#pragma once #include #include #include #include #include #include #include #include namespace EightBit { class MOS6502 : public Processor { public: struct opcode_decoded_t { int aaa = 0; int bbb = 0; int cc = 0; opcode_decoded_t() {} opcode_decoded_t(uint8_t opcode) { aaa = (opcode & 0b11100000) >> 5; // 0 - 7 bbb = (opcode & 0b00011100) >> 2; // 0 - 7 cc = (opcode & 0b00000011); // 0 - 3 } }; enum StatusBits { NF = Bit7, // Negative VF = Bit6, // Overflow RF = Bit5, // reserved BF = Bit4, // Brk DF = Bit3, // D (use BCD for arithmetic) IF = Bit2, // I (IRQ disable) ZF = Bit1, // Zero CF = Bit0, // Carry }; MOS6502(Bus& bus); Signal ExecutingInstruction; Signal ExecutedInstruction; virtual int execute(uint8_t opcode) final; virtual int step() final; uint8_t& X() { return x; } uint8_t& Y() { return y; } uint8_t& A() { return a; } uint8_t& S() { return s; } uint8_t& P() { return p; } protected: virtual void reset() final; virtual void SBC(uint8_t data); void SBC_b(uint8_t data); void SBC_d(uint8_t data); virtual void ADC(uint8_t data); void ADC_b(uint8_t data); void ADC_d(uint8_t data); private: void interrupt(uint8_t vector); void adjustZero(uint8_t datum) { clearFlag(P(), ZF, datum); } void adjustNegative(uint8_t datum) { setFlag(P(), NF, datum & NF); } void adjustNZ(uint8_t datum) { adjustZero(datum); adjustNegative(datum); } void getWord(uint8_t page, uint8_t offset, register16_t& output); virtual void push(uint8_t value) final; virtual uint8_t pop() final; #pragma region 6502 addressing modes #pragma region Addresses void Address_Absolute() { fetchWord(); } void Address_ZeroPage() { MEMPTR().low = fetchByte(); MEMPTR().high = 0; } void Address_ZeroPageIndirect() { Address_ZeroPage(); getWord(0, MEMPTR().low, MEMPTR()); } void Address_Indirect() { Address_Absolute(); getWord(MEMPTR().high, MEMPTR().low, MEMPTR()); } void Address_ZeroPageX() { Address_ZeroPage(); MEMPTR().low += X(); } void Address_ZeroPageY() { Address_ZeroPage(); MEMPTR().low += Y(); } bool Address_AbsoluteX() { Address_Absolute(); const auto page = MEMPTR().high; MEMPTR().word += X(); return MEMPTR().high != page; } bool Address_AbsoluteY() { Address_Absolute(); const auto page = MEMPTR().high; MEMPTR().word += Y(); return MEMPTR().high != page; } void Address_IndexedIndirectX() { Address_ZeroPageX(); getWord(0, MEMPTR().low, MEMPTR()); } bool Address_IndirectIndexedY() { Address_ZeroPageIndirect(); const auto page = MEMPTR().high; MEMPTR().word += Y(); return MEMPTR().high != page; } #pragma endregion Addresses #pragma region Addressing modes, read uint8_t AM_A() { return A(); } uint8_t AM_Immediate() { return fetchByte(); } uint8_t AM_Absolute() { Address_Absolute(); return getByte(MEMPTR()); } uint8_t AM_ZeroPage() { Address_ZeroPage(); return getByte(MEMPTR()); } uint8_t AM_AbsoluteX() { if (Address_AbsoluteX()) addCycle(); BUS().ADDRESS() = MEMPTR(); return getByte(); } uint8_t AM_AbsoluteY() { if (Address_AbsoluteY()) addCycle(); BUS().ADDRESS() = MEMPTR(); return getByte(); } uint8_t AM_ZeroPageX() { Address_ZeroPageX(); return getByte(MEMPTR()); } uint8_t AM_ZeroPageY() { Address_ZeroPageY(); return getByte(MEMPTR()); } uint8_t AM_IndexedIndirectX() { Address_IndexedIndirectX(); return getByte(MEMPTR()); } uint8_t AM_IndirectIndexedY() { if (Address_IndirectIndexedY()) addCycle(); BUS().ADDRESS() = MEMPTR(); return getByte(); } #pragma endregion Addressing modes, read #pragma region Addressing modes, write void AM_A(uint8_t value) { A() = value; } void AM_Absolute(uint8_t value) { Address_Absolute(); setByte(MEMPTR(), value); } void AM_ZeroPage(uint8_t value) { Address_ZeroPage(); setByte(MEMPTR(), value); } void AM_AbsoluteX(uint8_t value) { Address_AbsoluteX(); setByte(MEMPTR(), value); } void AM_AbsoluteY(uint8_t value) { Address_AbsoluteY(); setByte(MEMPTR(), value); } void AM_ZeroPageX(uint8_t value) { Address_ZeroPageX(); setByte(MEMPTR(), value); } void AM_ZeroPageY(uint8_t value) { Address_ZeroPageY(); setByte(MEMPTR(), value); } void AM_IndexedIndirectX(uint8_t value) { Address_IndexedIndirectX(); setByte(MEMPTR(), value); } void AM_IndirectIndexedY(uint8_t value) { Address_IndirectIndexedY(); setByte(MEMPTR(), value); } #pragma endregion