6502-emu/6502.c
Rob McMullen 986a9f33b6 Handle zero page wraparound in ($xx,X)
* fixes line #1100: CFF4  C9 5D     CMP
2017-12-18 11:58:03 -08:00

939 lines
27 KiB
C

#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include "6502.h"
//#define DEBUG
int lengths[NUM_MODES]; // instruction length table, indexed by addressing mode
uint8_t * (*get_ptr[NUM_MODES])(); // addressing mode decoder table
Instruction instructions[0x100]; // instruction data table
Instruction inst; // the current instruction (used for convenience)
int jumping; // used to check that we don't need to increment the PC after a jump
/* Flag Checks */
static inline void N_flag(int8_t val)
{
SR.bits.sign = val < 0;
}
static inline void Z_flag(uint8_t val)
{
SR.bits.zero = val == 0;
}
/* Stack Helpers */
static inline void stack_push(uint8_t val)
{
memory[0x100+(SP--)] = val;
}
static inline uint8_t stack_pull()
{
return memory[0x100+(++SP)];
}
/* Memory read/write wrappers */
static inline uint8_t * read_ptr()
{
return read_addr = get_ptr[inst.mode]();
}
static inline uint8_t * write_ptr()
{
return write_addr = get_ptr[inst.mode]();
}
/* Instruction Implementations */
static void inst_ADC()
{
uint8_t operand = * read_ptr();
int tmp = A + operand + (SR.bits.carry & 1);
SR.bits.carry = tmp > 0xFF;
SR.bits.overflow = ((A^tmp)&(operand^tmp)&0x80) != 0;
A = tmp & 0xFF;
N_flag(A);
Z_flag(A);
}
static void inst_AND()
{
A &= * read_ptr();
N_flag(A);
Z_flag(A);
}
static void inst_ASL()
{
uint8_t tmp = * read_ptr();
SR.bits.carry = (tmp & 0x80) != 0;
tmp <<= 1;
N_flag(tmp);
Z_flag(tmp);
* write_ptr() = tmp;
}
static void inst_BCC()
{
if (!SR.bits.carry) {
PC = read_ptr() - memory;
}
}
static void inst_BCS()
{
if (SR.bits.carry) {
PC = read_ptr() - memory;
}
}
static void inst_BEQ()
{
if (SR.bits.zero) {
PC = read_ptr() - memory;
}
}
static void inst_BIT()
{
uint8_t tmp = * read_ptr();
N_flag(tmp);
Z_flag(tmp & A);
SR.bits.overflow = (tmp & 0x40) != 0;
}
static void inst_BMI()
{
if (SR.bits.sign) {
PC = read_ptr() - memory;
}
}
static void inst_BNE()
{
if (!SR.bits.zero) {
PC = read_ptr() - memory;
}
}
static void inst_BPL()
{
if (!SR.bits.sign) {
PC = read_ptr() - memory;
}
}
static void inst_BRK()
{
uint16_t newPC;
memcpy(&newPC, &memory[IRQ_VEC], sizeof(newPC));
PC += 2;
stack_push(PC >> 8);
stack_push(PC & 0xFF);
SR.bits.brk = 1;
stack_push(SR.byte);
SR.bits.interrupt = 1;
PC = newPC;
jumping = 1;
}
static void inst_BVC()
{
if (!SR.bits.overflow) {
PC = read_ptr() - memory;
}
}
static void inst_BVS()
{
if (SR.bits.overflow) {
PC = read_ptr() - memory;
}
}
static void inst_CLC()
{
SR.bits.carry = 0;
}
static void inst_CLD()
{
SR.bits.decimal = 0;
}
static void inst_CLI()
{
SR.bits.interrupt = 0;
}
static void inst_CLV()
{
SR.bits.overflow = 0;
}
static void inst_CMP()
