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1146 Zeilen
57 KiB
Diff
From 0000000000000000000000000000000000000000 Mon Sep 17 00:00:00 2001
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From: theosib <millerti@172.16.221.1>
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Date: Thu, 27 Sep 2018 01:43:35 -0600
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Subject: [PATCH] Eigencraft redstone implementation
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Author: theosib <millerti@172.16.221.1>
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Original license: MIT
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This patch implements theosib's redstone algorithms to completely overhaul the way redstone works.
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The new algorithms should be many times faster than current vanilla ones.
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From the original author's comments, it looks like it shouldn't interfere with any redstone save for very extreme edge-cases.
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Surprisingly, not a lot was touched aside from a few obfuscation helpers and BlockRedstoneWire.
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A lot of this code is self-contained in a helper class.
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Aside from making the obvious class/function renames and obfhelpers I didn't need to modify much.
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Just added Bukkit's event system and took a few liberties with dead code and comment misspellings.
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== AT ==
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public net.minecraft.world.level.block.RedStoneWireBlock shouldSignal
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public net.minecraft.world.level.block.RedStoneWireBlock canSurvive(Lnet/minecraft/world/level/block/state/BlockState;Lnet/minecraft/world/level/LevelReader;Lnet/minecraft/core/BlockPos;)Z
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Co-authored-by: egg82 <phantom_zero@ymail.com>
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diff --git a/src/main/java/com/destroystokyo/paper/util/RedstoneWireTurbo.java b/src/main/java/com/destroystokyo/paper/util/RedstoneWireTurbo.java
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new file mode 100644
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index 0000000000000000000000000000000000000000..9f17170179cc99d84ad25a1e838aff3d8cc66f93
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--- /dev/null
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+++ b/src/main/java/com/destroystokyo/paper/util/RedstoneWireTurbo.java
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@@ -0,0 +1,958 @@
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+package com.destroystokyo.paper.util;
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+
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+import java.util.List;
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+import java.util.Map;
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+import java.util.concurrent.ThreadLocalRandom;
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+import net.minecraft.core.BlockPos;
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+import net.minecraft.core.Direction;
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+import net.minecraft.world.item.ItemStack;
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+import net.minecraft.world.item.Items;
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+import net.minecraft.world.level.Level;
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+import net.minecraft.world.level.block.Block;
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+import net.minecraft.world.level.block.RedStoneWireBlock;
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+import net.minecraft.world.level.block.state.BlockState;
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+import org.bukkit.craftbukkit.block.CraftBlock;
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+import org.bukkit.event.block.BlockRedstoneEvent;
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+
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+import com.google.common.collect.Lists;
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+import com.google.common.collect.Maps;
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+
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+/**
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+ * Used for the faster redstone algorithm.
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+ * Original author: theosib
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+ * Original license: MIT
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+ *
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+ * Ported to Paper and updated to 1.13 by egg82
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+ */
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+public class RedstoneWireTurbo {
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+ /*
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+ * This is Helper class for BlockRedstoneWire. It implements a minimally-invasive
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+ * bolt-on accelerator that performs a breadth-first search through redstone wire blocks
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+ * in order to more efficiently and deterministically compute new redstone wire power levels
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+ * and determine the order in which other blocks should be updated.
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+ *
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+ * Features:
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+ * - Changes to BlockRedstoneWire are very limited, no other classes are affected, and the
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+ * choice between old and new redstone wire update algorithms is switchable on-line.
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+ * - The vanilla implementation relied on World.notifyNeighborsOfStateChange for redstone
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+ * wire blocks to communicate power level changes to each other, generating 36 block
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+ * updates per call. This improved implementation propagates power level changes directly
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+ * between redstone wire blocks. Redstone wire power levels are therefore computed more quickly,
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+ * and block updates are sent only to non-redstone blocks, many of which may perform an
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+ * action when informed of a change in redstone power level. (Note: Block updates are not
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+ * the same as state changes to redstone wire. Wire block states are updated as soon
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+ * as they are computed.)
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+ * - Of the 36 block updates generated by a call to World.notifyNeighborsOfStateChange,
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+ * 12 of them are obviously redundant (e.g. the west neighbor of the east neighbor).
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+ * These are eliminated.
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+ * - Updates to redstone wire and other connected blocks are propagated in a breath-first
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+ * manner, radiating out from the initial trigger (a block update to a redstone wire
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+ * from something other than redstone wire).
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+ * - Updates are scheduled both deterministically and in an intuitive order, addressing bug
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+ * MC-11193.
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+ * - All redstone behavior that used to be locational now works the same in all locations.
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+ * - All behaviors of redstone wire that used to be orientational now work the same in all
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+ * orientations, as long as orientation can be determined; random otherwise. Some other
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+ * redstone components still update directionally (e.g. switches), and this code can't
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+ * compensate for that.
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+ * - Information that is otherwise computed over and over again or which is expensive to
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+ * to compute is cached for faster lookup. This includes coordinates of block position
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+ * neighbors and block states that won't change behind our backs during the execution of
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+ * this search algorithm.
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+ * - Redundant block updates (both to redstone wire and to other blocks) are heavily
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+ * consolidated. For worst-case scenarios (depowering of redstone wire) this results
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+ * in a reduction of block updates by as much as 95% (factor of 1/21). Due to overheads,
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+ * empirical testing shows a speedup better than 10x. This addresses bug MC-81098.
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+ *
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+ * Extensive testing has been performed to ensure that existing redstone contraptions still
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+ * behave as expected. Results of early testing that identified undesirable behavior changes
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+ * were addressed. Additionally, real-time performance testing revealed compute inefficiencies
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+ * With earlier implementations of this accelerator. Some compatibility adjustments and
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+ * performance optimizations resulted in harmless increases in block updates above the
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+ * theoretical minimum.
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+ *
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+ * Only a single redstone machine was found to break: An instant dropper line hack that
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+ * relies on powered rails and quasi-connectivity but doesn't work in all directions. The
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+ * replacement is to lay redstone wire directly on top of the dropper line, which now works
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+ * reliably in any direction.
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+ *
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+ * There are numerous other optimization that can be made, but those will be provided later in
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+ * separate updates. This version is designed to be minimalistic.
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+ *
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+ * Many thanks to the following individuals for their help in testing this functionality:
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+ * - pokechu22, _MethodZz_, WARBEN, NarcolepticFrog, CommandHelper (nessie), ilmango,
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+ * OreoLamp, Xcom6000, tryashtar, RedCMD, Smokey95Dog, EDDxample, Rays Works,
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+ * Nodnam, BlockyPlays, Grumm, NeunEinser, HelVince.
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+ */
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+
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+ /* Reference to BlockRedstoneWire object, which uses this accelerator */
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+ private final RedStoneWireBlock wire;
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+
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+ /*
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+ * Implementation:
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+ *
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+ * RedstoneWire Blocks are updated in concentric rings or "layers" radiating out from the
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+ * initial block update that came from a call to BlockRedstoneWire.neighborChanged().
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+ * All nodes put in Layer N are those with Manhattan distance N from the trigger
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+ * position, reachable through connected redstone wire blocks.
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+ *
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+ * Layer 0 represents the trigger block position that was input to neighborChanged.
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+ * Layer 1 contains the immediate neighbors of that position.
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+ * Layer N contains the neighbors of blocks in layer N-1, not including
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+ * those in previous layers.
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+ *
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+ * Layers enforce an update order that is a function of Manhattan distance
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+ * from the initial coordinates input to neighborChanged. The same
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+ * coordinates may appear in multiple layers, but redundant updates are minimized.
