/* Fake6502 CPU emulator core v1.1 ******************* * (c)2011 Mike Chambers (miker00lz@gmail.com) * ***************************************************** * v1.1 - Small bugfix in BIT opcode, but it was the * * difference between a few games in my NES * * emulator working and being broken! * * I went through the rest carefully again * * after fixing it just to make sure I didn't * * have any other typos! (Dec. 17, 2011) * * * * v1.0 - First release (Nov. 24, 2011) * ***************************************************** * LICENSE: This source code is released into the * * public domain, but if you use it please do give * * credit. I put a lot of effort into writing this! * * * ***************************************************** * Fake6502 is a MOS Technology 6502 CPU emulation * * engine in C. It was written as part of a Nintendo * * Entertainment System emulator I've been writing. * * * * It has been pretty well-tested in the NES emu, * * and the clock-cycle timing in particular has been * * VERY thoroughly checked out. It matches with the * * real 6502 processor 100%. * * * * A couple important things to know about are two * * defines in the code. One is "UNDOCUMENTED" which, * * when defined, allows Fake6502 to compile with * * full support for the more predictable * * undocumented instructions of the 6502. If it is * * undefined, undocumented opcodes just act as NOPs. * * * * The other define is "NES_CPU", which causes the * * code to compile without support for binary-coded * * decimal (BCD) support for the ADC and SBC * * opcodes. The Ricoh 2A03 CPU in the NES does not * * support BCD, but is otherwise identical to the * * standard MOS 6502. (Note that this define is * * enabled in this file if you haven't changed it * * yourself. If you're not emulating a NES, you * * should comment it out.) * * * * If you do discover an error in timing accuracy, * * or operation in general please e-mail me at the * * address above so that I can fix it. Thank you! * * * ***************************************************** * Usage: * * * * Fake6502 requires you to provide two external * * functions: * * * * uint8_t read6502(uint16_t address) * * void write6502(uint16_t address, uint8_t value) * * * * You may optionally pass Fake6502 the pointer to a * * function which you want to be called after every * * emulated instruction. This function should be a * * void with no parameters expected to be passed to * * it. * * * * This can be very useful. For example, in a NES * * emulator, you check the number of clock ticks * * that have passed so you can know when to handle * * APU events. * * * * To pass Fake6502 this pointer, use the * * hookexternal(void *funcptr) function provided. * * * * To disable the hook later, pass NULL to it. * ***************************************************** * Useful functions in this emulator: * * * * void reset6502() * * - Call this once before you begin execution. * * * * void exec6502(uint32_t tickcount) * * - Execute 6502 code up to the next specified * * count of clock ticks. * * * * void step6502() * * - Execute a single instrution. * * * * void irq6502() * * - Trigger a hardware