{
uint8_t operand = * read_ptr();
uint8_t tmpDiff = A - operand;
N_flag(tmpDiff);
Z_flag(tmpDiff);
SR.bits.carry = A >= operand;
}
static void inst_CPX()
{
uint8_t operand = * read_ptr();
uint8_t tmpDiff = X - operand;
N_flag(tmpDiff);
Z_flag(tmpDiff);
SR.bits.carry = X >= operand;
}
static void inst_CPY()
{
uint8_t operand = * read_ptr();
uint8_t tmpDiff = Y - operand;
N_flag(tmpDiff);
Z_flag(tmpDiff);
SR.bits.carry = Y >= operand;
}
static void inst_DEC()
{
uint8_t tmp = * read_ptr();
tmp--;
N_flag(tmp);
Z_flag(tmp);
* write_ptr() = tmp;
}
static void inst_DEX()
{
X--;
N_flag(X);
Z_flag(X);
}
static void inst_DEY()
{
Y--;
N_flag(Y);
Z_flag(Y);
}
static void inst_EOR()
{
A ^= * read_ptr();
N_flag(A);
Z_flag(A);
}
static void inst_INC()
{
uint8_t tmp = * read_ptr();
tmp++;
N_flag(tmp);
Z_flag(tmp);
* write_ptr() = tmp;
}
static void inst_INX()
{
X++;
N_flag(X);
Z_flag(X);
}
static void inst_INY()
{
Y++;
N_flag(Y);
Z_flag(Y);
}
static void inst_JMP()
{
PC = read_ptr() - memory;
jumping = 1;
}
static void inst_JSR()
{
uint16_t newPC = read_ptr() - memory;
PC += 2;
stack_push(PC >> 8);
stack_push(PC & 0xFF);
PC = newPC;
jumping = 1;
}
static void inst_LDA()
{
A = * read_ptr();
N_flag(A);
Z_flag(A);
}
static void inst_LDX()
{
X = * read_ptr();
N_flag(X);
Z_flag(X);
}
static void inst_LDY()
{
Y = * read_ptr();
N_flag(Y);
Z_flag(Y);
}
static void inst_LSR()
{
uint8_t tmp = * read_ptr();
SR.bits.carry = tmp & 1;
tmp >>= 1;
N_flag(tmp);
Z_flag(tmp);
* write_ptr() = tmp;
}
static void inst_NOP()
{
// nothing
}
static void inst_ORA()
{
A |= * read_ptr();
N_flag(A);
Z_flag(A);
}
static void inst_PHA()
{
stack_push(A);
}
static void inst_PHP()
{
union StatusReg pushed_sr;
// PHP sets the BRK flag in the byte that is pushed onto the stack,
// but doesn't affect the status register itself. this is slightly
// unexpected, but it's what the real hardware does.
//
// See http://visual6502.org/wiki/index.php?title=6502_BRK_and_B_bit
pushed_sr.byte = SR.byte;
pushed_sr.bits.brk = 1;
stack_push(pushed_sr.byte);
}
static void inst_PLA()
{
A = stack_pull();
N_flag(A);
Z_flag(A);
}
static void inst_PLP()
{
SR.byte = stack_pull();
SR.bits.unused = 1;
SR.bits.brk = 0;
}
static void inst_ROL()
{
int tmp = (* read_ptr()) << 1;
tmp |= SR.bits.carry & 1;
SR.bits.carry = tmp > 0xFF;
tmp &= 0xFF;
N_flag(tmp);
Z_flag(tmp);
* write_ptr() = tmp;
}
static void inst_ROR()
{
int tmp = * read_ptr();
tmp |= SR.bits.carry << 8;
SR.bits.carry = tmp & 1;
tmp >>= 1;
N_flag(tmp);
Z_flag(tmp);
* write_ptr() = tmp;
}
static void inst_RTI()
{
SR.byte = stack_pull();
SR.bits.unused = 1;
PC = stack_pull();
PC |= stack_pull() << 8;
//PC += 1;
jumping = 1;
}
static void inst_RTS()
{
PC = stack_pull();
PC |= stack_pull() << 8;
PC += 1;
jumping = 1;
}