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+ * Block updates are sent layer-by-layer. If multiple of a block's neighbors experience
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+ * redstone wire changes before its layer is processed, then those updates will be merged.
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+ * If a block's update has been sent, but its neighboring redstone changes
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+ * after that, then another update will be sent. This preserves compatibility with
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+ * machines that rely on zero-tick behavior, except that the new functionality is non-
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+ * locational.
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+ *
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+ * Within each layer, updates are ordered left-to-right relative to the direction of
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+ * information flow. This makes the implementation non-orientational. Only when
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+ * this direction is ambiguous is randomness applied (intentionally).
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+ */
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+ private List<UpdateNode> updateQueue0 = Lists.newArrayList();
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+ private List<UpdateNode> updateQueue1 = Lists.newArrayList();
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+ private List<UpdateNode> updateQueue2 = Lists.newArrayList();
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+
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+ public RedstoneWireTurbo(RedStoneWireBlock wire) {
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+ this.wire = wire;
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+ }
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+
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+ /*
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+ * Compute neighbors of a block. When a redstone wire value changes, previously it called
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+ * World.notifyNeighborsOfStateChange. That lists immediately neighboring blocks in
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+ * west, east, down, up, north, south order. For each of those neighbors, their own
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+ * neighbors are updated in the same order. This generates 36 updates, but 12 of them are
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+ * redundant; for instance the west neighbor of a block's east neighbor.
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+ *
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+ * Note that this ordering is only used to create the initial list of neighbors. Once
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+ * the direction of signal flow is identified, the ordering of updates is completely
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+ * reorganized.
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+ */
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+ public static BlockPos[] computeAllNeighbors(final BlockPos pos) {
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+ final int x = pos.getX();
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+ final int y = pos.getY();
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+ final int z = pos.getZ();
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+ final BlockPos[] n = new BlockPos[24];
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+
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+ // Immediate neighbors, in the same order as
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+ // World.notifyNeighborsOfStateChange, etc.:
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+ // west, east, down, up, north, south
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+ n[0] = new BlockPos(x - 1, y, z);
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+ n[1] = new BlockPos(x + 1, y, z);
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+ n[2] = new BlockPos(x, y - 1, z);
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+ n[3] = new BlockPos(x, y + 1, z);
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+ n[4] = new BlockPos(x, y, z - 1);
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+ n[5] = new BlockPos(x, y, z + 1);
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+
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+ // Neighbors of neighbors, in the same order,
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+ // except that duplicates are not included
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+ n[6] = new BlockPos(x - 2, y, z);
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+ n[7] = new BlockPos(x - 1, y - 1, z);
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+ n[8] = new BlockPos(x - 1, y + 1, z);
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+ n[9] = new BlockPos(x - 1, y, z - 1);
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+ n[10] = new BlockPos(x - 1, y, z + 1);
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+ n[11] = new BlockPos(x + 2, y, z);
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+ n[12] = new BlockPos(x + 1, y - 1, z);
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+ n[13] = new BlockPos(x + 1, y + 1, z);
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+ n[14] = new BlockPos(x + 1, y, z - 1);
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+ n[15] = new BlockPos(x + 1, y, z + 1);
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+ n[16] = new BlockPos(x, y - 2, z);
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+ n[17] = new BlockPos(x, y - 1, z - 1);
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+ n[18] = new BlockPos(x, y - 1, z + 1);
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+ n[19] = new BlockPos(x, y + 2, z);
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+ n[20] = new BlockPos(x, y + 1, z - 1);
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+ n[21] = new BlockPos(x, y + 1, z + 1);
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+ n[22] = new BlockPos(x, y, z - 2);
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+ n[23] = new BlockPos(x, y, z + 2);
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+ return n;
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+ }
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+
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+ /*
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+ * We only want redstone wires to update redstone wires that are
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+ * immediately adjacent. Some more distant updates can result
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+ * in cross-talk that (a) wastes time and (b) can make the update
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+ * order unintuitive. Therefore (relative to the neighbor order
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+ * computed by computeAllNeighbors), updates are not scheduled
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+ * for redstone wire in those non-connecting positions. On the
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+ * other hand, updates will always be sent to *other* types of blocks
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+ * in any of the 24 neighboring positions.
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+ */
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+ private static final boolean[] update_redstone = {
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+ true, true, false, false, true, true, // 0 to 5
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+ false, true, true, false, false, false, // 6 to 11
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+ true, true, false, false, false, true, // 12 to 17
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+ true, false, true, true, false, false // 18 to 23
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+ };
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+
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+ // Internal numbering for cardinal directions
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+ private static final int North = 0;
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+ private static final int East = 1;
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+ private static final int South = 2;
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+ private static final int West = 3;
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+
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+ /*
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+ * These lookup tables completely remap neighbor positions into a left-to-right
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+ * ordering, based on the cardinal direction that is determined to be forward.
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+ * See below for more explanation.
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+ */
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+ private static final int[] forward_is_north = {2, 3, 16, 19, 0, 4, 1, 5, 7, 8, 17, 20, 12, 13, 18, 21, 6, 9, 22, 14, 11, 10, 23, 15};
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+ private static final int[] forward_is_east = {2, 3, 16, 19, 4, 1, 5, 0, 17, 20, 12, 13, 18, 21, 7, 8, 22, 14, 11, 15, 23, 9, 6, 10};
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+ private static final int[] forward_is_south = {2, 3, 16, 19, 1, 5, 0, 4, 12, 13, 18, 21, 7, 8, 17, 20, 11, 15, 23, 10, 6, 14, 22, 9};
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+ private static final int[] forward_is_west = {2, 3, 16, 19, 5, 0, 4, 1, 18, 21, 7, 8, 17, 20, 12, 13, 23, 10, 6, 9, 22, 15, 11, 14};
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+
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+ /* For any orientation, we end up with the update order defined below. This order is relative to any redstone wire block
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+ * that is itself having an update computed, and this center position is marked with C.
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+ * - The update position marked 0 is computed first, and the one marked 23 is last.
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+ * - Forward is determined by the local direction of information flow into position C from prior updates.
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+ * - The first updates are scheduled for the four positions below and above C.
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+ * - Then updates are scheduled for the four horizontal neighbors of C, followed by the positions below and above those neighbors.
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+ * - Finally, updates are scheduled for the remaining positions with Manhattan distance 2 from C (at the same Y coordinate).
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+ * - For a given horizontal distance from C, updates are scheduled starting from directly left and stepping clockwise to directly
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+ * right. The remaining positions behind C are scheduled counterclockwise so as to maintain the left-to-right ordering.
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+ * - If C is in layer N of the update schedule, then all 24 positions may be scheduled for layer N+1. For redstone wire, no
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+ * updates are scheduled for positions that cannot directly connect. Additionally, the four positions above and below C
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+ * are ALSO scheduled for layer N+2.
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+ * - This update order was selected after experimenting with a number of alternative schedules, based on its compatibility
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+ * with existing redstone designs and behaviors that were considered to be intuitive by various testers. WARBEN in particular
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+ * made some of the most challenging test cases, but the 3-tick clocks (made by RedCMD) were also challenging to fix,
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+ * along with the rail-based instant dropper line built by ilmango. Numerous others made test cases as well, including
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+ * NarcolepticFrog, nessie, and Pokechu22.
