/* * Copyright (C) 2002-2007 The DOSBox Team * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* $Id: fpu_instructions.h,v 1.32 2009/04/25 06:59:54 qbix79 Exp $ */ static void FPU_FINIT(void) { FPU_SetCW(0x37F); fpu.sw = 0; TOP=FPU_GET_TOP(); fpu.tags[0] = TAG_Empty; fpu.tags[1] = TAG_Empty; fpu.tags[2] = TAG_Empty; fpu.tags[3] = TAG_Empty; fpu.tags[4] = TAG_Empty; fpu.tags[5] = TAG_Empty; fpu.tags[6] = TAG_Empty; fpu.tags[7] = TAG_Empty; fpu.tags[8] = TAG_Valid; // is only used by us } static void FPU_FCLEX(void){ fpu.sw &= 0x7f00; //should clear exceptions } static void FPU_FNOP(void){ return; } static void FPU_PUSH(double in){ TOP = (TOP - 1) &7; //actually check if empty fpu.tags[TOP] = TAG_Valid; fpu.regs[TOP].d = in; // LOG(LOG_FPU,LOG_ERROR)("Pushed at %d %g to the stack",newtop,in); return; } static void FPU_PREP_PUSH(void){ TOP = (TOP - 1) &7; fpu.tags[TOP] = TAG_Valid; } static void FPU_FPOP(void){ fpu.tags[TOP]=TAG_Empty; //maybe set zero in it as well TOP = ((TOP+1)&7); // LOG(LOG_FPU,LOG_ERROR)("popped from %d %g off the stack",top,fpu.regs[top].d); return; } static double FROUND(double in){ switch(fpu.round){ case ROUND_Nearest: if (in-floor(in)>0.5) return (floor(in)+1); else if (in-floor(in)<0.5) return (floor(in)); else return (((static_cast(floor(in)))&1)!=0)?(floor(in)+1):(floor(in)); break; case ROUND_Down: return (floor(in)); break; case ROUND_Up: return (ceil(in)); break; case ROUND_Chop: return in; //the cast afterwards will do it right maybe cast here break; default: return in; break; } } #define BIAS80 16383 #define BIAS64 1023 static Real64 FPU_FLD80(PhysPt addr) { struct { Bit16s begin; FPU_Reg eind; } test; test.eind.l.lower = mem_readd(addr); test.eind.l.upper = mem_readd(addr+4); test.begin = mem_readw(addr+8); Bit64s exp64 = (((test.begin&0x7fff) - BIAS80)); Bit64s blah = ((exp64 >0)?exp64:-exp64)&0x3ff; Bit64s exp64final = ((exp64 >0)?blah:-blah) +BIAS64; Bit64s mant64 = (test.eind.ll >> 11) & LONGTYPE(0xfffffffffffff); Bit64s sign = (test.begin&0x8000)?1:0; FPU_Reg result; result.ll = (sign <<63)|(exp64final << 52)| mant64; return result.d; //mant64= test.mant80/2***64 * 2 **53 } static void FPU_ST80(PhysPt addr,Bitu reg) { struct { Bit16s begin; FPU_Reg eind; } test; Bit64s sign80 = (fpu.regs[reg].ll&LONGTYPE(0x8000000000000000))?1:0; Bit64s exp80 = fpu.regs[reg].ll&LONGTYPE(0x7ff0000000000000); Bit64s exp80final = (exp80>>52) - BIAS64 + BIAS80; Bit64s mant80 = fpu.regs[reg].ll&LONGTYPE(0x000fffffffffffff); Bit64s mant80final = (mant80 << 11); // Elvira wants the 8 and tcalc doesn't if(fpu.regs[reg].d != 0) mant80final |= LONGTYPE(0x8000000000000000); test.begin= (static_cast(sign80)<<15)| static_cast(exp80final); test.eind.ll = mant80final; mem_writed(addr,test.eind.l.lower); mem_writed(addr+4,test.eind.l.upper); mem_writew(addr+8,test.begin); } static void FPU_FLD_F32(PhysPt addr,Bitu store_to) { union { float f; Bit32u l; } blah; blah.l = mem_readd(addr); fpu.regs[store_to].d = static_cast(blah.f); } static void FPU_FLD_F64(PhysPt addr,Bitu store_to) { fpu.regs[store_to].l.lower = mem_readd(addr); fpu.regs[store_to].l.upper = mem_readd(addr+4); } static void FPU_FLD_F80(PhysPt