IRQ in the 6502 core. * * * * void nmi6502() * * - Trigger an NMI in the 6502 core. * * * * void hookexternal(void *funcptr) * * - Pass a pointer to a void function taking no * * parameters. This will cause Fake6502 to call * * that function once after each emulated * * instruction. * * * ***************************************************** * Useful variables in this emulator: * * * * uint32_t clockticks6502 * * - A running total of the emulated cycle count. * * * * uint32_t instructions * * - A running total of the total emulated * * instruction count. This is not related to * * clock cycle timing. * * * *****************************************************/ #include #include //6502 defines //#define UNDOCUMENTED //when this is defined, undocumented opcodes are handled. //otherwise, they're simply treated as NOPs. //#define NES_CPU //when this is defined, the binary-coded decimal (BCD) //status flag is not honored by ADC and SBC. the 2A03 //CPU in the Nintendo Entertainment System does not //support BCD operation. #define FLAG_CARRY 0x01 #define FLAG_ZERO 0x02 #define FLAG_INTERRUPT 0x04 #define FLAG_DECIMAL 0x08 #define FLAG_BREAK 0x10 #define FLAG_CONSTANT 0x20 #define FLAG_OVERFLOW 0x40 #define FLAG_SIGN 0x80 #define BASE_STACK 0x100 #define saveaccum(n) a = (uint8_t)((n) & 0x00FF) //flag modifier macros #define setcarry() status |= FLAG_CARRY #define clearcarry() status &= (~FLAG_CARRY) #define setzero() status |= FLAG_ZERO #define clearzero() status &= (~FLAG_ZERO) #define setinterrupt() status |= FLAG_INTERRUPT #define clearinterrupt() status &= (~FLAG_INTERRUPT) #define setdecimal() status |= FLAG_DECIMAL #define cleardecimal() status &= (~FLAG_DECIMAL) #define setoverflow() status |= FLAG_OVERFLOW #define clearoverflow() status &= (~FLAG_OVERFLOW) #define setsign() status |= FLAG_SIGN #define clearsign() status &= (~FLAG_SIGN) //flag calculation macros #define zerocalc(n) {\ if ((n) & 0x00FF) clearzero();\ else setzero();\ } #define signcalc(n) {\ if ((n) & 0x0080) setsign();\ else clearsign();\ } #define carrycalc(n) {\ if ((n) & 0xFF00) setcarry();\ else clearcarry();\ } #define overflowcalc(n, m, o) { /* n = result, m = accumulator, o = memory */ \ if (((n) ^ (uint16_t)(m)) & ((n) ^ (o)) & 0x0080) setoverflow();\ else clearoverflow();\ } //6502 CPU registers uint16_t pc; uint8_t sp, a, x, y, status; //helper variables uint32_t instructions = 0; //keep track of total instructions executed uint32_t clockticks6502 = 0, clockgoal6502 = 0; uint16_t oldpc, ea, reladdr, value, result; uint8_t opcode, oldstatus; //externally supplied functions extern uint8_t read6502(uint16_t address); extern void write6502(uint16_t address, uint8_t value); //a few general functions used by various other functions void push16(uint16_t pushval) { write6502(BASE_STACK + sp, (pushval >> 8) & 0xFF); write6502(BASE_STACK + ((sp - 1) & 0xFF), pushval & 0xFF); sp -= 2; } void push8(uint8_t pushval) { write6502(BASE_STACK + sp--, pushval); } uint16_t pull16() { uint16_t temp16; temp16 = read6502(BASE_STACK + ((sp + 1) & 0xFF)) | ((uint16_t)read6502(BASE_STACK + ((sp + 2) & 0xFF)) << 8); sp += 2; return(temp16); } uint8_t