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+ *
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+ * - The forward direction is determined locally. So when there are branches in the redstone wire, the left one will get updated
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+ * before the right one. Each branch can have its own relative forward direction, resulting in the left side of a left branch
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+ * having priority over the right branch of a left branch, which has priority over the left branch of a right branch, followed
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+ * by the right branch of a right branch. And so forth. Since redstone power reduces to zero after a path distance of 15,
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+ * that imposes a practical limit on the branching. Note that the branching is not tracked explicitly -- relative forward
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+ * directions dictate relative sort order, which maintains the proper global ordering. This also makes it unnecessary to be
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+ * concerned about branches meeting up with each other.
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+ *
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+ * ^
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+ * |
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+ * Forward
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+ * <-- Left Right -->
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+ *
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+ * 18
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+ * 10 17 5 19 11
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+ * 2 8 0 12 16 4 C 6 20 9 1 13 3
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+ * 14 21 7 23 15
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+ * Further 22 Further
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+ * Down Down Up Up
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+ *
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+ * Backward
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+ * |
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+ * V
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+ */
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+
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+ // This allows the above remapping tables to be looked up by cardial direction index
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+ private static final int[][] reordering = { forward_is_north, forward_is_east, forward_is_south, forward_is_west };
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+
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+ /*
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+ * Input: Array of UpdateNode objects in an order corresponding to the positions
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+ * computed by computeAllNeighbors above.
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+ * Output: Array of UpdateNode objects oriented using the above remapping tables
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+ * corresponding to the identified heading (direction of information flow).
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+ */
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+ private static void orientNeighbors(final UpdateNode[] src, final UpdateNode[] dst, final int heading) {
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+ final int[] re = reordering[heading];
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+ for (int i = 0; i < 24; i++) {
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+ dst[i] = src[re[i]];
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+ }
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+ }
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+
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+ /*
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+ * Structure to keep track of redstone wire blocks and
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+ * neighbors that will receive updates.
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+ */
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+ private static class UpdateNode {
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+ public static enum Type {
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+ UNKNOWN, REDSTONE, OTHER
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+ }
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+
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+ BlockState currentState; // Keep track of redstone wire value
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+ UpdateNode[] neighbor_nodes; // References to neighbors (directed graph edges)
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+ BlockPos self; // UpdateNode's own position
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+ BlockPos parent; // Which block pos spawned/updated this node
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+ Type type = Type.UNKNOWN; // unknown, redstone wire, other type of block
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+ int layer; // Highest layer this node is scheduled in
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+ boolean visited; // To keep track of information flow direction, visited restone wire is marked
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+ int xbias, zbias; // Remembers directionality of ancestor nodes; helps eliminate directional ambiguities.
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+ }
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+
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+ /*
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+ * Keep track of all block positions discovered during search and their current states.
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+ * We want to remember one entry for each position.
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+ */
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+ private final Map<BlockPos, UpdateNode> nodeCache = Maps.newHashMap();
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+
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+ /*
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+ * For a newly created UpdateNode object, determine what type of block it is.
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+ */
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+ private void identifyNode(final Level worldIn, final UpdateNode upd1) {
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+ final BlockPos pos = upd1.self;
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+ final BlockState oldState = worldIn.getBlockState(pos);
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+ upd1.currentState = oldState;
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+
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+ // Some neighbors of redstone wire are other kinds of blocks.
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+ // These need to receive block updates to inform them that
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+ // redstone wire values have changed.
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+ final Block block = oldState.getBlock();
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+ if (block != wire) {
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+ // Mark this block as not redstone wire and therefore
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+ // requiring updates
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+ upd1.type = UpdateNode.Type.OTHER;
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+
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+ // Non-redstone blocks may propagate updates, but those updates
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+ // are not handled by this accelerator. Therefore, we do not
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+ // expand this position's neighbors.
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+ return;
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+ }
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+
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+ // One job of BlockRedstoneWire.neighborChanged is to convert
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+ // redstone wires to items if the block beneath was removed.
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+ // With this accelerator, BlockRedstoneWire.neighborChanged
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+ // is only typically called for a single wire block, while
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+ // others are processed internally by the breadth first search
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+ // algorithm. To preserve this game behavior, this check must
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+ // be replicated here.
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+ if (!wire.canSurvive(null, worldIn, pos)) {
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+ // Pop off the redstone dust
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+ Block.popResource(worldIn, pos, new ItemStack(Items.REDSTONE)); // TODO
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+ worldIn.removeBlock(pos, false);
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+
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+ // Mark this position as not being redstone wire
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+ upd1.type = UpdateNode.Type.OTHER;
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+
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+ // Note: Sending updates to air blocks leads to an empty method.
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+ // Testing shows this to be faster than explicitly avoiding updates to
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+ // air blocks.
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+ return;
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+ }
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+
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+ // If the above conditions fail, then this is a redstone wire block.
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+ upd1.type = UpdateNode.Type.REDSTONE;
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+ }
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+
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+ /*
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+ * Given which redstone wire blocks have been visited and not visited
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+ * around the position currently being updated, compute the cardinal
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+ * direction that is "forward."
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+ *
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+ * rx is the forward direction along the West/East axis
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+ * rz is the forward direction along the North/South axis
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+ */
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+ static private int computeHeading(final int rx, final int rz) {
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+ // rx and rz can only take on values -1, 0, and 1, so we can
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+ // compute a code number that allows us to use a single switch
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+ // to determine the heading.
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+ final int code = (rx + 1) + 3 * (rz + 1);
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+ switch (code) {
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+ case 0: {
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+ // Both rx and rz are -1 (northwest)
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+ // Randomly choose one to be forward.
|
|
+ final int j = ThreadLocalRandom.current().nextInt(0, 1);
|
|
+ return (j == 0) ? North : West;
|
|
+ }
|
|
+ case 1: {
|
|
+ // rx=0, rz=-1
|
|
+ // Definitively North
|
|
+ return North;
|
|
+ }
|
|
+ case 2: {
|
|
+ // rx=1, rz=-1 (northeast)
|
|
+ // Choose randomly between north and east
|
|
+ final int j = ThreadLocalRandom.current().nextInt(0, 1);
|
|
+ return (j == 0) ? North : East;
|
|
+ }
|
|
+ case 3: {
|
|
+ // rx=-1, rz=0
|
|
+ // Definitively West
|
|
+ return West;
|
|
+ }
|
|
+ case 4: {
|
|
+ // rx=0, rz=0
|
|
+ // Heading is completely ambiguous. Choose
|
|
+ // randomly among the four cardinal directions.
|
|
+ return ThreadLocalRandom.current().nextInt(0, 4);
|
|
+ }
|
|
+ case 5: {
|
|
+ // rx=1, rz=0
|
|
+ // Definitively East
|
|
+ return East;
|
|
+ }
|
|
+ case 6: {
|
|
+ // rx=-1, rz=1 (southwest)
|
|
+ // Choose randomly between south and west
|
|
+ final int j = ThreadLocalRandom.current().nextInt(0, 1);
|
|
+ return (j == 0) ? South : West;
|
|
+ }
|
|
+ case 7: {
|
|
+ // rx=0, rz=1
|
|
+ // Definitively South
|
|
+ return South;
|
|
+ }
|
|
+ case 8: {
|
|
+ // rx=1, rz=1 (southeast)
|
|
+ // Choose randomly between south and east
|
|
+ final int j = ThreadLocalRandom.current().nextInt(0, 1);
|
|
+ return (j == 0) ? South : East;
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // We should never get here
|
|
+ return ThreadLocalRandom.current().nextInt(0, 4);
|
|
+ }
|
|
+
|
|
+ // Select whether to use updateSurroundingRedstone from BlockRedstoneWire (old)
|
|
+ // or this helper class (new)
|
|
+ private static final boolean old_current_change = false;
|
|
+
|
|
+ /*
|
|
+ * Process a node whose neighboring redstone wire has experienced value changes.
