/**
* Get the total energy request in this network
*
* @param ignoreTiles Tiles to ignore in the request calculations (NOTE: only used in initial
* (internal) check.
* @return Amount of energy requested in this network
*/
@Override
public float getRequest(TileEntity... ignoreTiles) {
if (EnergyNetwork.tickCount != this.tickDone) {
// Start the new tick - initialise everything
this.ignoreAcceptors.clear();
this.ignoreAcceptors.addAll(Arrays.asList(ignoreTiles));
this.doTickStartCalc();
if (EnergyConfigHandler.isBuildcraftLoaded()) {
for (IConductor wire : this.conductors) {
if (wire instanceof TileBaseUniversalConductor) {
// This will call getRequest() but that's no problem, on the second call it will just
// return the totalRequested
((TileBaseUniversalConductor) wire).reconfigureBC();
}
}
}
}
return this.totalRequested - this.totalEnergy - this.totalSent;
}
/**
* A universal network that works with multiple energy systems.
*
* @author radfast, micdoodle8, Calclavia, Aidancbrady
*/
public class EnergyNetwork implements IElectricityNetwork {
private boolean isMekLoaded =
EnergyConfigHandler.isMekanismLoaded() && !EnergyConfigHandler.disableMekanismOutput;
private boolean isRF1Loaded =
EnergyConfigHandler.isRFAPIv1Loaded() && !EnergyConfigHandler.disableRFOutput;
private boolean isRF2Loaded =
EnergyConfigHandler.isRFAPIv2Loaded() && !EnergyConfigHandler.disableRFOutput;
private boolean isIC2Loaded =
EnergyConfigHandler.isIndustrialCraft2Loaded() && !EnergyConfigHandler.disableIC2Output;
private boolean isBCLoaded =
EnergyConfigHandler.isBuildcraftLoaded() && !EnergyConfigHandler.disableBuildCraftOutput;
/* Re-written by radfast for better performance
*
* Imagine a 30 producer, 80 acceptor network...
*
* Before: it would have called the inner loop in produce() 2400 times each tick. Not good!
*
* After: the inner loop runs 80 times - part of it is in doTickStartCalc() at/near the tick start, and part of it is in doProduce() at the end of the tick
*/
public static int tickCount = 0;
private int tickDone = -1;
private float totalRequested = 0F;
private float totalStorageExcess = 0F;
private float totalEnergy = 0F;
private float totalSent = 0F;
private boolean doneScheduled = false;
private boolean spamstop = false;
private boolean loopPrevention = false;
public int networkTierGC = 1;
private int producersTierGC = 1;
/*
* connectedAcceptors is all the acceptors connected to this network
* connectedDirections is the directions of those connections (from the point of view of the acceptor tile)
* Note: each position in those two linked lists matches
* so, an acceptor connected on two sides will be in connectedAcceptors twice
*/
private List<TileEntity> connectedAcceptors = new LinkedList<TileEntity>();
private List<ForgeDirection> connectedDirections = new LinkedList<ForgeDirection>();
/*
* availableAcceptors is the acceptors which can receive energy (this tick)
* availableconnectedDirections is a map of those acceptors and the directions they will receive from (from the point of view of the acceptor tile)
* Note: each acceptor will only be included once in these collections
* (there is no point trying to put power into a machine twice from two different sides)
*/
private Set<TileEntity> availableAcceptors = new HashSet<TileEntity>();
private Map<TileEntity, ForgeDirection> availableconnectedDirections =
new HashMap<TileEntity, ForgeDirection>();
private Map<TileEntity, Float> energyRequests = new HashMap<TileEntity, Float>();
private List<TileEntity> ignoreAcceptors = new LinkedList<TileEntity>();
private final Set<IConductor> conductors = new HashSet<IConductor>();
// This is an energy per tick which exceeds what any normal machine will request, so the requester
// must be an energy storage - for example, a battery or an energy cube
private static final float ENERGY_STORAGE_LEVEL = 200F;
@Override
public Set<IConductor> getTransmitters() {
return this.conductors;
}
/**
* Get the total energy request in this network
*
* @param ignoreTiles Tiles to ignore in the request calculations (NOTE: only used in initial
* (internal) check.
