#include "stdafx.h" #include "LR35902.h" // based on http://www.z80.info/decoding.htm // Half carry flag help from https://github.com/oubiwann/z80 EightBit::LR35902::LR35902(Bus& memory) : IntelProcessor(memory), m_bus(memory), m_ime(false), m_prefixCB(false) { } void EightBit::LR35902::reset() { IntelProcessor::reset(); SP().word = 0xfffe; di(); } void EightBit::LR35902::initialise() { IntelProcessor::initialise(); AF().word = 0xffff; BC().word = 0xffff; DE().word = 0xffff; HL().word = 0xffff; m_prefixCB = false; } #pragma region Interrupt routines void EightBit::LR35902::di() { IME() = false; } void EightBit::LR35902::ei() { IME() = true; } int EightBit::LR35902::interrupt(uint8_t value) { cycles = 0; di(); restart(value); return 4; } #pragma endregion Interrupt routines #pragma region Flag manipulation helpers void EightBit::LR35902::postIncrement(uint8_t& f, uint8_t value) { adjustZero(f, value); clearFlag(f, NF); clearFlag(f, HC, lowNibble(value)); } void EightBit::LR35902::postDecrement(uint8_t& f, uint8_t value) { adjustZero(f, value); setFlag(f, NF); clearFlag(f, HC, lowNibble(value + 1)); } #pragma endregion Flag manipulation helpers #pragma region PC manipulation: call/ret/jp/jr bool EightBit::LR35902::jrConditionalFlag(uint8_t& f, int flag) { switch (flag) { case 0: // NZ return jrConditional(!(f & ZF)); case 1: // Z return jrConditional(f & ZF); case 2: // NC return jrConditional(!(f & CF)); case 3: // C return jrConditional(f & CF); } throw std::logic_error("Unhandled JR conditional"); } bool EightBit::LR35902::jumpConditionalFlag(uint8_t& f, int flag) { switch (flag) { case 0: // NZ return jumpConditional(!(f & ZF)); case 1: // Z return jumpConditional(f & ZF); case 2: // NC return jumpConditional(!(f & CF)); case 3: // C return jumpConditional(f & CF); } throw std::logic_error("Unhandled JP conditional"); } void EightBit::LR35902::reti() { ret(); ei(); } bool EightBit::LR35902::returnConditionalFlag(uint8_t& f, int flag) { switch (flag) { case 0: // NZ return returnConditional(!(f & ZF)); case 1: // Z return returnConditional(f & ZF); case 2: // NC return returnConditional(!(f & CF)); case 3: // C return returnConditional(f & CF); } throw std::logic_error("Unhandled RET conditional"); } bool EightBit::LR35902::callConditionalFlag(uint8_t& f, int flag) { switch (flag) { case 0: // NZ return callConditional(!(f & ZF)); case 1: // Z return callConditional(f & ZF); case 2: // NC return callConditional(!(f & CF)); case 3: // C return callConditional(f & CF); } throw std::logic_error("Unhandled CALL conditional"); } #pragma endregion PC manipulation: call/ret/jp/jr #pragma region 16-bit arithmetic void EightBit::LR35902::sbc(uint8_t& f, register16_t& operand, register16_t value) { auto before = operand; auto carry = (f & CF) >> 4; auto result = before.word - value.word - carry; operand.word = result; clearFlag(f, ZF, operand.word); adjustHalfCarrySub(f, before.high, value.high, operand.high); setFlag(f, NF); setFlag(f, CF, result & Bit16); } void EightBit::LR35902::adc(uint8_t& f, register16_t& operand, register16_t value) { auto before = operand; auto carry = (f & CF) >> 4; auto result = before.word + value.word + carry; operand.word = result; clearFlag(f, ZF, result); adjustHalfCarryAdd(f, before.high, value.high, operand.high); clearFlag(f, NF); setFlag(f, CF, result & Bit16); } void EightBit::LR35902::add(uint8_t& f, register16_t& operand, register16_t value) { auto before = operand; auto result = before.word + value.word; operand.word = result; clearFlag(f, NF); setFlag(f, CF, result & Bit16); adjustHalfCarryAdd(f, before.high, value.high, operand.high); } #pragma endregion 16-bit arithmetic #pragma region ALU void EightBit::LR35902::add(uint8_t& f, uint8_t& operand, uint8_t value, int carry) { register16_t result; result.word = operand + value + carry; adjustHalfCarryAdd(f, operand, value, result.low); operand = result.low; clearFlag(f, NF); setFlag(f, CF, result.word & Bit8); adjustZero(f, operand); } void EightBit::LR35902::adc(uint8_t& f, uint8_t& operand, uint8_t value) { add(operand, value, (f & CF) >> 4); } void EightBit::LR35902::subtract(uint8_t& f, uint8_t& operand, uint8_t value, int carry) { register16_t result; result.word = operand - value - carry; adjustHalfCarrySub(f, operand, value, result.low); operand = result.low; setFlag(f, NF); setFlag(f, CF, result.word & Bit8); adjustZero(f, operand); } void EightBit::LR35902::sbc(uint8_t& f, uint8_t& operand, uint8_t value) { subtract(operand, value, (f & CF) >> 4); } void EightBit::LR35902::andr(uint8_t& f, uint8_t& operand, uint8_t value) { operand &= value; setFlag(f, HC); clearFlag(f, CF | NF); adjustZero(f, operand); } void EightBit::LR35902::xorr(uint8_t& f, uint8_t& operand, uint8_t value) { operand ^= value; clearFlag(f, HC | CF | NF); adjustZero(f, operand); } void EightBit::LR35902::orr(uint8_t& f, uint8_t& operand, uint8_t value) { operand |= value; clearFlag(f, HC | CF | NF); adjustZero(f, operand); } void EightBit::LR35902::compare(uint8_t& f, uint8_t check, uint8_t value) { subtract(f, check, value); } #pragma endregion ALU #pragma region Shift and rotate uint8_t& EightBit::LR35902::rlc(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); setFlag(f, CF, operand & Bit7); operand = _rotl8(operand, 1); adjustZero(f, operand); return operand; } uint8_t& EightBit::LR35902::rrc(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); setFlag(f, CF, operand & Bit0); operand = _rotr8(operand, 1); adjustZero(f, operand); return operand; } uint8_t& EightBit::LR35902::rl(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); const auto carry = (f & CF) >> 4; setFlag(f, CF, operand & Bit7); operand = (operand << 1) | carry; adjustZero(f, operand); return operand; } uint8_t& EightBit::LR35902::rr(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); const auto carry = (f & CF) >> 4; setFlag(f, CF, operand & Bit0); operand = (operand >> 1) | (carry << 7); adjustZero(f, operand); return operand; } // uint8_t& EightBit::LR35902::sla(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); setFlag(f, CF, operand & Bit7); operand <<= 1; adjustZero(f, operand); return operand; } uint8_t& EightBit::LR35902::sra(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); setFlag(f, CF, operand & Bit0); operand = (operand >> 1) | operand & Bit7; adjustZero(f, operand); return operand; } uint8_t& EightBit::LR35902::srl(uint8_t& f, uint8_t& operand) { clearFlag(f, NF | HC); setFlag(f, CF, operand & Bit0); operand = (operand >> 1) & ~Bit7; adjustZero(f, operand); return operand; } #pragma endregion Shift and rotate #pragma region BIT/SET/RES uint8_t& EightBit::LR35902::bit(uint8_t& f, int n, uint8_t& operand) { auto carry = f & CF; uint8_t discarded = operand; andr(f, discarded, 1 << n); setFlag(f, CF, carry); return operand; } uint8_t& EightBit::LR35902::res(int n, uint8_t& operand) { return operand &= ~(1 << n); } uint8_t& EightBit::LR35902::set(int n, uint8_t& operand) { return operand |= (1 << n); } #pragma endregion BIT/SET/RES #pragma region Miscellaneous instructions void EightBit::LR35902::daa(uint8_t& a, uint8_t& f) { int updated = a; if (f & NF) { if (f & HC) updated = (updated - 6) & Mask8; if (f & CF) updated -= 0x60; } else { if ((f & HC) || lowNibble(updated) > 9) updated += 6; if ((f & CF) || updated > 0x9F) updated += 0x60; } clearFlag(f, HC | ZF); setFlag(f, CF, (f & CF) || (updated & Bit8)); a = updated & Mask8; adjustZero(f, a); } void EightBit::LR35902::cpl(uint8_t& a, uint8_t& f) { a = ~a; setFlag(f, HC | NF); } void EightBit::LR35902::scf(uint8_t& a, uint8_t& f) { setFlag(f, CF); clearFlag(f, HC | NF); } void EightBit::LR35902::ccf(uint8_t& a, uint8_t& f) { auto