|
|
+ */
|
|
+ private void updateNode(final Level worldIn, final UpdateNode upd1, final int layer) {
|
|
+ final BlockPos pos = upd1.self;
|
|
+
|
|
+ // Mark this redstone wire as having been visited so that it can be used
|
|
+ // to calculate direction of information flow.
|
|
+ upd1.visited = true;
|
|
+
|
|
+ // Look up the last known state.
|
|
+ // Due to the way other redstone components are updated, we do not
|
|
+ // have to worry about a state changing behind our backs. The rare
|
|
+ // exception is handled by scheduleReentrantNeighborChanged.
|
|
+ final BlockState oldState = upd1.currentState;
|
|
+
|
|
+ // Ask the wire block to compute its power level from its neighbors.
|
|
+ // This will also update the wire's power level and return a new
|
|
+ // state if it has changed. When a wire power level is changed,
|
|
+ // calculateCurrentChanges will immediately update the block state in the world
|
|
+ // and return the same value here to be cached in the corresponding
|
|
+ // UpdateNode object.
|
|
+ BlockState newState;
|
|
+ if (old_current_change) {
|
|
+ newState = wire.calculateCurrentChanges(worldIn, pos, pos, oldState);
|
|
+ } else {
|
|
+ // Looking up block state is slow. This accelerator includes a version of
|
|
+ // calculateCurrentChanges that uses cahed wire values for a
|
|
+ // significant performance boost.
|
|
+ newState = this.calculateCurrentChanges(worldIn, upd1);
|
|
+ }
|
|
+
|
|
+ // Only inform neighbors if the state has changed
|
|
+ if (newState != oldState) {
|
|
+ // Store the new state
|
|
+ upd1.currentState = newState;
|
|
+
|
|
+ // Inform neighbors of the change
|
|
+ propagateChanges(worldIn, upd1, layer);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * This identifies the neighboring positions of a new UpdateNode object,
|
|
+ * determines their types, and links those to into the graph. Then based on
|
|
+ * what nodes in the redstone wire graph have been visited, the neighbors
|
|
+ * are reordered left-to-right relative to the direction of information flow.
|
|
+ */
|
|
+ private void findNeighbors(final Level worldIn, final UpdateNode upd1) {
|
|
+ final BlockPos pos = upd1.self;
|
|
+
|
|
+ // Get the list of neighbor coordinates
|
|
+ final BlockPos[] neighbors = computeAllNeighbors(pos);
|
|
+
|
|
+ // Temporary array of neighbors in cardinal ordering
|
|
+ final UpdateNode[] neighbor_nodes = new UpdateNode[24];
|
|
+
|
|
+ // Target array of neighbors sorted left-to-right
|
|
+ upd1.neighbor_nodes = new UpdateNode[24];
|
|
+
|
|
+ for (int i=0; i<24; i++) {
|
|
+ // Look up each neighbor in the node cache
|
|
+ final BlockPos pos2 = neighbors[i];
|
|
+ UpdateNode upd2 = nodeCache.get(pos2);
|
|
+ if (upd2 == null) {
|
|
+ // If this is a previously unreached position, create
|
|
+ // a new update node, add it to the cache, and identify what it is.
|
|
+ upd2 = new UpdateNode();
|
|
+ upd2.self = pos2;
|
|
+ upd2.parent = pos;
|
|
+ nodeCache.put(pos2, upd2);
|
|
+ identifyNode(worldIn, upd2);
|
|
+ }
|
|
+
|
|
+ // For non-redstone blocks, any of the 24 neighboring positions
|
|
+ // should receive a block update. However, some block coordinates
|
|
+ // may contain a redstone wire that does not directly connect to the
|
|
+ // one being expanded. To avoid redundant calculations and confusing
|
|
+ // cross-talk, those neighboring positions are not included.
|
|
+ if (update_redstone[i] || upd2.type != UpdateNode.Type.REDSTONE) {
|
|
+ neighbor_nodes[i] = upd2;
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // Determine the directions from which the redstone signal may have come from. This
|
|
+ // checks for redstone wire at the same Y level and also Y+1 and Y-1, relative to the
|
|
+ // block being expanded.
|
|
+ final boolean fromWest = (neighbor_nodes[0].visited || neighbor_nodes[7].visited || neighbor_nodes[8].visited);
|
|
+ final boolean fromEast = (neighbor_nodes[1].visited || neighbor_nodes[12].visited || neighbor_nodes[13].visited);
|
|
+ final boolean fromNorth = (neighbor_nodes[4].visited || neighbor_nodes[17].visited || neighbor_nodes[20].visited);
|
|
+ final boolean fromSouth = (neighbor_nodes[5].visited || neighbor_nodes[18].visited || neighbor_nodes[21].visited);
|
|
+
|
|
+ int cx = 0, cz = 0;
|
|
+ if (fromWest) cx += 1;
|
|
+ if (fromEast) cx -= 1;
|
|
+ if (fromNorth) cz += 1;
|
|
+ if (fromSouth) cz -= 1;
|
|
+
|
|
+ int heading;
|
|
+ if (cx==0 && cz==0) {
|
|
+ // If there is no clear direction, try to inherit the heading from ancestor nodes.
|
|
+ heading = computeHeading(upd1.xbias, upd1.zbias);
|
|
+
|
|
+ // Propagate that heading to descendant nodes.
|
|
+ for (int i=0; i<24; i++) {
|
|
+ final UpdateNode nn = neighbor_nodes[i];
|
|
+ if (nn != null) {
|
|
+ nn.xbias = upd1.xbias;
|
|
+ nn.zbias = upd1.zbias;
|
|
+ }
|
|
+ }
|
|
+ } else {
|
|
+ if (cx != 0 && cz != 0) {
|
|
+ // If the heading is somewhat ambiguous, try to disambiguate based on
|
|
+ // ancestor nodes.
|
|
+ if (upd1.xbias != 0) cz = 0;
|
|
+ if (upd1.zbias != 0) cx = 0;
|
|
+ }
|
|
+ heading = computeHeading(cx, cz);
|
|
+
|
|
+ // Propagate that heading to descendant nodes.
|
|
+ for (int i=0; i<24; i++) {
|
|
+ final UpdateNode nn = neighbor_nodes[i];
|
|
+ if (nn != null) {
|
|
+ nn.xbias = cx;
|
|
+ nn.zbias = cz;
|
|
+ }
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // Reorder neighboring UpdateNode objects according to the forward direction
|
|
+ // determined above.
|
|
+ orientNeighbors(neighbor_nodes, upd1.neighbor_nodes, heading);
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * For any redstone wire block in layer N, inform neighbors to recompute their states
|
|
+ * in layers N+1 and N+2;
|
|
+ */
|
|
+ private void propagateChanges(final Level worldIn, final UpdateNode upd1, final int layer) {
|
|
+ if (upd1.neighbor_nodes == null) {
|
|
+ // If this node has not been expanded yet, find its neighbors
|
|
+ findNeighbors(worldIn, upd1);
|
|
+ }
|
|
+
|
|
+ final BlockPos pos = upd1.self;
|
|
+
|
|
+ // All neighbors may be scheduled for layer N+1
|
|
+ final int layer1 = layer + 1;
|
|
+
|
|
+ // If the node being updated (upd1) has already been expanded, then merely
|
|
+ // schedule updates to its neighbors.