static void inst_SBC()
{
uint8_t operand = ~(* read_ptr()); // identical to ACD with the operand inverted
int tmp = A + operand + (SR.bits.carry & 1);
SR.bits.carry = tmp > 0xFF;
SR.bits.overflow = ((A^tmp)&(operand^tmp)&0x80) != 0;
A = tmp & 0xFF;
N_flag(A);
Z_flag(A);
}
static void inst_SEC()
{
SR.bits.carry = 1;
}
static void inst_SED()
{
SR.bits.decimal = 1;
}
static void inst_SEI()
{
SR.bits.interrupt = 1;
}
static void inst_STA()
{
* write_ptr() = A;
}
static void inst_STX()
{
* write_ptr() = X;
}
static void inst_STY()
{
* write_ptr() = Y;
}
static void inst_TAX()
{
X = A;
N_flag(X);
Z_flag(X);
}
static void inst_TAY()
{
Y = A;
N_flag(Y);
Z_flag(Y);
}
static void inst_TSX()
{
X = SP;
N_flag(X);
Z_flag(X);
}
static void inst_TXA()
{
A = X;
N_flag(A);
Z_flag(A);
}
static void inst_TXS()
{
SP = X;
}
static void inst_TYA()
{
A = Y;
N_flag(A);
Z_flag(A);
}
/* Addressing Implementations */
uint8_t * get_IMM()
{
return &memory[(uint16_t) (PC+1)];
}
uint16_t get_uint16()
{ // used only as part of other modes
uint16_t index;
memcpy(&index, get_IMM(), sizeof(index)); // hooray for optimising compilers
return index;
}
uint8_t * get_ZP()
{
return &memory[* get_IMM()];
}
uint8_t * get_ZPX()
{
return &memory[((* get_IMM()) + X) & 0xFF];
}
uint8_t * get_ZPY()
{
return &memory[((* get_IMM()) + Y) & 0xFF];
}
uint8_t * get_ACC()
{
return &A;
}
uint8_t * get_ABS()
{
return &memory[get_uint16()];
}
uint8_t * get_ABSX()
{
return &memory[(uint16_t) (get_uint16() + X)];
}
uint8_t * get_ABSY()
{
return &memory[(uint16_t) (get_uint16() + Y)];
}
uint8_t * get_IND()
{
uint16_t ptr;
memcpy(&ptr, get_ABS(), sizeof(ptr));
return &memory[ptr];
}
uint8_t * get_XIND()
{
uint16_t ptr;
ptr = ((* get_IMM()) + X) & 0xFF;
if (ptr == 0xff) { // check for wraparound in zero page
ptr = memory[ptr] + (memory[ptr & 0xff00] << 8);
}
else {
memcpy(&ptr, &memory[ptr], sizeof(ptr));
}
return &memory[ptr];
}
uint8_t * get_INDY()
{
uint16_t ptr;
memcpy(&ptr, get_ZP(), sizeof(ptr));
ptr += Y;
return &memory[ptr];
}
uint8_t * get_REL()
{
return &memory[(uint16_t) (PC + (int8_t) * get_IMM())];
}
uint8_t * get_JMP_IND_BUG()
{
uint8_t * addr;
uint16_t ptr;
ptr = get_uint16();
if ((ptr & 0xff) == 0xff) {
// Bug when crosses a page boundary. When using relative index ($xxff),
// instead of using the last byte of the page and the first byte of the
// next page, it uses the first byte of the same page. E.g. jmp ($baff)
// would use the value at $baff as the LSB, but $ba00 as the high byte
// instead of $bb00. This was fixed in the 65C02
ptr = memory[ptr] + (memory[ptr & 0xff00] << 8);
}
else {
addr = &memory[ptr];
memcpy(&ptr, addr, sizeof(ptr));
}
return &memory[ptr];
}
/* Construction of Tables */
void init_tables() // this is only done at runtime to improve code readability.
