package makamys.neodymium.renderer; import static org.lwjgl.opengl.GL11.*; import static org.lwjgl.opengl.GL14.*; import static org.lwjgl.opengl.GL15.*; import static org.lwjgl.opengl.GL20.*; import static org.lwjgl.opengl.GL30.*; import java.nio.FloatBuffer; import java.nio.IntBuffer; import java.nio.file.Path; import java.util.ArrayList; import java.util.Arrays; import java.util.Collections; import java.util.Comparator; import java.util.HashMap; import java.util.HashSet; import java.util.Iterator; import java.util.List; import java.util.Map; import java.util.Queue; import java.util.Set; import java.util.concurrent.ConcurrentLinkedQueue; import org.lwjgl.BufferUtils; import org.lwjgl.input.Keyboard; import org.lwjgl.opengl.GL11; import org.lwjgl.util.vector.Matrix4f; import makamys.neodymium.Config; import makamys.neodymium.Neodymium; import makamys.neodymium.ducks.IWorldRenderer; import makamys.neodymium.renderer.Mesh.GPUStatus; import makamys.neodymium.util.GuiHelper; import makamys.neodymium.util.Preprocessor; import makamys.neodymium.util.Util; import net.minecraft.block.Block; import net.minecraft.block.material.Material; import net.minecraft.client.Minecraft; import net.minecraft.client.renderer.WorldRenderer; import net.minecraft.client.renderer.texture.TextureAtlasSprite; import net.minecraft.client.renderer.texture.TextureMap; import net.minecraft.entity.Entity; import net.minecraft.entity.EntityLivingBase; import net.minecraft.util.EnumFacing; import net.minecraft.world.ChunkCoordIntPair; import net.minecraft.world.IBlockAccess; import net.minecraft.world.World; import net.minecraft.world.chunk.Chunk; import net.minecraft.world.gen.ChunkProviderServer; import net.minecraftforge.event.world.ChunkEvent; /** The main renderer class. */ public class NeoRenderer { public boolean hasInited = false; public boolean destroyPending; private boolean[] wasDown = new boolean[256]; private int renderQuads = 0; public boolean renderWorld; public boolean rendererActive; private boolean showMemoryDebugger; private static int MAX_MESHES = 100000; private int VAO, shaderProgram; private IntBuffer[] piFirst = new IntBuffer[2]; private IntBuffer[] piCount = new IntBuffer[2]; private List[] sentMeshes = (List[])new ArrayList[] {new ArrayList(), new ArrayList()}; GPUMemoryManager mem; List myChunks = new ArrayList(); List pendingLODChunks = new ArrayList<>(); private boolean hasServerInited = false; private Map loadedRegionsMap = new HashMap<>(); public World world; // TODO make these packets to make this work on dedicated servers Queue farChunks = new ConcurrentLinkedQueue<>(); List serverChunkLoadQueue = new ArrayList<>(); private double lastSortX = Double.NaN; private double lastSortY = Double.NaN; private double lastSortZ = Double.NaN; private double interpX; private double interpY; private double interpZ; int interpXDiv; int interpYDiv; int interpZDiv; private long lastGCTime = -1; private long lastSaveTime = -1; private long gcInterval = 10 * 1000; private long saveInterval = 60 * 1000; private int renderedMeshes, renderedQuads; private int frameCount; public int renderRange = 48; // unused LOD thing.. private boolean freezeMeshes; public