/* * Snes9x - Portable Super Nintendo Entertainment System (TM) emulator. * * (c) Copyright 1996 - 2001 Gary Henderson (gary.henderson@ntlworld.com) and * Jerremy Koot (jkoot@snes9x.com) * * Super FX C emulator code * (c) Copyright 1997 - 1999 Ivar (ivar@snes9x.com) and * Gary Henderson. * Super FX assembler emulator code (c) Copyright 1998 zsKnight and _Demo_. * * DSP1 emulator code (c) Copyright 1998 Ivar, _Demo_ and Gary Henderson. * C4 asm and some C emulation code (c) Copyright 2000 zsKnight and _Demo_. * C4 C code (c) Copyright 2001 Gary Henderson (gary.henderson@ntlworld.com). * * (c) Copyright 2014 - 2016 Daniel De Matteis. (UNDER NO CIRCUMSTANCE * WILL COMMERCIAL RIGHTS EVER BE APPROPRIATED TO ANY PARTY) * * DOS port code contains the works of other authors. See headers in * individual files. * * Snes9x homepage: http://www.snes9x.com * * Permission to use, copy, modify and distribute Snes9x in both binary and * source form, for non-commercial purposes, is hereby granted without fee, * providing that this license information and copyright notice appear with * all copies and any derived work. * * This software is provided 'as-is', without any express or implied * warranty. In no event shall the authors be held liable for any damages * arising from the use of this software. * * Snes9x is freeware for PERSONAL USE only. Commercial users should * seek permission of the copyright holders first. Commercial use includes * charging money for Snes9x or software derived from Snes9x. * * The copyright holders request that bug fixes and improvements to the code * should be forwarded to them so everyone can benefit from the modifications * in future versions. * * Super NES and Super Nintendo Entertainment System are trademarks of * Nintendo Co., Limited and its subsidiary companies. */ #ifdef USE_SA1 #include "snes9x.h" #include "ppu.h" #include "cpuexec.h" #include "sa1.h" static void S9xSA1CharConv2(); static void S9xSA1DMA(); static void S9xSA1ReadVariableLengthData(bool8 inc, bool8 no_shift); void S9xSA1Init() { SA1.NMIActive = FALSE; SA1.IRQActive = FALSE; SA1.WaitingForInterrupt = FALSE; SA1.Waiting = FALSE; SA1.Flags = 0; SA1.Executing = FALSE; memset(&Memory.FillRAM [0x2200], 0, 0x200); Memory.FillRAM [0x2200] = 0x20; Memory.FillRAM [0x2220] = 0x00; Memory.FillRAM [0x2221] = 0x01; Memory.FillRAM [0x2222] = 0x02; Memory.FillRAM [0x2223] = 0x03; Memory.FillRAM [0x2228] = 0xff; SA1.op1 = 0; SA1.op2 = 0; SA1.arithmetic_op = 0; SA1.sum = 0; SA1.overflow = FALSE; } void S9xSA1Reset() { SA1Registers.PB = 0; SA1Registers.PC = Memory.FillRAM [0x2203] | (Memory.FillRAM [0x2204] << 8); SA1Registers.D.W = 0; SA1Registers.DB = 0; SA1Registers.SH = 1; SA1Registers.SL = 0xFF; SA1Registers.XH = 