{
/* Instruction Lengths */
lengths[ACC] = 1;
lengths[ABS] = 3;
lengths[ABSX] = 3;
lengths[ABSY] = 3;
lengths[IMM] = 2;
lengths[IMPL] = 1;
lengths[IND] = 3;
lengths[XIND] = 2;
lengths[INDY] = 2;
lengths[REL] = 2;
lengths[ZP] = 2;
lengths[ZPX] = 2;
lengths[ZPY] = 2;
lengths[JMP_IND_BUG] = 3;
/* Addressing Modes */
get_ptr[ACC] = get_ACC;
get_ptr[ABS] = get_ABS;
get_ptr[ABSX] = get_ABSX;
get_ptr[ABSY] = get_ABSY;
get_ptr[IMM] = get_IMM;
get_ptr[IND] = get_IND;
get_ptr[XIND] = get_XIND;
get_ptr[INDY] = get_INDY;
get_ptr[REL] = get_REL;
get_ptr[ZP] = get_ZP;
get_ptr[ZPX] = get_ZPX;
get_ptr[ZPY] = get_ZPY;
get_ptr[JMP_IND_BUG] = get_JMP_IND_BUG;
/* Instructions */
instructions[0x00] = (Instruction) {"BRK impl", inst_BRK, IMPL, 7,};
instructions[0x01] = (Instruction) {"ORA X,ind", inst_ORA, XIND, 6};
instructions[0x02] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x03] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x04] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x05] = (Instruction) {"ORA zpg", inst_ORA, ZP, 5};
instructions[0x06] = (Instruction) {"ASL zpg", inst_ASL, ZP, 1};
instructions[0x07] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x08] = (Instruction) {"PHP impl", inst_PHP, IMPL, 1};
instructions[0x09] = (Instruction) {"ORA #", inst_ORA, IMM, 1};
instructions[0x0A] = (Instruction) {"ASL A", inst_ASL, ACC, 1};
instructions[0x0B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x0C] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x0D] = (Instruction) {"ORA abs", inst_ORA, ABS, 1};
instructions[0x0E] = (Instruction) {"ASL abs", inst_ASL, ABS, 1};
instructions[0x0F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x10] = (Instruction) {"BPL rel", inst_BPL, REL, 1};
instructions[0x11] = (Instruction) {"ORA ind,Y", inst_ORA, INDY, 1};
instructions[0x12] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x13] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x14] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x15] = (Instruction) {"ORA zpg,X", inst_ORA, ZPX, 1};
instructions[0x16] = (Instruction) {"ASL zpg,X", inst_ASL, ZPX, 1};
instructions[0x17] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x18] = (Instruction) {"CLC impl", inst_CLC, IMPL, 1};
instructions[0x19] = (Instruction) {"ORA abs,Y", inst_ORA, ABSY, 1};
instructions[0x1A] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x1B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x1C] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x1D] = (Instruction) {"ORA abs,X", inst_ORA, ABSX, 1};
instructions[0x1E] = (Instruction) {"ASL abs,X", inst_ASL, ABSX, 1};
instructions[0x1F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x20] = (Instruction) {"JSR abs", inst_JSR, ABS, 1};
instructions[0x21] = (Instruction) {"AND X,ind", inst_AND, XIND, 1};
instructions[0x22] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x23] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x24] = (Instruction) {"BIT zpg", inst_BIT, ZP, 1};
instructions[0x25] = (Instruction) {"AND zpg", inst_AND, ZP, 1};
instructions[0x26] = (Instruction) {"ROL zpg", inst_ROL, ZP, 1};
instructions[0x27] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x28] = (Instruction) {"PLP impl", inst_PLP, IMPL, 1};
instructions[0x29] = (Instruction) {"AND #", inst_AND, IMM, 1};
instructions[0x2A] = (Instruction) {"ROL A", inst_ROL, ACC, 1};
instructions[0x2B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x2C] = (Instruction) {"BIT abs", inst_BIT, ABS, 1};
instructions[0x2D] = (Instruction) {"AND abs", inst_AND, ABS, 1};
instructions[0x2E] = (Instruction) {"ROL abs", inst_ROL, ABS, 1};
