/* * CPU1541.h - 6502 (1541) emulation (line based) * * Frodo (C) 1994-1997,2002 Christian Bauer */ #ifndef _CPU_1541_H #define _CPU_1541_H #include "CIA.h" #include "C64.h" // Set this to 1 if the 6502 PC should be represented by a real pointer #ifndef FRODO_SC #ifndef PC_IS_POINTER #define PC_IS_POINTER 1 #endif #endif // Set this to 1 for more precise CPU cycle calculation #ifndef PRECISE_CPU_CYCLES #define PRECISE_CPU_CYCLES 0 #endif // Interrupt types enum { INT_VIA1IRQ, INT_VIA2IRQ, INT_IECIRQ // INT_RESET (private) }; class C64; class Job1541; class C64Display; struct MOS6502State; // 6502 emulation (1541) class MOS6502_1541 { public: MOS6502_1541(C64 *c64, Job1541 *job, C64Display *disp, uint8 *Ram, uint8 *Rom); #ifdef FRODO_SC void EmulateCycle(void); // Emulate one clock cycle #else int EmulateLine(int cycles_left); // Emulate until cycles_left underflows #endif void Reset(void); void AsyncReset(void); // Reset the CPU asynchronously void GetState(MOS6502State *s); void SetState(MOS6502State *s); uint8 ExtReadByte(uint16 adr); void ExtWriteByte(uint16 adr, uint8 byte); void CountVIATimers(int cycles); void NewATNState(void); void IECInterrupt(void); void TriggerJobIRQ(void); bool InterruptEnabled(void); MOS6526_2 *TheCIA2; // Pointer to C64 CIA 2 uint8 IECLines; // State of IEC lines (bit 7 - DATA, bit 6 - CLK) bool Idle; // true: 1541 is idle private: uint8 read_byte(uint16 adr); uint8 read_byte_io(uint16 adr); uint16 read_word(uint16 adr); void write_byte(uint16 adr, uint8 byte); void write_byte_io(uint16 adr, uint8 byte); uint8 read_zp(uint16 adr); uint16 read_zp_word(uint16 adr); void write_zp(uint16 adr, uint8 byte); void jump(uint16 adr); void illegal_op(uint8 op, uint16 at); void illegal_jump(uint16 at, uint16 to); void do_adc(uint8 byte); void do_sbc(uint8 byte); uint8 *ram; // Pointer to main RAM uint8 *rom; // Pointer to ROM C64 *the_c64; // Pointer to C64 object C64Display *the_display; // Pointer to C64 display object Job1541 *the_job; // Pointer to 1541 job object union { // Pending interrupts uint8 intr[4]; // Index: See definitions above unsigned long intr_any; } interrupt; uint8 n_flag, z_flag; bool v_flag, d_flag, i_flag, c_flag; uint8 a, x, y, sp; #if PC_IS_POINTER uint8 *pc, *pc_base; #else uint16 pc; #endif #ifdef FRODO_SC uint32 first_irq_cycle; uint8 state, op; // Current state and opcode uint16 ar, ar2; // Address registers uint8 rdbuf; // Data buffer for RMW instructions uint8 ddr, pr; // Processor port #else int borrowed_cycles; // Borrowed cycles from next line #endif uint8 via1_pra; // PRA of VIA 1 uint8 via1_ddra; // DDRA of VIA 1 uint8 via1_prb; // PRB of VIA 1 uint8 via1_ddrb; // DDRB of VIA 1 uint16 via1_t1c; // T1 Counter of VIA 1 uint16 via1_t1l; // T1 Latch of VIA 1 uint16 via1_t2c; // T2 Counter of VIA 1 uint16 via1_t2l; // T2 