package gregtech.api.interfaces.tileentity; import static gregtech.api.enums.GT_Values.F; import static gregtech.api.enums.GT_Values.T; import gregtech.api.enums.SubTag; import gregtech.api.util.GT_Utility; import ic2.api.energy.tile.IEnergySink; import net.minecraft.tileentity.TileEntity; import net.minecraftforge.common.util.ForgeDirection; import cofh.api.energy.IEnergyReceiver; /** * THIS IS GOING TO BE USED IN 1.8 * * Interface for getting Connected to the GregTech Energy Network. * * This is all you need to connect to the GT Network. * IColoredTileEntity is needed for not connecting differently coloured Blocks to each other. * IHasWorldObjectAndCoords is needed for the InWorld related Stuff. @BaseTileEntity does implement most of that Interface. */ public interface IExperimentalEnergyTileEntity extends IColoredTileEntity, IHasWorldObjectAndCoords { /** * Inject Energy Call for Electricity. Gets called by EnergyEmitters to inject Energy into your Block * * Note: you have to check for @inputEnergyFrom because the Network won't check for that by itself. * * @param aSide 0 - 5 = Vanilla Directions of YOUR Block the Energy gets inserted to. 6 = No specific Side (don't do Side checks for this Side) * @return amount of used Amperes. 0 if not accepted anything. */ public long injectEnergy(SubTag aEnergyType, byte aSide, long aPrimary, long aSecondary); /** Sided Energy Input */ public boolean inputEnergyFrom(SubTag aEnergyType, byte aSide); /** Sided Energy Output */ public boolean outputsEnergyTo(SubTag aEnergyType, byte aSide); /** Utility for the Network */ public static class Util { private static boolean RF_ENERGY = F, IC_ENERGY = F, CHECK_ALL = T; public static int RF_PER_EU = 4; private static void checkAvailabilities() { if (CHECK_ALL) { try { Class tClass = cofh.api.energy.IEnergyReceiver.class; tClass.getCanonicalName(); RF_ENERGY = T; } catch(Throwable e) {/**/} try { Class tClass = ic2.api.energy.tile.IEnergySink.class; tClass.getCanonicalName(); IC_ENERGY = T; } catch(Throwable e) {/**/} CHECK_ALL = F; } } /** * Emits Energy to the adjacent Blocks. Also compatible with adjacent IC2 TileEntities when electric and RF TileEntities when RedstoneFlux. * @return the amount of used secondary value. */ public static final long emitEnergyToNetwork(SubTag aEnergyType, long aPrimary, long aSecondary, IExperimentalEnergyTileEntity aEmitter) { long rUsedSecondary = 0; checkAvailabilities(); for (byte i = 0, j = 0; i < 6 && aSecondary > rUsedSecondary; i++) if (aEmitter.outputsEnergyTo(aEnergyType, i)) { j = GT_Utility.getOppositeSide(i); TileEntity tTileEntity = aEmitter.getTileEntityAtSide(i); if (tTileEntity instanceof IExperimentalEnergyTileEntity) { if (aEmitter.getColorization() >= 0) { byte tColor = ((IExperimentalEnergyTileEntity)tTileEntity).getColorization(); if (tColor >= 0 && tColor != aEmitter.getColorization()) continue; } rUsedSecondary+=((IExperimentalEnergyTileEntity)tTileEntity).injectEnergy(aEnergyType, j, aPrimary, aSecondary-rUsedSecondary); } else if (IC_ENERGY && aEnergyType == SubTag.ENERGY_ELECTRICITY && tTileEntity instanceof IEnergySink) { if (((IEnergySink)tTileEntity).acceptsEnergyFrom((TileEntity)aEmitter, ForgeDirection.getOrientation(j))) { while (aSecondary > rUsedSecondary && ((IEnergySink)tTileEntity).getDemandedEnergy() > 0 && ((IEnergySink)tTileEntity).injectEnergy(ForgeDirection.getOrientation(j), aPrimary, aPrimary) < aPrimary) rUsedSecondary++; } } else if (RF_ENERGY && aEnergyType == SubTag.ENERGY_REDSTONE_FLUX && tTileEntity instanceof IEnergyReceiver && ((IEnergyReceiver)tTileEntity).canConnectEnergy(ForgeDirection.getOrientation(j))) { rUsedSecondary+=((IEnergyReceiver)tTileEntity).receiveEnergy(ForgeDirection.getOrientation(j), (int)aSecondary, F); } } return rUsedSecondary; } } }