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mirror of https://github.com/jborza/emu6502.git synced 2024-11-21 23:31:19 +00:00
emu6502/cpu.c
2019-04-29 06:37:56 +02:00

516 lines
18 KiB
C

#include "state.h"
#include "cpu.h"
#include "opcodes.h"
#include "memory.h"
#include <stdio.h>
#include <memory.h>
#include <stdlib.h>
void* unimplemented_instruction(State6502* state) {
printf("Error: unimplemented instruction\n");
exit(1);
}
int is_negative(byte value) {
return ((1 << 7) & value) != 0;
}
void set_z_flag(State6502 * state, byte value) {
state->flags.z = value == 0;
}
void set_NV_flags(State6502 * state, byte value) {
state->flags.n = is_negative(value);
state->flags.v = ((1 << 6) & value) != 0;
}
void set_NZ_flags(State6502 * state, byte value) {
set_z_flag(state, value);
//N flag
state->flags.n = is_negative(value);
}
byte flags_as_byte(State6502* state) {
byte flags_value;
memcpy(&flags_value, &state->flags, sizeof(Flags));
return flags_value;
}
void clear_flags(State6502 * state) {
state->flags.b =
state->flags.c =
state->flags.d =
state->flags.i =
state->flags.n =
state->flags.v =
state->flags.z = 0;
state->flags.pad = 1; //unused is supposed to be 1
}
void clear_state(State6502 * state) {
state->a = 0;
state->x = 0;
state->y = 0;
state->pc = 0;
state->sp = 0xFF;
clear_flags(state);
state->running = 1;
}
void push_byte_to_stack(State6502 * state, byte value) {
//stack located between $0100 to $01FF
state->memory[STACK_HOME + state->sp--] = value;
}
void push_word_to_stack(State6502* state, word value) {
push_byte_to_stack(state, (value >> 8) & 0xFF);
push_byte_to_stack(state, value & 0xFF);
}
byte pop_byte_from_stack(State6502 * state) {
return state->memory[STACK_HOME + ++(state->sp)];
}
word pop_word_from_stack(State6502* state) {
byte low = pop_byte_from_stack(state);
byte high = pop_byte_from_stack(state);
return low + ((word)high << 8);
}
//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_NZ_flags(state, state->a);
}
void LDX(State6502 * state, byte operand) {
state->x = operand;
set_NZ_flags(state, state->x);
}
void LDY(State6502 * state, byte operand) {
state->y = operand;
set_NZ_flags(state, state->y);
}
void STA(State6502 * state, word address) {
state->memory[address] = state->a;
}
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]);
}
void EOR(State6502 * state, byte operand) {
state->a = state->a ^ operand;
set_NV_flags(state, state->a);
}
void JMP(State6502 * state, word address) {
state->pc = address;
}
void SBC(State6502 * state, byte operand) {
//subtract operand from A
word operand_word = operand;
//borrow the complement of carry flag - if the carry flag is 1, borrow 0 and vice versa
word result_word = state->a - operand_word - !state->flags.c;
byte result = result_word & 0xFF;
// overflow flag if the the result doesn't fit into the signed byte range -128 to 127
state->flags.v = ((state->a ^ operand) & 0x80) && ((state->a ^ result) & 0x80);
state->a = result;
state->flags.n = is_negative(state->a);
state->flags.z = state->a == 0;
state->flags.c = result_word <= 0xFF;
}
void ADC(State6502 * state, byte operand) {
//add operand to A
word result_word = operand + state->a + (state->flags.c ? 1 : 0);
byte result = result_word & 0xFF;
//set overflow flag if the result's sign would change - the result doesn't fit into a signed byte
//there is overflow if the inputs do not have different signs and the input sign is different from the output sign
//meaning two numbers that have the same sign are added, and the result has a different sign.
//overflow = <'a' and 'arg' have the same sign> & <the sign of 'a'and 'sum' differs> & <extract sign bit>
state->flags.v = !((state->a ^ operand) & 0x80) && ((state->a ^ result) & 0x80);
state->a = result;
state->flags.n = is_negative(state->a);
state->flags.z = state->a == 0;
state->flags.c = result_word > 0xFF;
}
void BIT(State6502 * state, byte operand) {
//BIT sets the Z flag as though the value in the address tested were ANDed with the accumulator.
