package gregtech.common; import cpw.mods.fml.common.IWorldGenerator; import cpw.mods.fml.common.registry.GameRegistry; import gregtech.api.GregTech_API; import gregtech.api.util.GT_Log; import gregtech.api.world.GT_Worldgen; import gregtech.common.blocks.GT_TileEntity_Ores; import net.minecraft.init.Blocks; import net.minecraft.util.MathHelper; import net.minecraft.world.World; import net.minecraft.world.biome.BiomeGenBase; import net.minecraft.world.chunk.Chunk; import net.minecraft.world.chunk.IChunkProvider; import net.minecraft.world.gen.ChunkProviderEnd; import net.minecraft.world.gen.ChunkProviderHell; import java.util.ArrayList; import java.util.List; import java.util.Random; public class GT_Worldgenerator implements IWorldGenerator { public static boolean sAsteroids = true; private static int mEndAsteroidProbability = 300; private static int mSize = 100; private static int endMinSize = 50; private static int endMaxSize = 200; private static boolean endAsteroids = true; public List mList = new ArrayList(); public boolean mIsGenerating = false; public GT_Worldgenerator() { endAsteroids = GregTech_API.sWorldgenFile.get("endasteroids", "GenerateAsteroids", true); endMinSize = GregTech_API.sWorldgenFile.get("endasteroids", "AsteroidMinSize", 50); endMaxSize = GregTech_API.sWorldgenFile.get("endasteroids", "AsteroidMaxSize", 200); mEndAsteroidProbability = GregTech_API.sWorldgenFile.get("endasteroids", "AsteroidProbability", 300); GameRegistry.registerWorldGenerator(this, 1073741823); } public void generate(Random aRandom, int aX, int aZ, World aWorld, IChunkProvider aChunkGenerator, IChunkProvider aChunkProvider) { this.mList.add(new WorldGenContainer(new Random(aRandom.nextInt()), aX * 16, aZ * 16, ((aChunkGenerator instanceof ChunkProviderEnd)) || (aWorld.getBiomeGenForCoords(aX * 16 + 8, aZ * 16 + 8) == BiomeGenBase.sky) ? 1 : ((aChunkGenerator instanceof ChunkProviderHell)) || (aWorld.getBiomeGenForCoords(aX * 16 + 8, aZ * 16 + 8) == BiomeGenBase.hell) ? -1 : 0, aWorld, aChunkGenerator, aChunkProvider, aWorld.getBiomeGenForCoords(aX * 16 + 8, aZ * 16 + 8).biomeName)); if (!this.mIsGenerating) { this.mIsGenerating = true; for (int i = 0; i < this.mList.size(); i++) { ((Runnable) this.mList.get(i)).run(); } this.mList.clear(); this.mIsGenerating = false; } } public static class WorldGenContainer implements Runnable { public final Random mRandom; public final int mX; public final int mZ; public final int mDimensionType; public final World mWorld; public final IChunkProvider mChunkGenerator; public final IChunkProvider mChunkProvider; public final String mBiome; public WorldGenContainer(Random aRandom, int aX, int aZ, int aDimensionType, World aWorld, IChunkProvider aChunkGenerator, IChunkProvider aChunkProvider, String aBiome) { this.mRandom = aRandom; this.mX = aX; this.mZ = aZ; this.mDimensionType = aDimensionType; this.mWorld = aWorld; this.mChunkGenerator = aChunkGenerator; this.mChunkProvider = aChunkProvider; this.mBiome = aBiome; } public void run() { if ((Math.abs(this.mX / 16) % 3 == 1) && (Math.abs(this.mZ / 16) % 3 == 1)) { if ((GT_Worldgen_GT_Ore_Layer.sWeight > 0) && (GT_Worldgen_GT_Ore_Layer.sList.size() > 0)) { boolean temp = true; int tRandomWeight; for (int i = 0; (i < 256) && (temp); i++) { tRandomWeight = this.mRandom.nextInt(GT_Worldgen_GT_Ore_Layer.sWeight); for (GT_Worldgen tWorldGen : GT_Worldgen_GT_Ore_Layer.sList) { tRandomWeight -= ((GT_Worldgen_GT_Ore_Layer) tWorldGen).mWeight; if (tRandomWeight <= 0) { try { if (tWorldGen.executeWorldgen(this.mWorld, this.mRandom, this.mBiome, this.mDimensionType, this.mX, this.mZ, this.mChunkGenerator, this.mChunkProvider)) { temp = false; } break; } catch (Throwable e) { e.printStackTrace(GT_Log.err); } } } } } int i = 0; for (int tX = this.mX - 16; i < 3; tX += 16) { int j = 0; for (int tZ = this.mZ - 16; j < 3; tZ += 16) { String tBiome = this.mWorld.getBiomeGenForCoords(tX + 8, tZ + 