NeoRenderer(World world){ this.world = world; if(shouldRenderInWorld(world)) { hasInited = init(); } renderWorld = true; rendererActive = true; } public void preRenderSortedRenderers(int renderPass, double alpha, WorldRenderer[] sortedWorldRenderers) { if(renderPass != 0) return; Neodymium.fogEventWasPosted = false; renderedMeshes = 0; renderedQuads = 0; Minecraft.getMinecraft().entityRenderer.enableLightmap((double)alpha); if(hasInited) { mainLoop(); if(Minecraft.getMinecraft().currentScreen == null) { handleKeyboard(); } if(mem.getCoherenceRate() < 0.95f || frameCount % 4 == 0) { mem.runGC(false); } lastGCTime = System.currentTimeMillis(); if(lastSaveTime == -1 || (System.currentTimeMillis() - lastSaveTime) > saveInterval && Config.saveMeshes) { onSave(); lastSaveTime = System.currentTimeMillis(); } if(rendererActive && renderWorld) { Entity rve = Minecraft.getMinecraft().renderViewEntity; interpX = rve.lastTickPosX + (rve.posX - rve.lastTickPosX) * alpha; interpY = rve.lastTickPosY + (rve.posY - rve.lastTickPosY) * alpha + rve.getEyeHeight(); interpZ = rve.lastTickPosZ + (rve.posZ - rve.lastTickPosZ) * alpha; interpXDiv = Math.floorDiv((int)Math.floor(interpX), 16); interpYDiv = Math.floorDiv((int)Math.floor(interpY), 16); interpZDiv = Math.floorDiv((int)Math.floor(interpZ), 16); if(frameCount % Config.sortFrequency == 0) { sort(); } updateMeshes(); initIndexBuffers(); render(alpha); } } frameCount++; Minecraft.getMinecraft().entityRenderer.disableLightmap((double)alpha); } public void onRenderTickEnd() { if(destroyPending) { destroy(); Neodymium.renderer = null; return; } if(showMemoryDebugger && mem != null) { GuiHelper.begin(); mem.drawInfo(); GuiHelper.end(); } } private void sort() { Entity player = Minecraft.getMinecraft().renderViewEntity; for(List list : sentMeshes) { list.sort(new MeshDistanceComparator(Math.floor(player.posX / 16.0), Math.floor(player.posY / 16.0), Math.floor(player.posZ / 16.0))); } } private void updateMeshes() { for(List list : sentMeshes) { for(Mesh mesh : list) { mesh.update(); } } } private static int[] renderedMeshesReturn = new int[1]; private static int[] renderedQuadsReturn = new int[1]; private void initIndexBuffers() { for(int i = 0; i < 2; i++) { piFirst[i].limit(MAX_MESHES); piCount[i].limit(MAX_MESHES); for(Mesh mesh : sentMeshes[i]) { if(mesh.visible && (Config.maxMeshesPerFrame == -1 || renderedMeshes < Config.maxMeshesPerFrame)) { mesh.writeToIndexBuffer(piFirst[i], piCount[i], renderedMeshesReturn, renderedQuadsReturn, interpXDiv, interpYDiv, interpZDiv); renderedMeshes += renderedMeshesReturn[0]; renderedQuads += renderedQuadsReturn[0]; } } piFirst[i].flip(); piCount[i].flip(); } } private boolean isNormalMeshVisible(Mesh mesh) { switch(mesh.normal) { case POSITIVE_X: return interpXDiv >= ((mesh.x + 0)); case NEGATIVE_X: return interpXDiv < ((mesh.x + 1)); case POSITIVE_Y: return interpYDiv >= ((mesh.y + 0)); case NEGATIVE_Y: return interpYDiv < ((mesh.y + 1)); case POSITIVE_Z: return interpZDiv >= ((mesh.z + 0)); case NEGATIVE_Z: return interpZDiv < ((mesh.z + 1)); default: return true; } } private void mainLoop() { /*while(!farChunks.isEmpty()) { NeoChunk lodChunk = receiveFarChunk(farChunks.remove()); sendChunkToGPU(lodChunk); }*/ if(Minecraft.getMinecraft().playerController.netClientHandler.doneLoadingTerrain) { Entity player = Minecraft.getMinecraft().renderViewEntity; List newServerChunkLoadQueue = new ArrayList<>(); if(Double.isNaN(lastSortX) || getLastSortDistanceSq(player) > 16 * 16) { /*int centerX = (int)Math.floor(player.posX / 16.0); int centerZ = (int)Math.floor(player.posZ / 16.0); for(int x = -renderRange; x <= renderRange; x++) { for(int z = -renderRange; z <= renderRange; z++) { if(x * x + z * z < renderRange * renderRange) { int chunkX = centerX + x; int chunkZ = centerZ + z; if(getLODChunk(chunkX, chunkZ).needsChunk) { newServerChunkLoadQueue.add(new ChunkCoordIntPair(chunkX, chunkZ)); getLODChunk(chunkX, chunkZ).needsChunk = false; } } } } Collections.sort(newServerChunkLoadQueue, new ChunkCoordDistanceComparator(player.posX, player.posY, player.posZ)); addToServerChunkLoadQueue(newServerChunkLoadQueue); lastSortX = player.posX; lastSortY = player.posY; lastSortZ = player.posZ;*/ for(Iterator it = loadedRegionsMap.keySet().iterator(); it.hasNext();) { ChunkCoordIntPair k = it.next(); NeoRegion v = loadedRegionsMap.get(k); if(v.isEmpty()) { v.destroy(getSaveDir()); it.remove(); } else { v.tick(player); } } } } } public float getFarPlaneDistanceMultiplier() { return (float)Config.farPlaneDistanceMultiplier; } public void afterSetupFog(int mode, float alpha, float farPlaneDistance) { EntityLivingBase entity = Minecraft.getMinecraft().renderViewEntity; if(Neodymium.fogEventWasPosted && !Minecraft.getMinecraft().theWorld.provider.doesXZShowFog((int)entity.posX, (int)entity.posZ)) { GL11.glFogf(GL11.GL_FOG_START, mode < 0 ? 0 : farPlaneDistance * (float)Config.fogStart); GL11.glFogf(GL11.GL_FOG_END, mode < 0 ? farPlaneDistance/4 : farPlaneDistance * (float)Config.fogEnd); } } private void handleKeyboard() { if(Config.debugPrefix == 0 || (Config.debugPrefix != -1 && Keyboard.isKeyDown(Config.debugPrefix))) { if(Keyboard.isKeyDown(Keyboard.KEY_F) && !wasDown[Keyboard.KEY_F]) { rendererActive = !rendererActive; } if(Keyboard.isKeyDown(Keyboard.KEY_V) && !wasDown[Keyboard.KEY_V]) { renderWorld = !renderWorld; } if(Keyboard.isKeyDown(Keyboard.KEY_R) && !wasDown[Keyboard.KEY_R]) { reloadShader(); } if(Keyboard.isKeyDown(Keyboard.KEY_M) && !wasDown[Keyboard.KEY_M]) { showMemoryDebugger = !showMemoryDebugger; //LODChunk chunk = getLODChunk(9, -18); //setMeshVisible(chunk.chunkMeshes[7], false, true); //freezeMeshes = false; //chunk.chunkMeshes[7].quadCount = 256; //setMeshVisible(chunk.chunkMeshes[7], true, true); } } for(int i = 0; i < 256; i++) { wasDown[i] = Keyboard.isKeyDown(i); } } FloatBuffer modelView = BufferUtils.createFloatBuffer(16); FloatBuffer projBuf = BufferUtils.createFloatBuffer(16); IntBuffer viewportBuf = BufferUtils.createIntBuffer(16); FloatBuffer projInvBuf = BufferUtils.createFloatBuffer(16); FloatBuffer fogColorBuf = BufferUtils.createFloatBuffer(16); FloatBuffer fogStartEnd = BufferUtils.createFloatBuffer(2); Matrix4f projMatrix = new Matrix4f(); private void render(double alpha) { if(shaderProgram == 