this test to avoid clobbering the real thing */ v = vv; /* this is needed by lStkSqr and dStkSqr */ Arg1 = &argfirst; Arg2 = &argsecond; /* needed by all the ?Stk* functions */ fg = (double)(1L << bitshift); fgLimit = (double)0x7fffffffL / fg; ShiftBack = 32 - bitshift; Delta16 = bitshift - 16; bitshiftless1 = bitshift-1; } /* PB 910417 here to end changed. Allocate sub-arrays from one main farmemalloc, using global variable typespecific_workarea; calcfrac.c releases this area when calculation ends or is terminated. Moved the "f" array to be allocated as part of this. */ static void parser_allocate(void) { unsigned int f_size,Store_size,Load_size,v_size; free_workarea(); f_size = sizeof(void(far * far *)(void)) * MAX_OPS; Store_size = sizeof(union Arg far *) * MAX_OPS; Load_size = sizeof(union Arg far *) * MAX_OPS; v_size = sizeof(struct ConstArg) * MAX_ARGS; typespecific_workarea = farmemalloc((long)(f_size+Load_size+Store_size+v_size)); f = (void(far * far *)(void))typespecific_workarea; Store = (union Arg far * far *)(f + MAX_OPS); Load = (union Arg far * far *)(Store + MAX_OPS); v = (struct ConstArg far *)(Load + MAX_OPS); } static void free_workarea() { if(typespecific_workarea) { farmemfree(typespecific_workarea); typespecific_workarea = NULL; } }