Examples of ic2.api.energy.event.EnergyTileUnloadEvent

ic2.api.item.IElectricItem
Event announcing terminated energy tiles. This event notifies subscribers of unloaded energy tiles, e.g. after getting unloaded through the chunk they are in or after being destroyed by the player or another block pick/destruction mechanism. Every energy tile which wants to get disconnected from the IC2 Energy Network has to either post this event or alternatively call EnergyNet.removeTileEntity(). You may use this event to build a static representation of energy tiles for your own energy grid implementation if you need to. It's not required if you always lookup energy paths on demand. See ic2/api/energy/usage.txt for an overall description of the energy net api.

  public boolean isItemValid(int slot, ItemStack stack)
  {
    // Decide if the item is a valid IC2 electrical item
    if (stack != null && stack.getItem() instanceof IElectricItem)
    {
      IElectricItem item = (IElectricItem)(stack.getItem());
      // Is the item appropriate for this slot?
      if (slot == Info.CB_SLOT_POWER_SOURCE && item.canProvideEnergy(stack) && item.getTier(stack) <= powerTier) return true;
      if (slot >= Info.CB_SLOT_CHARGING && slot < Info.CB_SLOT_CHARGING + 12 && item.getTier(stack) <= baseTier) return true;
      if (slot >= Info.CB_SLOT_UPGRADE && slot < Info.CB_SLOT_UPGRADE + 4 && (stack.isItemEqual(Info.ic2overclockerUpg) || stack.isItemEqual(Info.ic2transformerUpg) || stack.isItemEqual(Info.ic2storageUpg))) return true;
      if (slot == Info.CB_SLOT_INPUT && item.getTier(stack) <= baseTier) return true;
      if (slot == Info.CB_SLOT_OUTPUT) return true; // GUI won't allow placement of items here, but if the bench or an external machine does, it should at least let it sit there as long as it's an electrical item.
    }
    return false; 
  }

View Full Code Here

    int chargeReturned = 0;


    ItemStack stack = getStackInSlot(Info.CB_SLOT_POWER_SOURCE);
    if (stack != null && stack.getItem() instanceof IElectricItem && currentEnergy < adjustedStorage)
    {
      IElectricItem powerSource = (IElectricItem)(stack.getItem());


      int emptyItemID = powerSource.getEmptyItemId(stack);
      int chargedItemID = powerSource.getChargedItemId(stack);


      if (stack.itemID == chargedItemID)
      {
        if (powerSource.getTier(stack) <= powerTier && powerSource.canProvideEnergy(stack))
        {
          int itemTransferLimit = powerSource.getTransferLimit(stack);
          int energyNeeded = adjustedStorage - currentEnergy;


          // Test if the amount of energy we have room for is greater than what the item can transfer per tick.
          if (energyNeeded > itemTransferLimit)
          {

View Full Code Here

    for (int i = Info.CB_SLOT_CHARGING; i < Info.CB_SLOT_CHARGING + 12; i++)
    {
      ItemStack stack = contents[i];
      if (stack != null && stack.getItem() instanceof IElectricItem && stack.stackSize == 1)
      {
        IElectricItem item = (IElectricItem)(stack.getItem());
        if (item.getTier(stack) <= baseTier)
        {
          int itemTransferLimit = item.getTransferLimit(stack);
          if (itemTransferLimit == 0) itemTransferLimit = baseMaxInput;
          int adjustedTransferLimit = (int)Math.ceil(chargeFactor * itemTransferLimit);
          int amountNeeded;
          int missing;
          int consumption;
          if (item.getChargedItemId(stack) != item.getEmptyItemId(stack) || stack.isStackable())
          {
            // Running stack.copy() on every item every tick would be a horrible thing for performance, but the workaround is needed
            // for ElectricItem.charge adding stackTagCompounds for charge level to EmptyItemID batteries even when run in simulate mode.
            // Limiting its use by what is hopefully a broad enough test to catch all cases where it's necessary in order to avoid problems.
            // Using it for any item types listed as stackable and for any items where the charged and empty item IDs differ.
            final ItemStack stackCopy = stack.copy();
            amountNeeded = ElectricItem.charge(stackCopy, adjustedTransferLimit, baseTier, true, true);
            if (amountNeeded == adjustedTransferLimit)
            {
              missing = ElectricItem.charge(stackCopy, item.getMaxCharge(stackCopy), baseTier, true, true);
            }
            else missing = amountNeeded;
          }
          else
          {
            amountNeeded = ElectricItem.charge(stack, adjustedTransferLimit, baseTier, true, true);
            if (amountNeeded == adjustedTransferLimit)
            {
              missing = ElectricItem.charge(stack, item.getMaxCharge(stack), baseTier, true, true);
            }
            else missing = amountNeeded;
          }


          // How long will this item take and how much will it drain?