* @return Amount of energy requested in this network
*/
@Override
public float getRequest(TileEntity... ignoreTiles) {
if (EnergyNetwork.tickCount != this.tickDone) {
// Start the new tick - initialise everything
this.ignoreAcceptors.clear();
this.ignoreAcceptors.addAll(Arrays.asList(ignoreTiles));
this.doTickStartCalc();
if (EnergyConfigHandler.isBuildcraftLoaded()) {
for (IConductor wire : this.conductors) {
if (wire instanceof TileBaseUniversalConductor) {
// This will call getRequest() but that's no problem, on the second call it will just
// return the totalRequested
((TileBaseUniversalConductor) wire).reconfigureBC();
}
}
}
}
return this.totalRequested - this.totalEnergy - this.totalSent;
}
/**
* Produce energy into the network
*
* @param energy Amount of energy to send into the network
* @param doReceive Whether to put energy into the network (true) or just simulate (false)
* @param ignoreTiles TileEntities to ignore for energy transfers.
* @return Amount of energy REMAINING from the passed energy parameter
*/
@Override
public float produce(
float energy, boolean doReceive, int producerTier, TileEntity... ignoreTiles) {
if (this.loopPrevention) {
return energy;
}
if (energy > 0F) {
if (EnergyNetwork.tickCount != this.tickDone) {
this.tickDone = EnergyNetwork.tickCount;
// Start the new tick - initialise everything
this.ignoreAcceptors.clear();
this.ignoreAcceptors.addAll(Arrays.asList(ignoreTiles));
this.producersTierGC = 1;
this.doTickStartCalc();
} else {
this.ignoreAcceptors.addAll(Arrays.asList(ignoreTiles));
}
if (!this.doneScheduled && this.totalRequested > 0.0F) {
TickHandlerServer.scheduleNetworkTick(this);
this.doneScheduled = true;
}
// On a regular mid-tick produce(), just figure out how much is totalEnergy this tick and
// return the used amount
// This will return 0 if totalRequested is 0 - for example a network with no acceptors
float totalEnergyLast = this.totalEnergy;
// Add the energy for distribution by this grid later this tick
// Note: totalEnergy cannot exceed totalRequested
if (doReceive) {
this.totalEnergy += Math.min(energy, this.totalRequested - totalEnergyLast);
if (producerTier > 1) {
this.producersTierGC = 2;
}
}
if (this.totalRequested >= totalEnergyLast + energy) {
return 0F; // All the electricity will be used
}
if (totalEnergyLast >= this.totalRequested) {
return energy; // None of the electricity will be used
}
return totalEnergyLast + energy - this.totalRequested; // Some of the electricity will be used
}
return energy;
}
/** Called on server tick end, from the Galacticraft Core tick handler. */
public void tickEnd() {
this.doneScheduled = false;
this.loopPrevention = true;
// Finish the last tick if there was some to send and something to receive it
if (this.totalEnergy > 0F) {
// Call doTickStartCalc a second time in case anything has updated meanwhile
this.doTickStartCalc();
if (this.totalRequested > 0F) {
this.totalSent = this.doProduce();
if (this.totalSent < this.totalEnergy) {
// Any spare energy left is retained for the next tick
this.totalEnergy -= this.totalSent;
} else {
this.totalEnergy = 0F;
}
} else this.totalEnergy = 0F;
} else {
this.totalEnergy = 0F;
}
this.loopPrevention = false;
}
/**
* Refreshes all tiles in network, and updates requested energy
*
* @param ignoreTiles TileEntities to ignore for energy calculations.