Latch of VIA 1 uint8 via1_sr; // SR of VIA 1 uint8 via1_acr; // ACR of VIA 1 uint8 via1_pcr; // PCR of VIA 1 uint8 via1_ifr; // IFR of VIA 1 uint8 via1_ier; // IER of VIA 1 uint8 via2_pra; // PRA of VIA 2 uint8 via2_ddra; // DDRA of VIA 2 uint8 via2_prb; // PRB of VIA 2 uint8 via2_ddrb; // DDRB of VIA 2 uint16 via2_t1c; // T1 Counter of VIA 2 uint16 via2_t1l; // T1 Latch of VIA 2 uint16 via2_t2c; // T2 Counter of VIA 2 uint16 via2_t2l; // T2 Latch of VIA 2 uint8 via2_sr; // SR of VIA 2 uint8 via2_acr; // ACR of VIA 2 uint8 via2_pcr; // PCR of VIA 2 uint8 via2_ifr; // IFR of VIA 2 uint8 via2_ier; // IER of VIA 2 }; // 6502 state struct MOS6502State { uint8 a, x, y; uint8 p; // Processor flags uint16 pc, sp; uint8 intr[4]; // Interrupt state bool instruction_complete; bool idle; uint8 via1_pra; // VIA 1 uint8 via1_ddra; uint8 via1_prb; uint8 via1_ddrb; uint16 via1_t1c; uint16 via1_t1l; uint16 via1_t2c; uint16 via1_t2l; uint8 via1_sr; uint8 via1_acr; uint8 via1_pcr; uint8 via1_ifr; uint8 via1_ier; uint8 via2_pra; // VIA 2 uint8 via2_ddra; uint8 via2_prb; uint8 via2_ddrb; uint16 via2_t1c; uint16 via2_t1l; uint16 via2_t2c; uint16 via2_t2l; uint8 via2_sr; uint8 via2_acr; uint8 via2_pcr; uint8 via2_ifr; uint8 via2_ier; }; /* * Trigger job loop IRQ */ #ifdef FRODO_SC inline void MOS6502_1541::TriggerJobIRQ(void) { if (!(interrupt.intr[INT_VIA2IRQ])) first_irq_cycle = the_c64->CycleCounter; interrupt.intr[INT_VIA2IRQ] = true; Idle = false; } #else inline void MOS6502_1541::TriggerJobIRQ(void) { interrupt.intr[INT_VIA2IRQ] = true; Idle = false; } #endif /* * Count VIA timers */ inline void MOS6502_1541::CountVIATimers(int cycles) { unsigned long tmp; via1_t1c = tmp = via1_t1c - cycles; if (tmp > 0xffff) { if (via1_acr & 0x40) // Reload from latch in free-run mode via1_t1c = via1_t1l; via1_ifr |= 0x40; } if (!(via1_acr & 0x20)) { // Only count in one-shot mode via1_t2c = tmp = via1_t2c - cycles; if (tmp > 0xffff) via1_ifr |= 0x20; } via2_t1c = tmp = via2_t1c - cycles; if (tmp > 0xffff) { if (via2_acr & 0x40) // Reload from latch in free-run mode via2_t1c = via2_t1l; via2_ifr |= 0x40; if (via2_ier & 0x40) TriggerJobIRQ(); } if (!(via2_acr & 0x20)) { // Only count in one-shot mode via2_t2c = tmp = via2_t2c - cycles; if (tmp > 0xffff) via2_ifr |= 0x20; } } /* * ATN line probably changed state, recalc IECLines */ inline void MOS6502_1541::NewATNState(void) { uint8 byte = ~via1_prb & via1_ddrb; IECLines = (byte << 6) & ((~byte ^ TheCIA2->IECLines) << 3) & 0x80 // DATA (incl. ATN acknowledge) | (byte << 3) & 0x40; // CLK } /* * Interrupt by negative edge of ATN on IEC bus */ inline void MOS6502_1541::IECInterrupt(void) { ram[0x7c] = 1; // Wake up 1541 Idle = false; } /* * Test if interrupts are enabled (for job loop) */ inline bool MOS6502_1541::InterruptEnabled(void) { return !i_flag; } #endif