li/cil/oc/server/component/Robot.scala - minecraft/opencomputers - Rivoreo Source Code Repositories

 package li.cil.oc.server.component

 import li.cil.oc.Settings
 import li.cil.oc.api.network.{RobotContext, LuaCallback, Arguments, Context}
 import li.cil.oc.common.tileentity
 import li.cil.oc.server.component.robot.{Player, ActivationType}
 import li.cil.oc.server.{PacketSender => ServerPacketSender}
 import net.minecraft.block.{BlockFluid, Block}
 import net.minecraft.entity.item.{EntityMinecart, EntityMinecartContainer, EntityItem}
 import net.minecraft.entity.{EntityLivingBase, Entity}
 import net.minecraft.inventory.{IInventory, ISidedInventory}
 import net.minecraft.item.{ItemStack, ItemBlock}
 import net.minecraft.tileentity.TileEntityChest
 import net.minecraft.util.{MovingObjectPosition, EnumMovingObjectType}
 import net.minecraftforge.common.ForgeDirection
 import net.minecraftforge.fluids.FluidRegistry
 import scala.Some
 import scala.collection.convert.WrapAsScala._

 class Robot(val robot: tileentity.Robot) extends Computer(robot) with RobotContext {
   def actualSlot(n: Int) = robot.actualSlot(n)

   def world = robot.world

   def x = robot.x

   def y = robot.y

   def z = robot.z

   // ----------------------------------------------------------------------- //

   override def isRobot = true

   def selectedSlot = robot.selectedSlot

   def player = robot.player()

   @LuaCallback(value = "level", direct = true)
   def level(context: Context, args: Arguments): Array[AnyRef] = {
     result(robot.level + robot.xp / robot.xpForNextLevel)
   }

   // ----------------------------------------------------------------------- //

   @LuaCallback("select")
   def select(context: Context, args: Arguments): Array[AnyRef] = {
     if (args.count > 0 && args.checkAny(0) != null) {
       val slot = checkSlot(args, 0)
       if (slot != selectedSlot) {
         robot.selectedSlot = slot
         ServerPacketSender.sendRobotSelectedSlotChange(robot)
       }
     }
     result(selectedSlot - actualSlot(0) + 1)
   }

   @LuaCallback(value = "count", direct = true)
   def count(context: Context, args: Arguments): Array[AnyRef] = {
     val slot =
       if (args.count > 0 && args.checkAny(0) != null) checkSlot(args, 0)
       else selectedSlot
     result(stackInSlot(slot) match {
       case Some(stack) => stack.stackSize
       case _ => 0
     })
   }

   @LuaCallback(value = "space", direct = true)
   def space(context: Context, args: Arguments): Array[AnyRef] = {
     val slot =
       if (args.count > 0 && args.checkAny(0) != null) checkSlot(args, 0)
       else selectedSlot
     result(stackInSlot(slot) match {
       case Some(stack) => math.min(robot.getInventoryStackLimit, stack.getMaxStackSize) - stack.stackSize
       case _ => robot.getInventoryStackLimit
     })
   }

   @LuaCallback("compareTo")
   def compareTo(context: Context, args: Arguments): Array[AnyRef] = {
     val slot = checkSlot(args, 0)
     result((stackInSlot(selectedSlot), stackInSlot(slot)) match {
       case (Some(stackA), Some(stackB)) => haveSameItemType(stackA, stackB)
       case (None, None) => true
       case _ => false
     })
   }