*/
private void doTickStartCalc() {
this.tickDone = EnergyNetwork.tickCount;
this.totalSent = 0F;
this.refreshAcceptors();
if (!EnergyUtil.initialisedIC2Methods) {
EnergyUtil.initialiseIC2Methods();
}
if (this.conductors.size() == 0) {
return;
}
this.loopPrevention = true;
this.availableAcceptors.clear();
this.availableconnectedDirections.clear();
this.energyRequests.clear();
this.totalRequested = 0.0F;
this.totalStorageExcess = 0F;
if (!this.connectedAcceptors.isEmpty()) {
float e;
final Iterator<ForgeDirection> acceptorDirection = this.connectedDirections.iterator();
for (TileEntity acceptor : this.connectedAcceptors) {
// This tries all sides of the acceptor which are connected (see refreshAcceptors())
ForgeDirection sideFrom = acceptorDirection.next();
// But the grid will only put energy into the acceptor from one side - once it's in
// availableAcceptors
if (!this.ignoreAcceptors.contains(acceptor)
&& !this.availableAcceptors.contains(acceptor)) {
e = 0.0F;
if (acceptor instanceof IElectrical) {
e = ((IElectrical) acceptor).getRequest(sideFrom);
} else if (isRF2Loaded && acceptor instanceof IEnergyReceiver) {
e =
((IEnergyReceiver) acceptor).receiveEnergy(sideFrom, Integer.MAX_VALUE, true)
/ EnergyConfigHandler.TO_RF_RATIO;
} else if (isMekLoaded && acceptor instanceof IStrictEnergyAcceptor) {
e =
(float)
((((IStrictEnergyAcceptor) acceptor).getMaxEnergy()
- ((IStrictEnergyAcceptor) acceptor).getEnergy())
/ EnergyConfigHandler.TO_MEKANISM_RATIO);
} else if (isRF1Loaded && acceptor instanceof IEnergyHandler) {
e =
((IEnergyHandler) acceptor).receiveEnergy(sideFrom, Integer.MAX_VALUE, true)
/ EnergyConfigHandler.TO_RF_RATIO;
} else if (isIC2Loaded && acceptor instanceof IEnergySink) {
double result = 0;
try {
result = (Double) EnergyUtil.demandedEnergyIC2.invoke(acceptor);
} catch (Exception ex) {
if (ConfigManagerCore.enableDebug) {
ex.printStackTrace();
}
}
// Cap IC2 power transfer at 128EU/t for standard Alu wire, 256EU/t for heavy Alu wire
result = Math.max(result, (this.networkTierGC == 2) ? 256D : 128D);
e = (float) result / EnergyConfigHandler.TO_IC2_RATIO;
} else if (isBCLoaded
&& EnergyConfigHandler.getBuildcraftVersion() == 6
&& MjAPI.getMjBattery(acceptor, MjAPI.DEFAULT_POWER_FRAMEWORK, sideFrom) != null)
// New BC API
{
e =
(float)
MjAPI.getMjBattery(acceptor, MjAPI.DEFAULT_POWER_FRAMEWORK, sideFrom)
.getEnergyRequested()
/ EnergyConfigHandler.TO_BC_RATIO;
} else if (isBCLoaded && acceptor instanceof IPowerReceptor)
// Legacy BC API
{
PowerReceiver BCreceiver = ((IPowerReceptor) acceptor).getPowerReceiver(sideFrom);
if (BCreceiver != null) {
e = (float) BCreceiver.powerRequest() / EnergyConfigHandler.TO_BC_RATIO;
}
}
if (e > 0.0F) {
this.availableAcceptors.add(acceptor);
this.availableconnectedDirections.put(acceptor, sideFrom);
this.energyRequests.put(acceptor, Float.valueOf(e));
this.totalRequested += e;
if (e > EnergyNetwork.ENERGY_STORAGE_LEVEL) {
this.totalStorageExcess += e - EnergyNetwork.ENERGY_STORAGE_LEVEL;
}
}
}
}
}
this.loopPrevention = false;
}
/**
* Complete the energy transfer. Called internally on server tick end.
