using Codice.CM.Client.Differences; using System; using System.Runtime.CompilerServices; using System.Runtime.InteropServices; using UnityEngine.UIElements; namespace VirtualNes.Core { public unsafe class PPU { public const int SCREEN_WIDTH = 272; public const int SCREEN_HEIGHT = 240; private GCHandle BGwriteGCH; private GCHandle BGmonoGCH; private GCHandle SPwriteGCH; private byte* BGwrite; private byte* BGmono; private byte* SPwrite; private static byte[][] CreateCOLORMAP() { byte[][] res = new byte[5][]; res[0] = new byte[64] { 0x35, 0xFF, 0x16, 0x22, 0x1C, 0xFF, 0xFF, 0x15, 0xFF, 0x00, 0x27, 0x05, 0x04, 0x27, 0x08, 0x30, 0x21, 0xFF, 0xFF, 0x29, 0x3C, 0xFF, 0x36, 0x12, 0xFF, 0x2B, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x01, 0xFF, 0x31, 0xFF, 0x2A, 0x2C, 0x0C, 0xFF, 0xFF, 0xFF, 0x07, 0x34, 0x06, 0x13, 0xFF, 0x26, 0x0F, 0xFF, 0x19, 0x10, 0x0A, 0xFF, 0xFF, 0xFF, 0x17, 0xFF, 0x11, 0x09, 0xFF, 0xFF, 0x25, 0x18, 0xFF }; res[1] = new byte[64] { 0xFF, 0x27, 0x18, 0xFF, 0x3A, 0x25, 0xFF, 0x31, 0x16, 0x13, 0x38, 0x34, 0x20, 0x23, 0x31, 0x1A, 0xFF, 0x21, 0x06, 0xFF, 0x1B, 0x29, 0xFF, 0x22, 0xFF, 0x24, 0xFF, 0xFF, 0xFF, 0x08, 0xFF, 0x03, 0xFF, 0x36, 0x26, 0x33, 0x11, 0xFF, 0x10, 0x02, 0x14, 0xFF, 0x00, 0x09, 0x12, 0x0F, 0xFF, 0x30, 0xFF, 0xFF, 0x2A, 0x17, 0x0C, 0x01, 0x15, 0x19, 0xFF, 0x2C, 0x07, 0x37, 0xFF, 0x05, 0xFF, 0xFF }; res[2] = new byte[64] { 0xFF, 0xFF, 0xFF, 0x10, 0x1A, 0x30, 0x31, 0x09, 0x01, 0x0F, 0x36, 0x08, 0x15, 0xFF, 0xFF, 0xF0, 0x22, 0x1C, 0xFF, 0x12, 0x19, 0x18, 0x17, 0xFF, 0x00, 0xFF, 0xFF, 0x02, 0x16, 0x06, 0xFF, 0x35, 0x23, 0xFF, 0x8B, 0xF7, 0xFF, 0x27, 0x26, 0x20, 0x29, 0xFF, 0x21, 0x24, 0x11, 0xFF, 0xEF, 0xFF, 0x2C, 0xFF, 0xFF, 0xFF, 0x07, 0xF9, 0x28, 0xFF, 0x0A, 0xFF, 0x32, 0x37, 0x13, 0xFF, 0xFF, 0x0C }; res[3] = new byte[64] { 0x18, 0xFF, 0x1C, 0x89, 0x0F, 0xFF, 0x01, 0x17, // 00-07 0x10, 0x0F, 0x2A, 0xFF, 0x36, 0x37, 0x1A, 0xFF, // 08-0F 0x25, 0xFF, 0x12, 0xFF, 0x0F, 0xFF, 0xFF, 0x26, // 10-17 0xFF, 0xFF, 0x22, 0xFF, 0xFF, 0x0F, 0x3A, 0x21, // 18-1F 0x05, 0x0A, 0x07, 0xC2, 0x13, 0xFF, 0x00, 0x15, // 20-27 0x0C, 0xFF, 0x11, 0xFF, 0xFF, 0x38, 0xFF, 0xFF, // 28-2F 0xFF, 0xFF, 0x08, 0x16, 0xFF, 0xFF, 0x30, 0x3C, // 30-37 0x0F, 0x27, 0xFF, 0x60, 0x29, 0xFF, 0x30, 0x09 // 38-3F }; res[4] = new byte[64] { // Super Xevious/Gradius 0x35, 0xFF, 0x16, 0x22, 0x1C, 0x09, 0xFF, 0x15, // 00-07 0x20, 0x00, 0x27, 0x05, 0x04, 0x28, 0x08, 0x30, // 08-0F 0x21, 0xFF, 0xFF, 0x29, 0x3C, 0xFF, 0x36, 0x12, // 10-17 0xFF, 0x2B, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x01, // 18-1F 0xFF, 0x31, 0xFF, 0x2A, 0x2C, 0x0C, 0x1B, 0xFF, // 20-27 0xFF, 0x07, 0x34, 0x06, 0xFF, 0x25, 0x26, 0x0F, // 28-2F 0xFF, 0x19, 0x10, 0x0A, 0xFF, 0xFF, 0xFF, 0x17, // 30-37 0xFF, 0x11, 0x1A, 0xFF, 0x38, 0xFF, 0x18, 0x3A, // 38-3F }; return res; } private static byte[][] VSColorMap = CreateCOLORMAP(); // PPU Control Register #1 PPU #0 public const byte PPU_VBLANK_BIT = 0x80; public const byte PPU_SPHIT_BIT = 0x40; // 堘偆丠 public const byte PPU_SP16_BIT = 0x20; public const byte PPU_BGTBL_BIT = 0x10; public const byte PPU_SPTBL_BIT = 0x08; public const byte PPU_INC32_BIT = 0x04; public const byte PPU_NAMETBL_BIT = 0x03; // PPU Control Register #2 PPU #1 public const byte PPU_BGCOLOR_BIT = 0xE0; public const byte PPU_SPDISP_BIT = 0x10; public const byte PPU_BGDISP_BIT = 0x08; public const byte PPU_SPCLIP_BIT = 0x04; public const byte PPU_BGCLIP_BIT = 0x02; public const byte PPU_COLORMODE_BIT = 0x01; // PPU Status Register PPU #2 public const byte PPU_VBLANK_FLAG = 0x80; public const byte PPU_SPHIT_FLAG = 0x40; public const byte PPU_SPMAX_FLAG = 0x20; public const byte PPU_WENABLE_FLAG = 0x10; // SPRITE Attribute public const byte SP_VMIRROR_BIT = 0x80; public const byte SP_HMIRROR_BIT = 0x40; public const byte SP_PRIORITY_BIT = 0x20; public const byte SP_COLOR_BIT = 0x03; private NES nes; private bool bExtLatch; // For MMC5 private bool bChrLatch; // For MMC2/MMC4 private bool bExtNameTable; // For Super Monkey no Dai Bouken private bool bExtMono; // For Final Fantasy private ushort loopy_y; private ushort loopy_shift; private GCHandle lpScreenGCH; private byte* lpScreen; /// 作为lpScreen数组的索引 private byte* lpScanline; private int ScanlineNo; private byte[] lpColormode; private bool bVSMode; private int nVSColorMap; private byte VSSecurityData; private byte[] Bit2Rev = new byte[256]; public PPU(NES nes) { this.nes = nes; lpScreen = null; lpColormode = null; bVSMode = false; nVSColorMap = -1; VSSecurityData = 0; for (int i = 0; i < 256; i++) { byte m = 0x80; byte c = 0; for (int j = 0; j < 8; j++) { if ((i & (1 << j)) > 0) c |= m; m >>= 1; } Bit2Rev[i] = c; } BGwriteGCH = GCHandle.Alloc(new byte[33 + 1], GCHandleType.Pinned); BGmonoGCH = GCHandle.Alloc(new byte[33 + 1], GCHandleType.Pinned); SPwriteGCH = GCHandle.Alloc(new byte[33 + 1], GCHandleType.Pinned); BGwrite = (byte*)BGwriteGCH.AddrOfPinnedObject(); BGmono = (byte*)BGmonoGCH.AddrOfPinnedObject(); SPwrite = (byte*)SPwriteGCH.AddrOfPinnedObject(); } public void Dispose() { lpScreenGCH.Free(); BGwriteGCH.Free(); BGmonoGCH.Free(); SPwriteGCH.Free(); } internal byte Read(ushort addr) { byte data = 0x00; switch (addr) { // Write only Register case 0x2000: // PPU Control Register #1(W) case 0x2001: // PPU Control Register #2(W) case 0x2003: // SPR-RAM Address Register(W) case 0x2005: // PPU Scroll Register(W2) case 0x2006: // VRAM Address Register(W2) data = MMU.PPU7_Temp; // 懡暘 break; // Read/Write Register case 0x2002: // PPU Status Register(R) //DEBUGOUT( "2002 RD L:%3d C:%8d\n", ScanlineNo, nes->cpu->GetTotalCycles() ); data = (byte)(MMU.PPUREG[2] | VSSecurityData); MMU.PPU56Toggle = 0; byte temp = unchecked((byte)~PPU_VBLANK_FLAG); MMU.PPUREG[2] &= temp; break; case 0x2004: // SPR_RAM I/O Register(RW) data = MMU.SPRAM[MMU.PPUREG[3]++]; break; case 0x2007: // VRAM I/O Register(RW) addr = (ushort)(MMU.loopy_v & 0x3FFF); data = MMU.PPU7_Temp; if ((MMU.PPUREG[0] & PPU_INC32_BIT) != 0) MMU.loopy_v += 32; else MMU.loopy_v++; if (addr >= 0x3000) { if (addr >= 0x3F00) { // data &= 0x3F; if ((addr & 0x0010) == 0) { return MMU.BGPAL[addr & 0x000F]; } else { return MMU.SPPAL[addr & 0x000F]; } } addr &= 0xEFFF; } MMU.PPU7_Temp = MMU.PPU_MEM_BANK[addr >> 10][addr & 0x03FF]; break; } return data; } internal void SetRenderScanline(int scanline) { ScanlineNo = scanline; if (scanline < 240) { lpScanline = lpScreen + SCREEN_WIDTH * scanline; } } internal void Write(ushort addr, byte data) { if (bVSMode && VSSecurityData != 0) { if (addr == 0x2000) { addr = 0x2001; } else if (addr == 0x2001) { addr = 0x2000; } } switch (addr) { // Read only Register case 0x2002: // PPU Status register(R) break; // Write Register case 0x2000: // PPU Control Register #1(W) // NameTable select // t:0000110000000000=d:00000011 MMU.loopy_t = (ushort)((MMU.loopy_t & 0xF3FF) | ((data & 0x03) << 10)); if ((data & 0x80) != 0 && (MMU.PPUREG[0] & 0x80) == 0 && (MMU.PPUREG[2] & 0x80) != 0) { nes.cpu.NMI(); // hmm... } MMU.PPUREG[0] = data; break; case 0x2001: // PPU Control Register #2(W) MMU.PPUREG[1] = data; break; case 0x2003: // SPR-RAM Address Register(W) MMU.PPUREG[3] = data; break; case 0x2004: // SPR_RAM I/O Register(RW) MMU.SPRAM[MMU.PPUREG[3]++] = data; break; case 0x2005: // PPU Scroll Register(W2) //DEBUGOUT( "SCR WRT L:%3d C:%8d\n", ScanlineNo, nes->cpu->GetTotalCycles() ); if (MMU.PPU56Toggle == 0) { // First write // tile X t:0000000000011111=d:11111000 MMU.loopy_t = (ushort)((MMU.loopy_t & 0xFFE0) | ((data) >> 3)); // scroll offset X x=d:00000111 MMU.loopy_x = (ushort)(data & 0x07); } else { // Second write // tile Y t:0000001111100000=d:11111000 MMU.loopy_t = (ushort)((MMU.loopy_t & 0xFC1F) | (((data) & 0xF8) << 2)); // scroll offset Y t:0111000000000000=d:00000111 MMU.loopy_t = (ushort)((MMU.loopy_t & 0x8FFF) | (((data) & 0x07) << 12)); } MMU.PPU56Toggle = (byte)(MMU.PPU56Toggle == 0 ? 1 : 0); break; case 0x2006: // VRAM Address Register(W2) if (MMU.PPU56Toggle == 0) { // First write // t:0011111100000000=d:00111111 // t:1100000000000000=0 MMU.loopy_t = (ushort)((MMU.loopy_t & 0x00FF) | (((data) & 0x3F) << 8)); } else { // Second write // t:0000000011111111=d:11111111 MMU.loopy_t = (ushort)((MMU.loopy_t & 0xFF00) | data); // v=t MMU.loopy_v = MMU.loopy_t; nes.mapper.PPU_Latch(MMU.loopy_v); } MMU.PPU56Toggle = (byte)(MMU.PPU56Toggle == 0 ? 1 : 0); break; case 0x2007: // VRAM I/O Register(RW) ushort vaddr = (ushort)(MMU.loopy_v & 0x3FFF); if ((MMU.PPUREG[0] & PPU_INC32_BIT) != 0) MMU.loopy_v += 32; else MMU.loopy_v++; if (vaddr >= 0x3000) { if (vaddr >= 0x3F00) { data &= 0x3F; if (bVSMode && nVSColorMap != -1) { byte temp = VSColorMap[nVSColorMap][data]; if (temp != 0xFF) { data = (byte)(temp & 0x3F); } } if ((vaddr & 0x000F) == 0) { MMU.BGPAL[0] = MMU.SPPAL[0] = data; } else if ((vaddr & 0x0010) == 0) { MMU.BGPAL[vaddr & 0x000F] = data; } else { MMU.SPPAL[vaddr & 0x000F] = data; } MMU.BGPAL[0x04] = MMU.BGPAL[0x08] = MMU.BGPAL[0x0C] = MMU.BGPAL[0x00]; MMU.SPPAL[0x00] = MMU.SPPAL[0x04] = MMU.SPPAL[0x08] = MMU.SPPAL[0x0C] = MMU.BGPAL[0x00]; return; } vaddr &= 0xEFFF; } if (MMU.PPU_MEM_TYPE[vaddr >> 10] != MMU.BANKTYPE_VROM) { MMU.PPU_MEM_BANK[vaddr >> 10][vaddr & 0x03FF] = data; } break; } } internal void DMA(byte data) { ushort addr = (ushort)(data << 8); for (ushort i = 0; i < 256; i++) { MMU.SPRAM[i] = nes.Read((ushort)(addr + i)); } } internal void Reset() { bExtLatch = false; bChrLatch = false; bExtNameTable = false; bExtMono = false; MMU.PPUREG[0] = MMU.PPUREG[1] = 0; MMU.PPU56Toggle = 0; MMU.PPU7_Temp = 0xFF; // VS Excitebike偱偍偐偟偔側傞($2006傪撉傒偵峴偔僶僌偑偁傞) // PPU7_Temp = 0; MMU.loopy_v = MMU.loopy_t = 0; MMU.loopy_x = loopy_y = 0; loopy_shift = 0; if (lpScreen != null) Unsafe.InitBlockUnaligned(lpScreen, 