#include #include #include #include "ibm.h" #include "x86.h" #include "x87.h" #include "mem.h" #include "cpu.h" #include "fdc.h" #include "pic.h" #include "timer.h" #include "nmi.h" #include "386_common.h" #include "codegen.h" #undef CPU_BLOCK_END #define CPU_BLOCK_END() static inline void fetch_ea_32_long(uint32_t rmdat) { eal_r = eal_w = NULL; easeg = cpu_state.ea_seg->base; if (cpu_rm == 4) { uint8_t sib = rmdat >> 8; switch (cpu_mod) { case 0: cpu_state.eaaddr = cpu_state.regs[sib & 7].l; cpu_state.pc++; break; case 1: cpu_state.pc++; cpu_state.eaaddr = ((uint32_t)(int8_t)getbyte()) + cpu_state.regs[sib & 7].l; // pc++; break; case 2: cpu_state.eaaddr = (fastreadl(cs + cpu_state.pc + 1)) + cpu_state.regs[sib & 7].l; cpu_state.pc += 5; break; } /*SIB byte present*/ if ((sib & 7) == 5 && !cpu_mod) cpu_state.eaaddr = getlong(); else if ((sib & 6) == 4 && !cpu_state.ssegs) { easeg = ss; cpu_state.ea_seg = &cpu_state.seg_ss; } if (((sib >> 3) & 7) != 4) cpu_state.eaaddr += cpu_state.regs[(sib >> 3) & 7].l << (sib >> 6); } else { cpu_state.eaaddr = cpu_state.regs[cpu_rm].l; if (cpu_mod) { if (cpu_rm == 5 && !cpu_state.ssegs) { easeg = ss; cpu_state.ea_seg = &cpu_state.seg_ss; } if (cpu_mod == 1) { cpu_state.eaaddr += ((uint32_t)(int8_t)(rmdat >> 8)); cpu_state.pc++; } else { cpu_state.eaaddr += getlong(); } } else if (cpu_rm == 5) { cpu_state.eaaddr = getlong(); } } if (easeg != 0xFFFFFFFF && ((easeg + cpu_state.eaaddr) & 0xFFF) <= 0xFFC) { uint32_t addr = easeg + cpu_state.eaaddr; if ( readlookup2[addr >> 12] != -1) eal_r = (uint32_t *)(readlookup2[addr >> 12] + addr); if (writelookup2[addr >> 12] != -1) eal_w = (uint32_t *)(writelookup2[addr >> 12] + addr); } } static inline void fetch_ea_16_long(uint32_t rmdat) { eal_r = eal_w = NULL; easeg = cpu_state.ea_seg->base; if (!cpu_mod && cpu_rm == 6) { cpu_state.eaaddr = getword(); } else { switch (cpu_mod) { case 0: cpu_state.eaaddr = 0; break; case 1: cpu_state.eaaddr = (uint16_t)(int8_t)(rmdat >> 8); cpu_state.pc++; break; case 2: cpu_state.eaaddr = getword(); break; } cpu_state.eaaddr += (*mod1add[0][cpu_rm]) + (*mod1add[1][cpu_rm]); if (mod1seg[cpu_rm] == &ss && !cpu_state.ssegs) { easeg = ss; cpu_state.ea_seg = &cpu_state.seg_ss; } cpu_state.eaaddr &= 0xFFFF; } if (easeg != 0xFFFFFFFF && ((easeg + cpu_state.eaaddr) & 0xFFF) <= 0xFFC) { uint32_t addr = easeg + cpu_state.eaaddr; if ( readlookup2[addr >> 12] != -1) eal_r = (uint32_t *)(readlookup2[addr >> 12] + addr); if (writelookup2[addr >> 12] != -1) eal_w = (uint32_t *)(writelookup2[addr >> 12] + addr); } } #define fetch_ea_16(rmdat) cpu_state.pc++; cpu_mod=(rmdat >> 6) & 3; cpu_reg=(rmdat >> 3) & 7; cpu_rm = rmdat & 7; if (cpu_mod != 3) { fetch_ea_16_long(rmdat); if (cpu_state.abrt) return 0; } #define fetch_ea_32(rmdat) cpu_state.pc++; cpu_mod=(rmdat >> 6) & 3; cpu_reg=(rmdat >> 3) & 7; cpu_rm = rmdat & 7; if (cpu_mod != 3) { fetch_ea_32_long(rmdat); } if (cpu_state.abrt) return 0 #include "x86_flags.h" #define getbytef() ((uint8_t)(fetchdat)); cpu_state.pc++ #define getwordf() ((uint16_t)(fetchdat)); cpu_state.pc+=2 #define getbyte2f() ((uint8_t)(fetchdat>>8)); cpu_state.pc++ #define getword2f() ((uint16_t)(fetchdat>>8)); cpu_state.pc+=2 #define OP_TABLE(name) ops_ ## name #define CLOCK_CYCLES(c) cycles -= (c) #define CLOCK_CYCLES_ALWAYS(c) cycles -= (c) #include "x86_ops.h" void exec386(int cycs) { uint8_t temp; uint32_t addr; int tempi; int cycdiff; int oldcyc; cycles+=cycs; // output=3; while (cycles>0) { int cycle_period = (timer_target - (uint32_t)tsc) + 1; x86_was_reset = 0; cycdiff=0; oldcyc=cycles; // pclog("%i %02X\n", ins, ram[8]); while (cycdiff < cycle_period) { int ins_cycles = cycles; cpu_state.oldpc = cpu_state.pc; cpu_state.op32 = use32; cpu_state.ea_seg = &cpu_state.seg_ds; cpu_state.ssegs = 0; fetchdat = fastreadl(cs + cpu_state.pc); if (!cpu_state.abrt) { uint8_t opcode = fetchdat & 0xFF; fetchdat >>= 8; trap = cpu_state.flags & T_FLAG; if (output == 3) { pclog("%04X(%06X):%04X : %08X %08X %08X %08X %04X %04X %04X(%08X) %04X %04X %04X(%08X) %08X %08X %08X SP=%04X:%08X %02X %04X %i %08X %08X %i %i %02X %02X %02X %02X %02X\n",CS,cs,cpu_state.pc,EAX,EBX,ECX,EDX,CS,DS,ES,es,FS,GS,SS,ss,EDI,ESI,EBP,SS,ESP,opcode,cpu_state.flags,ins,0, ldt.base, CPL, stack32, pic.pend, pic.mask, pic.mask2, pic2.pend, pic2.mask); } cpu_state.pc++; x86_opcodes[(opcode | cpu_state.op32) & 0x3ff](fetchdat); if (x86_was_reset) break; } if (cpu_state.abrt) { flags_rebuild(); // pclog("Abort\n"); // if (CS == 0x228) pclog("Abort at %04X:%04X - %i %i %i\n",CS,pc,notpresent,nullseg,abrt); tempi = cpu_state.abrt & ABRT_MASK; cpu_state.abrt = 0; x86_doabrt(tempi); if (cpu_state.abrt) { cpu_state.abrt = 0; cpu_state.pc = cpu_state.oldpc; pclog("Double fault %i\n", ins); pmodeint(8, 0); if (cpu_state.abrt) { cpu_state.abrt = 0; softresetx86(); cpu_set_edx(); pclog("Triple fault - reset\n"); } } } if (cpu_state.smi_pending) { cpu_state.smi_pending = 0; x86_smi_enter(); } else if (trap) { flags_rebuild(); // oldpc=pc; if (msw&1) { pmodeint(1,0); } else { writememw(ss,(SP-2)&0xFFFF,cpu_state.flags); writememw(ss,(SP-4)&0xFFFF,CS); writememw(ss,(SP-6)&0xFFFF,cpu_state.pc); SP-=6; addr = (1 << 2) + idt.base; cpu_state.flags &= ~I_FLAG; cpu_state.flags &= ~T_FLAG; cpu_state.pc=readmemw(0,addr); loadcs(readmemw(0,addr+2)); } } else if (nmi && nmi_enable && nmi_mask) { cpu_state.oldpc = cpu_state.pc; // pclog("NMI\n"); x86_int(2); nmi_enable = 0; if (nmi_auto_clear) { nmi_auto_clear = 0; nmi = 0; } } else if ((cpu_state.flags & I_FLAG) && pic_intpending) { temp=picinterrupt(); if (temp!=0xFF) { // if (temp == 0x54) pclog("Take int 54\n"); // if (output) output=3; // if (temp == 0xd) pclog("Hardware int %02X %i %04X(%08X):%08X\n",temp,ins, CS,cs,pc); // if (temp==0x54) output=3; flags_rebuild(); if (msw&1) { pmodeint(temp,0); } else { writememw(ss,(SP-2)&0xFFFF,cpu_state.flags); writememw(ss,(SP-4)&0xFFFF,CS); writememw(ss,(SP-6)&0xFFFF,cpu_state.pc); SP-=6; addr = (temp << 2) + idt.base; cpu_state.flags &= ~I_FLAG; cpu_state.flags &= ~T_FLAG; cpu_state.pc=readmemw(0,addr); loadcs(readmemw(0,addr+2)); // if (temp==0x76) pclog("INT to %04X:%04X\n",CS,pc); } // pclog("Now at %04X(%08X):%08X\n", CS, cs, pc); } } ins++; insc++; ins_cycles -= cycles; tsc += ins_cycles; cycdiff=oldcyc-cycles; if (timetolive) { timetolive--; if (!timetolive) fatal("Life expired\n"); } } if (TIMER_VAL_LESS_THAN_VAL(timer_target, (uint32_t)tsc)) timer_process(); } }