*
* @return Amount of energy SENT to all acceptors
*/
private float doProduce() {
float sent = 0.0F;
if (!this.availableAcceptors.isEmpty()) {
float energyNeeded = this.totalRequested;
float energyAvailable = this.totalEnergy;
float reducor = 1.0F;
float energyStorageReducor = 1.0F;
if (energyNeeded > energyAvailable) {
// If not enough energy, try reducing what goes into energy storage (if any)
energyNeeded -= this.totalStorageExcess;
// If there's still not enough, put the minimum into energy storage (if any) and, anyhow,
// reduce everything proportionately
if (energyNeeded > energyAvailable) {
energyStorageReducor = 0F;
reducor = energyAvailable / energyNeeded;
} else {
// Energyavailable exceeds the total needed but only if storage does not fill all in one
// go - this is a common situation
energyStorageReducor = (energyAvailable - energyNeeded) / this.totalStorageExcess;
}
}
float currentSending;
float sentToAcceptor;
int tierProduced = Math.min(this.producersTierGC, this.networkTierGC);
TileEntity debugTE = null;
try {
for (TileEntity tileEntity : this.availableAcceptors) {
debugTE = tileEntity;
// Exit the loop if there is no energy left at all (should normally not happen, should be
// some even for the last acceptor)
if (sent >= energyAvailable) {
break;
}
// The base case is to give each acceptor what it is requesting
currentSending = this.energyRequests.get(tileEntity);
// If it's an energy store, we may need to damp it down if energyStorageReducor is less
// than 1
if (currentSending > EnergyNetwork.ENERGY_STORAGE_LEVEL) {
currentSending =
EnergyNetwork.ENERGY_STORAGE_LEVEL
+ (currentSending - EnergyNetwork.ENERGY_STORAGE_LEVEL) * energyStorageReducor;
}
// Reduce everything proportionately if there is not enough energy for all needs
currentSending *= reducor;
if (currentSending > energyAvailable - sent) {
currentSending = energyAvailable - sent;
}
ForgeDirection sideFrom = this.availableconnectedDirections.get(tileEntity);
if (tileEntity instanceof IElectrical) {
sentToAcceptor =
((IElectrical) tileEntity)
.receiveElectricity(sideFrom, currentSending, tierProduced, true);
} else if (isRF2Loaded && tileEntity instanceof IEnergyReceiver) {
final int currentSendinginRF =
(currentSending >= Integer.MAX_VALUE / EnergyConfigHandler.TO_RF_RATIO)
? Integer.MAX_VALUE
: (int) (currentSending * EnergyConfigHandler.TO_RF_RATIO);
sentToAcceptor =
((IEnergyReceiver) tileEntity).receiveEnergy(sideFrom, currentSendinginRF, false)
/ EnergyConfigHandler.TO_RF_RATIO;
} else if (isMekLoaded && tileEntity instanceof IStrictEnergyAcceptor) {
sentToAcceptor =
(float)
((IStrictEnergyAcceptor) tileEntity)
.transferEnergyToAcceptor(
sideFrom, currentSending * EnergyConfigHandler.TO_MEKANISM_RATIO)
/ EnergyConfigHandler.TO_MEKANISM_RATIO;
} else if (isRF1Loaded && tileEntity instanceof IEnergyHandler) {
final int currentSendinginRF =
(currentSending >= Integer.MAX_VALUE / EnergyConfigHandler.TO_RF_RATIO)
? Integer.MAX_VALUE
: (int) (currentSending * EnergyConfigHandler.TO_RF_RATIO);
sentToAcceptor =
((IEnergyHandler) tileEntity).receiveEnergy(sideFrom, currentSendinginRF, false)
/ EnergyConfigHandler.TO_RF_RATIO;
} else if (isIC2Loaded && tileEntity instanceof IEnergySink) {
double energySendingIC2 = currentSending * EnergyConfigHandler.TO_IC2_RATIO;