|
|
+ for (int i = 0; i < 24; i++) {
|
|
+ final UpdateNode upd2 = upd1.neighbor_nodes[i];
|
|
+
|
|
+ // This test ensures that an UpdateNode is never scheduled to the same layer
|
|
+ // more than once. Also, skip non-connecting redstone wire blocks
|
|
+ if (upd2 != null && layer1 > upd2.layer) {
|
|
+ upd2.layer = layer1;
|
|
+ updateQueue1.add(upd2);
|
|
+
|
|
+ // Keep track of which block updated this neighbor
|
|
+ upd2.parent = pos;
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // Nodes above and below are scheduled ALSO for layer N+2
|
|
+ final int layer2 = layer + 2;
|
|
+
|
|
+ // Repeat of the loop above, but only for the first four (above and below) neighbors
|
|
+ // and for layer N+2;
|
|
+ for (int i = 0; i < 4; i++) {
|
|
+ final UpdateNode upd2 = upd1.neighbor_nodes[i];
|
|
+ if (upd2 != null && layer2 > upd2.layer) {
|
|
+ upd2.layer = layer2;
|
|
+ updateQueue2.add(upd2);
|
|
+ upd2.parent = pos;
|
|
+ }
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // The breadth-first search below will send block updates to blocks
|
|
+ // that are not redstone wire. If one of those updates results in
|
|
+ // a distant redstone wire getting an update, then this.neighborChanged
|
|
+ // will get called. This would be a reentrant call, and
|
|
+ // it is necessary to properly integrate those updates into the
|
|
+ // on-going search through redstone wire. Thus, we make the layer
|
|
+ // currently being processed visible at the object level.
|
|
+
|
|
+ // The current layer being processed by the breadth-first search
|
|
+ private int currentWalkLayer = 0;
|
|
+
|
|
+ private void shiftQueue() {
|
|
+ final List<UpdateNode> t = updateQueue0;
|
|
+ t.clear();
|
|
+ updateQueue0 = updateQueue1;
|
|
+ updateQueue1 = updateQueue2;
|
|
+ updateQueue2 = t;
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * Perform a breadth-first (layer by layer) traversal through redstone
|
|
+ * wire blocks, propagating value changes to neighbors in an order
|
|
+ * that is a function of distance from the initial call to
|
|
+ * this.neighborChanged.
|
|
+ */
|
|
+ private void breadthFirstWalk(final Level worldIn) {
|
|
+ shiftQueue();
|
|
+ currentWalkLayer = 1;
|
|
+
|
|
+ // Loop over all layers
|
|
+ while (updateQueue0.size()>0 || updateQueue1.size()>0) {
|
|
+ // Get the set of blocks in this layer
|
|
+ final List<UpdateNode> thisLayer = updateQueue0;
|
|
+
|
|
+ // Loop over all blocks in the layer. Recall that
|
|
+ // this is a List, preserving the insertion order of
|
|
+ // left-to-right based on direction of information flow.
|
|
+ for (UpdateNode upd : thisLayer) {
|
|
+ if (upd.type == UpdateNode.Type.REDSTONE) {
|
|
+ // If the node is is redstone wire,
|
|
+ // schedule updates to neighbors if its value
|
|
+ // has changed.
|
|
+ updateNode(worldIn, upd, currentWalkLayer);
|
|
+ } else {
|
|
+ // If this block is not redstone wire, send a block update.
|
|
+ // Redstone wire blocks get state updates, but they don't
|
|
+ // need block updates. Only non-redstone neighbors need updates.
|
|
+
|
|
+ // World.neighborChanged is called from
|
|
+ // World.notifyNeighborsOfStateChange, and
|
|
+ // notifyNeighborsOfStateExcept. We don't use
|
|
+ // World.notifyNeighborsOfStateChange here, since we are
|
|
+ // already keeping track of all of the neighbor positions
|
|
+ // that need to be updated. All on its own, handling neighbors
|
|
+ // this way reduces block updates by 1/3 (24 instead of 36).
|
|
+// worldIn.neighborChanged(upd.self, wire, upd.parent);
|
|
+
|
|
+ // [Space Walker]
|
|
+ // The neighbor update system got a significant overhaul in 1.19.
|
|
+ // Shape and block updates are now added to a stack before being
|
|
+ // processed. These changes make it so any neighbor updates emitted
|
|
+ // by this accelerator will not be processed until after the entire
|
|
+ // wire network has updated. This has a significant impact on the
|
|
+ // behavior and introduces Vanilla parity issues.
|
|
+ // To circumvent this issue we bypass the neighbor update stack and
|
|
+ // call BlockStateBase#neighborChanged directly. This change mostly
|
|
+ // restores old behavior, at the cost of bypassing the
|
|
+ // max-chained-neighbor-updates server property.
|
|
+ worldIn.getBlockState(upd.self).handleNeighborChanged(worldIn, upd.self, wire, upd.parent, false);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // Move on to the next layer
|
|
+ shiftQueue();
|
|
+ currentWalkLayer++;
|
|
+ }
|
|
+
|
|
+ currentWalkLayer = 0;
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * Normally, when Minecraft is computing redstone wire power changes, and a wire power level
|
|
+ * change sends a block update to a neighboring functional component (e.g. piston, repeater, etc.),
|
|
+ * those updates are queued. Only once all redstone wire updates are complete will any component
|
|
+ * action generate any further block updates to redstone wire. Instant repeater lines, for instance,
|
|
+ * will process all wire updates for one redstone line, after which the pistons will zero-tick,
|
|
+ * after which the next redstone line performs all of its updates. Thus, each wire is processed in its
|
|
+ * own discrete wave.
|
|
+ *
|
|
+ * However, there are some corner cases where this pattern breaks, with a proof of concept discovered
|
|
+ * by Rays Works, which works the same in vanilla. The scenario is as follows:
|
|
+ * (1) A redstone wire is conducting a signal.
|
|
+ * (2) Part-way through that wave of updates, a neighbor is updated that causes an update to a completely
|
|
+ * separate redstone wire.
|
|
+ * (3) This results in a call to BlockRedstoneWire.neighborChanged for that other wire, in the middle of
|
|
+ * an already on-going propagation through the first wire.
|
|
+ *
|
|
+ * The vanilla code, being depth-first, would end up fully processing the second wire before going back
|
|
+ * to finish processing the first one. (Although technically, vanilla has no special concept of "being
|
|
+ * in the middle" of processing updates to a wire.) For the breadth-first algorithm, we give this
|
|
+ * situation special handling, where the updates for the second wire are incorporated into the schedule
|
|
+ * for the first wire, and then the callstack is allowed to unwind back to the on-going search loop in
|
|
+ * order to continue processing both the first and second wire in the order of distance from the initial
|
|
+ * trigger.
|
|
+ */
|
|
+ private BlockState scheduleReentrantNeighborChanged(final Level worldIn, final BlockPos pos, final BlockState newState, final BlockPos source) {
|
|
+ if (source != null) {
|
|
+ // If the cause of the redstone wire update is known, we can use that to help determine
|
|
+ // direction of information flow.
|
|
+ UpdateNode src = nodeCache.get(source);
|
|
+ if (src == null) {
|
|
+ src = new UpdateNode();
|
|
+ src.self = source;
|
|
+ src.parent = source;
|
|
+ src.visited = true;
|
|
+ identifyNode(worldIn, src);
|
|
+ nodeCache.put(source, src);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // Find or generate a node for the redstone block position receiving the update
|
|
+ UpdateNode upd = nodeCache.get(pos);
|
|
+ if (upd == null) {
|
|
+ upd = new UpdateNode();
|
|
+ upd.self = pos;
|
|
+ upd.parent = pos;
|
|
+ upd.visited = true;
|
|
+ identifyNode(worldIn, upd);
|
|
+ nodeCache.put(pos, upd);
|
|
+ }
|
|
+ upd.currentState = newState;
|
|
+
|
|
+ // Receiving this block update may mean something in the world changed.