//The N and V flags are set to match bits 7 and 6 respectively in the value stored at the tested address.
set_NV_flags(state, operand);
state->flags.z = (state->a & operand) == 0;
}
void cmp_internal(State6502 * state, byte register_value, byte operand) {
//set carry flag if A >= M
state->flags.c = register_value >= operand;
//set zero flag if A == M
state->flags.z = register_value == operand;
//set negative flag if A - M is negative
state->flags.n = is_negative(register_value - operand);
}
void CMP(State6502 * state, byte operand) {
cmp_internal(state, state->a, operand);
}
void CPX(State6502 * state, byte operand) {
cmp_internal(state, state->x, operand);
}
void CPY(State6502 * state, byte operand) {
cmp_internal(state, state->y, operand);
}
byte asl(State6502 * state, byte operand) {
byte result = operand << 1;
state->flags.c = operand > 0x80;
set_NZ_flags(state, result);
return result;
}
void ASL_A(State6502 * state) {
state->a = asl(state, state->a);
}
void ASL_MEM(State6502 * state, word address) {
byte operand = state->memory[address];
state->memory[address] = operand;
state->memory[address] = asl(state, operand);
}
byte lsr(State6502 * state, byte operand) {
byte result = operand >> 1;
state->flags.c = (operand & 0x01) != 0;
set_NZ_flags(state, result);
return result;
}
void LSR_A(State6502 * state) {
state->a = lsr(state, state->a);
}
void LSR_MEM(State6502 * state, word address) {
byte operand = state->memory[address];
state->memory[address] = lsr(state, operand);
}
byte rol(State6502 * state, byte operand) {
word result_word = (operand << 1) | state->flags.c;
state->flags.c = result_word > 0xFF;
byte result = result_word & 0xFF;
set_NZ_flags(state, result);
return result;
}
void ROL_A(State6502 * state) {
state->a = rol(state, state->a);
}
void ROL_MEM(State6502 * state, word address) {
byte operand = state->memory[address];
state->memory[address] = rol(state, operand);
}
byte ror(State6502 * state, byte operand) {
word result_word = (operand >> 1) | (state->flags.c << 7);
state->flags.c = (result_word & 0x01) != 0;
byte result = result_word & 0xFF;
set_NZ_flags(state, result);
return result;
}
void ROR_A(State6502 * state) {
state->a = rol(state, state->a);
}
void ROR_MEM(State6502 * state, word address) {
byte operand = state->memory[address];
state->memory[address] = ror(state, operand);
}
void JSR(State6502 * state, word address) {
//JSR pushes the address-1 of the next operation on to the stack before transferring program control to the following address.