0; SA1Registers.YH = 0; SA1Registers.P.W = 0; SA1.ShiftedPB = 0; SA1.ShiftedDB = 0; SA1SetFlags(MemoryFlag | IndexFlag | IRQ | Emulation); SA1ClearFlags(Decimal); SA1.WaitingForInterrupt = FALSE; SA1.PC = NULL; SA1.PCBase = NULL; S9xSA1SetPCBase(SA1Registers.PC); SA1.S9xOpcodes = S9xSA1OpcodesM1X1; S9xSA1UnpackStatus(); S9xSA1FixCycles(); SA1.Executing = TRUE; SA1.BWRAM = Memory.SRAM; Memory.FillRAM [0x2225] = 0; } void S9xSA1SetBWRAMMemMap(uint8 val) { int c; if (val & 0x80) { for (c = 0; c < 0x400; c += 16) { SA1_Map [c + 6] = SA1_Map [c + 0x806] = (uint8*) MAP_BWRAM_BITMAP2; SA1_Map [c + 7] = SA1_Map [c + 0x807] = (uint8*) MAP_BWRAM_BITMAP2; SA1_WriteMap [c + 6] = SA1_WriteMap [c + 0x806] = (uint8*) MAP_BWRAM_BITMAP2; SA1_WriteMap [c + 7] = SA1_WriteMap [c + 0x807] = (uint8*) MAP_BWRAM_BITMAP2; } SA1.BWRAM = Memory.SRAM + (val & 0x7f) * 0x2000 / 4; } else { for (c = 0; c < 0x400; c += 16) { SA1_Map [c + 6] = SA1_Map [c + 0x806] = (uint8*) MAP_BWRAM; SA1_Map [c + 7] = SA1_Map [c + 0x807] = (uint8*) MAP_BWRAM; SA1_WriteMap [c + 6] = SA1_WriteMap [c + 0x806] = (uint8*) MAP_BWRAM; SA1_WriteMap [c + 7] = SA1_WriteMap [c + 0x807] = (uint8*) MAP_BWRAM; } SA1.BWRAM = Memory.SRAM + (val & 7) * 0x2000; } } void S9xFixSA1AfterSnapshotLoad() { SA1.ShiftedPB = (uint32) SA1Registers.PB << 16; SA1.ShiftedDB = (uint32) SA1Registers.DB << 16; S9xSA1SetPCBase(SA1.ShiftedPB + SA1Registers.PC); S9xSA1UnpackStatus(); S9xSA1FixCycles(); SA1.VirtualBitmapFormat = (Memory.FillRAM [0x223f] & 0x80) ? 2 : 4; Memory.BWRAM = Memory.SRAM + (Memory.FillRAM [0x2224] & 7) * 0x2000; S9xSA1SetBWRAMMemMap(Memory.FillRAM [0x2225]); SA1.Waiting = (Memory.FillRAM [0x2200] & 0x60) != 0; SA1.Executing = !SA1.Waiting; } // SA9xSA1GetByte --- begin static uint8 S9xSA1GetByte_default(uint32 address) { #ifdef DEBUGGER // printf ("R(B) %06x\n", address); #endif return (0); } static uint8 S9xSA1GetByte_PPU(uint32 address) { return (S9xGetSA1(address & 0xffff)); } static uint8 S9xSA1GetByte_SA1RAM(uint32 address) { return (*(Memory.SRAM + (address & 0xffff))); } static uint8 S9xSA1GetByte_BWRAM(uint32 address) { return (*(SA1.BWRAM + ((address & 0x7fff) - 0x6000))); } static uint8 S9xSA1GetByte_BWRAM_BITMAP(uint32 address) { address -= 0x600000; if (SA1.VirtualBitmapFormat == 2) return ((Memory.SRAM [(address >> 2) & 0xffff] >> ((address & 3) << 1)) & 3); else return ((Memory.SRAM [(address >> 1) & 0xffff] >> ((address & 1) << 2)) & 15); } static uint8 S9xSA1GetByte_BWRAM_BITMAP2(uint32 address) { address = (address & 0xffff) - 0x6000; if (SA1.VirtualBitmapFormat == 2) return ((SA1.BWRAM [(address >> 2) & 0xffff] >> ((address & 3) << 1)) & 3); else return ((SA1.BWRAM [(address >> 1) & 0xffff] >> ((address & 1) << 2)) & 15); } // GetByte