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mirror of https://github.com/jborza/emu6502.git synced 2024-11-21 23:31:19 +00:00
emu6502/cpu.c
2019-04-15 23:34:21 +02:00

356 lines
13 KiB
C

#include "state.h"
#include "cpu.h"
#include "opcodes.h"
#include <stdio.h>
#include <memory.h>
#include <stdlib.h>
void* unimplemented_instruction(State6502* state) {
printf("Error: unimplemented instruction\n");
exit(1);
}
void set_NV_flags(State6502* state, byte value) {
//N flag
state->flags.n = ((1 << 7) & value) != 0;
//TODO implement NV flags
}
void set_NZ_flags(State6502 * state, byte value) {
//Z flag
if (value) {
state->flags.z = 0;
}
else {
state->flags.z = 1;
}
printf("setting z flag to %d\n", state->flags.z);
//N flag
state->flags.n = ((1 << 7) & value) != 0;
}
void clear_flags(State6502 * state) {
memcpy(&state->flags, &state->a, 1);
}
void clear_state(State6502 * state) {
state->a = 0;
state->x = 0;
state->y = 0;
state->pc = 0;
state->sp = 0;
clear_flags(state);
state->running = 1;
}
byte pop_byte(State6502 * state) {
return state->memory[state->pc++];
}
//bitwise or with accumulator
void ORA(State6502 * state, byte operand) {
byte result = state->a | operand;
set_NV_flags(state, result);
state->a = result;
}
//bitwise and with accumulator
void AND(State6502 * state, byte operand) {
byte result = state->a & operand;
set_NV_flags(state, result);
state->a = result;
}
//load accumulator
void LDA(State6502 * state, byte operand) {
state->a = operand;
set_NV_flags(state, state->a);
}
void LDX(State6502 * state, byte operand) {
state->x = operand;
set_NV_flags(state, state->x);
}
void LDY(State6502 * state, byte operand) {
state->y = operand;
set_NV_flags(state, state->y);
}
void STX(State6502 * state, word address) {
state->memory[address] = state->x;
}
void STY(State6502 * state, word address) {
state->memory[address] = state->y;
}
void INC(State6502 * state, word address) {
state->memory[address] += 1;
set_NZ_flags(state, state->memory[address]);
}
void DEC(State6502 * state, word address) {
state->memory[address] -= 1;
set_NZ_flags(state, state->memory[address]);
}
word pop_word(State6502 * state) {
byte low = pop_byte(state);
byte high = pop_byte(state);
word result = (high << 8) | low;
return result;
}
word read_word(State6502 * state, word address) {
return state->memory[address] | state->memory[address + 1] << 8;
}
word get_address_zero_page(State6502 * state) {
return pop_byte(state);
}
byte get_byte_zero_page(State6502 * state) {
//8 bit addressing, only the first 256 bytes of the memory
return state->memory[get_address_zero_page(state)];
}
word get_address_zero_page_x(State6502 * state) {
//address is zero page, so wraparound byte
byte address = pop_byte(state) + state->x;
return address;
}
byte get_byte_zero_page_x(State6502 * state) {
return state->memory[get_address_zero_page_x(state)];
}
word get_address_zero_page_y(State6502 * state) {
//address is zero page, so wraparound byte
byte address = pop_byte(state) + state->y;
return address;
}
byte get_byte_zero_page_y(State6502 * state) {
return state->memory[get_address_zero_page_y(state)];
}
word get_address_absolute(State6502 * state) {
//absolute indexed, 16 bits
word address = pop_word(state);
return address;
}
byte get_byte_absolute(State6502 * state)
{
//absolute indexed, 16 bits
return state->memory[get_address_absolute(state)];
}
word get_address_absolute_x(State6502* state) {
//absolute added with the contents of x register
word address = pop_word(state) + state->x;
return address;
}
byte get_byte_absolute_x(State6502 * state) {
return state->memory[get_address_absolute_x(state)];
}
word get_address_absolute_y(State6502* state) {
//absolute added with the contents of x register
word address = pop_word(state) + state->y;
return address;
}
byte get_byte_absolute_y(State6502 * state) {
//absolute added with the contents of y register
return state->memory[get_address_absolute_y(state)];
}
byte get_byte_indirect_x(State6502 * state) {
//pre-indexed indirect with the X register
//zero-page address is added to x register
byte indirect_address = pop_byte(state) + state->x;
//pointing to address of a word holding the address of the operand
word address = read_word(state, indirect_address);
return state->memory[address];
}
byte get_byte_indirect_y(State6502 * state) {
//post-indexed indirect
//zero-page address as an argument
byte indirect_address = pop_byte(state);
//the address and the following byte is read as a word, adding Y register