|
|
+ // Therefore we clear the cached block info about all neighbors of
|
|
+ // the position receiving the update and then re-identify what they are.
|
|
+ if (upd.neighbor_nodes != null) {
|
|
+ for (int i=0; i<24; i++) {
|
|
+ final UpdateNode upd2 = upd.neighbor_nodes[i];
|
|
+ if (upd2 == null) continue;
|
|
+ upd2.type = UpdateNode.Type.UNKNOWN;
|
|
+ upd2.currentState = null;
|
|
+ identifyNode(worldIn, upd2);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // The block at 'pos' is a redstone wire and has been updated already by calling
|
|
+ // wire.calculateCurrentChanges, so we don't schedule that. However, we do need
|
|
+ // to schedule its neighbors. By passing the current value of 'currentWalkLayer' to
|
|
+ // propagateChanges, the neighbors of 'pos' are scheduled for layers currentWalkLayer+1
|
|
+ // and currentWalkLayer+2.
|
|
+ propagateChanges(worldIn, upd, currentWalkLayer);
|
|
+
|
|
+ // Return here. The call stack will unwind back to the first call to
|
|
+ // updateSurroundingRedstone, whereupon the new updates just scheduled will
|
|
+ // be propagated. This also facilitates elimination of superfluous and
|
|
+ // redundant block updates.
|
|
+ return newState;
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * New version of pre-existing updateSurroundingRedstone, which is called from
|
|
+ * wire.updateSurroundingRedstone, which is called from wire.neighborChanged and a
|
|
+ * few other methods in BlockRedstoneWire. This sets off the breadth-first
|
|
+ * walk through all redstone dust connected to the initial position triggered.
|
|
+ */
|
|
+ public BlockState updateSurroundingRedstone(final Level worldIn, final BlockPos pos, final BlockState state, final BlockPos source) {
|
|
+ // Check this block's neighbors and see if its power level needs to change
|
|
+ // Use the calculateCurrentChanges method in BlockRedstoneWire since we have no
|
|
+ // cached block states at this point.
|
|
+ final BlockState newState = wire.calculateCurrentChanges(worldIn, pos, pos, state);
|
|
+
|
|
+ // If no change, exit
|
|
+ if (newState == state) {
|
|
+ return state;
|
|
+ }
|
|
+
|
|
+ // Check to see if this update was received during an on-going breadth first search
|
|
+ if (currentWalkLayer > 0 || nodeCache.size() > 0) {
|
|
+ // As breadthFirstWalk progresses, it sends block updates to neighbors. Some of those
|
|
+ // neighbors may affect the world so as to cause yet another redstone wire block to receive
|
|
+ // an update. If that happens, we need to integrate those redstone wire updates into the
|
|
+ // already on-going graph walk being performed by breadthFirstWalk.
|
|
+ return scheduleReentrantNeighborChanged(worldIn, pos, newState, source);
|
|
+ }
|
|
+ // If there are no on-going walks through redstone wire, then start a new walk.
|
|
+
|
|
+ // If the source of the block update to the redstone wire at 'pos' is known, we can use
|
|
+ // that to help determine the direction of information flow.
|
|
+ if (source != null) {
|
|
+ final UpdateNode src = new UpdateNode();
|
|
+ src.self = source;
|
|
+ src.parent = source;
|
|
+ src.visited = true;
|
|
+ nodeCache.put(source, src);
|
|
+ identifyNode(worldIn, src);
|
|
+ }
|
|
+
|
|
+ // Create a node representing the block at 'pos', and then propagate updates
|
|
+ // to its neighbors. As stated above, the call to wire.calculateCurrentChanges
|
|
+ // already performs the update to the block at 'pos', so it is not added to the schedule.
|
|
+ final UpdateNode upd = new UpdateNode();
|
|
+ upd.self = pos;
|
|
+ upd.parent = source!=null ? source : pos;
|
|
+ upd.currentState = newState;
|
|
+ upd.type = UpdateNode.Type.REDSTONE;
|
|
+ upd.visited = true;
|
|
+ nodeCache.put(pos, upd);
|
|
+ propagateChanges(worldIn, upd, 0);
|
|
+
|
|
+ // Perform the walk over all directly reachable redstone wire blocks, propagating wire value
|
|
+ // updates in a breadth first order out from the initial update received for the block at 'pos'.
|
|
+ breadthFirstWalk(worldIn);
|
|
+
|
|
+ // With the whole search completed, clear the list of all known blocks.
|
|
+ // We do not want to keep around state information that may be changed by other code.
|
|
+ // In theory, we could cache the neighbor block positions, but that is a separate
|
|
+ // optimization.
|
|
+ nodeCache.clear();
|
|
+
|
|
+ return newState;
|
|
+ }
|
|
+
|
|
+ // For any array of neighbors in an UpdateNode object, these are always
|
|
+ // the indices of the four immediate neighbors at the same Y coordinate.
|
|
+ private static final int[] rs_neighbors = {4, 5, 6, 7};
|
|
+ private static final int[] rs_neighbors_up = {9, 11, 13, 15};
|
|
+ private static final int[] rs_neighbors_dn = {8, 10, 12, 14};
|
|
+
|
|
+ /*
|
|
+ * Updated calculateCurrentChanges that is optimized for speed and uses
|
|
+ * the UpdateNode's neighbor array to find the redstone states of neighbors
|
|
+ * that might power it.
|
|
+ */
|
|
+ private BlockState calculateCurrentChanges(final Level worldIn, final UpdateNode upd) {
|
|
+ BlockState state = upd.currentState;
|
|
+ final int i = state.getValue(RedStoneWireBlock.POWER).intValue();
|
|
+ int j = 0;
|
|
+ j = getMaxCurrentStrength(upd, j);
|
|
+ int l = 0;
|
|
+
|
|
+ wire.shouldSignal = false;
|
|
+ // Unfortunately, World.isBlockIndirectlyGettingPowered is complicated,
|
|
+ // and I'm not ready to try to replicate even more functionality from
|
|
+ // elsewhere in Minecraft into this accelerator. So sadly, we must
|
|
+ // suffer the performance hit of this very expensive call. If there
|
|
+ // is consistency to what this call returns, we may be able to cache it.
|
|
+ final int k = worldIn.getBestNeighborSignal(upd.self);
|
|
+ wire.shouldSignal = true;
|
|
+
|
|
+ // The variable 'k' holds the maximum redstone power value of any adjacent blocks.
|
|
+ // If 'k' has the highest level of all neighbors, then the power level of this
|
|
+ // redstone wire will be set to 'k'. If 'k' is already 15, then nothing inside the
|
|
+ // following loop can affect the power level of the wire. Therefore, the loop is
|
|
+ // skipped if k is already 15.
|
|
+ if (k < 15) {
|
|
+ if (upd.neighbor_nodes == null) {
|
|
+ // If this node's neighbors are not known, expand the node
|
|
+ findNeighbors(worldIn, upd);
|
|
+ }
|
|
+
|
|
+ // These remain constant, so pull them out of the loop.
|
|
+ // Regardless of which direction is forward, the UpdateNode for the
|
|
+ // position directly above the node being calculated is always
|
|
+ // at index 1.