0, SCREEN_WIDTH * SCREEN_HEIGHT); if (lpColormode != null) MemoryUtility.memset(lpColormode, 0, SCREEN_HEIGHT); } internal void FrameStart() { if ((MMU.PPUREG[1] & (PPU_SPDISP_BIT | PPU_BGDISP_BIT)) != 0) { MMU.loopy_v = MMU.loopy_t; loopy_shift = MMU.loopy_x; loopy_y = (ushort)((MMU.loopy_v & 0x7000) >> 12); } if (lpScreen != null) { Unsafe.InitBlockUnaligned(lpScreen, 0x3F, SCREEN_WIDTH); } if (lpColormode != null) { lpColormode[0] = 0; } } internal void ScanlineNext() { if ((MMU.PPUREG[1] & (PPU_BGDISP_BIT | PPU_SPDISP_BIT)) != 0) { if ((MMU.loopy_v & 0x7000) == 0x7000) { MMU.loopy_v &= 0x8FFF; if ((MMU.loopy_v & 0x03E0) == 0x03A0) { MMU.loopy_v ^= 0x0800; MMU.loopy_v &= 0xFC1F; } else { if ((MMU.loopy_v & 0x03E0) == 0x03E0) { MMU.loopy_v &= 0xFC1F; } else { MMU.loopy_v += 0x0020; } } } else { MMU.loopy_v += 0x1000; } loopy_y = (ushort)((MMU.loopy_v & 0x7000) >> 12); } } internal void ScanlineStart() { if ((MMU.PPUREG[1] & (PPU_BGDISP_BIT | PPU_SPDISP_BIT)) != 0) { MMU.loopy_v = (ushort)((MMU.loopy_v & 0xFBE0) | (MMU.loopy_t & 0x041F)); loopy_shift = MMU.loopy_x; loopy_y = (ushort)((MMU.loopy_v & 0x7000) >> 12); nes.mapper.PPU_Latch((ushort)(0x2000 + (MMU.loopy_v & 0x0FFF))); } } internal void Scanline(int scanline, bool bMax, bool bLeftClip) { byte chr_h = 0, chr_l = 0, attr = 0; Unsafe.InitBlockUnaligned(BGwrite, 0, 34); Unsafe.InitBlockUnaligned(BGmono, 0, 34); // Linecolor mode lpColormode[scanline] = (byte)(((MMU.PPUREG[1] & PPU_BGCOLOR_BIT) >> 5) | ((MMU.PPUREG[1] & PPU_COLORMODE_BIT) << 7)); // Render BG if ((MMU.PPUREG[1] & PPU_BGDISP_BIT) == 0) { Unsafe.InitBlockUnaligned(lpScanline, MMU.BGPAL[0], SCREEN_WIDTH); if (nes.GetRenderMethod() == EnumRenderMethod.TILE_RENDER) { nes.EmulationCPU(NES.FETCH_CYCLES * 4 * 32); } } else { if (nes.GetRenderMethod() != EnumRenderMethod.TILE_RENDER) { if (!bExtLatch) { // Without Extension Latch byte* pScn = lpScanline + (8 - loopy_shift); byte* pBGw = BGwrite; int tileofs = (MMU.PPUREG[0] & PPU_BGTBL_BIT) << 8; int ntbladr = 0x2000 + (MMU.loopy_v & 0x0FFF); int attradr = 0x23C0 + (MMU.loopy_v & 0x0C00) + ((MMU.loopy_v & 0x0380) >> 4); int ntbl_x = ntbladr & 0x001F; int attrsft = (ntbladr & 0x0040) >> 4; var pNTBL = MMU.PPU_MEM_BANK[ntbladr >> 10]; int tileadr; int cache_tile = unchecked((int)(0xFFFF0000)); byte cache_attr = 0xFF; chr_h = chr_l = attr = 0; attradr &= 0x3FF; for (int i = 0; i < 33; i++) { tileadr = tileofs + pNTBL[ntbladr & 0x03FF] * 0x10 + loopy_y; attr = (byte)(((pNTBL[attradr + (ntbl_x >> 2)] >> ((ntbl_x & 2) + attrsft)) & 3) << 2); if (cache_tile == tileadr && cache_attr == attr) { *(uint*)(pScn + 0) = *(uint*)(pScn - 8); *(uint*)(pScn + 4) = *(uint*)(pScn - 4); *(pBGw + 0) = *(pBGw - 1); } else { cache_tile = tileadr; cache_attr = attr; chr_l = MMU.PPU_MEM_BANK[tileadr >> 10][tileadr & 0x03FF]; chr_h = MMU.PPU_MEM_BANK[tileadr >> 10][(tileadr & 0x03FF) + 8]; *pBGw = (byte)(chr_h | chr_l); fixed (byte* pBGPAL = &MMU.BGPAL[attr]) { int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); pScn[0] = pBGPAL[(c1 >> 6)]; pScn[4] = pBGPAL[(c1 >> 2) & 3]; pScn[1] = pBGPAL[(c2 >> 6)]; pScn[5] = pBGPAL[(c2 >> 2) & 3]; pScn[2] = pBGPAL[(c1 >> 4) & 3]; pScn[6] = pBGPAL[c1 & 3]; pScn[3] = pBGPAL[(c2 >> 4) & 