word address = read_word(state, indirect_address) + state->y;
return state->memory[address];
}
int emulate_6502_op(State6502 * state) {
byte* opcode = &state->memory[state->pc++];
switch (*opcode) {
case ADC_IMM: unimplemented_instruction(state); break;
case ADC_ZP: unimplemented_instruction(state); break;
case ADC_ZPX: unimplemented_instruction(state); break;
case ADC_ABS: unimplemented_instruction(state); break;
case ADC_ABSX: unimplemented_instruction(state); break;
case ADC_ABSY: unimplemented_instruction(state); break;
case ADC_INDX: unimplemented_instruction(state); break;
case ADC_INDY: unimplemented_instruction(state); break;
case AND_IMM: AND(state, pop_byte(state)); break;
case AND_ZP: AND(state, get_byte_zero_page(state)); break;
case AND_ZPX: AND(state, get_byte_zero_page_x(state)); break;
case AND_ABS: AND(state, get_byte_absolute(state)); break;
case AND_ABSX: AND(state, get_byte_absolute_x(state)); break;
case AND_ABSY: AND(state, get_byte_absolute_y(state)); break;
case AND_INDX: AND(state, get_byte_indirect_x(state)); break;
case AND_INDY: AND(state, get_byte_indirect_y(state)); break;
case ASL_ACC: unimplemented_instruction(state); break;
case ASL_ZP: unimplemented_instruction(state); break;
case ASL_ZPX: unimplemented_instruction(state); break;
case ASL_ABS: unimplemented_instruction(state); break;
case ASL_ABSX: unimplemented_instruction(state); break;
case BCC_REL: unimplemented_instruction(state); break;
case BCS_REL: unimplemented_instruction(state); break;
case BEQ_REL: unimplemented_instruction(state); break;
case BMI_REL: unimplemented_instruction(state); break;
case BNE_REL: unimplemented_instruction(state); break;
case BPL_REL: unimplemented_instruction(state); break;
case BVC_REL: unimplemented_instruction(state); break;
case BVS_REL: unimplemented_instruction(state); break;
case BIT_ZP: unimplemented_instruction(state); break;
case BIT_ABS: unimplemented_instruction(state); break;
case BRK: state->running = 0;
state->flags.b = 1;
break; //BRK
case CLC: unimplemented_instruction(state); break;
case CLD: unimplemented_instruction(state); break;
case CLI: unimplemented_instruction(state); break;
case CLV: unimplemented_instruction(state); break;
case NOP: break; //NOP
case PHA: unimplemented_instruction(state); break;
case PLA: unimplemented_instruction(state); break;
case PHP: //push processor status
//push(state->flags);
unimplemented_instruction(state); break;
case PLP: //pull procesor status
//state->flags = pop();
unimplemented_instruction(state); break;
case RTI: unimplemented_instruction(state); break;
case RTS: unimplemented_instruction(state); break;
case SEC: unimplemented_instruction(state); break;
case SED: unimplemented_instruction(state); break;
case SEI: unimplemented_instruction(state); break;
case TAX: state->x = state->a; set_NZ_flags(state, state->x); break; //TODO test
case TXA: state->a = state->x; set_NZ_flags(state, state->a); break; //TODO test
case TAY: state->y = state->a; set_NZ_flags(state, state->y); break; //TODO test
case TYA: state->a = state->y; set_NZ_flags(state, state->a); break; //TODO test
case TSX: unimplemented_instruction(state); break;
case TXS: unimplemented_instruction(state); break;
case CMP_IMM: unimplemented_instruction(state); break;
case CMP_ZP: unimplemented_instruction(state); break;
case CMP_ZPX: unimplemented_instruction(state); break;
case CMP_ABS: unimplemented_instruction(state); break;
case CMP_ABSX: unimplemented_instruction(state); break;
case CMP_ABSY: unimplemented_instruction(state); break;
case CMP_INDX: unimplemented_instruction(state); break;
case CMP_INDY: unimplemented_instruction(state); break;
case CPX_IMM: unimplemented_instruction(state); break;
case CPX_ZP: unimplemented_instruction(state); break;
case CPX_ABS: unimplemented_instruction(state); break;
case CPY_IMM: unimplemented_instruction(state); break;
case CPY_ZP: unimplemented_instruction(state); break;
case CPY_ABS: unimplemented_instruction(state); break;
case DEC_ZP: DEC(state, get_address_zero_page(state)); break;
case DEC_ZPX: DEC(state, get_address_zero_page_x(state)); break;
case DEC_ABS: DEC(state, get_address_absolute(state)); break;
case DEC_ABSX: DEC(state, get_address_absolute_x(state)); break;
case DEX: state->x -= 1; set_NZ_flags(state, state->x); break;
case DEY: state->y -= 1; set_NZ_flags(state, state->y); break;
case INX: state->x += 1; set_NZ_flags(state, state->x); break;
case INY: state->y += 1; set_NZ_flags(state, state->y); break;
