/*****************************************************************************\ Snes9x - Portable Super Nintendo Entertainment System (TM) emulator. This file is licensed under the Snes9x License. For further information, consult the LICENSE file in the root directory. \*****************************************************************************/ #include "snes9x.h" #include "memmap.h" #define CPU SA1 #define ICPU SA1 #define Registers SA1Registers #define OpenBus SA1OpenBus #define S9xGetByte S9xSA1GetByte #define S9xGetWord S9xSA1GetWord #define S9xSetByte S9xSA1SetByte #define S9xSetWord S9xSA1SetWord #define S9xSetPCBase S9xSA1SetPCBase #define S9xOpcodesM1X1 S9xSA1OpcodesM1X1 #define S9xOpcodesM1X0 S9xSA1OpcodesM1X0 #define S9xOpcodesM0X1 S9xSA1OpcodesM0X1 #define S9xOpcodesM0X0 S9xSA1OpcodesM0X0 #define S9xOpcodesE1 S9xSA1OpcodesE1 #define S9xOpcodesSlow S9xSA1OpcodesSlow #define S9xOpcode_IRQ S9xSA1Opcode_IRQ #define S9xOpcode_NMI S9xSA1Opcode_NMI #define S9xUnpackStatus S9xSA1UnpackStatus #define S9xPackStatus S9xSA1PackStatus #define S9xFixCycles S9xSA1FixCycles #define Immediate8 SA1Immediate8 #define Immediate16 SA1Immediate16 #define Relative SA1Relative #define RelativeLong SA1RelativeLong #define Absolute SA1Absolute #define AbsoluteLong SA1AbsoluteLong #define AbsoluteIndirect SA1AbsoluteIndirect #define AbsoluteIndirectLong SA1AbsoluteIndirectLong #define AbsoluteIndexedIndirect SA1AbsoluteIndexedIndirect #define Direct SA1Direct #define DirectIndirectIndexed SA1DirectIndirectIndexed #define DirectIndirectIndexedLong SA1DirectIndirectIndexedLong #define DirectIndexedIndirect SA1DirectIndexedIndirect #define DirectIndexedX SA1DirectIndexedX #define DirectIndexedY SA1DirectIndexedY #define AbsoluteIndexedX SA1AbsoluteIndexedX #define AbsoluteIndexedY SA1AbsoluteIndexedY #define AbsoluteLongIndexedX SA1AbsoluteLongIndexedX #define DirectIndirect SA1DirectIndirect #define DirectIndirectLong SA1DirectIndirectLong #define StackRelative SA1StackRelative #define StackRelativeIndirectIndexed SA1StackRelativeIndirectIndexed #define SA1_OPCODES #include "cpuops.cpp" static void S9xSA1UpdateTimer (void); void S9xSA1MainLoop (void) { if (Memory.FillRAM[0x2200] & 0x60) { SA1.Cycles += 6; // FIXME S9xSA1UpdateTimer(); return; } // SA-1 NMI if ((Memory.FillRAM[0x2200] & 0x10) && !(Memory.FillRAM[0x220b] & 0x10)) { Memory.FillRAM[0x2301] |= 0x10; Memory.FillRAM[0x220b] |= 0x10; if (SA1.WaitingForInterrupt) { SA1.WaitingForInterrupt = FALSE; SA1Registers.PCw++; } S9xSA1Opcode_NMI(); } else if (!SA1CheckFlag(IRQ)) { // SA-1 Timer IRQ if ((Memory.FillRAM[0x220a] & 0x40) && !