   @LuaCallback("transferTo")
   def transferTo(context: Context, args: Arguments): Array[AnyRef] = {
     val slot = checkSlot(args, 0)
     val count = checkOptionalItemCount(args, 1)
     if (slot == selectedSlot || count == 0) {
       result(true)
     }
     else result((stackInSlot(selectedSlot), stackInSlot(slot)) match {
       case (Some(from), Some(to)) =>
         if (haveSameItemType(from, to)) {
           val space = math.min(robot.getInventoryStackLimit, to.getMaxStackSize) - to.stackSize
           val amount = math.min(count, math.min(space, from.stackSize))
           if (amount > 0) {
             from.stackSize -= amount
             to.stackSize += amount
             assert(from.stackSize >= 0)
             if (from.stackSize == 0) {
               robot.setInventorySlotContents(selectedSlot, null)
             }
             true
           }
           else false
         }
         else if (count >= from.stackSize) {
           robot.setInventorySlotContents(slot, from)
           robot.setInventorySlotContents(selectedSlot, to)
           true
         }
         else false
       case (Some(from), None) =>
         robot.setInventorySlotContents(slot, robot.decrStackSize(selectedSlot, count))
         true
       case _ => false
     })
   }

   @LuaCallback("compare")
   def compare(context: Context, args: Arguments): Array[AnyRef] = {
     val side = checkSideForAction(args, 0)
     stackInSlot(selectedSlot) match {
       case Some(stack) => Option(stack.getItem) match {
         case Some(item: ItemBlock) =>
           val (bx, by, bz) = (x + side.offsetX, y + side.offsetY, z + side.offsetZ)
           val idMatches = item.getBlockID == world.getBlockId(bx, by, bz)
           val subTypeMatches = !item.getHasSubtypes || item.getMetadata(stack.getItemDamage) == world.getBlockMetadata(bx, by, bz)
           return result(idMatches && subTypeMatches)
         case _ =>
       }
       case _ =>
     }
     result(false)
   }

   @LuaCallback("drop")
   def drop(context: Context, args: Arguments): Array[AnyRef] = {
     val facing = checkSideForAction(args, 0)
     val count = checkOptionalItemCount(args, 1)
     val dropped = robot.decrStackSize(selectedSlot, count)
     if (dropped != null && dropped.stackSize > 0) {
       def tryDropIntoInventory(inventory: IInventory, filter: (Int) => Boolean) = {
         var success = false
         val maxStackSize = math.min(inventory.getInventoryStackLimit, dropped.getMaxStackSize)
         val shouldTryMerge = !dropped.isItemStackDamageable && dropped.getMaxStackSize > 1 && inventory.getInventoryStackLimit > 1
         if (shouldTryMerge) {
           for (slot <- 0 until inventory.getSizeInventory if dropped.stackSize > 0 && filter(slot)) {
             val existing = inventory.getStackInSlot(slot)
             val shouldMerge = existing != null && existing.stackSize < maxStackSize &&
               existing.isItemEqual(dropped) && ItemStack.areItemStackTagsEqual(existing, dropped)
             if (shouldMerge) {
               val space = maxStackSize - existing.stackSize
               val amount = math.min(space, dropped.stackSize)
               assert(amount > 0)
               success = true
               existing.stackSize += amount
               dropped.stackSize -= amount
             }
           }
         }

         def canDropIntoSlot(slot: Int) = filter(slot) && inventory.isItemValidForSlot(slot, dropped) && inventory.getStackInSlot(slot) == null
         for (slot <- 0 until inventory.getSizeInventory if dropped.stackSize > 0 && canDropIntoSlot(slot)) {
           val amount = math.min(maxStackSize, dropped.stackSize)
           inventory.setInventorySlotContents(slot, dropped.splitStack(amount))
           success = true
         }
         if (success) {
           inventory.onInventoryChanged()
         }
         player.inventory.addItemStackToInventory(dropped)
         success
       }