View Full Code Here

  {
    ItemStack stack = contents[Info.CB_SLOT_INPUT];
    if (stack != null && stack.getItem() instanceof IElectricItem)
    {
      // Input slot contains something electrical. If possible, move one of it into the charging area.
      IElectricItem item = (IElectricItem)(stack.getItem());
      for (int slot = Info.CB_SLOT_CHARGING; slot < Info.CB_SLOT_CHARGING + 12; ++slot)
      {
        if (contents[slot] == null)
        {
          // Grab one unit from input and move it to the selected slot.

View Full Code Here

  public boolean isItemValid(int slot, ItemStack stack)
  {
    // Decide if the item is a valid IC2 electrical item
    if (stack != null && stack.getItem() instanceof IElectricItem)
    {
      IElectricItem item = (IElectricItem)(stack.getItem());
      // Is the item appropriate for this slot?
      if (slot == Info.BS_SLOT_OUTPUT) return true; // GUI won't allow placement of items here, but if the bench or an external machine does, it should at least let it sit there as long as it's an electrical item.
      if (item.canProvideEnergy(stack) && item.getTier(stack) <= powerTier)
      {
        if ((slot >= Info.BS_SLOT_POWER_START && slot < Info.BS_SLOT_POWER_START + 12) || slot == Info.BS_SLOT_INPUT) return true;
      }
    }
    return false;

View Full Code Here

      }


      ItemStack stack = contents[i];
      if (stack != null && stack.getItem() instanceof IElectricItem && stack.stackSize == 1)
      {
        IElectricItem item = (IElectricItem)(stack.getItem());
        if (item.getTier(stack) <= powerTier && item.canProvideEnergy(stack))
        {
          int emptyItemID = item.getEmptyItemId(stack);
          int chargedItemID = item.getChargedItemId(stack);


          if (stack.itemID == chargedItemID)
          {
            int transferLimit = item.getTransferLimit(stack);
            //int amountNeeded = baseMaxOutput - currentEnergy;
            if (transferLimit == 0) transferLimit = packetSize;
            //if (transferLimit > amountNeeded) transferLimit = amountNeeded;


            int chargeReturned = ElectricItem.discharge(stack, transferLimit, powerTier, false, false);

View Full Code Here

        if (slot == Info.BS_SLOT_OUTPUT) continue;


        ItemStack currentStack = contents[slot];
        if (currentStack != null && currentStack.getItem() instanceof IElectricItem)
        {
          IElectricItem powerSource = (IElectricItem)(currentStack.getItem());
          if (powerSource.getTier(currentStack) <= powerTier) // && powerSource.canProvideEnergy()
          {
            int emptyItemID = powerSource.getEmptyItemId(currentStack);
            int chargedItemID = powerSource.getChargedItemId(currentStack);
            if (emptyItemID != chargedItemID)
            {
              if (currentStack.itemID == emptyItemID)
              {
                // Pick Me

View Full Code Here

  {
    //System.out.println("aII: opMode " + opMode);
    ItemStack stack = contents[Info.BS_SLOT_INPUT];
    if (stack == null || !(stack.getItem() instanceof IElectricItem) || (opMode == 1 && hasEnoughItems)) return;


    IElectricItem item = (IElectricItem)stack.getItem();
    if (item.canProvideEnergy(stack))
    {
      // Input slot contains a power source. If possible, move one of it into the discharging area.
      for (int slot = Info.BS_SLOT_POWER_START; slot < Info.BS_SLOT_POWER_START + 12; ++slot)
      {
        if (contents[slot] == null)

View Full Code Here

      if (i == Info.BS_SLOT_OUTPUT) continue;


      final ItemStack stack = contents[i];
      if (stack != null && stack.getItem() instanceof IElectricItem && stack.stackSize == 1)
      {
        final IElectricItem item = (IElectricItem)(stack.getItem());
        if (item.getTier(stack) <= powerTier && item.canProvideEnergy(stack) && stack.itemID == item.getChargedItemId(stack))
        {
          final int chargeReturned = ElectricItem.discharge(stack, Integer.MAX_VALUE, powerTier, true, true);
          if (chargeReturned > 0)
          {
            // Add the energy we received to our current energy level

View Full Code Here

  public static boolean isItemChargeable(ItemStack stack, int tier)
  {
    // Decide if the item is a valid IC2 electrical item
    if (stack != null && stack.getItem() instanceof IElectricItem)
    {
      IElectricItem item = (IElectricItem)(stack.getItem());
      if (item.getTier(stack) <= tier) return true;
    }
    return false;
  }

View Full Code Here

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