if (energySendingIC2 >= 1D) {
double result = 0;
try {
if (EnergyUtil.voltageParameterIC2) {
result =
(Double)
EnergyUtil.injectEnergyIC2.invoke(
tileEntity, sideFrom, energySendingIC2, 120D);
} else {
result =
(Double)
EnergyUtil.injectEnergyIC2.invoke(tileEntity, sideFrom, energySendingIC2);
}
} catch (Exception ex) {
if (ConfigManagerCore.enableDebug) {
ex.printStackTrace();
}
}
sentToAcceptor = currentSending - (float) result / EnergyConfigHandler.TO_IC2_RATIO;
if (sentToAcceptor < 0F) {
sentToAcceptor = 0F;
}
} else {
sentToAcceptor = 0F;
}
} else if (isBCLoaded
&& EnergyConfigHandler.getBuildcraftVersion() == 6
&& MjAPI.getMjBattery(tileEntity, MjAPI.DEFAULT_POWER_FRAMEWORK, sideFrom) != null)
// New BC API
{
sentToAcceptor =
(float)
MjAPI.getMjBattery(tileEntity, MjAPI.DEFAULT_POWER_FRAMEWORK, sideFrom)
.addEnergy(currentSending * EnergyConfigHandler.TO_BC_RATIO)
/ EnergyConfigHandler.TO_BC_RATIO;
} else if (isBCLoaded && tileEntity instanceof IPowerReceptor)
// Legacy BC API
{
PowerReceiver receiver = ((IPowerReceptor) tileEntity).getPowerReceiver(sideFrom);
if (receiver != null) {
double toSendBC =
Math.min(
currentSending * EnergyConfigHandler.TO_BC_RATIO, receiver.powerRequest());
sentToAcceptor =
(float)
receiver.receiveEnergy(
buildcraft.api.power.PowerHandler.Type.PIPE, toSendBC, sideFrom)
/ EnergyConfigHandler.TO_BC_RATIO;
} else {
sentToAcceptor = 0F;
}
} else {
sentToAcceptor = 0F;
}
if (sentToAcceptor / currentSending > 1.002F && sentToAcceptor > 0.01F) {
if (!this.spamstop) {
FMLLog.info(
"Energy network: acceptor took too much energy, offered "
+ currentSending
+ ", took "
+ sentToAcceptor
+ ". "
+ tileEntity.toString());
this.spamstop = true;
}
sentToAcceptor = currentSending;
}
sent += sentToAcceptor;
}
} catch (Exception e) {
GCLog.severe("DEBUG Energy network loop issue, please report this");
if (debugTE != null)
GCLog.severe(
"Problem was likely caused by tile in dim "
+ debugTE.getWorldObj().provider.dimensionId
+ " at "
+ debugTE.xCoord
+ ","
+ debugTE.yCoord
+ ","
+ debugTE.zCoord
+ " Type:"
+ debugTE.getClass().getSimpleName());
}
}
if (EnergyNetwork.tickCount % 200 == 0) {
this.spamstop = false;
}
float returnvalue = sent;
if (returnvalue > this.totalEnergy) {
returnvalue = this.totalEnergy;
}
if (returnvalue < 0F) {
returnvalue = 0F;
}
return returnvalue;
}
/** Refresh validity of each conductor in the network */
public void refreshWithChecks() {
int tierfound = 2;
Iterator<IConductor> it = this.conductors.iterator();
while (it.hasNext()) {
IConductor conductor = it.next();
if (conductor == null) {
it.remove();
continue;
}
TileEntity tile = (TileEntity) conductor;
World world = tile.getWorldObj();
// Remove any conductors in unloaded chunks
if (tile.isInvalid()
|| world == null
|| !world.blockExists(tile.xCoord, tile.yCoord, tile.zCoord)) {
it.remove();
continue;
}
if (conductor != world.getTileEntity(tile.xCoord, tile.yCoord, tile.zCoord)) {
it.remove();
continue;
}
if (conductor.getTierGC() < 2) {
tierfound = 1;
}
if (conductor.getNetwork() != this) {
conductor.setNetwork(this);
conductor.onNetworkChanged();
}
}
// This will set the network tier to 2 if all the conductors are tier 2
this.networkTierGC = tierfound;
}
@Override
public void refresh() {
int tierfound = 2;