       world.getBlockTileEntity(x + facing.offsetX, y + facing.offsetY, z + facing.offsetZ) match {
         case chest: TileEntityChest =>
           val inventory = Block.chest.getInventory(world, chest.xCoord, chest.yCoord, chest.zCoord)
           result(tryDropIntoInventory(inventory,
             slot => inventory.isItemValidForSlot(slot, dropped)))
         case inventory: ISidedInventory =>
           result(tryDropIntoInventory(inventory,
             slot => inventory.isItemValidForSlot(slot, dropped) && inventory.canInsertItem(slot, dropped, facing.getOpposite.ordinal())))
         case inventory: IInventory =>
           result(tryDropIntoInventory(inventory,
             slot => inventory.isItemValidForSlot(slot, dropped)))
         case _ =>
           for (entity <- player.entitiesOnSide[EntityMinecartContainer](facing) if entity.isUseableByPlayer(player)) {
             if (tryDropIntoInventory(entity, slot => entity.isItemValidForSlot(slot, dropped))) {
               return result(true)
             }
           }
           player.dropPlayerItemWithRandomChoice(dropped, inPlace = false)
           context.pause(Settings.get.dropDelay)
           result(true)
       }
     }
     else result(false)
   }

   @LuaCallback("place")
   def place(context: Context, args: Arguments): Array[AnyRef] = {
     val facing = checkSideForAction(args, 0)
     val sides =
       if (args.isInteger(1)) {
         Iterable(checkSideForFace(args, 1, facing))
       }
       else {
         ForgeDirection.VALID_DIRECTIONS.filter(_ != facing.getOpposite).toIterable
       }
     val sneaky = args.isBoolean(2) && args.checkBoolean(2)
     val stack = player.robotInventory.selectedItemStack
     if (stack == null || stack.stackSize == 0) {
       return result(false, "nothing selected")
     }

     for (side <- sides) {
       val player = robot.player(facing, side)
       player.setSneaking(sneaky)
       val success = Option(pick(player, Settings.get.useAndPlaceRange)) match {
         case Some(hit) if hit.typeOfHit == EnumMovingObjectType.TILE =>
           val (bx, by, bz, hx, hy, hz) = clickParamsFromHit(hit)
           player.placeBlock(stack, bx, by, bz, hit.sideHit, hx, hy, hz)
         case None if Settings.get.canPlaceInAir && player.closestEntity[Entity]().isEmpty =>
           val (bx, by, bz, hx, hy, hz) = clickParamsFromFacing(facing, side)
           player.placeBlock(stack, bx, by, bz, side.getOpposite.ordinal, hx, hy, hz)
         case _ => false
       }
       player.setSneaking(false)
       if (stack.stackSize <= 0) {
         robot.setInventorySlotContents(player.robotInventory.selectedSlot, null)
       }
       if (success) {
         context.pause(Settings.get.placeDelay)
         robot.animateSwing(Settings.get.placeDelay)
         return result(true)
       }
     }

     result(false)
   }

   @LuaCallback("suck")
   def suck(context: Context, args: Arguments): Array[AnyRef] = {
     val facing = checkSideForAction(args, 0)
     val count = checkOptionalItemCount(args, 1)

     def trySuckFromInventory(inventory: IInventory, filter: (Int) => Boolean) = {
       var success = false
       for (slot <- 0 until inventory.getSizeInventory if !success && filter(slot)) {
         val stack = inventory.getStackInSlot(slot)
         if (stack != null) {
           val maxStackSize = math.min(robot.getInventoryStackLimit, stack.getMaxStackSize)
           val amount = math.min(maxStackSize, math.min(stack.stackSize, count))
           val sucked = stack.splitStack(amount)
           success = player.inventory.addItemStackToInventory(sucked)
           stack.stackSize += sucked.stackSize
           if (stack.stackSize == 0) {
             inventory.setInventorySlotContents(slot, null)
           }
         }
       }
       if (success) {
         inventory.onInventoryChanged()
       }
       success
     }