|
|
+ UpdateNode center_up = upd.neighbor_nodes[1];
|
|
+ boolean center_up_is_cube = center_up.currentState.isRedstoneConductor(worldIn, center_up.self); // TODO
|
|
+
|
|
+ for (int m = 0; m < 4; m++) {
|
|
+ // Get the neighbor array index of each of the four cardinal
|
|
+ // neighbors.
|
|
+ int n = rs_neighbors[m];
|
|
+
|
|
+ // Get the max redstone power level of each of the cardinal
|
|
+ // neighbors
|
|
+ UpdateNode neighbor = upd.neighbor_nodes[n];
|
|
+ l = getMaxCurrentStrength(neighbor, l);
|
|
+
|
|
+ // Also check the positions above and below the cardinal
|
|
+ // neighbors
|
|
+ boolean neighbor_is_cube = neighbor.currentState.isRedstoneConductor(worldIn, neighbor.self); // TODO
|
|
+ if (!neighbor_is_cube) {
|
|
+ UpdateNode neighbor_down = upd.neighbor_nodes[rs_neighbors_dn[m]];
|
|
+ l = getMaxCurrentStrength(neighbor_down, l);
|
|
+ } else
|
|
+ if (!center_up_is_cube) {
|
|
+ UpdateNode neighbor_up = upd.neighbor_nodes[rs_neighbors_up[m]];
|
|
+ l = getMaxCurrentStrength(neighbor_up, l);
|
|
+ }
|
|
+ }
|
|
+ }
|
|
+
|
|
+ // The new code sets this RedstoneWire block's power level to the highest neighbor
|
|
+ // minus 1. This usually results in wire power levels dropping by 2 at a time.
|
|
+ // This optimization alone has no impact on update order, only the number of updates.
|
|
+ j = l - 1;
|
|
+
|
|
+ // If 'l' turns out to be zero, then j will be set to -1, but then since 'k' will
|
|
+ // always be in the range of 0 to 15, the following if will correct that.
|
|
+ if (k > j) j = k;
|
|
+
|
|
+ // egg82's amendment
|
|
+ // Adding Bukkit's BlockRedstoneEvent - er.. event.
|
|
+ if (i != j) {
|
|
+ BlockRedstoneEvent event = new BlockRedstoneEvent(CraftBlock.at(worldIn, upd.self), i, j);
|
|
+ worldIn.getCraftServer().getPluginManager().callEvent(event);
|
|
+ j = event.getNewCurrent();
|
|
+ }
|
|
+
|
|
+ if (i != j) {
|
|
+ // If the power level has changed from its previous value, compute a new state
|
|
+ // and set it in the world.
|
|
+ // Possible optimization: Don't commit state changes to the world until they
|
|
+ // need to be known by some nearby non-redstone-wire block.
|
|
+ BlockPos pos = new BlockPos(upd.self.getX(), upd.self.getY(), upd.self.getZ());
|
|
+ if (wire.canSurvive(null, worldIn, pos)) {
|
|
+ state = state.setValue(RedStoneWireBlock.POWER, Integer.valueOf(j));
|
|
+ // [Space Walker] suppress shape updates and emit those manually to
|
|
+ // bypass the new neighbor update stack.
|
|
+ if (worldIn.setBlock(upd.self, state, Block.UPDATE_KNOWN_SHAPE | Block.UPDATE_CLIENTS))
|
|
+ updateNeighborShapes(worldIn, upd.self, state);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ return state;
|
|
+ }
|
|
+
|
|
+ private static final Direction[] UPDATE_SHAPE_ORDER = { Direction.WEST, Direction.EAST, Direction.NORTH, Direction.SOUTH, Direction.DOWN, Direction.UP };
|
|
+
|
|
+ /*
|
|
+ * [Space Walker]
|
|
+ * This method emits shape updates around the given block,
|
|
+ * bypassing the new neighbor update stack. Diagonal shape
|
|
+ * updates are omitted, as they are mostly unnecessary.
|
|
+ * Diagonal shape updates are emitted exclusively to other
|
|
+ * redstone wires, in order to update their connection properties.
|
|
+ * Wire connections should never change as a result of power
|
|
+ * changes, so the only behavioral change will be in scenarios
|
|
+ * where earlier shape updates have been suppressed to keep a
|
|
+ * redstone wire in an invalid state.
|
|
+ */
|
|
+ public void updateNeighborShapes(Level level, BlockPos pos, BlockState state) {
|
|
+ // these updates will be added to the stack and processed after the entire network has updated
|
|
+ state.updateIndirectNeighbourShapes(level, pos, Block.UPDATE_KNOWN_SHAPE | Block.UPDATE_CLIENTS);
|
|
+
|
|
+ for (Direction dir : UPDATE_SHAPE_ORDER) {
|
|
+ BlockPos neighborPos = pos.relative(dir);
|
|
+ BlockState neighborState = level.getBlockState(neighborPos);
|
|
+
|
|
+ BlockState newState = neighborState.updateShape(dir.getOpposite(), state, level, neighborPos, pos);
|
|
+ Block.updateOrDestroy(neighborState, newState, level, neighborPos, Block.UPDATE_CLIENTS);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * Optimized function to compute a redstone wire's power level based on cached
|
|
+ * state.
|
|
+ */
|
|
+ private static int getMaxCurrentStrength(final UpdateNode upd, final int strength) {
|
|
+ if (upd.type != UpdateNode.Type.REDSTONE) return strength;
|
|
+ final int i = upd.currentState.getValue(RedStoneWireBlock.POWER).intValue();
|
|
+ return i > strength ? i : strength;
|
|
+ }
|
|
+}
|
|
diff --git a/src/main/java/net/minecraft/world/level/block/RedStoneWireBlock.java b/src/main/java/net/minecraft/world/level/block/RedStoneWireBlock.java
|
|
index c73bf0b36252796ca93c500affa2be568e3f6c9e..18ed178223cca85dbba65b1e07741622e266d318 100644
|
|
--- a/src/main/java/net/minecraft/world/level/block/RedStoneWireBlock.java
|
|
+++ b/src/main/java/net/minecraft/world/level/block/RedStoneWireBlock.java
|
|
@@ -258,6 +258,116 @@ public class RedStoneWireBlock extends Block {
|
|
return floor.isFaceSturdy(world, pos, Direction.UP) || floor.is(Blocks.HOPPER);
|
|
}
|
|
|
|
+ // Paper start - Optimize redstone
|
|
+ // The bulk of the new functionality is found in RedstoneWireTurbo.java
|
|
+ com.destroystokyo.paper.util.RedstoneWireTurbo turbo = new com.destroystokyo.paper.util.RedstoneWireTurbo(this);
|
|
+
|
|
+ /*
|
|
+ * Modified version of pre-existing updateSurroundingRedstone, which is called from
|
|
+ * this.neighborChanged and a few other methods in this class.
|
|
+ * Note: Added 'source' argument so as to help determine direction of information flow
|
|
+ */
|
|
+ private void updateSurroundingRedstone(Level worldIn, BlockPos pos, BlockState state, BlockPos source) {
|
|
+ if (worldIn.paperConfig().misc.redstoneImplementation == io.papermc.paper.configuration.WorldConfiguration.Misc.RedstoneImplementation.EIGENCRAFT) {
|
|
+ turbo.updateSurroundingRedstone(worldIn, pos, state, source);
|
|
+ return;
|
|
+ }
|
|
+ updatePowerStrength(worldIn, pos, state);
|
|
+ }
|
|
+
|
|
+ /*
|
|
+ * Slightly modified method to compute redstone wire power levels from neighboring blocks.