0) return; GL11.glPushAttrib(GL11.GL_ENABLE_BIT); GL11.glDisable(GL11.GL_TEXTURE_2D); glUseProgram(shaderProgram); updateUniforms(alpha); renderMeshes(); glUseProgram(0); GL11.glDepthMask(true); GL11.glPopAttrib(); } private void updateUniforms(double alpha) { int u_modelView = glGetUniformLocation(shaderProgram, "modelView"); int u_proj = glGetUniformLocation(shaderProgram, "proj"); int u_playerPos = glGetUniformLocation(shaderProgram, "playerPos"); int u_light = glGetUniformLocation(shaderProgram, "lightTex"); int u_viewport = glGetUniformLocation(shaderProgram, "viewport"); int u_projInv = glGetUniformLocation(shaderProgram, "projInv"); int u_fogColor = glGetUniformLocation(shaderProgram, "fogColor"); int u_fogStartEnd = glGetUniformLocation(shaderProgram, "fogStartEnd"); glGetFloat(GL_MODELVIEW_MATRIX, modelView); glGetFloat(GL_PROJECTION_MATRIX, projBuf); glGetInteger(GL_VIEWPORT, viewportBuf); projMatrix.load(projBuf); projBuf.flip(); projMatrix.invert(); projMatrix.store(projInvBuf); projInvBuf.flip(); fogColorBuf.limit(16); glGetFloat(GL_FOG_COLOR, fogColorBuf); fogColorBuf.limit(4); if(Config.renderFog) { fogStartEnd.put(glGetFloat(GL_FOG_START)); fogStartEnd.put(glGetFloat(GL_FOG_END)); } else { fogStartEnd.put(-1); fogStartEnd.put(-1); } fogStartEnd.flip(); glUniformMatrix4(u_modelView, false, modelView); glUniformMatrix4(u_proj, false, projBuf); glUniformMatrix4(u_projInv, false, projInvBuf); glUniform4f(u_viewport, viewportBuf.get(0),viewportBuf.get(1),viewportBuf.get(2),viewportBuf.get(3)); glUniform4(u_fogColor, fogColorBuf); glUniform2(u_fogStartEnd, fogStartEnd); float originX = 0; float originY = 0; float originZ = 0; glUniform3f(u_playerPos, (float)interpX - originX, (float)interpY - originY, (float)interpZ - originZ); glUniform1i(u_light, 1); modelView.position(0); projBuf.position(0); viewportBuf.position(0); projInvBuf.position(0); fogColorBuf.position(0); fogStartEnd.position(0); } private void renderMeshes() { glBindVertexArray(VAO); GL11.glDisable(GL11.GL_BLEND); if(Config.wireframe) { GL11.glPolygonMode(GL11.GL_FRONT_AND_BACK, GL11.GL_LINE); } glMultiDrawArrays(GL_QUADS, piFirst[0], piCount[0]); if(Config.wireframe) { GL11.glPolygonMode(GL11.GL_FRONT_AND_BACK, GL11.GL_FILL); } GL11.glEnable(GL11.GL_BLEND); GL11.glBlendFunc(GL11.GL_SRC_ALPHA, GL11.GL_ONE_MINUS_SRC_ALPHA); if(Config.wireframe) { GL11.glPolygonMode(GL11.GL_FRONT_AND_BACK, GL11.GL_LINE); } glMultiDrawArrays(GL_QUADS, piFirst[1], piCount[1]); if(Config.wireframe) { GL11.glPolygonMode(GL11.GL_FRONT_AND_BACK, GL11.GL_FILL); } glBindVertexArray(0); } public boolean init() { Map uploadedSprites = ((TextureMap)Minecraft.getMinecraft().getTextureManager().getTexture(TextureMap.locationBlocksTexture)).mapUploadedSprites; reloadShader(); VAO = glGenVertexArrays(); glBindVertexArray(VAO); mem = new GPUMemoryManager(); glBindBuffer(GL_ARRAY_BUFFER, mem.VBO); int stride = MeshQuad.getStride(); glVertexAttribPointer(0, 3, GL_FLOAT, false, stride, 0); glVertexAttribPointer(1, 2, GL_FLOAT, false, stride, 3 * 4); glVertexAttribPointer(2, 2, GL_SHORT, false, stride, 5 * 4); glVertexAttribPointer(3, 4, GL_UNSIGNED_BYTE, false, stride, 6 * 4); glVertexAttribPointer(4, 4, GL_UNSIGNED_BYTE, false, stride, 7 * 4); // we only need 2 bytes for