instructions[0x2F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x30] = (Instruction) {"BMI rel", inst_BMI, REL, 1};
instructions[0x31] = (Instruction) {"AND ind,Y", inst_AND, INDY, 1};
instructions[0x32] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x33] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x34] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x35] = (Instruction) {"AND zpg,X", inst_AND, ZPX, 1};
instructions[0x36] = (Instruction) {"ROL zpg,X", inst_ROL, ZPX, 1};
instructions[0x37] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x38] = (Instruction) {"SEC impl", inst_SEC, IMPL, 1};
instructions[0x39] = (Instruction) {"AND abs,Y", inst_AND, ABSY, 1};
instructions[0x3A] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x3B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x3C] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x3D] = (Instruction) {"AND abs,X", inst_AND, ABSX, 1};
instructions[0x3E] = (Instruction) {"ROL abs,X", inst_ROL, ABSX, 1};
instructions[0x3F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x40] = (Instruction) {"RTI impl", inst_RTI, IMPL, 1};
instructions[0x41] = (Instruction) {"EOR X,ind", inst_EOR, XIND, 1};
instructions[0x42] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x43] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x44] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x45] = (Instruction) {"EOR zpg", inst_EOR, ZP, 1};
instructions[0x46] = (Instruction) {"LSR zpg", inst_LSR, ZP, 1};
instructions[0x47] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x48] = (Instruction) {"PHA impl", inst_PHA, IMPL, 1};
instructions[0x49] = (Instruction) {"EOR #", inst_EOR, IMM, 1};
instructions[0x4A] = (Instruction) {"LSR A", inst_LSR, ACC, 1};
instructions[0x4B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x4C] = (Instruction) {"JMP abs", inst_JMP, ABS, 1};
instructions[0x4D] = (Instruction) {"EOR abs", inst_EOR, ABS, 1};
instructions[0x4E] = (Instruction) {"LSR abs", inst_LSR, ABS, 1};
instructions[0x4F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x50] = (Instruction) {"BVC rel", inst_BVC, REL, 1};
instructions[0x51] = (Instruction) {"EOR ind,Y", inst_EOR, INDY, 1};
instructions[0x52] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x53] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x54] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x55] = (Instruction) {"EOR zpg,X", inst_EOR, ZPX, 1};
instructions[0x56] = (Instruction) {"LSR zpg,X", inst_LSR, ZPX, 1};
instructions[0x57] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x58] = (Instruction) {"CLI impl", inst_CLI, IMPL, 1};
instructions[0x59] = (Instruction) {"EOR abs,Y", inst_EOR, ABSY, 1};
instructions[0x5A] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x5B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x5C] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x5D] = (Instruction) {"EOR abs,X", inst_EOR, ABSX, 1};
instructions[0x5E] = (Instruction) {"LSR abs,X", inst_LSR, ABSX, 1};
instructions[0x5F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x60] = (Instruction) {"RTS impl", inst_RTS, IMPL, 1};
instructions[0x61] = (Instruction) {"ADC X,ind", inst_ADC, XIND, 1};
instructions[0x62] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x63] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x64] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x65] = (Instruction) {"ADC zpg", inst_ADC, ZP, 1};
instructions[0x66] = (Instruction) {"ROR zpg", inst_ROR, ZP, 1};
instructions[0x67] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x68] = (Instruction) {"PLA impl", inst_PLA, IMPL, 1};
instructions[0x69] = (Instruction) {"ADC #", inst_ADC, IMM, 1};
