//#define DEBUG_OCCLUSION using System; using ClassicalSharp.GraphicsAPI; using OpenTK; namespace ClassicalSharp { ///

Class responsible for converting a 16x16x16 into an optimised mesh of vertices.

/// This class is heavily optimised and as such may suffer from slightly unreadable code. public partial class ChunkMeshBuilder { int X, Y, Z; float x1, y1, z1, x2, y2, z2; byte tile; BlockInfo info; Map map; Game game; IGraphicsApi graphics; const int chunkSize = 16, extChunkSize = 18; const int chunkSize2 = 16 * 16, extChunkSize2 = 18 * 18; const int chunkSize3 = 16 * 16 * 16, extChunkSize3 = 18 * 18 * 18; public ChunkMeshBuilder( Game game ) { this.game = game; graphics = game.Graphics; info = game.BlockInfo; game.Events.TerrainAtlasChanged += TerrainAtlasChanged; } internal int width, length, height, clipLevel; int maxX, maxY, maxZ; byte[] counts = new byte[chunkSize3 * TileSide.Sides]; byte[] chunk = new byte[extChunkSize3]; bool BuildChunk( int x1, int y1, int z1 ) { PreStretchTiles( x1, y1, z1 ); if( ReadChunkData( x1, y1, z1 ) ) return false; Stretch( x1, y1, z1 ); PostStretchTiles( x1, y1, z1 ); int xMax = Math.Min( width, x1 + chunkSize ); int yMax = Math.Min( height, y1 + chunkSize ); int zMax = Math.Min( length, z1 + chunkSize ); for( int y = y1, yy = 0; y < yMax; y++, yy++ ) { for( int z = z1, zz = 0; z < zMax; z++, zz++ ) { int chunkIndex = (yy + 1) * extChunkSize2 + (zz + 1) * extChunkSize + (0 + 1); for( int x = x1, xx = 0; x < xMax; x++, xx++ ) { tile = chunk[chunkIndex]; if( tile != 0 ) RenderTile( chunkIndex, xx, yy, zz, x, y, z ); chunkIndex++; } } } return true; } unsafe bool ReadChunkData( int x1, int y1, int z1 ) { bool allAir = true, allSolid = true; fixed( byte* chunkPtr = chunk, mapPtr = map.mapData ) { int* chunkIntPtr = (int*)chunkPtr; for( int i = 0; i < extChunkSize3 / sizeof( int ); i++ ) { *chunkIntPtr++ = 0; } for( int yy = -1; yy < 17; yy++ ) { int y = yy + y1; if( y < 0 ) continue; if( y > maxY ) break; for( int zz = -1; zz < 17; zz++ ) { int z = zz + z1; if( z < 0 ) continue; if( z > maxZ ) break; int index = ( y * length + z ) * width + ( x1 - 1 - 1 ); int chunkIndex = ( yy + 1 ) * extChunkSize2 + ( zz + 1 ) * extChunkSize + ( -1 + 1 ) - 1; for( int xx = -1; xx < 17; xx++ ) { int x = xx + x1; index++; chunkIndex++; if( x < 0 ) continue; if( x > maxX ) break; byte block = mapPtr[index]; if( block == 9 ) block = 8; // Still water --> Water if( block == 11 ) block = 10; // Still lava --> Lava if( allAir && block != 0 ) allAir = false; if( allSolid && !info.IsOpaque[block] ) allSolid = false; chunkPtr[chunkIndex] = block; } } } if( x1 == 0 || y1 == 0 || z1 == 0 || x1 + chunkSize >= width || y1 + chunkSize >= height || z1 + chunkSize >= length ) allSolid = false; if( !