addr) { fpu.regs[TOP].d = FPU_FLD80(addr); } static void FPU_FLD_I16(PhysPt addr,Bitu store_to) { Bit16s blah = mem_readw(addr); fpu.regs[store_to].d = static_cast(blah); } static void FPU_FLD_I32(PhysPt addr,Bitu store_to) { Bit32s blah = mem_readd(addr); fpu.regs[store_to].d = static_cast(blah); } static void FPU_FLD_I64(PhysPt addr,Bitu store_to) { FPU_Reg blah; blah.l.lower = mem_readd(addr); blah.l.upper = mem_readd(addr+4); fpu.regs[store_to].d = static_cast(blah.ll); } static void FPU_FBLD(PhysPt addr,Bitu store_to) { Bit64u val = 0; Bitu in = 0; Bit64u base = 1; for(Bitu i = 0;i < 9;i++){ in = mem_readb(addr + i); val += ( (in&0xf) * base); //in&0xf shouldn't be higher then 9 base *= 10; val += ((( in>>4)&0xf) * base); base *= 10; } //last number, only now convert to float in order to get //the best signification Real64 temp = static_cast(val); in = mem_readb(addr + 9); temp += ( (in&0xf) * base ); if(in&0x80) temp *= -1.0; fpu.regs[store_to].d = temp; } static INLINE void FPU_FLD_F32_EA(PhysPt addr) { FPU_FLD_F32(addr,8); } static INLINE void FPU_FLD_F64_EA(PhysPt addr) { FPU_FLD_F64(addr,8); } static INLINE void FPU_FLD_I32_EA(PhysPt addr) { FPU_FLD_I32(addr,8); } static INLINE void FPU_FLD_I16_EA(PhysPt addr) { FPU_FLD_I16(addr,8); } static void FPU_FST_F32(PhysPt addr) { union { float f; Bit32u l; } blah; //should depend on rounding method blah.f = static_cast(fpu.regs[TOP].d); mem_writed(addr,blah.l); } static void FPU_FST_F64(PhysPt addr) { mem_writed(addr,fpu.regs[TOP].l.lower); mem_writed(addr+4,fpu.regs[TOP].l.upper); } static void FPU_FST_F80(PhysPt addr) { FPU_ST80(addr,TOP); } static void FPU_FST_I16(PhysPt addr) { mem_writew(addr,static_cast(FROUND(fpu.regs[TOP].d))); } static void FPU_FST_I32(PhysPt addr) { mem_writed(addr,static_cast(FROUND(fpu.regs[TOP].d))); } static void FPU_FST_I64(PhysPt addr) { FPU_Reg blah; blah.ll = static_cast(FROUND(fpu.regs[TOP].d)); mem_writed(addr,blah.l.lower); mem_writed(addr+4,blah.l.upper); } static void FPU_FBST(PhysPt addr) { FPU_Reg val = fpu.regs[TOP]; bool sign = false; if(val.d<0.0){ //sign sign=true; val.d=-val.d; } //numbers from back to front Real64 temp=val.d; Bitu p; for(Bitu i=0;i<9;i++){ val.d=temp; temp = static_cast(static_cast(floor(val.d/10.0))); p = static_cast(val.d - 10.0*temp); val.d=temp; temp = static_cast(static_cast(floor(val.d/10.0))); p |= (static_cast(val.d - 10.0*temp)<<4); mem_writeb(addr+i,p); } val.d=temp; temp = static_cast(static_cast(floor(val.d/10.0))); p = static_cast(val.d - 10.0*temp); if(sign) p|=0x80; mem_writeb(addr+9,p); } static void FPU_FADD(Bitu op1, Bitu op2){ fpu.regs[op1].d+=fpu.regs[op2].d; //flags and such :) return; } static void FPU_FSIN(void){ fpu.regs[TOP].d = sin(fpu.regs[TOP].d); FPU_SET_C2(0); //flags and such :) return; } static void FPU_FSINCOS(void){ Real64 temp = fpu.regs[TOP].d; fpu.regs[TOP].d = sin(temp); FPU_PUSH(cos(temp)); FPU_SET_C2(0); //flags and such :) return; } static void FPU_FCOS(void){ fpu.regs[TOP].d = cos(fpu.regs[TOP].d); FPU_SET_C2(0); //flags and such :) return; } static void FPU_FSQRT(void){ fpu.regs[TOP].d = sqrt(fpu.regs[TOP].d); //flags and such :) return; } static void FPU_FPATAN(void){ fpu.regs[STV(1)].d = atan2(fpu.regs[STV(1)].d,fpu.regs[TOP].d); FPU_FPOP(); //flags and such :) return; } static void FPU_FPTAN(void){ fpu.regs[TOP].d = tan(fpu.regs[TOP].d); FPU_PUSH(1.0); FPU_SET_C2(0); //flags and such :) return; } static void FPU_FDIV(Bitu st, Bitu other){ fpu.regs[st].d= fpu.regs[st].d/fpu.regs[other].d; //flags and such :) return; } static void FPU_FDIVR(Bitu st, Bitu other){ fpu.regs[st].d= fpu.regs[other].d/fpu.regs[st].d; // flags and such :) return; } static void FPU_FMUL(Bitu st, Bitu other){ fpu.regs[st].d*=fpu.regs[other].d; //flags and such :) return; } static void FPU_FSUB(Bitu st, Bitu other){ fpu.regs[st].d = fpu.regs[st].d - fpu.regs[other].d; //flags and such :) return; } static void FPU_FSUBR(Bitu st, Bitu other){ fpu.regs[st].d= fpu.regs[other].d - fpu.regs[st].d; //flags and such :) return; } static void FPU_FXCH(Bitu st, Bitu other){ FPU_Tag tag = fpu.tags[other]; FPU_Reg reg = fpu.regs[other]; fpu.tags[other] = fpu.tags[st]; fpu.regs[other] = fpu.regs[st]; fpu.tags[st] = tag; fpu.regs[st] = reg; } static void FPU_FST(Bitu st, Bitu other){ fpu.tags[other] = fpu.tags[st]; fpu.regs[other] = fpu.regs[st]; } static void FPU_FCOM(Bitu st, Bitu other){ if(((fpu.tags[st] != TAG_Valid) && (fpu.tags[st] != TAG_Zero)) || ((fpu.tags[other] != TAG_Valid) && (fpu.tags[other] != TAG_Zero))){ FPU_SET_C3(1);FPU_SET_C2(1);FPU_SET_C0(1);return; } if(fpu.regs[st].d == fpu.regs[other].d){ FPU_SET_C3(1);FPU_SET_C2(0);FPU_SET_C0(0);return; } if(fpu.regs[st].d < fpu.regs[other].d){ FPU_SET_C3(0);FPU_SET_C2(0);FPU_SET_C0(1);return; } // st > other FPU_SET_C3(0);FPU_SET_C2(0);FPU_SET_C0(0);return; } static void FPU_FUCOM(Bitu st, Bitu other){ //does atm the same as fcom FPU_FCOM(st,other); } static void FPU_FRNDINT(void){ Bit64s temp= static_cast(FROUND(fpu.regs[TOP].d)); fpu.regs[TOP].d=static_cast(temp); } static void FPU_FPREM(void){ Real64 valtop = fpu.regs[TOP].d; Real64 valdiv = fpu.regs[STV(1)].d; Bit64s ressaved = static_cast( (valtop/valdiv) ); // Some backups // Real64 res=valtop - ressaved*valdiv; // res= fmod(valtop,valdiv); fpu.regs[TOP].d = valtop - ressaved*valdiv; FPU_SET_C0(static_cast(ressaved&4)); FPU_SET_C3(static_cast(ressaved&2)); FPU_SET_C1(static_cast(ressaved&1)); FPU_SET_C2(0); } static void FPU_FPREM1(void){ Real64 valtop = fpu.regs[TOP].d; Real64 valdiv = fpu.regs[STV(1)].d; double quot = valtop/valdiv; double quotf = floor(quot); Bit64s ressaved; if (quot-quotf>0.5) ressaved = static_cast(quotf+1); else if (quot-quotf<0.5) ressaved = static_cast(quotf); else ressaved = static_cast((((static_cast(quotf))&1)!=0)?(quotf+1):(quotf)); fpu.regs[TOP].d = valtop - ressaved*valdiv; FPU_SET_C0(static_cast(ressaved&4)); FPU_SET_C3(static_cast(ressaved&2)); FPU_SET_C1(static_cast(ressaved&1)); FPU_SET_C2(0); } static void FPU_FXAM(void){ if(fpu.regs[TOP].ll & LONGTYPE(0x8000000000000000)) //sign { FPU_SET_C1(1); } else { FPU_SET_C1(0); } if(fpu.tags[TOP] == TAG_Empty) { FPU_SET_C3(1);FPU_SET_C2(0);FPU_SET_C0(1); return; } if(fpu.regs[TOP].d == 0.0) //zero or normalized number. { FPU_SET_C3(1);FPU_SET_C2(0);FPU_SET_C0(0); } else { FPU_SET_C3(0);FPU_SET_C2(1);FPU_SET_C0(0); } } static