|
|
+ * Modifications cut the number of power level changes by about 45% from vanilla, and this
|
|
+ * optimization synergizes well with the breadth-first search implemented in
|
|
+ * RedstoneWireTurbo.
|
|
+ * Note: RedstoneWireTurbo contains a faster version of this code.
|
|
+ * Note: Made this public so that RedstoneWireTurbo can access it.
|
|
+ */
|
|
+ public BlockState calculateCurrentChanges(Level worldIn, BlockPos pos1, BlockPos pos2, BlockState state) {
|
|
+ BlockState iblockstate = state;
|
|
+ int i = state.getValue(POWER);
|
|
+ int j = 0;
|
|
+ j = this.getPower(j, worldIn.getBlockState(pos2));
|
|
+ this.shouldSignal = false;
|
|
+ int k = worldIn.getBestNeighborSignal(pos1);
|
|
+ this.shouldSignal = true;
|
|
+
|
|
+ if (worldIn.paperConfig().misc.redstoneImplementation == io.papermc.paper.configuration.WorldConfiguration.Misc.RedstoneImplementation.VANILLA) {
|
|
+ // This code is totally redundant to if statements just below the loop.
|
|
+ if (k > 0 && k > j - 1) {
|
|
+ j = k;
|
|
+ }
|
|
+ }
|
|
+
|
|
+ int l = 0;
|
|
+
|
|
+ // The variable 'k' holds the maximum redstone power value of any adjacent blocks.
|
|
+ // If 'k' has the highest level of all neighbors, then the power level of this
|
|
+ // redstone wire will be set to 'k'. If 'k' is already 15, then nothing inside the
|
|
+ // following loop can affect the power level of the wire. Therefore, the loop is
|
|
+ // skipped if k is already 15.
|
|
+ if (worldIn.paperConfig().misc.redstoneImplementation == io.papermc.paper.configuration.WorldConfiguration.Misc.RedstoneImplementation.VANILLA || k < 15) {
|
|
+ for (Direction enumfacing : Direction.Plane.HORIZONTAL) {
|
|
+ BlockPos blockpos = pos1.relative(enumfacing);
|
|
+ boolean flag = blockpos.getX() != pos2.getX() || blockpos.getZ() != pos2.getZ();
|
|
+
|
|
+ if (flag) {
|
|
+ l = this.getPower(l, worldIn.getBlockState(blockpos));
|
|
+ }
|
|
+
|
|
+ if (worldIn.getBlockState(blockpos).isRedstoneConductor(worldIn, blockpos) && !worldIn.getBlockState(pos1.above()).isRedstoneConductor(worldIn, pos1)) {
|
|
+ if (flag && pos1.getY() >= pos2.getY()) {
|
|
+ l = this.getPower(l, worldIn.getBlockState(blockpos.above()));
|
|
+ }
|
|
+ } else if (!worldIn.getBlockState(blockpos).isRedstoneConductor(worldIn, blockpos) && flag && pos1.getY() <= pos2.getY()) {
|
|
+ l = this.getPower(l, worldIn.getBlockState(blockpos.below()));
|
|
+ }
|
|
+ }
|
|
+ }
|
|
+
|
|
+ if (worldIn.paperConfig().misc.redstoneImplementation == io.papermc.paper.configuration.WorldConfiguration.Misc.RedstoneImplementation.VANILLA) {
|
|
+ // The old code would decrement the wire value only by 1 at a time.
|
|
+ if (l > j) {
|
|
+ j = l - 1;
|
|
+ } else if (j > 0) {
|
|
+ --j;
|
|
+ } else {
|
|
+ j = 0;
|
|
+ }
|
|
+
|
|
+ if (k > j - 1) {
|
|
+ j = k;
|
|
+ }
|
|
+ } else {
|
|
+ // The new code sets this RedstoneWire block's power level to the highest neighbor
|
|
+ // minus 1. This usually results in wire power levels dropping by 2 at a time.
|
|
+ // This optimization alone has no impact on update order, only the number of updates.
|
|
+ j = l - 1;
|
|
+
|
|
+ // If 'l' turns out to be zero, then j will be set to -1, but then since 'k' will
|
|
+ // always be in the range of 0 to 15, the following if will correct that.
|
|
+ if (k > j) j = k;
|
|
+ }
|
|
+
|
|
+ if (i != j) {
|
|
+ org.bukkit.event.block.BlockRedstoneEvent event = new org.bukkit.event.block.BlockRedstoneEvent(org.bukkit.craftbukkit.block.CraftBlock.at(worldIn, pos1), i, j);
|
|
+ worldIn.getCraftServer().getPluginManager().callEvent(event);
|
|
+
|
|
+ j = event.getNewCurrent();
|
|
+ state = state.setValue(POWER, j);
|
|
+
|
|
+ if (worldIn.getBlockState(pos1) == iblockstate) {
|
|
+ // [Space Walker] suppress shape updates and emit those manually to
|
|
+ // bypass the new neighbor update stack.
|
|
+ if (worldIn.setBlock(pos1, state, Block.UPDATE_KNOWN_SHAPE | Block.UPDATE_CLIENTS))
|
|
+ turbo.updateNeighborShapes(worldIn, pos1, state);
|
|
+ }
|
|
+ }
|
|
+
|
|
+ return state;
|
|
+ }
|
|
+ // Paper end
|
|
+
|
|
private void updatePowerStrength(Level world, BlockPos pos, BlockState state) {
|
|
int i = this.calculateTargetStrength(world, pos);
|
|
|
|
@@ -327,6 +437,7 @@ public class RedStoneWireBlock extends Block {
|
|
return Math.max(i, j - 1);
|
|
}
|
|
|
|
+ private int getPower(int min, BlockState iblockdata) { return Math.max(min, getWireSignal(iblockdata)); } // Paper - Optimize redstone
|
|
private int getWireSignal(BlockState state) {
|
|
return state.is((Block) this) ? (Integer) state.getValue(RedStoneWireBlock.POWER) : 0;
|
|
}
|
|
@@ -349,7 +460,7 @@ public class RedStoneWireBlock extends Block {
|
|
@Override
|
|
protected void onPlace(BlockState state, Level world, BlockPos pos, BlockState oldState, boolean notify) {
|
|
if (!oldState.is(state.getBlock()) && !world.isClientSide) {
|
|
- this.updatePowerStrength(world, pos, state);
|
|
+ this.updateSurroundingRedstone(world, pos, state, null); // Paper - Optimize redstone
|
|
Iterator iterator = Direction.Plane.VERTICAL.iterator();
|
|
|
|
while (iterator.hasNext()) {
|
|
@@ -376,7 +487,7 @@ public class RedStoneWireBlock extends Block {
|
|
world.updateNeighborsAt(pos.relative(enumdirection), this);
|
|
}
|
|
|
|
- this.updatePowerStrength(world, pos, state);
|
|
+ this.updateSurroundingRedstone(world, pos, state, null); // Paper - Optimize redstone
|
|
this.updateNeighborsOfNeighboringWires(world, pos);
|
|
}
|
|
}
|
|
@@ -411,7 +522,7 @@ public class RedStoneWireBlock extends Block {
|
|
protected void neighborChanged(BlockState state, Level world, BlockPos pos, Block sourceBlock, BlockPos sourcePos, boolean notify) {
|
|
if (!world.isClientSide) {
|
|
if (state.canSurvive(world, pos)) {
|
|
- this.updatePowerStrength(world, pos, state);
|
|
+ this.updateSurroundingRedstone(world, pos, state, sourcePos); // Paper - Optimize redstone
|
|
} else {
|
|
dropResources(state, world, pos);
|
|
world.removeBlock(pos, false);
|