pull8() { return (read6502(BASE_STACK + ++sp)); } void reset6502() { pc = (uint16_t)read6502(0xFFFC) | ((uint16_t)read6502(0xFFFD) << 8); a = 0; x = 0; y = 0; sp = 0xFD; status |= FLAG_CONSTANT; } static void (*addrtable[256])(); static void (*optable[256])(); uint8_t penaltyop, penaltyaddr; //addressing mode functions, calculates effective addresses static void imp() { //implied } static void acc() { //accumulator } static void imm() { //immediate ea = pc++; } static void zp() { //zero-page ea = (uint16_t)read6502((uint16_t)pc++); } static void zpx() { //zero-page,X ea = ((uint16_t)read6502((uint16_t)pc++) + (uint16_t)x) & 0xFF; //zero-page wraparound } static void zpy() { //zero-page,Y ea = ((uint16_t)read6502((uint16_t)pc++) + (uint16_t)y) & 0xFF; //zero-page wraparound } static void rel() { //relative for branch ops (8-bit immediate value, sign-extended) reladdr = (uint16_t)read6502(pc++); if (reladdr & 0x80) reladdr |= 0xFF00; } static void abso() { //absolute ea = (uint16_t)read6502(pc) | ((uint16_t)read6502(pc+1) << 8); pc += 2; } static void absx() { //absolute,X uint16_t startpage; ea = ((uint16_t)read6502(pc) | ((uint16_t)read6502(pc+1) << 8)); startpage = ea & 0xFF00; ea += (uint16_t)x; if (startpage != (ea & 0xFF00)) { //one cycle penlty for page-crossing on some opcodes penaltyaddr = 1; } pc += 2; } static void absy() { //absolute,Y uint16_t startpage; ea = ((uint16_t)read6502(pc) | ((uint16_t)read6502(pc+1) << 8)); startpage = ea & 0xFF00; ea += (uint16_t)y; if (startpage != (ea & 0xFF00)) { //one cycle penlty for page-crossing on some opcodes penaltyaddr = 1; } pc += 2; } static void ind() { //indirect uint16_t eahelp, eahelp2; eahelp = (uint16_t)read6502(pc) | (uint16_t)((uint16_t)read6502(pc+1) << 8); eahelp2 = (eahelp & 0xFF00) | ((eahelp + 1) & 0x00FF); //replicate 6502 page-boundary wraparound bug ea = (uint16_t)read6502(eahelp) | ((uint16_t)read6502(eahelp2) << 8); pc += 2; } static void indx() { // (indirect,X) uint16_t eahelp; eahelp = (uint16_t)(((uint16_t)read6502(pc++) + (uint16_t)x) & 0xFF); //zero-page wraparound for table pointer ea = (uint16_t)read6502(eahelp & 0x00FF) | ((uint16_t)read6502((eahelp+1) & 0x00FF) << 8); } static void indy() { // (indirect),Y uint16_t eahelp, eahelp2, startpage; eahelp = (uint16_t)read6502(pc++); eahelp2 = (eahelp & 0xFF00) | ((eahelp + 1) & 0x00FF); //zero-page wraparound ea = (uint16_t)read6502(eahelp) | ((uint16_t)read6502(eahelp2) << 8); startpage = ea & 0xFF00; ea += (uint16_t)y; if (startpage != (ea & 0xFF00)) { //one cycle penlty for page-crossing on some opcodes penaltyaddr = 1; } } static uint16_t getvalue() { if (addrtable[opcode] == acc) return((uint16_t)a); else return((uint16_t)read6502(ea)); } static uint16_t getvalue16() { return((uint16_t)read6502(ea) | ((uint16_t)read6502(ea+1) << 8)); } static void putvalue(uint16_t saveval) { if (addrtable[opcode] == acc) a = (uint8_t)(saveval & 0x00FF); else write6502(ea, (saveval & 0x00FF)); } //instruction handler functions static void adc() { penaltyop = 1; value = getvalue(); result = (uint16_t)a + value + (uint16_t)(status & FLAG_CARRY); carrycalc(result); zerocalc(result); overflowcalc(result, a, value); signcalc(result); #ifndef