Addressing modes, write #pragma region 6502 addressing mode switching uint8_t AM_00(int bbb) { switch (bbb) { case 0b000: return AM_Immediate(); case 0b001: return AM_ZeroPage(); case 0b011: return AM_Absolute(); case 0b101: return AM_ZeroPageX(); case 0b111: return AM_AbsoluteX(); case 0b010: case 0b100: case 0b110: throw std::domain_error("Illegal addressing mode"); default: __assume(0); } } void AM_00(int bbb, uint8_t value) { switch (bbb) { case 0b000: assert(false); break; case 0b001: AM_ZeroPage(value); break; case 0b011: AM_Absolute(value); break; case 0b101: AM_ZeroPageX(value); break; case 0b111: AM_AbsoluteX(value); break; case 0b010: case 0b100: case 0b110: throw std::domain_error("Illegal addressing mode"); default: __assume(0); } } uint8_t AM_01(int bbb) { switch (bbb) { case 0b000: return AM_IndexedIndirectX(); case 0b001: return AM_ZeroPage(); case 0b010: return AM_Immediate(); case 0b011: return AM_Absolute(); case 0b100: return AM_IndirectIndexedY(); case 0b101: return AM_ZeroPageX(); case 0b110: return AM_AbsoluteY(); case 0b111: return AM_AbsoluteX(); default: __assume(0); } } void AM_01(int bbb, uint8_t value) { switch (bbb) { case 0b000: AM_IndexedIndirectX(value); break; case 0b001: AM_ZeroPage(value); break; case 0b010: assert(false); break; case 0b011: AM_Absolute(value); break; case 0b100: AM_IndirectIndexedY(value); break; case 0b101: AM_ZeroPageX(value); break; case 0b110: AM_AbsoluteY(value); break; case 0b111: AM_AbsoluteX(value); break; default: __assume(0); } } uint8_t AM_10(int bbb) { switch (bbb) { case 0b000: return AM_Immediate(); case 0b001: return AM_ZeroPage(); case 0b010: return AM_A(); case 0b011: return AM_Absolute(); case 0b101: return AM_ZeroPageX(); case 0b111: return AM_AbsoluteX(); case 0b100: case 0b110: throw std::domain_error("Illegal addressing mode"); default: __assume(0); } return 0xff; } void AM_10(int bbb, uint8_t value) { switch (bbb) { case 0b010: AM_A(value); break; case 0b001: case 0b011: case 0b101: case 0b111: setByte(MEMPTR(), value); break; case 0b000: case 0b100: case 0b110: throw std::domain_error("Illegal addressing mode"); default: __assume(0); } } uint8_t AM_10_x(int bbb) { switch (bbb) { case 0b000: return AM_Immediate(); case 0b001: return AM_ZeroPage(); case 0b010: return AM_A(); case 0b011: return AM_Absolute(); case 0b101: return AM_ZeroPageY(); case 0b111: return AM_AbsoluteY(); case 0b100: case 0b110: throw std::domain_error("Illegal addressing mode"); default: __assume(0); } } void AM_10_x(int bbb, uint8_t value) { switch (bbb) { case 0b000: assert(false); break; case 0b001: AM_ZeroPage(value); break; case 0b010: AM_A(value); break; case 0b011: AM_Absolute(value); break; case 0b101: AM_ZeroPageY(value); break; case 0b111: AM_AbsoluteY(value); break; case 0b100: case 0b110: throw std::domain_error("Illegal addressing mode"); default: __assume(0); } } #pragma endregion 6502 addressing mode switching #pragma endregion 6502 addressing modes void ASL(int bbb) { auto operand = AM_10(bbb); ASL(operand); AM_10(bbb, operand); } void ROL(int bbb) { auto operand = AM_10(bbb); ROL(operand); AM_10(bbb, operand); } void LSR(int bbb) { auto operand = AM_10(bbb); LSR(operand); AM_10(bbb, operand); } void ROR(int bbb) { auto operand = AM_10(bbb); ROR(operand); AM_10(bbb, operand); } void DEC(int bbb) { auto operand = AM_10(bbb); adjustNZ(--operand); AM_10(bbb, operand); } void INC(int bbb) { auto operand = AM_10(bbb); adjustNZ(++operand); AM_10(bbb, operand); } void ROR(uint8_t& output); void LSR(uint8_t& output); void BIT(uint8_t data); void ROL(uint8_t& output); void ASL(uint8_t& output); void CMP(uint8_t first, uint8_t second); void Branch(int8_t displacement); void Branch(bool flag); void PHP(); void PLP(); void JSR_abs(); void RTI(); void RTS(); void JMP_abs(); void JMP_ind(); void BRK(); const uint16_t PageOne = 0x100; // All interrupt vectors are on the 0xFF page const uint8_t IRQvector = 0xfe; const uint8_t RSTvector = 0xfc; const uint8_t NMIvector = 0xfa; uint8_t x; // index register X uint8_t y; // index register Y uint8_t a; // accumulator uint8_t s; // stack pointer uint8_t p; // processor status std::array m_timings; std::array m_decodedOpcodes; }; }