/*
* _____ _ _ _____ _
* | __ \| | | | / ____| | |
* | |__) | | ___ | |_| (___ __ _ _ _ __ _ _ __ ___ __| |
* | ___/| |/ _ \| __|\___ \ / _` | | | |/ _` | '__/ _ \/ _` |
* | | | | (_) | |_ ____) | (_| | |_| | (_| | | | __/ (_| |
* |_| |_|\___/ \__|_____/ \__, |\__,_|\__,_|_| \___|\__,_|
* | |
* |_|
* PlotSquared plot management system for Minecraft
* Copyright (C) 2020 IntellectualSites
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
package com.github.intellectualsites.plotsquared.plot.generator;
import com.github.intellectualsites.plotsquared.plot.PlotSquared;
import com.github.intellectualsites.plotsquared.plot.config.Settings;
import com.github.intellectualsites.plotsquared.plot.object.Location;
import com.github.intellectualsites.plotsquared.plot.object.PlotArea;
import com.github.intellectualsites.plotsquared.plot.object.PlotId;
import com.github.intellectualsites.plotsquared.plot.util.MathMan;
import com.github.intellectualsites.plotsquared.plot.util.block.ScopedLocalBlockQueue;
import com.google.common.base.Preconditions;
import com.sk89q.worldedit.world.biome.BiomeType;
import com.sk89q.worldedit.world.block.BaseBlock;
import com.sk89q.worldedit.world.block.BlockTypes;
import org.jetbrains.annotations.NotNull;
public class HybridGen extends IndependentPlotGenerator {
@Override public String getName() {
return PlotSquared.imp().getPluginName();
}
private void placeSchem(HybridPlotWorld world, ScopedLocalBlockQueue result, short relativeX,
short relativeZ, int x, int z, boolean isRoad) {
int minY; // Math.min(world.PLOT_HEIGHT, world.ROAD_HEIGHT);
if (isRoad || Settings.Schematics.PASTE_ON_TOP) {
minY = world.SCHEM_Y;
} else {
minY = 1;
}
BaseBlock[] blocks = world.G_SCH.get(MathMan.pair(relativeX, relativeZ));
if (blocks != null) {
for (int y = 0; y < blocks.length; y++) {
if (blocks[y] != null) {
result.setBlock(x, minY + y, z, blocks[y]);
}
}
}
BiomeType biome = world.G_SCH_B.get(MathMan.pair(relativeX, relativeZ));
if (biome != null) {
result.setBiome(x, z, biome);
}
}
@Override public void generateChunk(@NotNull ScopedLocalBlockQueue result, @NotNull PlotArea settings) {
Preconditions.checkNotNull(result, "result cannot be null");
Preconditions.checkNotNull(settings, "settings cannot be null");
HybridPlotWorld hpw = (HybridPlotWorld) settings;
// Biome
result.fillBiome(hpw.getPlotBiome());
// Bedrock
if (hpw.PLOT_BEDROCK) {
for (short x = 0; x < 16; x++) {
for (short z = 0; z < 16; z++) {
result.setBlock(x, 0, z, BlockTypes.BEDROCK.getDefaultState());
}
}
}
// Coords
Location min = result.getMin();
int bx = (min.getX()) - hpw.ROAD_OFFSET_X;
int bz = (min.getZ()) - hpw.ROAD_OFFSET_Z;
short rbx;
if (bx < 0) {
rbx = (short) (hpw.SIZE + (bx % hpw.SIZE));
} else {
rbx = (short) (bx % hpw.SIZE);
}
short rbz;
if (bz < 0) {
rbz = (short) (hpw.SIZE + (bz % hpw.SIZE));
} else {
rbz = (short) (bz % hpw.SIZE);
}
short[] rx = new short[16];
boolean[] gx = new boolean[16];
boolean[] wx = new boolean[16];
for (short i = 0; i < 16; i++) {
short v = (short) (rbx + i);
if (v >= hpw.SIZE) {
v -= hpw.SIZE;
}
rx[i] = v;
if (hpw.ROAD_WIDTH != 0) {
gx[i] = v < hpw.PATH_WIDTH_LOWER || v > hpw.PATH_WIDTH_UPPER;
wx[i] = v == hpw.PATH_WIDTH_LOWER || v == hpw.PATH_WIDTH_UPPER;
}
}
short[] rz = new short[16];
boolean[] gz = new boolean[16];
boolean[] wz = new boolean[16];
for (short i = 0; i < 16; i++) {
short v = (short) (rbz + i);
if (v >= hpw.SIZE) {
v -= hpw.SIZE;
}
rz[i] = v;