NES_CPU if (status & FLAG_DECIMAL) { clearcarry(); if ((a & 0x0F) > 0x09) { a += 0x06; } if ((a & 0xF0) > 0x90) { a += 0x60; setcarry(); } clockticks6502++; } #endif saveaccum(result); } static void and() { penaltyop = 1; value = getvalue(); result = (uint16_t)a & value; zerocalc(result); signcalc(result); saveaccum(result); } static void asl() { value = getvalue(); result = value << 1; carrycalc(result); zerocalc(result); signcalc(result); putvalue(result); } static void bcc() { if ((status & FLAG_CARRY) == 0) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void bcs() { if ((status & FLAG_CARRY) == FLAG_CARRY) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void beq() { if ((status & FLAG_ZERO) == FLAG_ZERO) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void bit() { value = getvalue(); result = (uint16_t)a & value; zerocalc(result); status = (status & 0x3F) | (uint8_t)(value & 0xC0); } static void bmi() { if ((status & FLAG_SIGN) == FLAG_SIGN) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void bne() { if ((status & FLAG_ZERO) == 0) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void bpl() { if ((status & FLAG_SIGN) == 0) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void brk6502() { pc++; push16(pc); //push next instruction address onto stack push8(status | FLAG_BREAK); //push CPU status to stack setinterrupt(); //set interrupt flag pc = (uint16_t)read6502(0xFFFE) | ((uint16_t)read6502(0xFFFF) << 8); } static void bvc() { if ((status & FLAG_OVERFLOW) == 0) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void bvs() { if ((status & FLAG_OVERFLOW) == FLAG_OVERFLOW) { oldpc = pc; pc += reladdr; if ((oldpc & 0xFF00) != (pc & 0xFF00)) clockticks6502 += 2; //check if jump crossed a page boundary else clockticks6502++; } } static void clc() { clearcarry(); } static void cld() { cleardecimal(); } static void cli() { clearinterrupt(); } static void clv() { clearoverflow(); } static void cmp() { penaltyop = 1; value = getvalue(); result = (uint16_t)a - value; if (a >= (uint8_t)(value & 0x00FF)) setcarry(); else clearcarry(); if (a == (uint8_t)(value & 0x00FF)) setzero(); else clearzero(); signcalc(result); } static void cpx() { value = getvalue(); result = (uint16_t)x - value; if (x >= (uint8_t)(value & 0x00FF)) setcarry(); else clearcarry(); if (x == (uint8_t)(value & 0x00FF)) setzero(); else clearzero(); signcalc(result); } static void cpy() { value = getvalue(); result = (uint16_t)y - value; if (y >= (uint8_t)(value & 0x00FF)) setcarry(); else clearcarry(); if (y == (uint8_t)(value & 0x00FF)) setzero(); else clearzero(); signcalc(result); } static void dec() { value = getvalue(); result = value - 1; zerocalc(result); signcalc(result); putvalue(result); } static void dex() { x--; zerocalc(x); signcalc(x); } static void dey() { y--; zerocalc(y); signcalc(y); } static void eor() { penaltyop = 1; value = getvalue(); result = (uint16_t)a ^ value; zerocalc(result); signcalc(result); saveaccum(result); } static void inc() { value = getvalue(); result = value + 1; zerocalc(result); signcalc(result); putvalue(result); } static void