Iterator<IConductor> it = this.conductors.iterator();
while (it.hasNext()) {
IConductor conductor = it.next();
if (conductor == null) {
it.remove();
continue;
}
TileEntity tile = (TileEntity) conductor;
World world = tile.getWorldObj();
// Remove any conductors in unloaded chunks
if (tile.isInvalid() || world == null) {
it.remove();
continue;
}
if (conductor.getTierGC() < 2) {
tierfound = 1;
}
if (conductor.getNetwork() != this) {
conductor.setNetwork(this);
conductor.onNetworkChanged();
}
}
// This will set the network tier to 2 if all the conductors are tier 2
this.networkTierGC = tierfound;
}
/** Refresh all energy acceptors in the network */
private void refreshAcceptors() {
this.connectedAcceptors.clear();
this.connectedDirections.clear();
this.refreshWithChecks();
try {
LinkedList<IConductor> conductorsCopy = new LinkedList();
conductorsCopy.addAll(this.conductors);
// This prevents concurrent modifications if something in the loop causes chunk loading
// (Chunk loading can change the network if new conductors are found)
for (IConductor conductor : conductorsCopy) {
final TileEntity[] adjacentConnections =
EnergyUtil.getAdjacentPowerConnections((TileEntity) conductor);
for (int i = 0; i < 6; i++) {
TileEntity acceptor = adjacentConnections[i];
if (!(acceptor instanceof IConductor) && acceptor != null && !acceptor.isInvalid()) {
// The direction 'sideFrom' is from the perspective of the acceptor, that's more useful
// than the conductor's perspective
ForgeDirection sideFrom = ForgeDirection.getOrientation(i ^ 1);
if (acceptor instanceof IElectrical) {
if (((IElectrical) acceptor).canConnect(sideFrom, NetworkType.POWER)) {
this.connectedAcceptors.add(acceptor);
this.connectedDirections.add(sideFrom);
}
} else if ((isRF2Loaded && acceptor instanceof IEnergyReceiver)
|| (isRF1Loaded && acceptor instanceof IEnergyHandler)) {
if (((IEnergyConnection) acceptor).canConnectEnergy(sideFrom)) {
this.connectedAcceptors.add(acceptor);
this.connectedDirections.add(sideFrom);
}
} else if (isMekLoaded && acceptor instanceof IStrictEnergyAcceptor) {
if (((IStrictEnergyAcceptor) acceptor).canReceiveEnergy(sideFrom)) {
this.connectedAcceptors.add(acceptor);
this.connectedDirections.add(sideFrom);
}
} else if (isIC2Loaded && acceptor instanceof IEnergyAcceptor) {
if (((IEnergyAcceptor) acceptor)
.acceptsEnergyFrom((TileEntity) conductor, sideFrom)) {
this.connectedAcceptors.add(acceptor);
this.connectedDirections.add(sideFrom);
}
} else if (isBCLoaded
&& EnergyConfigHandler.getBuildcraftVersion() == 6
&& MjAPI.getMjBattery(acceptor, MjAPI.DEFAULT_POWER_FRAMEWORK, sideFrom) != null) {
this.connectedAcceptors.add(acceptor);
this.connectedDirections.add(sideFrom);
} else if (isBCLoaded && acceptor instanceof IPowerReceptor) {
if (((IPowerReceptor) acceptor).getPowerReceiver(sideFrom) != null
&& (!(acceptor instanceof IPowerEmitter)
|| !((IPowerEmitter) acceptor).canEmitPowerFrom(sideFrom))) {
this.connectedAcceptors.add(acceptor);
this.connectedDirections.add(sideFrom);
}
}
}
}
}
} catch (Exception e) {
FMLLog.severe("Energy Network: Error when trying to refresh list of power acceptors.");
e.printStackTrace();
}
}
/**
* Combine this network with another electricitynetwork
*
* @param network Network to merge with
* @return The final, joined network