instructions[0x6A] = (Instruction) {"ROR A", inst_ROR, ACC, 1};
instructions[0x6B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x6C] = (Instruction) {"JMP ind", inst_JMP, JMP_IND_BUG, 1};
instructions[0x6D] = (Instruction) {"ADC abs", inst_ADC, ABS, 1};
instructions[0x6E] = (Instruction) {"ROR abs", inst_ROR, ABS, 1};
instructions[0x6F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x70] = (Instruction) {"BVS rel", inst_BVS, REL, 1};
instructions[0x71] = (Instruction) {"ADC ind,Y", inst_ADC, INDY, 1};
instructions[0x72] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x73] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x74] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x75] = (Instruction) {"ADC zpg,X", inst_ADC, ZPX, 1};
instructions[0x76] = (Instruction) {"ROR zpg,X", inst_ROR, ZPX, 1};
instructions[0x77] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x78] = (Instruction) {"SEI impl", inst_SEI, IMPL, 1};
instructions[0x79] = (Instruction) {"ADC abs,Y", inst_ADC, ABSY, 1};
instructions[0x7A] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x7B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x7C] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x7D] = (Instruction) {"ADC abs,X", inst_ADC, ABSX, 1};
instructions[0x7E] = (Instruction) {"ROR abs,X", inst_ROR, ABSX, 1};
instructions[0x7F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x80] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x81] = (Instruction) {"STA X,ind", inst_STA, XIND, 1};
instructions[0x82] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x83] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x84] = (Instruction) {"STY zpg", inst_STY, ZP, 1};
instructions[0x85] = (Instruction) {"STA zpg", inst_STA, ZP, 1};
instructions[0x86] = (Instruction) {"STX zpg", inst_STX, ZP, 1};
instructions[0x87] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x88] = (Instruction) {"DEY impl", inst_DEY, IMPL, 1};
instructions[0x89] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x8A] = (Instruction) {"TXA impl", inst_TXA, IMPL, 1};
instructions[0x8B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x8C] = (Instruction) {"STY abs", inst_STY, ABS, 1};
instructions[0x8D] = (Instruction) {"STA abs", inst_STA, ABS, 1};
instructions[0x8E] = (Instruction) {"STX abs", inst_STX, ABS, 1};
instructions[0x8F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x90] = (Instruction) {"BCC rel", inst_BCC, REL, 1};
instructions[0x91] = (Instruction) {"STA ind,Y", inst_STA, INDY, 1};
instructions[0x92] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x93] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x94] = (Instruction) {"STY zpg,X", inst_STY, ZPX, 1};
instructions[0x95] = (Instruction) {"STA zpg,X", inst_STA, ZPX, 1};
instructions[0x96] = (Instruction) {"STX zpg,Y", inst_STX, ZPY, 1};
instructions[0x97] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x98] = (Instruction) {"TYA impl", inst_TYA, IMPL, 1};
instructions[0x99] = (Instruction) {"STA abs,Y", inst_STA, ABSY, 1};
instructions[0x9A] = (Instruction) {"TXS impl", inst_TXS, IMPL, 1};
instructions[0x9B] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x9C] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x9D] = (Instruction) {"STA abs,X", inst_STA, ABSX, 1};
instructions[0x9E] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0x9F] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xA0] = (Instruction) {"LDY #", inst_LDY, IMM, 1};
instructions[0xA1] = (Instruction) {"LDA X,ind", inst_LDA, XIND, 1};
instructions[0xA2] = (Instruction) {"LDX #", inst_LDX, IMM, 1};