void FPU_F2XM1(void){ fpu.regs[TOP].d = pow(2.0,fpu.regs[TOP].d) - 1; return; } static void FPU_FYL2X(void){ fpu.regs[STV(1)].d*=log(fpu.regs[TOP].d)/log(static_cast(2.0)); FPU_FPOP(); return; } static void FPU_FYL2XP1(void){ fpu.regs[STV(1)].d*=log(fpu.regs[TOP].d+1.0)/log(static_cast(2.0)); FPU_FPOP(); return; } static void FPU_FSCALE(void){ fpu.regs[TOP].d *= pow(2.0,static_cast(static_cast(fpu.regs[STV(1)].d))); return; //2^x where x is chopped. } static void FPU_FSTENV(PhysPt addr){ FPU_SET_TOP(TOP); if(!cpu.code.big) { mem_writew(addr+0,static_cast(fpu.cw)); mem_writew(addr+2,static_cast(fpu.sw)); mem_writew(addr+4,static_cast(FPU_GetTag())); } else { mem_writed(addr+0,static_cast(fpu.cw)); mem_writed(addr+4,static_cast(fpu.sw)); mem_writed(addr+8,static_cast(FPU_GetTag())); } } static void FPU_FLDENV(PhysPt addr){ Bit16u tag; Bit32u tagbig; Bitu cw; if(!cpu.code.big) { cw = mem_readw(addr+0); fpu.sw = mem_readw(addr+2); tag = mem_readw(addr+4); } else { cw = mem_readd(addr+0); fpu.sw = (Bit16u)mem_readd(addr+4); tagbig = mem_readd(addr+8); tag = static_cast(tagbig); } FPU_SetTag(tag); FPU_SetCW(cw); TOP = FPU_GET_TOP(); } static void FPU_FSAVE(PhysPt addr){ FPU_FSTENV(addr); Bitu start = (cpu.code.big?28:14); for(Bitu i = 0;i < 8;i++){ FPU_ST80(addr+start,STV(i)); start += 10; } FPU_FINIT(); } static void FPU_FRSTOR(PhysPt addr){ FPU_FLDENV(addr); Bitu start = (cpu.code.big?28:14); for(Bitu i = 0;i < 8;i++){ fpu.regs[STV(i)].d = FPU_FLD80(addr+start); start += 10; } } static void FPU_FXTRACT(void) { // function stores real bias in st and // pushes the significant number onto the stack // if double ever uses a different base please correct this function FPU_Reg test = fpu.regs[TOP]; Bit64s exp80 = test.ll&LONGTYPE(0x7ff0000000000000); Bit64s exp80final = (exp80>>52) - BIAS64; Real64 mant = test.d / (pow(2.0,static_cast(exp80final))); fpu.regs[TOP].d = static_cast(exp80final); FPU_PUSH(mant); } static void FPU_FCHS(void){ fpu.regs[TOP].d = -1.0*(fpu.regs[TOP].d); } static void FPU_FABS(void){ fpu.regs[TOP].d = fabs(fpu.regs[TOP].d); } static void FPU_FTST(void){ fpu.regs[8].d = 0.0; FPU_FCOM(TOP,8); } static void FPU_FLD1(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = 1.0; } static void FPU_FLDL2T(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = L2T; } static void FPU_FLDL2E(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = L2E; } static void FPU_FLDPI(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = PI; } static void FPU_FLDLG2(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = LG2; } static void FPU_FLDLN2(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = LN2; } static void FPU_FLDZ(void){ FPU_PREP_PUSH(); fpu.regs[TOP].d = 0.0; fpu.tags[TOP] = TAG_Zero; } static INLINE void FPU_FADD_EA(Bitu op1){ FPU_FADD(op1,8); } static INLINE void FPU_FMUL_EA(Bitu op1){ FPU_FMUL(op1,8); } static INLINE void FPU_FSUB_EA(Bitu op1){ FPU_FSUB(op1,8); } static INLINE void FPU_FSUBR_EA(Bitu op1){ FPU_FSUBR(op1,8); } static INLINE void FPU_FDIV_EA(Bitu op1){ FPU_FDIV(op1,8); } static INLINE void FPU_FDIVR_EA(Bitu op1){ FPU_FDIVR(op1,8); } static INLINE void FPU_FCOM_EA(Bitu op1){ FPU_FCOM(op1,8); }