*/
@Override
public IElectricityNetwork merge(IElectricityNetwork network) {
if (network != null && network != this) {
Set<IConductor> thisNetwork = this.conductors;
Set<IConductor> thatNetwork = network.getTransmitters();
if (thisNetwork.size() >= thatNetwork.size()) {
thisNetwork.addAll(thatNetwork);
this.refresh();
if (network instanceof EnergyNetwork) {
((EnergyNetwork) network).destroy();
}
return this;
} else {
thatNetwork.addAll(thisNetwork);
network.refresh();
this.destroy();
return network;
}
}
return this;
}
private void destroy() {
this.conductors.clear();
this.connectedAcceptors.clear();
this.availableAcceptors.clear();
this.totalEnergy = 0F;
this.totalRequested = 0F;
try {
Class<?> clazz = Class.forName("micdoodle8.mods.galacticraft.core.tick.TickHandlerServer");
clazz.getMethod("removeNetworkTick", this.getClass()).invoke(null, this);
} catch (Exception e) {
e.printStackTrace();
}
}
public void split(IConductor splitPoint) {
if (splitPoint instanceof TileEntity) {
this.getTransmitters().remove(splitPoint);
splitPoint.setNetwork(null);
// If the size of the residual network is 1, it should simply be preserved
if (this.getTransmitters().size() > 1) {
World world = ((TileEntity) splitPoint).getWorldObj();
if (this.getTransmitters().size() > 0) {
TileEntity[] nextToSplit = new TileEntity[6];
boolean[] toDo = {true, true, true, true, true, true};
TileEntity tileEntity;
int xCoord = ((TileEntity) splitPoint).xCoord;
int yCoord = ((TileEntity) splitPoint).yCoord;
int zCoord = ((TileEntity) splitPoint).zCoord;
for (int j = 0; j < 6; j++) {
switch (j) {
case 0:
tileEntity = world.getTileEntity(xCoord, yCoord - 1, zCoord);
break;
case 1:
tileEntity = world.getTileEntity(xCoord, yCoord + 1, zCoord);
break;
case 2:
tileEntity = world.getTileEntity(xCoord, yCoord, zCoord - 1);
break;
case 3:
tileEntity = world.getTileEntity(xCoord, yCoord, zCoord + 1);
break;
case 4:
tileEntity = world.getTileEntity(xCoord - 1, yCoord, zCoord);
break;
case 5:
tileEntity = world.getTileEntity(xCoord + 1, yCoord, zCoord);
break;
default:
// Not reachable, only to prevent uninitiated compile errors
tileEntity = null;
break;
}
if (tileEntity instanceof IConductor) {
nextToSplit[j] = tileEntity;
} else toDo[j] = false;
}
for (int i1 = 0; i1 < 6; i1++) {
if (toDo[i1]) {
TileEntity connectedBlockA = nextToSplit[i1];
NetworkFinder finder =
new NetworkFinder(
world,
new BlockVec3(connectedBlockA),
new BlockVec3((TileEntity) splitPoint));
List<IConductor> partNetwork = finder.exploreNetwork();
// Mark any others still to do in the nextToSplit array which are connected to this,
// as dealt with
for (int i2 = i1 + 1; i2 < 6; i2++) {
TileEntity connectedBlockB = nextToSplit[i2];
if (toDo[i2]) {
if (partNetwork.contains(connectedBlockB)) {
toDo[i2] = false;
}
}
}
// Now make the new network from partNetwork
EnergyNetwork newNetwork = new EnergyNetwork();
newNetwork.getTransmitters().addAll(partNetwork);
newNetwork.refreshWithChecks();
}
}
this.destroy();
}
}
// Splitting a 1-block network leaves nothing
else if (this.getTransmitters().size() == 0) {
this.destroy();
}
}
}
@Override
public String toString() {
return "EnergyNetwork["
+ this.hashCode()
+ "|Wires:"
+ this.getTransmitters().size()
+ "|Acceptors:"
+ this.connectedAcceptors.size()
+ "]";
}
}