case EOR_IMM: unimplemented_instruction(state); break;
case EOR_ZP: unimplemented_instruction(state); break;
case EOR_ZPX: unimplemented_instruction(state); break;
case EOR_ABS: unimplemented_instruction(state); break;
case EOR_ABSX: unimplemented_instruction(state); break;
case EOR_ABSY: unimplemented_instruction(state); break;
case EOR_INDX: unimplemented_instruction(state); break;
case EOR_INDY: unimplemented_instruction(state); break;
case INC_ZP: INC(state, get_address_zero_page(state)); break;
case INC_ZPX: INC(state, get_address_zero_page_x(state)); break;
case INC_ABS: INC(state, get_address_absolute(state)); break;
case INC_ABSX: INC(state, get_address_absolute_x(state)); break;
case JMP_ABS: unimplemented_instruction(state); break;
case JMP_IND: unimplemented_instruction(state); break;
case JSR_ABS: unimplemented_instruction(state); break;
case LDA_IMM: LDA(state, pop_byte(state)); break;
case LDA_ZP: LDA(state, get_byte_zero_page(state)); break;
case LDA_ZPX: LDA(state, get_byte_zero_page_x(state)); break;
case LDA_ABS: LDA(state, get_byte_absolute(state)); break;
case LDA_ABSX: LDA(state, get_byte_absolute_x(state)); break;
case LDA_ABSY: LDA(state, get_byte_absolute_y(state)); break;
case LDA_INDX: LDA(state, get_byte_indirect_x(state)); break;
case LDA_INDY: LDA(state, get_byte_indirect_y(state)); break;
case LDX_IMM: LDX(state, pop_byte(state)); break;
case LDX_ZP: LDX(state, get_byte_zero_page(state)); break;
case LDX_ZPY: LDX(state, get_byte_zero_page_y(state)); break;
case LDX_ABS: LDX(state, get_byte_absolute(state)); break;
case LDX_ABSY: LDX(state, get_byte_absolute_y(state)); break;
case LDY_IMM: LDY(state, pop_byte(state)); break;
case LDY_ZP: LDY(state, get_byte_zero_page(state)); break;
case LDY_ZPX: LDY(state, get_byte_zero_page_x(state)); break;
case LDY_ABS: LDY(state, get_byte_absolute(state)); break;
case LDY_ABSX: LDY(state, get_byte_absolute_x(state)); break;
case LSR_ACC: unimplemented_instruction(state); break;
case LSR_ZP: unimplemented_instruction(state); break;
case LSR_ZPX: unimplemented_instruction(state); break;
case LSR_ABS: unimplemented_instruction(state); break;
case LSR_ABSX: unimplemented_instruction(state); break;
case ORA_IMM: ORA(state, pop_byte(state)); break;
case ORA_ZP: ORA(state, get_byte_zero_page(state)); break;
case ORA_ZPX: ORA(state, get_byte_zero_page_x(state)); break;
case ORA_ABS: ORA(state, get_byte_absolute(state)); break;
case ORA_ABSX: ORA(state, get_byte_absolute_x(state)); break;
case ORA_ABSY: ORA(state, get_byte_absolute_y(state)); break;
case ORA_INDX: ORA(state, get_byte_indirect_x(state)); break;
case ORA_INDY: ORA(state, get_byte_indirect_y(state)); break;
case ROL_ACC: unimplemented_instruction(state); break;
case ROL_ZP: unimplemented_instruction(state); break;
case ROL_ZPX: unimplemented_instruction(state); break;
case ROL_ABS: unimplemented_instruction(state); break;
case ROL_ABSX: unimplemented_instruction(state); break;
case ROR_ACC: unimplemented_instruction(state); break;
case ROR_ZP: unimplemented_instruction(state); break;
case ROR_ZPX: unimplemented_instruction(state); break;
case ROR_ABS: unimplemented_instruction(state); break;
case ROR_ABSX: unimplemented_instruction(state); break;
case SBC_IMM: unimplemented_instruction(state); break;
case SBC_ZP: unimplemented_instruction(state); break;
case SBC_ZPX: unimplemented_instruction(state); break;
case SBC_ABS: unimplemented_instruction(state); break;
case SBC_ABSX: unimplemented_instruction(state); break;
case SBC_ABSY: unimplemented_instruction(state); break;
case SBC_INDX: unimplemented_instruction(state); break;
case SBC_INDY: unimplemented_instruction(state); break;
case STA_ZP: unimplemented_instruction(state); break;
case STA_ZPX: unimplemented_instruction(state); break;
case STA_ABS: unimplemented_instruction(state); break;
case STA_ABSX: unimplemented_instruction(state); break;
case STA_ABSY: unimplemented_instruction(state); break;
case STA_INDX: unimplemented_instruction(state); break;
case STA_INDY: unimplemented_instruction(state); break;
case STX_ZP: STX(state, get_address_zero_page(state)); break;
case STX_ZPY: STX(state, get_address_zero_page_y(state)); break;
case STX_ABS: STX(state, get_address_absolute(state)); break;
case STY_ZP: STY(state, get_address_zero_page(state)); break;
case STY_ZPX: STY(state, get_address_zero_page_x(state)); break;
case STY_ABS: STY(state, get_address_absolute(state)); break;
default:
unimplemented_instruction(state); break;
}
return 0;
}