carry = f & CF; clearFlag(f, CF, carry); clearFlag(f, NF | HC); } uint8_t& EightBit::LR35902::swap(uint8_t& f, uint8_t& operand) { auto low = lowNibble(operand); auto high = highNibble(operand); operand = promoteNibble(low) | demoteNibble(high); adjustZero(f, operand); clearFlag(f, NF | HC | CF); return operand; } #pragma endregion Miscellaneous instructions int EightBit::LR35902::step() { ExecutingInstruction.fire(*this); m_prefixCB = false; cycles = 0; return fetchExecute(); } int EightBit::LR35902::execute(uint8_t opcode) { auto x = (opcode & 0b11000000) >> 6; auto y = (opcode & 0b111000) >> 3; auto z = (opcode & 0b111); auto p = (y & 0b110) >> 1; auto q = (y & 1); if (m_prefixCB) executeCB(x, y, z, p, q); else executeOther(x, y, z, p, q); if (cycles == 0) throw std::logic_error("Unhandled opcode"); return cycles * 4; } void EightBit::LR35902::executeCB(int x, int y, int z, int p, int q) { auto& a = A(); auto& f = F(); switch (x) { case 0: // rot[y] r[z] switch (y) { case 0: adjustZero(f, rlc(f, R(z, a))); break; case 1: adjustZero(f, rrc(f, R(z, a))); break; case 2: adjustZero(f, rl(f, R(z, a))); break; case 3: adjustZero(f, rr(f, R(z, a))); break; case 4: adjustZero(f, sla(f, R(z, a))); break; case 5: adjustZero(f, sra(f, R(z, a))); break; case 6: adjustZero(f, swap(f, R(z, a))); break; case 7: adjustZero(f, srl(f, R(z, a))); break; } cycles += 2; if (z == 6) { m_bus.fireWriteBusEvent(); cycles += 2; } break; case 1: // BIT y, r[z] bit(f, y, R(z, a)); cycles += 2; if (z == 6) { m_bus.fireReadBusEvent(); cycles += 2; } break; case 2: // RES y, r[z] res(y, R(z, a)); cycles += 2; if (z == 6) { m_bus.fireWriteBusEvent(); cycles += 2; } break; case 3: // SET y, r[z] set(y, R(z, a)); cycles += 2; if (z == 6) { m_bus.fireWriteBusEvent(); cycles += 2; } break; } } void EightBit::LR35902::executeOther(int x, int y, int z, int p, int q) { auto& a = A(); auto& f = F(); switch (x) { case 0: switch (z) { case 0: // Relative jumps and assorted ops switch (y) { case 0: // NOP cycles++; break; case 1: // GB: LD (nn),SP fetchWord(); setWordViaMemptr(SP()); cycles += 5; break; case 2: // GB: STOP stop(); cycles++; break; case 3: // JR d jr(fetchByte()); cycles += 4; break; case 4: // JR cc,d case 5: case 6: case 7: if (jrConditionalFlag(f, y - 4)) cycles++; cycles += 2; break; } break; case 1: // 16-bit load immediate/add switch (q) { case 0: // LD rp,nn fetchWord(RP(p)); cycles += 3; break; case 1: // ADD HL,rp add(f, HL(), RP(p)); cycles += 2; break; } break; case 2: // Indirect loading switch (q) { case 0: switch (p) { case 0: // LD (BC),A m_memory.write(BC().word, a); cycles += 2; break; case 1: // LD (DE),A m_memory.write(DE().word, a); cycles += 2; break; case 2: // GB: LDI (HL),A m_memory.write(HL().word++, a); cycles += 2; break; case 3: // GB: LDD (HL),A m_memory.write(HL().word--, a); cycles += 2; break; } break; case 1: switch (p) { case 0: // LD A,(BC) a = m_memory.read(BC().word); cycles += 2; break; case 1: // LD A,(DE) a = m_memory.read(DE().word); cycles += 2; break; case 2: // GB: LDI A,(HL) a = m_memory.read(HL().word++); cycles += 2; break; case 3: // GB: LDD A,(HL) a = m_memory.read(HL().word--); cycles += 2; break; } break; } break; case 3: // 16-bit INC/DEC switch (q) { case 0: // INC rp ++RP(p).word; break; case 1: // DEC rp --RP(p).word; break; } cycles += 2; break; case 4: // 8-bit INC postIncrement(f, ++R(y, a)); // INC r cycles++; if (y == 6) { m_bus.fireWriteBusEvent(); cycles += 2; } break; case 5: // 8-bit DEC postDecrement(f, --R(y, a)); // DEC r cycles++; if (y == 6) { m_bus.fireWriteBusEvent(); cycles += 2; } break; case 6: // 8-bit load immediate R(y, a) = fetchByte(); if (y == 6) m_bus.fireWriteBusEvent(); cycles += 2; break; case 7: // Assorted operations on accumulator/flags switch (y) { case 0: adjustZero(f, rlc(f, a)); break; case 