word address_to_push = state->pc - 1;
push_byte_to_stack(state, (address_to_push >> 8 & 0xFF));
push_byte_to_stack(state, address_to_push & 0xFF);
state->pc = address;
}
void RTS_(State6502* state) {
word address = pop_word_from_stack(state);
state->pc = address + 1;
}
void RTI_(State6502* state) {
//interrupt pushes PC first, then status register
//RTI should pull status register and program counter from the stack
byte sr = pop_byte_from_stack(state);
word address = pop_word_from_stack(state);
state->pc = address;
}
void BEQ(State6502* state) {
word address = get_address_relative(state);
if (state->flags.z)
state->pc = address;
}
void BNE(State6502* state) {
word address = get_address_relative(state);
if (!state->flags.z)
state->pc = address;
}
void BCC(State6502* state) {
word address = get_address_relative(state);
if (!state->flags.c)
state->pc = address;
}
void BCS(State6502* state) {
word address = get_address_relative(state);
if (state->flags.c)
state->pc = address;
}
void BMI(State6502* state) {
word address = get_address_relative(state);
if (state->flags.n)
state->pc = address;
}
void BPL(State6502* state) {
word address = get_address_relative(state);
if (!state->flags.n)
state->pc = address;
}
void BVS(State6502* state) {
word address = get_address_relative(state);
if (state->flags.v)
state->pc = address;
}
void BVC(State6502* state) {
word address = get_address_relative(state);
if (!state->flags.v)
state->pc = address;
}
void PLA_(State6502* state) {
state->a = pop_byte_from_stack(state);
set_NZ_flags(state, state->a);
}
void PLP_(State6502* state) {
byte value = pop_byte_from_stack(state);
memset(&state->flags, value, sizeof(Flags));
}
void PHP_(State6502* state) {
byte flags_value;
memcpy(&flags_value, &state->flags, sizeof(Flags));
push_byte_to_stack(state, flags_value);
}
int emulate_6502_op(State6502 * state) {
byte* opcode = &state->memory[state->pc++];
switch (*opcode) {
case ADC_IMM: ADC(state, fetch_byte(state)); break;
case ADC_ZP: ADC(state, get_byte_zero_page(state)); break;
case ADC_ZPX: ADC(state, get_byte_zero_page_x(state)); break;
case ADC_ABS: ADC(state, get_byte_absolute(state)); break;
case ADC_ABSX: ADC(state, get_byte_absolute_x(state)); break;
case ADC_ABSY: ADC(state, get_byte_absolute_y(state)); break;
case ADC_INDX: ADC(state, get_byte_indirect_x(state)); break;
case ADC_INDY: ADC(state, get_byte_indirect_y(state)); break;
case AND_IMM: AND(state, fetch_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: ASL_A(state); break;
case ASL_ZP: ASL_MEM(state, get_address_zero_page(state)); break;
case ASL_ZPX: ASL_MEM(state, get_address_zero_page_x(state)); break;
case ASL_ABS: ASL_MEM(state, get_address_absolute(state)); break;
case ASL_ABSX: ASL_MEM(state, get_address_absolute_x(state)); break;
case BCC_REL: BCC(state); break;
case BCS_REL: BCS(state); break;
case BEQ_REL: BEQ(state); break;
case BMI_REL: BMI(state); break;
case BNE_REL: BNE(state); break;
case BPL_REL: BPL(state); break;
case BVC_REL: BVC(state); break;
case BVS_REL: BVS(state); break;
case BIT_ZP: BIT(state, get_byte_zero_page(state)); break;
case BIT_ABS: BIT(state, get_byte_absolute(state)); break;
case BRK: state->running = 0;
state->flags.b = 1;
break; //BRK
case CLC: state->flags.c = 0; break;
case CLD: state->flags.d = 0; break;
case CLI: state->flags.i = 0; break;
case CLV: state->flags.v = 0; break;
case NOP: break; //NOP
case PHA: push_byte_to_stack(state, state->a); break; //push accumulator to stack
case PLA: PLA_(state); break; //pull accumulator from stack
case PHP: PHP_(state); break; //push processor status
case PLP: PLP_(state); break; //pull procesor status
case RTI: RTI_(state); break;
case RTS: RTS_(state); break;
case SEC: state->flags.c = 1; break;
case SED: state->flags.d = 1; break;
case SEI: state->flags.i = 1; break;
case TAX: state->x = state->a; set_NZ_flags(state, state->x); break;
case TXA: state->a = state->x; set_NZ_flags(state, state->a); break;
case TAY: state->y = state->a; set_NZ_flags(state, state->y); break;