inx() { x++; zerocalc(x); signcalc(x); } static void iny() { y++; zerocalc(y); signcalc(y); } static void jmp() { pc = ea; } static void jsr() { push16(pc - 1); pc = ea; } static void lda() { penaltyop = 1; value = getvalue(); a = (uint8_t)(value & 0x00FF); zerocalc(a); signcalc(a); } static void ldx() { penaltyop = 1; value = getvalue(); x = (uint8_t)(value & 0x00FF); zerocalc(x); signcalc(x); } static void ldy() { penaltyop = 1; value = getvalue(); y = (uint8_t)(value & 0x00FF); zerocalc(y); signcalc(y); } static void lsr() { value = getvalue(); result = value >> 1; if (value & 1) setcarry(); else clearcarry(); zerocalc(result); signcalc(result); putvalue(result); } static void nop() { switch (opcode) { case 0x1C: case 0x3C: case 0x5C: case 0x7C: case 0xDC: case 0xFC: penaltyop = 1; break; } } static void ora() { penaltyop = 1; value = getvalue(); result = (uint16_t)a | value; zerocalc(result); signcalc(result); saveaccum(result); } static void pha() { push8(a); } static void php() { push8(status | FLAG_BREAK); } static void pla() { a = pull8(); zerocalc(a); signcalc(a); } static void plp() { status = pull8() | FLAG_CONSTANT; } static void rol() { value = getvalue(); result = (value << 1) | (status & FLAG_CARRY); carrycalc(result); zerocalc(result); signcalc(result); putvalue(result); } static void ror() { value = getvalue(); result = (value >> 1) | ((status & FLAG_CARRY) << 7); if (value & 1) setcarry(); else clearcarry(); zerocalc(result); signcalc(result); putvalue(result); } static void rti() { status = pull8(); value = pull16(); pc = value; } static void rts() { value = pull16(); pc = value + 1; } static void sbc() { penaltyop = 1; value = getvalue() ^ 0x00FF; result = (uint16_t)a + value + (uint16_t)(status & FLAG_CARRY); carrycalc(result); zerocalc(result); overflowcalc(result, a, value); signcalc(result); #ifndef NES_CPU if (status & FLAG_DECIMAL) { clearcarry(); a -= 0x66; if ((a & 0x0F) > 0x09) { a += 0x06; } if ((a & 0xF0) > 0x90) { a += 0x60; setcarry(); } clockticks6502++; } #endif saveaccum(result); } static void sec() { setcarry(); } static void sed() { setdecimal(); } static void sei() { setinterrupt(); } static void sta() { putvalue(a); } static void stx() { putvalue(x); } static void sty() { putvalue(y); } static void tax() { x = a; zerocalc(x); signcalc(x); } static void tay() { y = a; zerocalc(y); signcalc(y); } static void tsx() { x = sp; zerocalc(x); signcalc(x); } static void txa() { a = x; zerocalc(a); signcalc(a); } static void txs() { sp = x; } static void tya() { a = y; zerocalc(a); signcalc(a); } //undocumented instructions #ifdef UNDOCUMENTED static void lax() { lda(); ldx(); } static void sax() { sta(); stx(); putvalue(a & x); if (penaltyop && penaltyaddr) clockticks6502--; } static void dcp() { dec(); cmp(); if (penaltyop && penaltyaddr) clockticks6502--; } static void isb() { inc(); sbc(); if (penaltyop && penaltyaddr) clockticks6502--; } static void slo() { asl(); ora(); if (penaltyop && penaltyaddr) clockticks6502--; } static void rla() { rol(); and(); if (penaltyop && penaltyaddr) clockticks6502--; } static void sre() { lsr(); eor(); if (penaltyop && penaltyaddr) clockticks6502--; } static