(Memory.FillRAM[0x220b] & 0x40)) { Memory.FillRAM[0x2301] |= 0x40; if (SA1.WaitingForInterrupt) { SA1.WaitingForInterrupt = FALSE; SA1Registers.PCw++; } S9xSA1Opcode_IRQ(); } else // SA-1 DMA IRQ if ((Memory.FillRAM[0x220a] & 0x20) && !(Memory.FillRAM[0x220b] & 0x20)) { Memory.FillRAM[0x2301] |= 0x20; if (SA1.WaitingForInterrupt) { SA1.WaitingForInterrupt = FALSE; SA1Registers.PCw++; } S9xSA1Opcode_IRQ(); } else // SA-1 IRQ if ((Memory.FillRAM[0x2200] & 0x80) && !(Memory.FillRAM[0x220b] & 0x80)) { Memory.FillRAM[0x2301] |= 0x80; if (SA1.WaitingForInterrupt) { SA1.WaitingForInterrupt = FALSE; SA1Registers.PCw++; } S9xSA1Opcode_IRQ(); } } #undef CPU int cycles = CPU.Cycles * 3; #define CPU SA1 for (; SA1.Cycles < cycles && !(Memory.FillRAM[0x2200] & 0x60);) { #ifdef DEBUGGER if (SA1.Flags & TRACE_FLAG) S9xSA1Trace(); #endif uint8 Op; struct SOpcodes *Opcodes; if (SA1.PCBase) { SA1OpenBus = Op = SA1.PCBase[Registers.PCw]; Opcodes = SA1.S9xOpcodes; SA1.Cycles += SA1.MemSpeed; } else { Op = S9xSA1GetByte(Registers.PBPC); Opcodes = S9xOpcodesSlow; } if ((SA1Registers.PCw & MEMMAP_MASK) + SA1.S9xOpLengths[Op] >= MEMMAP_BLOCK_SIZE) { uint32 oldPC = SA1Registers.PBPC; S9xSA1SetPCBase(SA1Registers.PBPC); SA1Registers.PBPC = oldPC; Opcodes = S9xSA1OpcodesSlow; } Registers.PCw++; (*Opcodes[Op].S9xOpcode)(); } S9xSA1UpdateTimer(); } static void S9xSA1UpdateTimer (void) // FIXME { SA1.PrevHCounter = SA1.HCounter; if (Memory.FillRAM[0x2210] & 0x80) { SA1.HCounter += (SA1.Cycles - SA1.PrevCycles); if (SA1.HCounter >= 0x800) { SA1.HCounter -= 0x800; SA1.PrevHCounter -= 0x800; if (++SA1.VCounter >= 0x200) SA1.VCounter = 0; } } else { SA1.HCounter += (SA1.Cycles - SA1.PrevCycles); if (SA1.HCounter >= Timings.H_Max_Master) { SA1.HCounter -= Timings.H_Max_Master; SA1.PrevHCounter -= Timings.H_Max_Master; if (++SA1.VCounter >= Timings.V_Max_Master) SA1.VCounter = 0; } } SA1.PrevCycles = SA1.Cycles; bool8 thisIRQ = Memory.FillRAM[0x2210] & 0x03; if (Memory.FillRAM[0x2210] & 0x01) { if (SA1.PrevHCounter >= SA1.HTimerIRQPos * ONE_DOT_CYCLE || SA1.HCounter < SA1.HTimerIRQPos * ONE_DOT_CYCLE) thisIRQ = FALSE; } if (Memory.FillRAM[0x2210] & 0x02) { if (SA1.VCounter != SA1.VTimerIRQPos * ONE_DOT_CYCLE) thisIRQ = FALSE; } // SA-1 Timer IRQ control if (!SA1.TimerIRQLastState && thisIRQ) { Memory.FillRAM[0x2301] |= 0x40; if (Memory.FillRAM[0x220a] & 0x40) { Memory.FillRAM[0x220b] &= ~0x40; #ifdef DEBUGGER S9xTraceFormattedMessage("--- SA-1 Timer IRQ triggered prev HC:%04d curr HC:%04d HTimer:%d Pos:%04d VTimer:%d Pos:%03d", SA1.PrevHCounter, SA1.HCounter, (Memory.FillRAM[0x2210] & 0x01) ? 1 : 0, SA1.HTimerIRQPos * ONE_DOT_CYCLE, (Memory.FillRAM[0x2210] & 0x02) ? 1 : 0, SA1.VTimerIRQPos); #endif } } SA1.TimerIRQLastState = thisIRQ; }