case TYA: state->a = state->y; set_NZ_flags(state, state->a); break;
case TSX: state->x = state->sp; set_NZ_flags(state, state->x); break;
case TXS: state->sp = state->x; set_NZ_flags(state, state->x); break;
case CMP_IMM: CMP(state, fetch_byte(state)); break; //TODO test
case CMP_ZP: CMP(state, get_byte_zero_page(state)); break; //TODO test
case CMP_ZPX: CMP(state, get_byte_zero_page_x(state)); break; //TODO test
case CMP_ABS: CMP(state, get_byte_absolute(state)); break;
case CMP_ABSX: CMP(state, get_byte_absolute_x(state)); break;//TODO test
case CMP_ABSY: CMP(state, get_byte_absolute_y(state)); break;//TODO test
case CMP_INDX: CMP(state, get_byte_indirect_x(state)); break;//TODO test
case CMP_INDY: CMP(state, get_byte_indirect_y(state)); break;//TODO test
case CPX_IMM: CPX(state, fetch_byte(state)); break;//TODO test
case CPX_ZP: CPX(state, get_byte_zero_page(state)); break;//TODO test
case CPX_ABS: CPX(state, get_byte_absolute(state)); break;//TODO test
case CPY_IMM: CPY(state, fetch_byte(state)); break;//TODO test
case CPY_ZP: CPY(state, get_byte_zero_page(state)); break;//TODO test
case CPY_ABS: CPY(state, get_byte_absolute(state)); break;//TODO test
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: EOR(state, fetch_byte(state)); break;
case EOR_ZP: EOR(state, get_byte_zero_page(state)); break;
case EOR_ZPX: EOR(state, get_byte_zero_page_x(state)); break;
case EOR_ABS: EOR(state, get_byte_absolute(state)); break;
case EOR_ABSX: EOR(state, get_byte_absolute_x(state)); break;
case EOR_ABSY: EOR(state, get_byte_absolute_y(state)); break;
case EOR_INDX: EOR(state, get_byte_indirect_x(state)); break;
case EOR_INDY: EOR(state, get_byte_indirect_y(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: JMP(state, get_address_absolute(state)); break;
case JMP_IND: JMP(state, get_address_indirect_jmp(state)); break;
case JSR_ABS: JSR(state, get_address_absolute(state)); break;
case LDA_IMM: LDA(state, fetch_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, fetch_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, fetch_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: LSR_A(state); break;
case LSR_ZP: LSR_MEM(state, get_address_zero_page(state)); break;
case LSR_ZPX: LSR_MEM(state, get_address_zero_page_x(state)); break;
case LSR_ABS: LSR_MEM(state, get_address_absolute(state)); break;
case LSR_ABSX: LSR_MEM(state, get_address_absolute_x(state)); break;
case ORA_IMM: ORA(state, fetch_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: ROL_A(state); break;
case ROL_ZP: ROL_MEM(state, get_address_zero_page(state)); break;
case ROL_ZPX: ROL_MEM(state, get_address_zero_page_x(state)); break;
case ROL_ABS: ROL_MEM(state, get_address_absolute(state)); break;
case ROL_ABSX: ROL_MEM(state, get_address_absolute_x(state)); break;
case ROR_ACC: ROR_A(state); break;
case ROR_ZP: ROR_MEM(state, get_address_zero_page(state)); break;
case ROR_ZPX: ROR_MEM(state, get_address_zero_page_x(state)); break;
case ROR_ABS: ROR_MEM(state, get_address_absolute(state)); break;
case ROR_ABSX: ROR_MEM(state, get_address_absolute_x(state)); break;
case SBC_IMM: SBC(state, fetch_byte(state)); break;
case SBC_ZP: SBC(state, get_byte_zero_page(state)); break;
case SBC_ZPX: SBC(state, get_byte_zero_page_x(state)); break;
case SBC_ABS: SBC(state, get_byte_absolute(state)); break;
case SBC_ABSX: SBC(state, get_byte_absolute_x(state)); break;
case SBC_ABSY: SBC(state, get_byte_absolute_y(state)); break;
case SBC_INDX: SBC(state, get_byte_indirect_x(state)); break;
case SBC_INDY: SBC(state, get_byte_indirect_y(state)); break;
case STA_ZP: STA(state, get_address_zero_page(state)); break;
case STA_ZPX: STA(state, get_address_zero_page_x(state)); break;
case STA_ABS: STA(state, get_address_absolute(state)); break;
case STA_ABSX: STA(state, get_address_absolute_x(state)); break;
case STA_ABSY: STA(state, get_address_absolute_y(state)); break;
case STA_INDX: STA(state, get_address_indirect_x(state)); break;
case STA_INDY: STA(state, get_address_indirect_y(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;
}