8).biomeName; if (tBiome == null) { tBiome = BiomeGenBase.plains.biomeName; } for (GT_Worldgen tWorldGen : GregTech_API.sWorldgenList) { try { tWorldGen.executeWorldgen(this.mWorld, this.mRandom, this.mBiome, this.mDimensionType, tX, tZ, this.mChunkGenerator, this.mChunkProvider); } catch (Throwable e) { e.printStackTrace(GT_Log.err); } } j++; } i++; } } //Asteroid Worldgen int tDimensionType = this.mWorld.provider.dimensionId; Random aRandom = new Random(); if (((tDimensionType == 1) && endAsteroids && ((mEndAsteroidProbability <= 1) || (aRandom.nextInt(mEndAsteroidProbability) == 0)))) { short primaryMeta = 0; short secondaryMeta = 0; short betweenMeta = 0; short sporadicMeta = 0; if ((GT_Worldgen_GT_Ore_Layer.sWeight > 0) && (GT_Worldgen_GT_Ore_Layer.sList.size() > 0)) { boolean temp = true; int tRandomWeight; for (int i = 0; (i < 256) && (temp); i++) { tRandomWeight = aRandom.nextInt(GT_Worldgen_GT_Ore_Layer.sWeight); for (GT_Worldgen_GT_Ore_Layer tWorldGen : GT_Worldgen_GT_Ore_Layer.sList) { tRandomWeight -= ((GT_Worldgen_GT_Ore_Layer) tWorldGen).mWeight; if (tRandomWeight <= 0) { try { if (tWorldGen.mEndAsteroid && tDimensionType == 1) { primaryMeta = tWorldGen.mPrimaryMeta; secondaryMeta = tWorldGen.mSecondaryMeta; betweenMeta = tWorldGen.mBetweenMeta; sporadicMeta = tWorldGen.mSporadicMeta; temp = false; break; } } catch (Throwable e) { e.printStackTrace(GT_Log.err); } } } } } int tX = mX + aRandom.nextInt(16); int tY = 50 + aRandom.nextInt(200 - 50); int tZ = mZ + aRandom.nextInt(16); if (tDimensionType == 1) { mSize = aRandom.nextInt((int) (endMaxSize - endMinSize)); } if ((mWorld.getBlock(tX, tY, tZ).isAir(mWorld, tX, tY, tZ))) { float var6 = aRandom.nextFloat() * 3.141593F; double var7 = tX + 8 + MathHelper.sin(var6) * mSize / 8.0F; double var9 = tX + 8 - MathHelper.sin(var6) * mSize / 8.0F; double var11 = tZ + 8 + MathHelper.cos(var6) * mSize / 8.0F; double var13 = tZ + 8 - MathHelper.cos(var6) * mSize / 8.0F; double var15 = tY + aRandom.nextInt(3) - 2; double var17 = tY + aRandom.nextInt(3) - 2; for (int var19 = 0; var19 <= mSize; var19++) { double var20 = var7 + (var9 - var7) * var19 / mSize; double var22 = var15 + (var17 - var15) * var19 / mSize; double var24 = var11 + (var13 - var11) * var19 / mSize; double var26 = aRandom.nextDouble() * mSize / 16.0D; double var28 = (MathHelper.sin(var19 * 3.141593F / mSize) + 1.0F) * var26 + 1.0D; double var30 = (MathHelper.sin(var19 * 3.141593F / mSize) + 1.0F) * var26 + 1.0D; int tMinX = MathHelper.floor_double(var20 - var28 / 2.0D); int tMinY = MathHelper.floor_double(var22 - var30 / 2.0D); int tMinZ = MathHelper.floor_double(var24 - var28 / 2.0D); int tMaxX = MathHelper.floor_double(var20 + var28 / 2.0D); int tMaxY = MathHelper.floor_double(var22 + var30 / 2.0D); int tMaxZ = MathHelper.floor_double(var24 + var28 / 2.0D); for (int eX = tMinX; eX <= tMaxX; eX++) { double var39 = (eX + 0.5D - var20) / (var28 / 2.0D); if (var39 * var39 < 1.0D) { for (int eY = tMinY; eY <= tMaxY; eY++) { double var42 = (eY + 0.5D - var22) / (var30 / 2.0D); if (var39 * var39 + var42 * var42 < 1.0D) { for (int eZ = tMinZ; eZ <= tMaxZ; eZ++) { double var45 = (eZ + 0.5D - var24) / (var28 / 2.0D); if ((var39 * var39 + var42 * var42 + var45 * var45 < 1.0D) && (mWorld.getBlock(tX, tY, tZ).isAir(mWorld, tX, tY, tZ))) { int ranOre = aRandom.nextInt(50); if (ranOre < 3) { GT_TileEntity_Ores.setOreBlock(mWorld, eX, eY, eZ, primaryMeta , true); } else if (ranOre < 6) { GT_TileEntity_Ores.setOreBlock(mWorld, eX, eY, eZ, secondaryMeta , true); } else if (ranOre < 8) { GT_TileEntity_Ores.setOreBlock(mWorld, eX, eY, eZ, betweenMeta , true); } else if (ranOre < 10) { GT_TileEntity_Ores.setOreBlock(mWorld, eX, eY, eZ, sporadicMeta , true); } else {mWorld.setBlock(eX, eY, eZ, Blocks.end_stone, 0, 0); } } } } } } } } } } Chunk tChunk = this.mWorld.getChunkFromBlockCoords(this.mX, this.mZ); if (tChunk != null) { tChunk.isModified = true; } } } }