1: adjustZero(f, rrc(f, a)); break; case 2: adjustZero(f, rl(f, a)); break; case 3: adjustZero(f, rr(f, a)); break; case 4: daa(a, f); break; case 5: cpl(a, f); break; case 6: scf(a, f); break; case 7: ccf(a, f); break; } cycles++; break; } break; case 1: // 8-bit loading if (z == 6 && y == 6) { // Exception (replaces LD (HL), (HL)) halt(); } else { R(y, a) = R(z, a); if ((y == 6) || (z == 6)) { // M operations if (y == 6) m_bus.fireWriteBusEvent(); else m_bus.fireReadBusEvent(); cycles++; } } cycles++; break; case 2: // Operate on accumulator and register/memory location switch (y) { case 0: // ADD A,r add(f, a, R(z, a)); break; case 1: // ADC A,r adc(f, a, R(z, a)); break; case 2: // SUB r subtract(f, a, R(z, a)); break; case 3: // SBC A,r sbc(f, a, R(z, a)); break; case 4: // AND r andr(f, a, R(z, a)); break; case 5: // XOR r xorr(f, a, R(z, a)); break; case 6: // OR r orr(f, a, R(z, a)); break; case 7: // CP r compare(f, a, R(z, a)); break; } cycles++; if (z == 6) { m_bus.fireReadBusEvent(); cycles++; } break; case 3: switch (z) { case 0: // Conditional return switch (y) { case 0: case 1: case 2: case 3: if (returnConditionalFlag(f, y)) cycles += 3; cycles += 2; break; case 4: // GB: LD (FF00 + n),A m_bus.writeRegister(fetchByte(), a); cycles += 3; break; case 5: { // GB: ADD SP,dd auto before = SP(); auto value = fetchByte(); auto result = SP().word + (int8_t)value; SP().word = result; clearFlag(f, ZF | NF); setFlag(f, CF, result & Bit16); adjustHalfCarryAdd(f, before.high, value, SP().high); } cycles += 4; break; case 6: // GB: LD A,(FF00 + n) a = m_bus.readRegister(fetchByte()); cycles += 3; break; case 7: { // GB: LD HL,SP + dd auto before = HL(); auto value = fetchByte(); auto result = SP().word + (int8_t)value; HL().word = result; clearFlag(f, ZF | NF); setFlag(f, CF, result & Bit16); adjustHalfCarryAdd(f, before.high, value, HL().high); } cycles += 3; break; } break; case 1: // POP & various ops switch (q) { case 0: // POP rp2[p] popWord(RP2(p)); cycles += 3; break; case 1: switch (p) { case 0: // RET ret(); cycles += 4; break; case 1: // GB: RETI reti(); cycles += 4; break; case 2: // JP HL PC() = HL(); cycles += 1; break; case 3: // LD SP,HL SP() = HL(); cycles += 2; break; } } break; case 2: // Conditional jump switch (y) { case 0: case 1: case 2: case 3: jumpConditionalFlag(f, y); cycles += 3; break; case 4: // GB: LD (FF00 + C),A m_bus.writeRegister(C(), a); cycles += 2; break; case 5: // GB: LD (nn),A fetchWord(); m_bus.write(MEMPTR().word, a); cycles += 4; break; case 6: // GB: LD A,(FF00 + C) a = m_bus.readRegister(C()); cycles += 2; break; case 7: // GB: LD A,(nn) fetchWord(); a = m_bus.read(MEMPTR().word); cycles += 4; break; } break; case 3: // Assorted operations switch (y) { case 0: // JP nn fetchWord(); jump(); cycles += 4; break; case 1: // CB prefix m_prefixCB = true; fetchExecute(); break; case 6: // DI di(); cycles++; break; case 7: // EI ei(); cycles++; break; } break; case 4: // Conditional call: CALL cc[y], nn if (callConditionalFlag(f, y)) cycles += 3; cycles += 3; break; case 5: // PUSH & various ops switch (q) { case 0: // PUSH rp2[p] pushWord(RP2(p)); cycles += 4; break; case 1: switch (p) { case 0: // CALL nn fetchWord(); call(); cycles += 6; break; } } break; case 6: // Operate on accumulator and immediate operand: alu[y] n switch (y) { case 0: // ADD A,n add(f, a, fetchByte()); break; case 1: // ADC A,n adc(f, a, fetchByte()); break; case 2: // SUB n subtract(f, a, fetchByte()); break; case 3: // SBC A,n sbc(f, a, fetchByte()); break; case 4: // AND n andr(f, a, fetchByte()); break; case 5: // XOR n xorr(f, a, fetchByte()); break; case 6: // OR n orr(f, a, fetchByte()); break; case 7: // CP n compare(f, a, fetchByte()); break; } cycles += 2; break; case 7: // Restart: RST y * 8 restart(y << 3); cycles += 4; break; } break; } }