void rra() { ror(); adc(); if (penaltyop && penaltyaddr) clockticks6502--; } #else #define lax nop #define sax nop #define dcp nop #define isb nop #define slo nop #define rla nop #define sre nop #define rra nop #endif static void (*addrtable[256])() = { /* | 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | A | B | C | D | E | F | */ /* 0 */ imp, indx, imp, indx, zp, zp, zp, zp, imp, imm, acc, imm, abso, abso, abso, abso, /* 0 */ /* 1 */ rel, indy, imp, indy, zpx, zpx, zpx, zpx, imp, absy, imp, absy, absx, absx, absx, absx, /* 1 */ /* 2 */ abso, indx, imp, indx, zp, zp, zp, zp, imp, imm, acc, imm, abso, abso, abso, abso, /* 2 */ /* 3 */ rel, indy, imp, indy, zpx, zpx, zpx, zpx, imp, absy, imp, absy, absx, absx, absx, absx, /* 3 */ /* 4 */ imp, indx, imp, indx, zp, zp, zp, zp, imp, imm, acc, imm, abso, abso, abso, abso, /* 4 */ /* 5 */ rel, indy, imp, indy, zpx, zpx, zpx, zpx, imp, absy, imp, absy, absx, absx, absx, absx, /* 5 */ /* 6 */ imp, indx, imp, indx, zp, zp, zp, zp, imp, imm, acc, imm, ind, abso, abso, abso, /* 6 */ /* 7 */ rel, indy, imp, indy, zpx, zpx, zpx, zpx, imp, absy, imp, absy, absx, absx, absx, absx, /* 7 */ /* 8 */ imm, indx, imm, indx, zp, zp, zp, zp, imp, imm, imp, imm, abso, abso, abso, abso, /* 8 */ /* 9 */ rel, indy, imp, indy, zpx, zpx, zpy, zpy, imp, absy, imp, absy, absx, absx, absy, absy, /* 9 */ /* A */ imm, indx, imm, indx, zp, zp, zp, zp, imp, imm, imp, imm, abso, abso, abso, abso, /* A */ /* B */ rel, indy, imp, indy, zpx, zpx, zpy, zpy, imp, absy, imp, absy, absx, absx, absy, absy, /* B */ /* C */ imm, indx, imm, indx, zp, zp, zp, zp, imp, imm, imp, imm, abso, abso, abso, abso, /* C */ /* D */ rel, indy, imp, indy, zpx, zpx, zpx, zpx, imp, absy, imp, absy, absx, absx, absx, absx, /* D */ /* E */ imm, indx, imm, indx, zp, zp, zp, zp, imp, imm, imp, imm, abso, abso, abso, abso, /* E */ /* F */ rel, indy, imp, indy, zpx, zpx, zpx, zpx, imp, absy, imp, absy, absx, absx, absx, absx /* F */ }; static void (*optable[256])() = { /* | 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | A | B | C | D | E | F | */ /* 0 */ brk6502, ora, nop, slo, nop, ora, asl, slo, php, ora, asl, nop, nop, ora, asl, slo, /* 0 */ /* 1 */ bpl, ora, nop, slo, nop, ora, asl, slo, clc, ora, nop, slo, nop, ora, asl, slo, /* 1 */ /* 2 */ jsr, and, nop, rla, bit, and, rol, rla, plp, and, rol, nop, bit, and, rol, rla, /* 2 */ /* 3 */ bmi, and, nop, rla, nop, and, rol, rla, sec, and, nop, rla, nop, and, rol, rla, /* 3 */ /* 4 */ rti, eor, nop, sre, nop, eor, lsr, sre, pha, eor, lsr, nop, jmp, eor, lsr, sre, /* 4 */ /* 5 */ bvc, eor, nop, sre, nop, eor, lsr, sre, cli, eor, nop, sre, nop, eor, lsr, sre, /* 5 */ /* 6 */ rts, adc, nop, rra, nop, adc, ror, rra, pla, adc, ror, nop, jmp, adc, ror, rra, /* 6 */ /* 7 */ bvs, adc, nop, rra, nop, adc, ror, rra, sei, adc, nop, rra, nop, adc, ror, rra, /* 7 */ /* 8 */ nop, sta, nop, sax, sty, sta, stx, sax, dey, nop, txa, nop, sty, sta, stx, sax, /* 8 */ /* 9 */ bcc, sta, nop, nop, sty, sta, stx, sax, tya, sta, txs, nop, nop, sta, nop, nop, /* 9 */ /* A */ ldy, lda, ldx, lax, ldy, lda, ldx, lax, tay, lda, tax, nop, ldy, lda, ldx, lax, /* A */ /* B */ bcs, lda, nop, lax, ldy, lda, ldx, lax, clv, lda, tsx, lax, ldy, lda, ldx, lax, /* B */ /* C */ cpy, cmp, nop, dcp, cpy, cmp, dec, dcp, iny, cmp, dex, nop, cpy, cmp, dec, dcp, /* C */ /* D */ bne, cmp, nop, dcp, nop, cmp, dec, dcp, cld, cmp, nop, dcp, nop, cmp, dec, dcp, /* D */ /* E */ cpx, sbc, nop, isb, cpx, sbc, inc, isb, inx, sbc, nop, sbc, cpx, sbc, inc, isb, /* E */ /* F */ beq, sbc, nop, isb, nop, sbc, inc, isb, sed, sbc, nop, isb, nop, sbc, inc, isb /* F */ }; static const uint32_t ticktable[256] = { /* | 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | A | B | C | D | E | F | */ /* 0 */ 7, 6, 2, 8, 3, 3, 5, 5, 3, 2, 2, 2, 4, 4, 6, 6, /* 0 */ /* 1 */ 2, 5, 2, 8, 4, 4, 6, 6, 2, 4, 2, 7, 4, 4, 7, 7, /* 1 */ /* 2 */ 6, 6, 2, 8, 3, 3, 5, 5, 4, 2, 2, 2, 4, 4, 6, 6, /* 2 */ /* 3 */ 2, 5, 2, 8, 4, 4, 6, 6, 2, 4, 2, 7, 4, 4, 7, 7, /* 3 */ /* 4 */ 6, 6, 2, 8, 3, 3, 5, 5, 3, 2, 2, 2, 3, 4, 6, 6, /* 4 */ /* 5 */ 2, 5, 2, 8, 4, 4, 6, 6, 2, 4, 2, 7, 4, 4, 7, 7, /* 5 */ /* 6 */ 6, 6, 2, 8, 3, 3, 5, 5, 4, 2, 2, 2, 5, 4, 6, 6, /* 6 */ /* 7 */ 2, 5, 2, 8, 4, 4, 6, 6, 2, 4, 2, 7, 4, 4, 7, 7, /* 7 */ /* 8 */ 2, 6, 2, 6, 3, 3, 3, 3, 2, 2, 2, 2, 4, 4, 4, 4, /* 8 */ /* 9 */ 2, 6, 2, 6, 4, 4, 4, 4, 2, 5, 2, 5, 5, 5, 5, 5, /* 9 */ /* A */ 2, 6, 2, 6, 3, 3, 3, 3, 2, 2, 2, 2, 4, 4, 4, 4, /* A */ /* B */ 2, 5, 2, 5, 4, 4, 4, 4, 2, 4, 2, 4, 4, 4, 4, 4, /* B */ /* C */ 2, 6, 2, 8, 3, 3, 5, 5, 2, 2, 2, 2, 4, 4, 6, 6, /* C */ /* D */ 2, 5, 2, 8, 4, 4, 6, 6, 2, 4, 2, 7, 4, 4, 7, 7, /* D */ /* E */ 2, 6, 2, 8, 3, 3, 5, 5, 2, 2, 2, 2, 4, 4, 6, 6, /* E */ /* F */ 2, 5, 2, 8, 4, 4, 6, 6, 2, 4, 2, 7, 4, 4, 7, 7 /* F */ }; void nmi6502() { push16(pc); push8(status); status |= FLAG_INTERRUPT; pc = (uint16_t)read6502(0xFFFA) | ((uint16_t)read6502(0xFFFB) << 8); } void irq6502() { push16(pc); push8(status); status |= FLAG_INTERRUPT; pc = (uint16_t)read6502(0xFFFE) | ((uint16_t)read6502(0xFFFF) << 8); } uint8_t callexternal = 0; void (*loopexternal)(); /* void exec6502(uint32_t tickcount) { clockgoal6502 += tickcount; while (clockticks6502 < clockgoal6502) { opcode = read6502(pc++); status |= FLAG_CONSTANT; penaltyop = 0; penaltyaddr = 0; (*addrtable[opcode])(); (*optable[opcode])(); clockticks6502 += ticktable[opcode]; if (penaltyop && penaltyaddr) clockticks6502++; instructions++; if (callexternal) (*loopexternal)(); } } */ void exec6502(unsigned int org) { clockticks6502 = 0; pc = org; while ((opcode = read6502(pc++)) != 0x00) { // end on BRK status |= FLAG_CONSTANT; penaltyop = 0; penaltyaddr = 0; (*addrtable[opcode])(); (*optable[opcode])(); clockticks6502 += ticktable[opcode]; if (penaltyop && penaltyaddr) clockticks6502++; instructions++; if (callexternal) (*loopexternal)(); } } void step6502() { opcode = read6502(pc++); status |= FLAG_CONSTANT; penaltyop = 0; penaltyaddr = 0; (*addrtable[opcode])(); (*optable[opcode])(); clockticks6502 += ticktable[opcode]; if (penaltyop && penaltyaddr) clockticks6502++; clockgoal6502 = clockticks6502; instructions++; if (callexternal) (*loopexternal)(); } void hookexternal(void *funcptr) { if (funcptr != (void *)NULL) { loopexternal = funcptr; callexternal = 1; } else callexternal = 0; }