JumpTable for Memmory map modes uint8(*S9xSA1GetByte_JumpTable[(1 << (16 - 12))])(uint32 address) = { S9xSA1GetByte_PPU, // MAP_PPU S9xSA1GetByte_default, // MAP_CPU S9xSA1GetByte_default, // MAP_DSP S9xSA1GetByte_SA1RAM, // MAP_LOROM_SRAM S9xSA1GetByte_default, // MAP_HIROM_SRAM S9xSA1GetByte_default, // MAP_NONE S9xSA1GetByte_default, // MAP_DEBUG S9xSA1GetByte_default, // MAP_C4 S9xSA1GetByte_BWRAM, // MAP_BWRAM S9xSA1GetByte_BWRAM_BITMAP, // MAP_BWRAM_BITMAP S9xSA1GetByte_BWRAM_BITMAP2, // MAP_BWRAM_BITMAP2 S9xSA1GetByte_SA1RAM, // MAP_SA1RAM S9xSA1GetByte_default, // MAP_LAST S9xSA1GetByte_default, // MAP_LAST+1 S9xSA1GetByte_default, // MAP_LAST+2 S9xSA1GetByte_default // MAP_LAST+3 }; uint8 S9xSA1GetByte(uint32 address) { uint8* GetAddress = SA1_Map [(address >> MEMMAP_SHIFT) & MEMMAP_MASK]; if (GetAddress >= (uint8*) MAP_LAST) return (*(GetAddress + (address & 0xffff))); return S9xSA1GetByte_JumpTable[(intptr_t) GetAddress](address); // return (SA1_Map [(address >> MEMMAP_SHIFT) & MEMMAP_MASK] >= (uint8 *)MAP_LAST) ? // (*((uint8 *)(SA1_Map [(address >> MEMMAP_SHIFT) & MEMMAP_MASK]) + (address & 0xffff))) : // S9xSA1GetByte_JumpTable[(int) SA1_Map [(address >> MEMMAP_SHIFT) & MEMMAP_MASK]](address); } /* uint16 S9xSA1GetWord (uint32 address) { uint8 *GetAddress = SA1_Map [(address >> MEMMAP_SHIFT) & MEMMAP_MASK]; if (GetAddress >= (uint8 *) MAP_LAST) return (*(GetAddress + (address & 0xffff))) | ((*(GetAddress + ((address+1) & 0xffff))) << 8); return (S9xSA1GetByte_JumpTable[(int) GetAddress](address)) | ((S9xSA1GetByte_JumpTable[(int) GetAddress](address+1)) << 8); } */ // SA9xSA1SetByte --- begin static void S9xSA1SetByte_default(uint8 byte, uint32 address) { } static void S9xSA1SetByte_PPU(uint8 byte, uint32 address) { S9xSetSA1(byte, address & 0xffff); } static void S9xSA1SetByte_SA1RAM(uint8 byte, uint32 address) { *(Memory.SRAM + (address & 0xffff)) = byte; } static void S9xSA1SetByte_BWRAM(uint8 byte, uint32 address) { *(SA1.BWRAM + ((address & 0x7fff) - 0x6000)) = byte; } static void S9xSA1SetByte_BWRAM_BITMAP(uint8 byte, uint32 address) { uint8* ptr; address -= 0x600000; if (SA1.VirtualBitmapFormat == 2) { ptr = &Memory.SRAM [(address >> 2) & 0xffff]; *ptr &= ~(3 << ((address & 3) << 1)); *ptr |= (byte & 3) << ((address & 3) << 1); } else { ptr = &Memory.SRAM [(address >> 1) & 0xffff]; *ptr &= ~(15 << ((address & 1) << 2)); *ptr |= (byte & 15) << ((address & 1) << 2); } address -= 0x600000; } static void S9xSA1SetByte_BWRAM_BITMAP2(uint8 byte, uint32 address) { uint8* ptr; address = (address & 0xffff) - 0x6000; if (SA1.VirtualBitmapFormat == 2) { ptr = &SA1.BWRAM [(address >> 2) & 0xffff]; *ptr &= ~(3 << ((address & 3) << 1)); *ptr |= (byte & 3) << ((address & 3) << 1); } else { ptr = &SA1.BWRAM [(address >> 1) & 0xffff]; *ptr &= ~(15 << ((address & 1) << 2)); *ptr |= (byte & 15) << ((address & 1) << 2); } } // SetByte JumpTable for Memmory map modes void (*S9xSA1SetByte_JumpTable[(1 << (16 - 12))])(uint8 byte, uint32 address) = { S9xSA1SetByte_PPU, // MAP_PPU S9xSA1SetByte_default, // MAP_CPU S9xSA1SetByte_default, // MAP_DSP S9xSA1SetByte_SA1RAM, // MAP_LOROM_SRAM S9xSA1SetByte_default, // MAP_HIROM_SRAM S9xSA1SetByte_default, // MAP_NONE S9xSA1SetByte_default, // MAP_DEBUG S9xSA1SetByte_default, // MAP_C4 S9xSA1SetByte_BWRAM, // MAP_BWRAM S9xSA1SetByte_BWRAM_BITMAP, // MAP_BWRAM_BITMAP S9xSA1SetByte_BWRAM_BITMAP2, // MAP_BWRAM_BITMAP2 S9xSA1SetByte_SA1RAM, // MAP_SA1RAM S9xSA1SetByte_default, // MAP_LAST S9xSA1SetByte_default, // MAP_LAST+1 S9xSA1SetByte_default, // MAP_LAST+2 S9xSA1SetByte_default // MAP_LAST+3 }; void S9xSA1SetByte(uint8 byte, uint32 address) { // MEMMAP_SHIFT 12 // MEMMAP_MASK 0xFFF uint8* Setaddress = SA1_WriteMap [(address >> MEMMAP_SHIFT) & MEMMAP_MASK]; if (Setaddress >= (uint8*) MAP_LAST) { *(Setaddress + (address & 0xffff)) = byte; return; } S9xSA1SetByte_JumpTable[(intptr_t)Setaddress](byte, address); } void S9xSA1SetPCBase(uint32 address) { uint8* GetAddress = SA1_Map [(address >> MEMMAP_SHIFT) & MEMMAP_MASK]; if (GetAddress >= (uint8*) MAP_LAST) { SA1.PCBase = GetAddress; SA1.PC = GetAddress + (address & 0xffff); return; } switch ((intptr_t) GetAddress) { case MAP_PPU: SA1.PCBase = Memory.FillRAM - 0x2000; SA1.PC = SA1.PCBase + (address & 0xffff); return; case MAP_CPU: SA1.PCBase = Memory.FillRAM - 0x4000; SA1.PC = SA1.PCBase + (address & 0xffff); return; case MAP_DSP: SA1.PCBase = Memory.FillRAM - 0x6000; SA1.PC = SA1.PCBase + (address & 0xffff); return; case MAP_SA1RAM: case MAP_LOROM_SRAM: SA1.PCBase = Memory.SRAM; SA1.PC = SA1.PCBase + (address & 0xffff); return; case MAP_BWRAM: SA1.PCBase = SA1.BWRAM - 0x6000; SA1.PC = SA1.PCBase + (address & 0xffff); return; case MAP_HIROM_SRAM: SA1.PCBase = Memory.SRAM - 0x6000; SA1.PC = SA1.PCBase + (address & 0xffff); return; case MAP_DEBUG: #ifdef DEBUGGER printf("SBP %06x\n", address); #endif default: case MAP_NONE: SA1.PCBase = Memory.RAM; SA1.PC = Memory.RAM + (address & 0xffff); return; } } void S9xSA1ExecuteDuringSleep() { } void S9xSetSA1MemMap(uint32 which1, uint8 map) { int c; int start = which1 * 0x100 + 0xc00; int start2 = which1 * 0x200; uint8* block; int i; if (which1 >= 2) start2 += 0x400; for (c = 0; c < 0x100; c += 16) { block = &Memory.ROM [(map & 7) * 0x100000 + (c << 12)]; for (i = c; i < c + 16; i++) Memory.Map [start + i] = SA1_Map [start + i] = block; } for (c = 0; c < 0x200; c += 16) { block = &Memory.ROM [(map & 7) * 0x100000 + (c << 11) - 0x8000]; for (i = c + 8; i < c + 16; i++) Memory.Map [start2 + i] = SA1_Map [start2 + i] = block; } } uint8 S9xGetSA1(uint32 address) { if ((address < 0x2300) && (address > 0x230d)) return (Memory.FillRAM [address]); switch (address) { case 0x2300: return ((uint8)((Memory.FillRAM [0x2209] & 0x5f) | (CPU.IRQActive & (SA1_IRQ_SOURCE | SA1_DMA_IRQ_SOURCE)))); case 0x2301: return ((Memory.FillRAM [0x2200] & 0xf) | (Memory.FillRAM [0x2301] & 0xf0)); case 0x2306: return ((uint8) SA1.sum); case 0x2307: return ((uint8)(SA1.sum >> 8)); case 0x2308: return ((uint8)(SA1.sum >> 16)); case 0x2309: return ((uint8)(SA1.sum >> 24)); case 0x230a: return ((uint8)(SA1.sum >> 32)); case 0x230b: return (Memory.FillRAM [address]); case 0x230c: return (Memory.FillRAM [0x230c]); case 0x230d: { uint8 byte = Memory.FillRAM [0x230d]; if (Memory.FillRAM [0x2258] & 0x80) S9xSA1ReadVariableLengthData(TRUE, FALSE); return (byte); } } return (Memory.FillRAM [address]); } void S9xSetSA1(uint8 byte, uint32 address) { if (address < 0x2200 || address > 0x22ff) return; switch (address) { case 0x2200: SA1.Waiting = (byte & 0x60) != 0; if (!(byte & 0x20) && (Memory.FillRAM [0x2200] & 0x20)) S9xSA1Reset(); if (byte & 0x80) { Memory.FillRAM [0x2301] |= 0x80; if (Memory.FillRAM [0x220a] & 0x80) { SA1.Flags |= IRQ_PENDING_FLAG; SA1.IRQActive |= SNES_IRQ_SOURCE; SA1.Executing = !SA1.Waiting && SA1.S9xOpcodes; } } if (byte & 0x10) Memory.FillRAM [0x2301] |= 0x10; break; case 0x2201: if (((byte ^ Memory.FillRAM [0x2201]) & 0x80) && (Memory.FillRAM [0x2300] & byte & 0x80)) S9xSetIRQ(SA1_IRQ_SOURCE); if (((byte ^ Memory.FillRAM [0x2201]) & 0x20) && (Memory.FillRAM [0x2300] & byte & 0x20)) S9xSetIRQ(SA1_DMA_IRQ_SOURCE); break; case 0x2202: if (byte & 0x80) { Memory.FillRAM [0x2300] &= ~0x80; S9xClearIRQ(SA1_IRQ_SOURCE); } if (byte & 0x20) { Memory.FillRAM [0x2300] &= ~0x20; S9xClearIRQ(SA1_DMA_IRQ_SOURCE); } break; case 0x2209: Memory.FillRAM [0x2209] = byte; if (byte & 0x80) Memory.FillRAM [0x2300] |= 0x80; if (byte & Memory.FillRAM [0x2201] & 0x80) S9xSetIRQ(SA1_IRQ_SOURCE); return; case 0x220a: if (((byte ^ Memory.FillRAM [0x220a]) & 0x80) && (Memory.FillRAM [0x2301] & byte & 0x80)) { SA1.Flags |= IRQ_PENDING_FLAG; SA1.IRQActive |= SNES_IRQ_SOURCE; } if (((byte ^ Memory.FillRAM [0x220a]) & 0x40) && (Memory.FillRAM [0x2301] & byte & 0x40)) { SA1.Flags |= IRQ_PENDING_FLAG; SA1.IRQActive |= TIMER_IRQ_SOURCE; } if (((byte ^ Memory.FillRAM [0x220a]) & 0x20) && (Memory.FillRAM [0x2301] & byte & 0x20)) { SA1.Flags |= IRQ_PENDING_FLAG; SA1.IRQActive |= DMA_IRQ_SOURCE; } if (((byte ^ Memory.FillRAM [0x220a]) & 0x10) && (Memory.FillRAM [0x2301] & byte & 0x10)) { } break; case 0x220b: if (byte & 0x80) { SA1.IRQActive &= ~SNES_IRQ_SOURCE; Memory.FillRAM [0x2301] &= ~0x80; } if (byte & 0x40) { SA1.IRQActive &= ~TIMER_IRQ_SOURCE; Memory.FillRAM [0x2301] &= ~0x40; } if (byte & 0x20) { SA1.IRQActive &= ~DMA_IRQ_SOURCE; Memory.FillRAM [0x2301] &= ~0x20; } if (byte & 0x10) { // Clear NMI Memory.FillRAM [0x2301] &= ~0x10; } if (!SA1.IRQActive) SA1.Flags &= ~IRQ_PENDING_FLAG; break; case 0x2220: case 0x2221: case 0x2222: case 0x2223: S9xSetSA1MemMap(address - 0x2220, byte); break; case 0x2224: Memory.BWRAM = Memory.SRAM + (byte & 7) * 0x2000; break; case 0x2225: if (byte != Memory.FillRAM [address]) S9xSA1SetBWRAMMemMap(byte); break; case 0x2231: if (byte & 0x80) SA1.in_char_dma = FALSE; break; case 0x2236: Memory.FillRAM [address] = byte; if ((Memory.FillRAM [0x2230] & 0xa4) == 0x80) { // Normal DMA to I-RAM S9xSA1DMA(); } else if ((Memory.FillRAM [0x2230] & 0xb0) == 0xb0) { Memory.FillRAM [0x2300] |= 0x20; if (Memory.FillRAM [0x2201] & 0x20) S9xSetIRQ(SA1_DMA_IRQ_SOURCE); SA1.in_char_dma = TRUE; } return; case 0x2237: Memory.FillRAM [address] = byte; if ((Memory.FillRAM [0x2230] & 0xa4) == 0x84) { // Normal DMA to BW-RAM S9xSA1DMA(); } return; case 0x223f: SA1.VirtualBitmapFormat = (byte & 0x80) ? 2 : 4; break; case 0x224f: Memory.FillRAM [address] = byte; if ((Memory.FillRAM [0x2230] & 0xb0) == 0xa0) { // Char conversion 2 DMA enabled memmove(&Memory.ROM [MAX_ROM_SIZE - 0x10000] + (SA1.in_char_dma << 4), &Memory.FillRAM [0x2240], 16); SA1.in_char_dma = (SA1.in_char_dma + 1) & 7; if ((SA1.in_char_dma & 3) == 0) S9xSA1CharConv2(); } return; case 0x2250: if (byte & 2) SA1.sum = 0; SA1.arithmetic_op = byte & 3; break; case 0x2251: SA1.op1 = (SA1.op1 & 0xff00) | byte; break; case 0x2252: SA1.op1 = (SA1.op1 & 0xff) | (byte << 8); break; case 0x2253: SA1.op2 = (SA1.op2 & 0xff00) | byte; break; case 0x2254: SA1.op2 = (SA1.op2 & 0xff) | (byte << 8); switch (SA1.arithmetic_op) { case 0: // multiply SA1.sum = SA1.op1 * SA1.op2; break; case 1: // divide if (SA1.op2 == 0) SA1.sum = SA1.op1 << 16; else { unsigned int x = (SA1.op1 / (int)((uint16) SA1.op2)); SA1.sum = x | ((SA1.op1 - (x * (uint16) SA1.op2)) << 16); // SA1.sum = (SA1.op1 / (int) ((uint16) SA1.op2)) | //((SA1.op1 % (int) ((uint16) SA1.op2)) << 16); } break; default: // cumulative sum SA1.sum += SA1.op1 * SA1.op2; if (SA1.sum & ((int64) 0xffffff << 32)) SA1.overflow = TRUE; break; } break; case 0x2258: // Variable bit-field length/auto inc/start. Memory.FillRAM [0x2258] = byte; S9xSA1ReadVariableLengthData(TRUE, FALSE); return; case 0x2259: case 0x225a: case 0x225b: // Variable bit-field start address Memory.FillRAM [address] = byte; // XXX: ??? SA1.variable_bit_pos = 0; S9xSA1ReadVariableLengthData(FALSE, TRUE); return; } if (address >= 0x2200 && address <= 0x22ff) Memory.FillRAM [address] = byte; } static void S9xSA1CharConv2() { uint32 dest = Memory.FillRAM [0x2235] | (Memory.FillRAM [0x2236] << 8); uint32 offset = (SA1.in_char_dma & 7) ? 