attribute 4, but GL freaks out if the stride isn't a multiple of 4, so we have 2 unused bytes glEnableVertexAttribArray(0); glEnableVertexAttribArray(1); glEnableVertexAttribArray(2); glEnableVertexAttribArray(3); glEnableVertexAttribArray(4); for(int i = 0; i < 2; i++) { piFirst[i] = BufferUtils.createIntBuffer(MAX_MESHES); piFirst[i].flip(); piCount[i] = BufferUtils.createIntBuffer(MAX_MESHES); piCount[i].flip(); } glBindBuffer(GL_ARRAY_BUFFER, 0); glBindVertexArray(0); return true; } public void reloadShader() { Set defines = new HashSet<>(); if(Config.renderFog) { defines.add("RENDER_FOG"); } if(Config.simplifyChunkMeshes) { defines.add("SIMPLIFY_MESHES"); } boolean errors = false; int vertexShader; vertexShader = glCreateShader(GL_VERTEX_SHADER); glShaderSource(vertexShader, Preprocessor.preprocess(Util.readFile("shaders/chunk.vert"), defines)); glCompileShader(vertexShader); if(glGetShaderi(vertexShader, GL_COMPILE_STATUS) == 0) { System.out.println("Error compiling vertex shader: " + glGetShaderInfoLog(vertexShader, 256)); errors = true; } int fragmentShader; fragmentShader = glCreateShader(GL_FRAGMENT_SHADER); glShaderSource(fragmentShader, Preprocessor.preprocess(Util.readFile("shaders/chunk.frag"), defines)); glCompileShader(fragmentShader); if(glGetShaderi(fragmentShader, GL_COMPILE_STATUS) == 0) { System.out.println("Error compiling fragment shader: " + glGetShaderInfoLog(fragmentShader, 256)); errors = true; } int newShaderProgram = glCreateProgram(); glAttachShader(newShaderProgram, vertexShader); glAttachShader(newShaderProgram, fragmentShader); glLinkProgram(newShaderProgram); if(glGetProgrami(newShaderProgram, GL_LINK_STATUS) == 0) { System.out.println("Error linking shader: " + glGetShaderInfoLog(newShaderProgram, 256)); errors = true; } if(!errors) { shaderProgram = newShaderProgram; } glDeleteShader(vertexShader); glDeleteShader(fragmentShader); } public void destroy() { onSave(); glDeleteProgram(shaderProgram); glDeleteVertexArrays(VAO); mem.destroy(); SimpleChunkMesh.instances = 0; SimpleChunkMesh.usedRAM = 0; ChunkMesh.instances = 0; ChunkMesh.usedRAM = 0; } public void onWorldRendererChanged(WorldRenderer wr, WorldRendererChange change) { int x = Math.floorDiv(wr.posX, 16); int y = Math.floorDiv(wr.posY, 16); int z = Math.floorDiv(wr.posZ, 16); NeoChunk lodChunk = getLODChunk(x, z); lodChunk.isSectionVisible[y] = change == WorldRendererChange.VISIBLE; if(change == WorldRendererChange.DELETED) { removeMesh(lodChunk.chunkMeshes[y]); if(lodChunk.chunkMeshes[y] != null) { lodChunk.chunkMeshes[y].destroy(); lodChunk.chunkMeshes[y] = null; } } lodChunkChanged(lodChunk); } public void onWorldRendererPost(WorldRenderer wr) { if(Config.disableChunkMeshes) return; int x = Math.floorDiv(wr.posX, 16); int y = Math.floorDiv(wr.posY, 16); int z = Math.floorDiv(wr.posZ, 16); if(Minecraft.getMinecraft().theWorld.getChunkFromChunkCoords(x, z).isChunkLoaded) { NeoChunk lodChunk = getLODChunk(x, z); lodChunk.isSectionVisible[y] = ((IWorldRenderer)wr).isDrawn(); lodChunk.putChunkMeshes(y, ((IWorldRenderer)wr).getChunkMeshes()); } } private double getLastSortDistanceSq(Entity player) { return Math.pow(lastSortX - player.posX, 