( allAir || allSolid ) ) { map.HeightmapHint( x1 - 1, z1 - 1, mapPtr ); } } return allAir || allSolid; } public void GetDrawInfo( int x, int y, int z, ref ChunkPartInfo[] normalParts, ref ChunkPartInfo[] translucentParts, ref byte occlusionFlags ) { if( !BuildChunk( x, y, z ) ) return; for( int i = 0; i < arraysCount; i++ ) { SetPartInfo( drawInfoNormal[i], i, ref normalParts ); SetPartInfo( drawInfoTranslucent[i], i, ref translucentParts ); } if( normalParts != null || translucentParts != null ) occlusionFlags = 0;//(byte)ComputeOcclusion(); } Vector3 minBB, maxBB; public void RenderTile( int chunkIndex, int xx, int yy, int zz, int x, int y, int z ) { X = x; Y = y; Z = z; int index = ((yy << 8) | (zz << 4) | xx) * TileSide.Sides; if( info.IsSprite[tile] ) { fullBright = info.FullBright[tile]; int count = counts[index + TileSide.Top]; if( count != 0 ) DrawSprite( count ); return; } int leftCount = counts[index++], rightCount = counts[index++], frontCount = counts[index++], backCount = counts[index++], bottomCount = counts[index++], topCount = counts[index++]; if( leftCount == 0 && rightCount == 0 && frontCount == 0 && backCount == 0 && bottomCount == 0 && topCount == 0 ) return; Vector3 min = info.MinBB[tile], max = info.MaxBB[tile]; x1 = x + min.X; y1 = y + min.Y; z1 = z + min.Z; x2 = x + max.X; y2 = y + max.Y; z2 = z + max.Z; this.minBB = min; this.maxBB = max; fullBright = info.FullBright[tile]; isTranslucent = info.IsTranslucent[tile]; lightFlags = info.LightOffset[tile]; if( leftCount != 0 ) DrawLeftFace( leftCount ); if( rightCount != 0 ) DrawRightFace( rightCount ); if( frontCount != 0 ) DrawFrontFace( frontCount ); if( backCount != 0 ) DrawBackFace( backCount ); if( bottomCount != 0 ) DrawBottomFace( bottomCount ); if( topCount != 0 ) DrawTopFace( topCount ); } void Stretch( int x1, int y1, int z1 ) { for( int i = 0; i < counts.Length; i++ ) { counts[i] = 1; } int xMax = Math.Min( width, x1 + chunkSize ); int yMax = Math.Min( height, y1 + chunkSize ); int zMax = Math.Min( length, z1 + chunkSize ); #if DEBUG_OCCLUSION int flags = ComputeOcclusion(); FastColour col = new FastColour( 60, 60, 60, 255 ); if( (flags & 1) != 0 ) col.R = 255; // x if( (flags & 4) != 0 ) col.G = 255; // y if( (flags & 2) != 0 ) col.B = 255; // z map.Sunlight = map.Shadowlight = col; map.SunlightXSide = map.ShadowlightXSide = col; map.SunlightZSide = map.ShadowlightZSide = col; map.SunlightYBottom = map.ShadowlightYBottom = col; #endif for( int y = y1, yy = 0; y < yMax; y++, yy++ ) { for( int z = z1, zz = 0; z < zMax; z++, zz++ ) { int chunkIndex = (yy + 1) * extChunkSize2 + (zz + 1) * extChunkSize + (-1 + 1); for( int x = x1, xx = 0; x < xMax; x++, xx++ ) { chunkIndex++; byte tile = chunk[chunkIndex]; if( tile == 0 ) continue; int countIndex = ((yy << 8) + (zz << 4) + xx) * TileSide.Sides; // Sprites only use one face to indicate stretching count, so we can take a shortcut here. // Note that sprites are not drawn with any of the DrawXFace, they are drawn using DrawSprite. if( info.IsSprite[tile] ) { countIndex += TileSide.Top; if( counts[countIndex] != 0 ) { X = x; Y = y; Z = z; AddSpriteVertices( tile, 1 ); counts[countIndex] = 1; } } else { X = x; Y = y; Z = z; fullBright = info.FullBright[tile]; TestAndStretchZ( zz, countIndex, tile, chunkIndex, x, 0, TileSide.Left, -1 ); TestAndStretchZ( zz, countIndex, tile, chunkIndex, x, maxX, TileSide.Right, 1 ); TestAndStretchX( xx, countIndex, tile, chunkIndex, z, 0, TileSide.Front, -extChunkSize ); TestAndStretchX( xx, countIndex, tile, chunkIndex, z, maxZ, TileSide.Back, extChunkSize ); if( y > 0 ) TestAndStretchX( xx, countIndex, tile, chunkIndex, y, 0, TileSide.Bottom, -extChunkSize2 ); else counts[countIndex + TileSide.Bottom] = 0; TestAndStretchX( xx, countIndex, tile, chunkIndex, y, maxY + 2, TileSide.Top, extChunkSize2 ); } } } } } void TestAndStretchX( int xx, int index, byte tile, int chunkIndex, int value, int test, int tileSide, int offset ) { index += tileSide; if( counts[index] != 0 ) { if( (value == test && Y < clipLevel) || (value != test && info.IsFaceHidden( tile, chunk[chunkIndex + offset], tileSide )) ) { counts[index] = 0; } else { int count = StretchX( xx, index, X, Y, Z, chunkIndex, tile, tileSide ); AddVertices( tile, count, tileSide ); counts[index] = (byte)count; } } } void TestAndStretchZ( int zz, int index, byte tile, int chunkIndex, int value, int test, int tileSide, int offset ) { index += tileSide; if( counts[index] != 0 ) { if( (value == test && Y < clipLevel) || (value != test && info.IsFaceHidden( tile, chunk[chunkIndex + offset], tileSide )) ) { counts[index] = 0; } else { int count = StretchZ( zz, index, X, Y, Z, chunkIndex, tile, tileSide ); AddVertices( tile, count, tileSide ); counts[index] = (byte)count; } } } byte GetNeighbour( int chunkIndex, int face ) { switch( face ) { case TileSide.Left: return chunk[chunkIndex - 1]; // x - 1 case TileSide.Right: return chunk[chunkIndex + 1]; // x + 1 case TileSide.Front: return chunk[chunkIndex - 18]; // z - 1 case TileSide.Back: return chunk[chunkIndex + 18]; // z + 1 case TileSide.Bottom: return chunk[chunkIndex - 324]; // y - 1 case TileSide.Top: return chunk[chunkIndex + 324]; // y + 1 } return 0; } int StretchX( int xx, int countIndex, int x, int y, int z, int chunkIndex, byte tile, int face ) { int count = 1; x++; chunkIndex++; countIndex += TileSide.Sides; int max = chunkSize - xx; bool stretchTile = info.CanStretch[tile * TileSide.Sides + face]; while( count < max && x < width && stretchTile && CanStretch( tile, chunkIndex, x, y, z, face ) ) { counts[countIndex] = 0; count++; x++; chunkIndex++; countIndex += TileSide.Sides; } return count; } int StretchZ( int zz, int countIndex, int x, int y, int z, int chunkIndex, byte tile, int face ) { int count = 1; z++; chunkIndex += extChunkSize; countIndex += chunkSize * TileSide.Sides; int max = chunkSize - zz; bool stretchTile = info.CanStretch[tile * TileSide.Sides + face]; while( count < max && z < length && stretchTile && CanStretch( tile, chunkIndex, x, y, z, face ) ) { counts[countIndex] = 0; count++; z++; chunkIndex += extChunkSize; countIndex += chunkSize * TileSide.Sides; } return count; } public void OnNewMap() { } public void OnNewMapLoaded() { map = game.Map; width = map.Width; height = map.Height; length = map.Length; clipLevel = Math.Max( 0, game.Map.SidesHeight ); maxX = width - 1; maxY = height - 1; maxZ = length - 1; } } public struct ChunkPartInfo { public int VbId, IndicesCount; public int leftIndex, rightIndex, frontIndex, backIndex, bottomIndex, topIndex; public ushort leftCount, rightCount, frontCount, backCount, bottomCount, topCount, spriteCount; } }