#pragma once #include #include "IntelProcessor.h" #include "Bus.h" #include "Signal.h" namespace EightBit { class LR35902 : public IntelProcessor { public: enum StatusBits { ZF = Bit7, NF = Bit6, HC = Bit5, CF = Bit4, }; LR35902(Bus& memory); Signal ExecutingInstruction; void stop() { m_stopped = true; } void start() { m_stopped = false; } bool stopped() const { return m_stopped; } bool& IME() { return m_ime; } void di(); void ei(); int interrupt(uint8_t value); virtual int execute(uint8_t opcode); int step(); virtual register16_t& AF() override { af.low &= 0xf0; return af; } virtual register16_t& BC() override { return bc; } virtual register16_t& DE() override { return de; } virtual register16_t& HL() override { return hl; } virtual void reset(); virtual void initialise(); private: Bus& m_bus; register16_t af; register16_t bc; register16_t de; register16_t hl; bool m_ime; bool m_prefixCB; bool m_stopped; uint8_t R(int r, uint8_t& a) { switch (r) { case 0: return B(); case 1: return C(); case 2: return D(); case 3: return E(); case 4: return H(); case 5: return L(); case 6: return m_memory.read(HL()); case 7: return a; } throw std::logic_error("Unhandled registry mechanism"); } void R(int r, uint8_t& a, uint8_t value) { switch (r) { case 0: B() = value; break; case 1: C() = value; break; case 2: D() = value; break; case 3: E() = value; break; case 4: H() = value; break; case 5: L() = value; break; case 6: m_memory.write(HL(), value); break; case 7: a = value; break; } } register16_t& RP(int rp) { __assume(rp < 4); __assume(rp >= 0); switch (rp) { case 0b00: return BC(); case 0b01: return DE(); case 0b10: return HL(); case 0b11: return SP(); default: __assume(0); } } register16_t& RP2(int rp) { __assume(rp < 4); __assume(rp >= 0); switch (rp) { case 0b00: return BC(); case 0b01: return DE(); case 0b10: return HL(); case 0b11: return AF(); default: __assume(0); } } static void adjustHalfCarryAdd(uint8_t& f, uint8_t before, uint8_t value, int calculation) { setFlag(f, HC, calculateHalfCarryAdd(before, value, calculation)); } static void adjustHalfCarrySub(uint8_t& f, uint8_t before, uint8_t value, int calculation) { setFlag(f, HC, calculateHalfCarrySub(before, value, calculation)); } static void subtract(uint8_t& f, uint8_t& operand, uint8_t value, int carry = 0); void executeCB(int x, int y, int z, int p, int q); void executeOther(int x, int y, int z, int p, int q); static void increment(uint8_t& f, uint8_t& operand); static void decrement(uint8_t& f, uint8_t& operand); void reti(); bool jrConditionalFlag(uint8_t& f, int flag); bool returnConditionalFlag(uint8_t& f, int flag); bool jumpConditionalFlag(uint8_t& f, int flag); bool callConditionalFlag(uint8_t& f, int flag); void add(uint8_t& f, register16_t& operand, register16_t value); static void add(uint8_t& f, uint8_t& operand, uint8_t value, int carry = 0); static void adc(uint8_t& f, uint8_t& operand, uint8_t value); static void sbc(uint8_t& f, uint8_t& operand, uint8_t value); static void andr(uint8_t& f, uint8_t& operand, uint8_t value); static void xorr(uint8_t& f, uint8_t& operand, uint8_t value); static void orr(uint8_t& f, uint8_t& operand, uint8_t value); static void compare(uint8_t& f, uint8_t check, uint8_t value); static uint8_t rlc(uint8_t& f, uint8_t operand); static uint8_t rrc(uint8_t& f, uint8_t operand); static uint8_t rl(uint8_t& f, uint8_t operand); static uint8_t rr(uint8_t& f, uint8_t operand); static uint8_t sla(uint8_t& f, uint8_t operand); static uint8_t sra(uint8_t& f, uint8_t operand); static uint8_t srl(uint8_t& f, uint8_t operand); static uint8_t bit(uint8_t& f, int n, uint8_t operand); static uint8_t res(int n, uint8_t operand); static uint8_t set(int n, uint8_t operand); static void daa(uint8_t& a, uint8_t& f); static void scf(uint8_t& a, uint8_t& f); static void ccf(uint8_t& a, uint8_t& f); static void cpl(uint8_t& a, uint8_t& f); static uint8_t swap(uint8_t& f, uint8_t operand); }; }