3]; pScn[7] = pBGPAL[c2 & 3]; } } pScn += 8; pBGw++; // Character latch(For MMC2/MMC4) if (bChrLatch) { nes.mapper.PPU_ChrLatch((ushort)(tileadr)); } if (++ntbl_x == 32) { ntbl_x = 0; ntbladr ^= 0x41F; attradr = 0x03C0 + ((ntbladr & 0x0380) >> 4); pNTBL = MMU.PPU_MEM_BANK[ntbladr >> 10]; } else { ntbladr++; } } } else { // With Extension Latch(For MMC5) byte* pScn = lpScanline + (8 - loopy_shift); byte* pBGw = BGwrite; int ntbladr = 0x2000 + (MMU.loopy_v & 0x0FFF); int ntbl_x = ntbladr & 0x1F; int cache_tile = unchecked((int)(0xFFFF0000)); byte cache_attr = 0xFF; byte exattr = 0; chr_h = chr_l = attr = 0; for (int i = 0; i < 33; i++) { nes.mapper.PPU_ExtLatchX(i); nes.mapper.PPU_ExtLatch((ushort)ntbladr, ref chr_l, ref chr_h, ref exattr); attr = (byte)(exattr & 0x0C); if (cache_tile != ((chr_h << 8) + chr_l) || cache_attr != attr) { cache_tile = ((chr_h << 8) + chr_l); cache_attr = attr; *pBGw = (byte)(chr_h | chr_l); fixed (byte* pBGPAL = &MMU.BGPAL[attr]) { int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); pScn[0] = pBGPAL[(c1 >> 6)]; pScn[4] = pBGPAL[(c1 >> 2) & 3]; pScn[1] = pBGPAL[(c2 >> 6)]; pScn[5] = pBGPAL[(c2 >> 2) & 3]; pScn[2] = pBGPAL[(c1 >> 4) & 3]; pScn[6] = pBGPAL[c1 & 3]; pScn[3] = pBGPAL[(c2 >> 4) & 3]; pScn[7] = pBGPAL[c2 & 3]; } } else { *(uint*)(pScn + 0) = *(uint*)(pScn - 8); *(uint*)(pScn + 4) = *(uint*)(pScn - 4); *(pBGw + 0) = *(pBGw - 1); } pScn += 8; pBGw++; if (++ntbl_x == 32) { ntbl_x = 0; ntbladr ^= 0x41F; } else { ntbladr++; } } } } else { if (!bExtLatch) { // Without Extension Latch if (!bExtNameTable) { byte* pScn = lpScanline + (8 - loopy_shift); byte* pBGw = BGwrite; int ntbladr = 0x2000 + (MMU.loopy_v & 0x0FFF); int attradr = 0x03C0 + ((MMU.loopy_v & 0x0380) >> 4); int ntbl_x = ntbladr & 0x001F; int attrsft = (ntbladr & 0x0040) >> 4; var pNTBL = MMU.PPU_MEM_BANK[ntbladr >> 10]; int tileadr = 0; int cache_tile = unchecked((int)(0xFFFF0000)); byte cache_attr = 0xFF; chr_h = chr_l = attr = 0; for (int i = 0; i < 33; i++) { tileadr = ((MMU.PPUREG[0] & PPU_BGTBL_BIT) << 8) + pNTBL[ntbladr & 0x03FF] * 0x10 + loopy_y; if (i != 0) { nes.EmulationCPU(NES.FETCH_CYCLES * 4); } attr = (byte)(((pNTBL[attradr + (ntbl_x >> 2)] >> ((ntbl_x & 2) + attrsft)) & 3) << 2); if (cache_tile != tileadr || cache_attr != attr) { cache_tile = tileadr; cache_attr = attr; chr_l = MMU.PPU_MEM_BANK[tileadr >> 10][tileadr & 0x03FF]; chr_h = MMU.PPU_MEM_BANK[tileadr >> 10][(tileadr & 0x03FF) + 8]; *pBGw = (byte)(chr_l | chr_h); fixed (byte* pBGPAL = &MMU.BGPAL[attr]) { int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); pScn[0] = pBGPAL[(c1 >> 6)]; pScn[4] = pBGPAL[(c1 >> 2) & 3]; pScn[1] = pBGPAL[(c2 >> 6)]; pScn[5] = pBGPAL[(c2 >> 2) & 3]; pScn[2] = pBGPAL[(c1 >> 4) & 3]; pScn[6] = pBGPAL[c1 & 3]; pScn[3] = pBGPAL[(c2 >> 4) & 3]; pScn[7] = pBGPAL[c2 & 3]; } } else { *(uint*)(pScn + 0) = *(uint*)(pScn - 8); *(uint*)(pScn + 4) = *(uint*)(pScn - 4); *(pBGw + 0) = *(pBGw - 1); } pScn += 8; pBGw++; // Character latch(For MMC2/MMC4) if (bChrLatch) { nes.mapper.PPU_ChrLatch((ushort)(tileadr)); } if (++ntbl_x == 32) { ntbl_x = 0; ntbladr ^= 0x41F; attradr = 0x03C0 + ((ntbladr & 0x0380) >> 4); pNTBL = MMU.PPU_MEM_BANK[ntbladr >> 10]; } else { ntbladr++; } } } else { byte* pScn = lpScanline + (8 - loopy_shift); byte* pBGw = BGwrite; int ntbladr; int tileadr; int cache_tile = unchecked((int)(0xFFFF0000)); byte cache_attr = 0xFF; chr_h = chr_l = attr = 0; ushort loopy_v_tmp = MMU.loopy_v; for (int i = 0; i < 33; i++) { if (i != 0) { nes.EmulationCPU(NES.FETCH_CYCLES * 4); } ntbladr = 0x2000 + (MMU.loopy_v & 0x0FFF); tileadr = ((MMU.PPUREG[0] & PPU_BGTBL_BIT) << 8) + MMU.PPU_MEM_BANK[ntbladr >> 10][ntbladr & 0x03FF] * 0x10 + ((MMU.loopy_v & 0x7000) >> 12); attr = (byte)(((MMU.PPU_MEM_BANK[ntbladr >> 10][0x03C0 + ((ntbladr & 0x0380) >> 4) + ((ntbladr & 0x001C) >> 2)] >> (((ntbladr & 0x40) >> 4) + (ntbladr & 0x02))) & 3) << 2); if (cache_tile != tileadr || cache_attr != attr) { cache_tile = tileadr; cache_attr = attr; chr_l = MMU.PPU_MEM_BANK[tileadr >> 10][tileadr & 0x03FF]; chr_h = MMU.PPU_MEM_BANK[tileadr >> 10][(tileadr & 0x03FF) + 8]; *pBGw = (byte)(chr_l | chr_h); fixed (byte* pBGPAL = &MMU.BGPAL[attr]) { int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); pScn[0] = pBGPAL[(c1 >> 6)]; pScn[4] = pBGPAL[(c1 >> 2) & 3]; pScn[1] = pBGPAL[(c2 >> 6)]; pScn[5] = pBGPAL[(c2 >> 2) & 3]; pScn[2] = pBGPAL[(c1 >> 4) & 3]; pScn[6] = pBGPAL[c1 & 3]; pScn[3] = pBGPAL[(c2 >> 4) & 3]; pScn[7] = pBGPAL[c2 & 3]; } } else { *(uint*)(pScn + 0) = *(uint*)(pScn - 8); *(uint*)(pScn + 4) = *(uint*)(pScn - 4); *(pBGw + 0) = *(pBGw - 1); } pScn += 8; pBGw++; // Character latch(For MMC2/MMC4) if (bChrLatch) { nes.mapper.PPU_ChrLatch((ushort)tileadr); } if ((MMU.loopy_v & 0x1F) == 0x1F) { MMU.loopy_v ^= 0x041F; } else { MMU.loopy_v++; } } MMU.loopy_v = loopy_v_tmp; } } else { // With Extension Latch(For MMC5) byte* pScn = lpScanline + (8 - loopy_shift); byte* pBGw = BGwrite; int ntbladr = 0x2000 + (MMU.loopy_v & 0x0FFF); int ntbl_x = ntbladr & 0x1F; int cache_tile = unchecked((int)0xFFFF0000); byte cache_attr = 0xFF; byte exattr = 0; chr_h = chr_l = attr = 0; for (int i = 0; i < 33; i++) { if (i != 0) { nes.EmulationCPU(NES.FETCH_CYCLES * 4); } nes.mapper.PPU_ExtLatchX(i); nes.mapper.PPU_ExtLatch((ushort)ntbladr, ref chr_l, ref chr_h, ref exattr); attr = (byte)(exattr & 0x0C); if (cache_tile != ((chr_h << 8) + chr_l) || cache_attr != attr) { cache_tile = ((chr_h << 8) + chr_l); cache_attr = attr; *pBGw = (byte)(chr_l | chr_h); fixed (byte* pBGPAL = &MMU.BGPAL[attr]) { int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); pScn[0] = pBGPAL[(c1 >> 6)]; pScn[4] = pBGPAL[(c1 >> 2) & 3]; pScn[1] = pBGPAL[(c2 >> 6)]; pScn[5] = pBGPAL[(c2 >> 2) & 3]; pScn[2] = pBGPAL[(c1 >> 4) & 3]; pScn[6] = pBGPAL[c1 & 3]; pScn[3] = pBGPAL[(c2 >> 4) & 3]; pScn[7] = pBGPAL[c2 & 3]; } } else { *(uint*)(pScn + 0) = *(uint*)(pScn - 8); *(uint*)(pScn + 4) = *(uint*)(pScn - 4); *(pBGw + 0) = *(pBGw - 1); } pScn += 8; pBGw++; if (++ntbl_x == 32) { ntbl_x = 0; ntbladr ^= 0x41F; } else { ntbladr++; } } } } if ((MMU.PPUREG[1] & PPU_BGCLIP_BIT) == 0 && bLeftClip) { byte* pScn = lpScanline + 8; for (int i = 0; i < 8; i++) { pScn[i] = MMU.BGPAL[0]; } } } // Render sprites var temp = ~PPU_SPMAX_FLAG; MMU.PPUREG[2] &= (byte)(MMU.PPUREG[2] & temp); // 昞帵婜娫奜偱偁傟偽僉儍儞僙儖 if (scanline > 239) return; if ((MMU.PPUREG[1] & PPU_SPDISP_BIT) == 0) { return; } int spmax = 0; int spraddr = 0, sp_y = 0, sp_h = 0; chr_h = chr_l = 0; fixed (byte* pBit2Rev = &Bit2Rev[0]) { byte* pBGw = BGwrite; byte* pSPw = SPwrite; Unsafe.InitBlockUnaligned(pSPw, 0, 34); spmax = 0; Sprite sp = new Sprite(MMU.SPRAM, 0); sp_h = (MMU.PPUREG[0] & PPU_SP16_BIT) != 0 ? 