if (hpw.ROAD_WIDTH != 0) {
gz[i] = v < hpw.PATH_WIDTH_LOWER || v > hpw.PATH_WIDTH_UPPER;
wz[i] = v == hpw.PATH_WIDTH_LOWER || v == hpw.PATH_WIDTH_UPPER;
}
}
// generation
for (short x = 0; x < 16; x++) {
if (gx[x]) {
for (short z = 0; z < 16; z++) {
// Road
for (int y = 1; y <= hpw.ROAD_HEIGHT; y++) {
result.setBlock(x, y, z, hpw.ROAD_BLOCK.toPattern());
}
if (hpw.ROAD_SCHEMATIC_ENABLED) {
placeSchem(hpw, result, rx[x], rz[z], x, z, true);
}
}
} else if (wx[x]) {
for (short z = 0; z < 16; z++) {
if (gz[z]) {
// road
for (int y = 1; y <= hpw.ROAD_HEIGHT; y++) {
result.setBlock(x, y, z, hpw.ROAD_BLOCK.toPattern());
}
if (hpw.ROAD_SCHEMATIC_ENABLED) {
placeSchem(hpw, result, rx[x], rz[z], x, z, true);
}
} else {
// wall
for (int y = 1; y <= hpw.WALL_HEIGHT; y++) {
result.setBlock(x, y, z, hpw.WALL_FILLING.toPattern());
}
if (!hpw.ROAD_SCHEMATIC_ENABLED) {
result.setBlock(x, hpw.WALL_HEIGHT + 1, z, hpw.WALL_BLOCK.toPattern());
} else {
placeSchem(hpw, result, rx[x], rz[z], x, z, true);
}
}
}
} else {
for (short z = 0; z < 16; z++) {
if (gz[z]) {
// road
for (int y = 1; y <= hpw.ROAD_HEIGHT; y++) {
result.setBlock(x, y, z, hpw.ROAD_BLOCK.toPattern());
}
if (hpw.ROAD_SCHEMATIC_ENABLED) {
placeSchem(hpw, result, rx[x], rz[z], x, z, true);
}
} else if (wz[z]) {
// wall
for (int y = 1; y <= hpw.WALL_HEIGHT; y++) {
result.setBlock(x, y, z, hpw.WALL_FILLING.toPattern());
}
if (!hpw.ROAD_SCHEMATIC_ENABLED) {
result.setBlock(x, hpw.WALL_HEIGHT + 1, z, hpw.WALL_BLOCK.toPattern());
} else {
placeSchem(hpw, result, rx[x], rz[z], x, z, true);
}
} else {
// plot
for (int y = 1; y < hpw.PLOT_HEIGHT; y++) {
result.setBlock(x, y, z, hpw.MAIN_BLOCK.toPattern());
}
result.setBlock(x, hpw.PLOT_HEIGHT, z, hpw.TOP_BLOCK.toPattern());
if (hpw.PLOT_SCHEMATIC) {
placeSchem(hpw, result, rx[x], rz[z], x, z, false);
}
}
}
}
}
}
/* @Override public boolean populateChunk(ScopedLocalBlockQueue result, PlotArea settings) {
HybridPlotWorld hpw = (HybridPlotWorld) settings;
if (hpw.G_SCH_STATE != null) {
Location min = result.getMin();
int cx = min.getX() >> 4;
int cz = min.getZ() >> 4;
int p1x = cx << 4;
int p1z = cz << 4;
int bx = p1x - hpw.ROAD_OFFSET_X;
int bz = p1z - hpw.ROAD_OFFSET_Z;
short rbx;
if (bx < 0) {
rbx = (short) (hpw.SIZE + (bx % hpw.SIZE));
} else {
rbx = (short) (bx % hpw.SIZE);
}
short rbz;
if (bz < 0) {
rbz = (short) (hpw.SIZE + (bz % hpw.SIZE));
} else {
rbz = (short) (bz % hpw.SIZE);
}
short[] rx = new short[16];
for (short i = 0; i < 16; i++) {
short v = (short) (rbx + i);
if (v >= hpw.SIZE) {
v -= hpw.SIZE;
}
rx[i] = v;
}
short[] rz = new short[16];
for (short i = 0; i < 16; i++) {
short v = (short) (rbz + i);
if (v >= hpw.SIZE) {
v -= hpw.SIZE;
}
rz[i] = v;
}
LocalBlockQueue queue = null;
for (short x = 0; x < 16; x++) {
for (short z = 0; z < 16; z++) {
int pair = MathMan.pair(rx[x], rz[z]);
HashMap map = hpw.G_SCH_STATE.get(pair);
if (map != null) {
for (Entry entry : map.entrySet()) {
if (queue == null) {
queue = GlobalBlockQueue.IMP.getNewQueue(hpw.worldname, false);
}
CompoundTag tag = entry.getValue();
SchematicHandler.manager
.restoreTile(queue, tag, p1x + x, entry.getKey(), p1z + z);
}
}
}
}
if (queue != null) {
queue.flush();
}
}
return false;
}*/
@Override public PlotArea getNewPlotArea(String world, String id, PlotId min, PlotId max) {
return new HybridPlotWorld(world, id, this, min, max);
}
@Override public void initialize(PlotArea area) {
// All initialization is done in the PlotArea class
}
}