2) + Math.pow(lastSortZ - player.posZ, 2); } private synchronized void addToServerChunkLoadQueue(List coords) { serverChunkLoadQueue.addAll(coords); } private NeoChunk receiveFarChunk(Chunk chunk) { NeoRegion region = getRegionContaining(chunk.xPosition, chunk.zPosition); return region.putChunk(chunk); } private NeoChunk getLODChunk(int chunkX, int chunkZ) { return getRegionContaining(chunkX, chunkZ).getChunkAbsolute(chunkX, chunkZ); } public void onStopServer() { } public synchronized void serverTick() { int chunkLoadsRemaining = Config.chunkLoadsPerTick; while(!serverChunkLoadQueue.isEmpty() && chunkLoadsRemaining-- > 0) { ChunkCoordIntPair coords = serverChunkLoadQueue.remove(0); ChunkProviderServer chunkProviderServer = Minecraft.getMinecraft().getIntegratedServer().worldServerForDimension(world.provider.dimensionId).theChunkProviderServer; Chunk chunk = chunkProviderServer.currentChunkProvider.provideChunk(coords.chunkXPos, coords.chunkZPos); SimpleChunkMesh.prepareFarChunkOnServer(chunk); farChunks.add(chunk); } } private NeoRegion getRegionContaining(int chunkX, int chunkZ) { ChunkCoordIntPair key = new ChunkCoordIntPair(Math.floorDiv(chunkX , 32), Math.floorDiv(chunkZ, 32)); NeoRegion region = loadedRegionsMap.get(key); if(region == null) { region = NeoRegion.load(getSaveDir(), Math.floorDiv(chunkX , 32), Math.floorDiv(chunkZ , 32)); loadedRegionsMap.put(key, region); } return region; } private void sendChunkToGPU(NeoChunk lodChunk) { Entity player = Minecraft.getMinecraft().renderViewEntity; lodChunk.tick(player); setVisible(lodChunk, true, true); } public void setVisible(NeoChunk chunk, boolean visible) { setVisible(chunk, visible, false); } public void setVisible(NeoChunk lodChunk, boolean visible, boolean forceCheck) { if(!forceCheck && visible == lodChunk.visible) return; lodChunk.visible = visible; lodChunkChanged(lodChunk); } public void lodChunkChanged(NeoChunk lodChunk) { int newLOD = (!lodChunk.hasChunkMeshes() && lodChunk.lod == 2) ? (Config.disableSimpleMeshes ? 0 : 1) : lodChunk.lod; for(SimpleChunkMesh sm : lodChunk.simpleMeshes) { if(sm != null) { if(lodChunk.isFullyVisible() && newLOD == 1) { if(!sm.visible) { setMeshVisible(sm, true); } } else { if(sm.visible) { setMeshVisible(sm, false); } } } } for(int y = 0; y < 16; y++) { for(int pass = 0; pass < 2; pass++) { ChunkMesh cm = lodChunk.chunkMeshes[y * 2 + pass]; if(cm != null) { if(lodChunk.isSectionVisible[y] && newLOD == 2) { if(!cm.visible) { setMeshVisible(cm, true); } } else { if(cm.visible) { setMeshVisible(cm, false); } } } } } } protected void setMeshVisible(Mesh mesh, boolean visible) { setMeshVisible(mesh, visible, false); } protected void setMeshVisible(Mesh mesh, boolean visible, boolean force) { if((!force && freezeMeshes) || mesh == null) return; if(mesh.visible != visible) { mesh.visible = visible; if(mesh.gpuStatus == GPUStatus.UNSENT) { mem.sendMeshToGPU(mesh); sentMeshes[mesh.pass].add(mesh); } } } public void removeMesh(Mesh mesh) { if(mesh == null) return; mem.deleteMeshFromGPU(mesh); sentMeshes[mesh.pass].remove(mesh); setMeshVisible(mesh, false); } public Chunk getChunkFromChunkCoords(int x, int z) { for(Chunk chunk : myChunks) { if(chunk.xPosition == x && chunk.zPosition == z) { return chunk; } } return null; } public boolean shouldSideBeRendered(Block block, IBlockAccess ba, int x, int y, int z, int w) { EnumFacing facing = EnumFacing.values()[w]; if(block.getMaterial() == Material.water && facing != EnumFacing.UP && facing != EnumFacing.DOWN && !Minecraft.getMinecraft().theWorld.getChunkFromBlockCoords(x, z).isChunkLoaded) { return false; } else { return block.shouldSideBeRendered(ba, x, y, z, w); } } public List getDebugText() { List text = new ArrayList<>(); text.addAll(Arrays.asList( "Neodymium " + Neodymium.VERSION )); text.addAll(mem.getDebugText()); text.addAll(Arrays.asList( //"Simple meshes: " + SimpleChunkMesh.instances + " (" + SimpleChunkMesh.usedRAM / 1024 / 1024 + "MB)", "Meshes: " + ChunkMesh.instances + " (" + ChunkMesh.usedRAM / 1024 / 1024 + "MB)", //"Total RAM used: " + ((SimpleChunkMesh.usedRAM + ChunkMesh.usedRAM) / 1024 / 1024) + " MB", "Rendered: " + renderedMeshes + " (" + renderedQuads / 1000 + "KQ)" )); return text; } public void onSave() { //System.out.println("Saving LOD regions..."); //long t0 = System.currentTimeMillis(); //loadedRegionsMap.forEach((k, v) -> v.save(getSaveDir())); //System.out.println("Finished saving LOD regions in " + ((System.currentTimeMillis() - t0) / 1000.0) + "s"); } public void onChunkLoad(ChunkEvent.Load event) { farChunks.add(event.getChunk()); } private Path getSaveDir(){ return Minecraft.getMinecraft().mcDataDir.toPath().resolve("neodymium").resolve(Minecraft.getMinecraft().getIntegratedServer().getFolderName()); } private boolean shouldRenderInWorld(World world) { return world != null && !world.provider.isHellWorld; } public static class LODChunkComparator implements Comparator { Entity player; public LODChunkComparator(Entity player) { this.player = player; } @Override public int compare(NeoChunk p1, NeoChunk p2) { int distSq1 = distSq(p1); int distSq2 = distSq(p2); return distSq1 < distSq2 ? -1 : distSq1 > distSq2 ? 1 : 0; } int distSq(NeoChunk p) { return (int)( Math.pow(((p.x * 16) - player.chunkCoordX), 2) + Math.pow(((p.z * 16) - player.chunkCoordZ), 2) ); } } public static class ChunkCoordDistanceComparator implements Comparator { double x, y, z; public ChunkCoordDistanceComparator(double x, double y, double z) { this.x = x; this.y = y; this.z = z; } @Override public int compare(ChunkCoordIntPair p1, ChunkCoordIntPair p2) { int distSq1 = distSq(p1); int distSq2 = distSq(p2); return distSq1 < distSq2 ? -1 : distSq1 > distSq2 ? 1 : 0; } int distSq(ChunkCoordIntPair p) { return (int)( Math.pow(((p.chunkXPos * 16) - x), 2) + Math.pow(((p.chunkZPos * 16) - z), 2) ); } } public static class MeshDistanceComparator implements Comparator { double x, y, z; MeshDistanceComparator(double x, double y, double z){ this.x = x; this.y = y; this.z = z; } @Override public int compare(Mesh a, Mesh b) { if(a.pass < b.pass) { return -1; } else if(a.pass > b.pass) { return 1; } else { double distSqA = a.distSq(x, y, z); double distSqB = b.distSq(x, y, z); if(distSqA > distSqB) { return 1; } else if(distSqA < distSqB) { return -1; } else { return 0; } } } } public static enum WorldRendererChange { VISIBLE, INVISIBLE, DELETED } }