instructions[0xA3] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xA4] = (Instruction) {"LDY zpg", inst_LDY, ZP, 1};
instructions[0xA5] = (Instruction) {"LDA zpg", inst_LDA, ZP, 1};
instructions[0xA6] = (Instruction) {"LDX zpg", inst_LDX, ZP, 1};
instructions[0xA7] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xA8] = (Instruction) {"TAY impl", inst_TAY, IMPL, 1};
instructions[0xA9] = (Instruction) {"LDA #", inst_LDA, IMM, 1};
instructions[0xAA] = (Instruction) {"TAX impl", inst_TAX, IMPL, 1};
instructions[0xAB] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xAC] = (Instruction) {"LDY abs", inst_LDY, ABS, 1};
instructions[0xAD] = (Instruction) {"LDA abs", inst_LDA, ABS, 1};
instructions[0xAE] = (Instruction) {"LDX abs", inst_LDX, ABS, 1};
instructions[0xAF] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xB0] = (Instruction) {"BCS rel", inst_BCS, REL, 1};
instructions[0xB1] = (Instruction) {"LDA ind,Y", inst_LDA, INDY, 1};
instructions[0xB2] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xB3] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xB4] = (Instruction) {"LDY zpg,X", inst_LDY, ZPX, 1};
instructions[0xB5] = (Instruction) {"LDA zpg,X", inst_LDA, ZPX, 1};
instructions[0xB6] = (Instruction) {"LDX zpg,Y", inst_LDX, ZPY, 1};
instructions[0xB7] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xB8] = (Instruction) {"CLV impl", inst_CLV, IMPL, 1};
instructions[0xB9] = (Instruction) {"LDA abs,Y", inst_LDA, ABSY, 1};
instructions[0xBA] = (Instruction) {"TSX impl", inst_TSX, IMPL, 1};
instructions[0xBB] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xBC] = (Instruction) {"LDY abs,X", inst_LDY, ABSX, 1};
instructions[0xBD] = (Instruction) {"LDA abs,X", inst_LDA, ABSX, 1};
instructions[0xBE] = (Instruction) {"LDX abs,Y", inst_LDX, ABSY, 1};
instructions[0xBF] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xC0] = (Instruction) {"CPY #", inst_CPY, IMM, 1};
instructions[0xC1] = (Instruction) {"CMP X,ind", inst_CMP, XIND, 1};
instructions[0xC2] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xC3] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xC4] = (Instruction) {"CPY zpg", inst_CPY, ZP, 1};
instructions[0xC5] = (Instruction) {"CMP zpg", inst_CMP, ZP, 1};
instructions[0xC6] = (Instruction) {"DEC zpg", inst_DEC, ZP, 1};
instructions[0xC7] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xC8] = (Instruction) {"INY impl", inst_INY, IMPL, 1};
instructions[0xC9] = (Instruction) {"CMP #", inst_CMP, IMM, 1};
instructions[0xCA] = (Instruction) {"DEX impl", inst_DEX, IMPL, 1};
instructions[0xCB] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xCC] = (Instruction) {"CPY abs", inst_CPY, ABS, 1};
instructions[0xCD] = (Instruction) {"CMP abs", inst_CMP, ABS, 1};
instructions[0xCE] = (Instruction) {"DEC abs", inst_DEC, ABS, 1};
instructions[0xCF] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xD0] = (Instruction) {"BNE rel", inst_BNE, REL, 1};
instructions[0xD1] = (Instruction) {"CMP ind,Y", inst_CMP, INDY, 1};
instructions[0xD2] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xD3] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xD4] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xD5] = (Instruction) {"CMP zpg,X", inst_CMP, ZPX, 1};
instructions[0xD6] = (Instruction) {"DEC zpg,X", inst_DEC, ZPX, 1};
instructions[0xD7] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xD8] = (Instruction) {"CLD impl", inst_CLD, IMPL, 1};
instructions[0xD9] = (Instruction) {"CMP abs,Y", inst_CMP, ABSY, 1};
instructions[0xDA] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xDB] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xDC] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xDD] = (Instruction) {"CMP abs,X", inst_CMP, ABSX, 1};