0 : 1; int depth = (Memory.FillRAM [0x2231] & 3) == 0 ? 8 : (Memory.FillRAM [0x2231] & 3) == 1 ? 4 : 2; int bytes_per_char = 8 * depth; uint8* p = &Memory.FillRAM [0x3000] + dest + offset * bytes_per_char; uint8* q = &Memory.ROM [MAX_ROM_SIZE - 0x10000] + offset * 64; if (depth == 8) { int l; for (l = 0; l < 8; l++, q += 8) { int b; for (b = 0; b < 8; b++) { uint8 r = *(q + b); *(p + 0) = (*(p + 0) << 1) | ((r >> 0) & 1); *(p + 1) = (*(p + 1) << 1) | ((r >> 1) & 1); *(p + 16) = (*(p + 16) << 1) | ((r >> 2) & 1); *(p + 17) = (*(p + 17) << 1) | ((r >> 3) & 1); *(p + 32) = (*(p + 32) << 1) | ((r >> 4) & 1); *(p + 33) = (*(p + 33) << 1) | ((r >> 5) & 1); *(p + 48) = (*(p + 48) << 1) | ((r >> 6) & 1); *(p + 49) = (*(p + 49) << 1) | ((r >> 7) & 1); } p += 2; } } } static void S9xSA1DMA() { uint32 src = Memory.FillRAM [0x2232] | (Memory.FillRAM [0x2233] << 8) | (Memory.FillRAM [0x2234] << 16); uint32 dst = Memory.FillRAM [0x2235] | (Memory.FillRAM [0x2236] << 8) | (Memory.FillRAM [0x2237] << 16); uint32 len = Memory.FillRAM [0x2238] | (Memory.FillRAM [0x2239] << 8); uint8* s; uint8* d; switch (Memory.FillRAM [0x2230] & 3) { case 0: // ROM s = SA1_Map [(src >> MEMMAP_SHIFT) & MEMMAP_MASK]; if (s >= (uint8*) MAP_LAST) s += (src & 0xffff); else s = Memory.ROM + (src & 0xffff); break; case 1: // BW-RAM src &= CPU.Memory_SRAMMask; len &= CPU.Memory_SRAMMask; s = Memory.SRAM + src; break; default: case 2: src &= 0x3ff; len &= 0x3ff; s = &Memory.FillRAM [0x3000] + src; break; } if (Memory.FillRAM [0x2230] & 4) { dst &= CPU.Memory_SRAMMask; len &= CPU.Memory_SRAMMask; d = Memory.SRAM + dst; } else { dst &= 0x3ff; len &= 0x3ff; d = &Memory.FillRAM [0x3000] + dst; } memmove(d, s, len); Memory.FillRAM [0x2301] |= 0x20; if (Memory.FillRAM [0x220a] & 0x20) { SA1.Flags |= IRQ_PENDING_FLAG; SA1.IRQActive |= DMA_IRQ_SOURCE; } } void S9xSA1ReadVariableLengthData(bool8 inc, bool8 no_shift) { uint32 data; uint8 s; uint32 addr = Memory.FillRAM [0x2259] | (Memory.FillRAM [0x225a] << 8) | (Memory.FillRAM [0x225b] << 16); uint8 shift = Memory.FillRAM [0x2258] & 15; if (no_shift) shift = 0; else if (shift == 0) shift = 16; s = shift + SA1.variable_bit_pos; if (s >= 16) { addr += (s >> 4) << 1; s &= 15; } data = S9xSA1GetWord(addr) | (S9xSA1GetWord(addr + 2) << 16); data >>= s; Memory.FillRAM [0x230c] = (uint8) data; Memory.FillRAM [0x230d] = (uint8)(data >> 8); if (inc) { SA1.variable_bit_pos = (SA1.variable_bit_pos + shift) & 15; Memory.FillRAM [0x2259] = (uint8) addr; Memory.FillRAM [0x225a] = (uint8)(addr >> 8); Memory.FillRAM [0x225b] = (uint8)(addr >> 16); } } #endif // USE_SA1