15 : 7; // Left clip if (bLeftClip && ((MMU.PPUREG[1] & PPU_SPCLIP_BIT) == 0)) { SPwrite[0] = 0xFF; } for (int i = 0; i < 64; i++, sp.AddOffset(1)) { sp_y = scanline - (sp.y + 1); // 僗僉儍儞儔僀儞撪偵SPRITE偑懚嵼偡傞偐傪僠僃僢僋 if (sp_y != (sp_y & sp_h)) continue; if ((MMU.PPUREG[0] & PPU_SP16_BIT) == 0) { // 8x8 Sprite spraddr = ((MMU.PPUREG[0] & PPU_SPTBL_BIT) << 9) + (sp.tile << 4); if ((sp.attr & SP_VMIRROR_BIT) == 0) spraddr += sp_y; else spraddr += 7 - sp_y; } else { // 8x16 Sprite spraddr = ((sp.tile & 1) << 12) + ((sp.tile & 0xFE) << 4); if ((sp.attr & SP_VMIRROR_BIT) == 0) spraddr += ((sp_y & 8) << 1) + (sp_y & 7); else spraddr += ((~sp_y & 8) << 1) + (7 - (sp_y & 7)); } // Character pattern chr_l = MMU.PPU_MEM_BANK[spraddr >> 10][spraddr & 0x3FF]; chr_h = MMU.PPU_MEM_BANK[spraddr >> 10][(spraddr & 0x3FF) + 8]; // Character latch(For MMC2/MMC4) if (bChrLatch) { nes.mapper.PPU_ChrLatch((ushort)spraddr); } // pattern mask if ((sp.attr & SP_HMIRROR_BIT) != 0) { chr_l = pBit2Rev[chr_l]; chr_h = pBit2Rev[chr_h]; } byte SPpat = (byte)(chr_l | chr_h); // Sprite hitcheck if (i == 0 && (MMU.PPUREG[2] & PPU_SPHIT_FLAG) == 0) { int BGpos = ((sp.x & 0xF8) + ((loopy_shift + (sp.x & 7)) & 8)) >> 3; int BGsft = 8 - ((loopy_shift + sp.x) & 7); byte BGmsk = (byte)(((pBGw[BGpos + 0] << 8) | pBGw[BGpos + 1]) >> BGsft); if ((SPpat & BGmsk) != 0) { MMU.PPUREG[2] |= PPU_SPHIT_FLAG; } } // Sprite mask int SPpos = sp.x / 8; int SPsft = 8 - (sp.x & 7); byte SPmsk = (byte)(((pSPw[SPpos + 0] << 8) | pSPw[SPpos + 1]) >> SPsft); ushort SPwrt = (ushort)(SPpat << SPsft); pSPw[SPpos + 0] = (byte)((pSPw[SPpos + 0]) | (SPwrt >> 8)); pSPw[SPpos + 1] = (byte)((pSPw[SPpos + 1]) | (SPwrt & 0xFF)); SPpat = (byte)(SPpat & ~SPmsk); if ((sp.attr & SP_PRIORITY_BIT) != 0) { // BG > SP priority int BGpos = ((sp.x & 0xF8) + ((loopy_shift + (sp.x & 7)) & 8)) >> 3; int BGsft = 8 - ((loopy_shift + sp.x) & 7); byte BGmsk = (byte)(((pBGw[BGpos + 0] << 8) | pBGw[BGpos + 1]) >> BGsft); SPpat = (byte)(SPpat & ~BGmsk); } // Attribute fixed (byte* pSPPAL = &MMU.SPPAL[(sp.attr & SP_COLOR_BIT) << 2]) { // Ptr byte* pScn = lpScanline + sp.x + 8; if (!bExtMono) { int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); if ((SPpat & 0x80) != 0) pScn[0] = pSPPAL[(c1 >> 6)]; if ((SPpat & 0x08) != 0) pScn[4] = pSPPAL[(c1 >> 2) & 3]; if ((SPpat & 0x40) != 0) pScn[1] = pSPPAL[(c2 >> 6)]; if ((SPpat & 0x04) != 0) pScn[5] = pSPPAL[(c2 >> 2) & 3]; if ((SPpat & 0x20) != 0) pScn[2] = pSPPAL[(c1 >> 4) & 3]; if ((SPpat & 0x02) != 0) pScn[6] = pSPPAL[c1 & 3]; if ((SPpat & 0x10) != 0) pScn[3] = pSPPAL[(c2 >> 4) & 3]; if ((SPpat & 0x01) != 0) pScn[7] = pSPPAL[c2 & 3]; } else { // Monocrome effect (for Final Fantasy) byte mono = BGmono[((sp.x & 0xF8) + ((loopy_shift + (sp.x & 7)) & 8)) >> 3]; int c1 = ((chr_l >> 1) & 0x55) | (chr_h & 0xAA); int c2 = (chr_l & 0x55) | ((chr_h << 1) & 0xAA); if ((SPpat & 0x80) != 0) pScn[0] = (byte)(pSPPAL[c1>>6] |mono); if ((SPpat & 0x08) != 0) pScn[4] = (byte)(pSPPAL[(c1>>2)&3] |mono); if ((SPpat & 0x40) != 0) pScn[1] = (byte)(pSPPAL[c2>>6] |mono); if ((SPpat & 0x04) != 0) pScn[5] = (byte)(pSPPAL[(c2>>2)&3] |mono); if ((SPpat & 0x20) != 0) pScn[2] = (byte)(pSPPAL[(c1>>4)&3] |mono); if ((SPpat & 0x02) != 0) pScn[6] = (byte)(pSPPAL[c1&3] |mono); if ((SPpat & 0x10) != 0) pScn[3] = (byte)(pSPPAL[(c2>>4)&3] |mono); if ((SPpat & 0x01) != 0) pScn[7] = (byte)(pSPPAL[c2 & 3] | mono); } } if (++spmax > 8 - 1) { if (!bMax) break; } } if (spmax > 8 - 1) { MMU.PPUREG[2] |= PPU_SPMAX_FLAG; } } } internal bool IsSprite0(int scanline) { // 僗僾儔僀僩orBG旕昞帵偼僉儍儞僙儖(僸僢僩偟側偄) if ((MMU.PPUREG[1] & (PPU_SPDISP_BIT | PPU_BGDISP_BIT)) != (PPU_SPDISP_BIT | PPU_BGDISP_BIT)) return false; // 婛偵僸僢僩偟偰偄偨傜僉儍儞僙儖 if ((MMU.PPUREG[2] & PPU_SPHIT_FLAG) != 0) return false; if ((MMU.PPUREG[0] & PPU_SP16_BIT) == 0) { // 8x8 if ((scanline < MMU.SPRAM[0] + 1) || (scanline > (MMU.SPRAM[0] + 7 + 1))) return false; } else { // 8x16 if ((scanline < MMU.SPRAM[0] + 1) || (scanline > (MMU.SPRAM[0] + 15 + 1))) return false; } return true; } internal void DummyScanline(int scanline) { int i; int spmax; int sp_h; MMU.PPUREG[2] = (byte)(MMU.PPUREG[2] & ~PPU_SPMAX_FLAG); // 僗僾儔僀僩旕昞帵偼僉儍儞僙儖 if ((MMU.PPUREG[1] & PPU_SPDISP_BIT) == 0) return; // 昞帵婜娫奜偱偁傟偽僉儍儞僙儖 if (scanline < 0 || scanline > 239) return; Sprite sp = new Sprite(MMU.SPRAM, 0); sp_h = (MMU.PPUREG[0] & PPU_SP16_BIT) != 0 ? 15 : 7; spmax = 0; // Sprite Max check for (i = 0; i < 64; i++, sp.AddOffset(1)) { // 僗僉儍儞儔僀儞撪偵SPRITE偑懚嵼偡傞偐傪僠僃僢僋 if ((scanline < sp.y + 1) || (scanline > (sp.y + sp_h + 1))) { continue; } if (++spmax > 8 - 1) { MMU.PPUREG[2] |= PPU_SPMAX_FLAG; break; } } } internal void VBlankEnd() { MMU.PPUREG[2] = (byte)(MMU.PPUREG[2] & ~PPU_VBLANK_FLAG); // VBlank扙弌帪偵僋儕傾偝傟傞 // 僄僉僒僀僩僶僀僋偱廳梫 MMU.PPUREG[2] = (byte)(MMU.PPUREG[2] & ~PPU_SPHIT_FLAG); } internal void VBlankStart() { MMU.PPUREG[2] |= PPU_VBLANK_FLAG; } public byte* GetScreenPtr() { return lpScreen; } public byte[] GetLineColorMode() { return lpColormode; } internal void SetScreenPtr(byte[] screenBuffer, byte[] colormode) { lpScreenGCH = GCHandle.Alloc(screenBuffer, GCHandleType.Pinned); lpScreen = (byte*)lpScreenGCH.AddrOfPinnedObject(); lpColormode = colormode; } internal bool IsDispON() { return (MMU.PPUREG[1] & (PPU_BGDISP_BIT | PPU_SPDISP_BIT)) != 0; } internal void SetExtLatchMode(bool bMode) { bExtLatch = bMode; } internal ushort GetPPUADDR() { return MMU.loopy_v; } internal ushort GetTILEY() { return loopy_y; } internal void SetChrLatchMode(bool bMode) { bChrLatch = bMode; } internal void SetExtNameTableMode(bool bMode) { bExtNameTable = bMode; } internal void SetExtMonoMode(bool bMode) { bExtMono = bMode; } internal int GetScanlineNo() { return ScanlineNo; } public struct Sprite { public byte y { get => raw[offset + 0]; set => raw[offset + 0] = value; } public byte tile { get => raw[offset + 1]; set => raw[offset + 1] = value; } public byte attr { get => raw[offset + 2]; set => raw[offset + 2] = value; } public byte x { get => raw[offset + 3]; set => raw[offset + 3] = value; } private byte[] raw; private int offset; public Sprite(byte[] raw, int offset) { this.raw = raw; this.offset = offset * 4; } public void AddOffset(int offset) { this.offset += offset * 4; } } } }