instructions[0xDE] = (Instruction) {"DEC abs,X", inst_DEC, ABSX, 1};
instructions[0xDF] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xE0] = (Instruction) {"CPX #", inst_CPX, IMM, 1};
instructions[0xE1] = (Instruction) {"SBC X,ind", inst_SBC, XIND, 1};
instructions[0xE2] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xE3] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xE4] = (Instruction) {"CPX zpg", inst_CPX, ZP, 1};
instructions[0xE5] = (Instruction) {"SBC zpg", inst_SBC, ZP, 1};
instructions[0xE6] = (Instruction) {"INC zpg", inst_INC, ZP, 1};
instructions[0xE7] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xE8] = (Instruction) {"INX impl", inst_INX, IMPL, 1};
instructions[0xE9] = (Instruction) {"SBC #", inst_SBC, IMM, 1};
instructions[0xEA] = (Instruction) {"NOP impl", inst_NOP, IMPL, 1};
instructions[0xEB] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xEC] = (Instruction) {"CPX abs", inst_CPX, ABS, 1};
instructions[0xED] = (Instruction) {"SBC abs", inst_SBC, ABS, 1};
instructions[0xEE] = (Instruction) {"INC abs", inst_INC, ABS, 1};
instructions[0xEF] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xF0] = (Instruction) {"BEQ rel", inst_BEQ, REL, 1};
instructions[0xF1] = (Instruction) {"SBC ind,Y", inst_SBC, INDY, 1};
instructions[0xF2] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xF3] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xF4] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xF5] = (Instruction) {"SBC zpg,X", inst_SBC, ZPX, 1};
instructions[0xF6] = (Instruction) {"INC zpg,X", inst_INC, ZPX, 1};
instructions[0xF7] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xF8] = (Instruction) {"SED impl", inst_SED, IMPL, 1};
instructions[0xF9] = (Instruction) {"SBC abs,Y", inst_SBC, ABSY, 1};
instructions[0xFA] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xFB] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xFC] = (Instruction) {"???", inst_NOP, IMPL, 1};
instructions[0xFD] = (Instruction) {"SBC abs,X", inst_SBC, ABSX, 1};
instructions[0xFE] = (Instruction) {"INC abs,X", inst_INC, ABSX, 1};
instructions[0xFF] = (Instruction) {"???", inst_NOP, IMPL, 1};
}
void reset_cpu(int _a, int _x, int _y, int _sp, int _sr, int _pc)
{
A = _a;
X = _x;
Y = _y;
SP = _sp;
SR.byte = _sr;
SR.bits.interrupt = 1;
SR.bits.unused = 1;
if (_pc < 0)
memcpy(&PC, &memory[-_pc], sizeof(PC));
else
PC = _pc;
}
int load_rom(char * filename)
{ // TODO allow more flexible loading
memset(memory, 0, sizeof(memory)); // clear ram first
FILE * fp = fopen(filename, "r");
if (fp == NULL) {
printf("Error: could not open file\n");
return -1;
}
if (!fread(&memory[0xC000], 0x4000, 1, fp)) {
printf("Error: ROM file too short.\n");
return -1;
}
fclose(fp);
return 0;
}
int step_cpu(int verbose) // returns cycle count
{
inst = instructions[memory[PC]];
if (verbose) {
// almost match for NES dump for easier comparison
printf("%04X ", PC);
if (lengths[inst.mode] == 3)
printf("%02X %02X %02X", memory[PC], memory[PC+1], memory[PC+2]);
else if (lengths[inst.mode] == 2)
printf("%02X %02X ", memory[PC], memory[PC+1]);
else
printf("%02X ", memory[PC]);
printf(" %-10s A:%02X X:%02X Y:%02X P:%02X SP:%02X CYC:%03d\n", inst.mnemonic, A, X, Y, SR.byte, SP, 0);
}
jumping = 0;
inst.function();
if (jumping == 0) PC += lengths[inst.mode];
return inst.cycles;
}
void save_memory(char * filename) { // dump memory for analysis (slows down emulation significantly)
if (filename == NULL) filename = "memdump";
FILE * fp = fopen(filename, "w");
fwrite(&memory, sizeof(memory), 1, fp);
fclose(fp);
}