     world.getBlockTileEntity(x + facing.offsetX, y + facing.offsetY, z + facing.offsetZ) match {
       case chest: TileEntityChest if chest.isUseableByPlayer(player) =>
         val inventory = Block.chest.getInventory(world, chest.xCoord, chest.yCoord, chest.zCoord)
         result(trySuckFromInventory(inventory, slot => true))
       case inventory: ISidedInventory if inventory.isUseableByPlayer(player) =>
         result(trySuckFromInventory(inventory,
           slot => inventory.canExtractItem(slot, inventory.getStackInSlot(slot), facing.getOpposite.ordinal())))
       case inventory: IInventory if inventory.isUseableByPlayer(player) =>
         result(trySuckFromInventory(inventory, slot => true))
       case _ =>
         for (entity <- player.entitiesOnSide[EntityMinecartContainer](facing) if entity.isUseableByPlayer(player)) {
           if (trySuckFromInventory(entity, slot => true)) {
             return result(true)
           }
         }
         for (entity <- player.entitiesOnSide[EntityItem](facing) if !entity.isDead && entity.delayBeforeCanPickup <= 0) {
           val stack = entity.getEntityItem
           val size = stack.stackSize
           entity.onCollideWithPlayer(player)
           if (stack.stackSize < size || entity.isDead) {
             context.pause(Settings.get.suckDelay)
             return result(true)
           }
         }
         result(false)
     }
   }

   // ----------------------------------------------------------------------- //

   @LuaCallback("detect")
   def detect(context: Context, args: Arguments): Array[AnyRef] = {
     val side = checkSideForAction(args, 0)
     val (something, what) = blockContent(side)
     result(something, what)
   }

   // ----------------------------------------------------------------------- //

   @LuaCallback("swing")
   def swing(context: Context, args: Arguments): Array[AnyRef] = {
     // Swing the equipped tool (left click).
     val facing = checkSideForAction(args, 0)
     val sides =
       if (args.isInteger(1)) {
         Iterable(checkSideForFace(args, 1, facing))
       }
       else {
         ForgeDirection.VALID_DIRECTIONS.filter(_ != facing.getOpposite).toIterable
       }

     def triggerDelay(delay: Double = Settings.get.swingDelay) = {
       context.pause(delay)
       robot.animateSwing(Settings.get.swingDelay)
     }
     def attack(entity: Entity) = {
       beginConsumeDrops(entity)
       player.attackTargetEntityWithCurrentItem(entity)
       // Mine carts have to be hit quickly in succession to break, so we click
       // until it breaks. But avoid an infinite loop... you never know.
       entity match {
         case _: EntityMinecart => for (_ <- 0 until 10 if !entity.isDead) {
           player.attackTargetEntityWithCurrentItem(entity)
         }
         case _ =>
       }
       endConsumeDrops(entity)
       triggerDelay()
       (true, "entity")
     }
     def click(x: Int, y: Int, z: Int, side: Int) = {
       val breakTime = player.clickBlock(x, y, z, side)
       val broke = breakTime > 0
       if (broke) {
         // Subtract one tick because we take one to trigger the action - a bit
         // more than one tick avoid floating point inaccuracy incurring another
         // tick of delay.
         triggerDelay(breakTime - 0.055)
       }
       (broke, "block")
     }

     for (side <- sides) {
       val player = robot.player(facing, side)
       val (success, what) = Option(pick(player, Settings.get.swingRange)) match {
         case Some(hit) =>
           hit.typeOfHit match {
             case EnumMovingObjectType.ENTITY =>
               attack(hit.entityHit)
             case EnumMovingObjectType.TILE =>
               click(hit.blockX, hit.blockY, hit.blockZ, hit.sideHit)
           }
         case _ => // Retry with full block bounds, disregarding swing range.
           player.closestEntity[EntityLivingBase]() match {
             case Some(entity) =>
               attack(entity)
             case _ =>
               if (world.extinguishFire(player, x, y, z, facing.ordinal)) {
                 triggerDelay()
                 (true, "fire")
               }
               else (false, "air")
           }
       }
       if (success) {
         return result(true, what)
       }
     }

     result(false)
   }

   @LuaCallback("use")
   def use(context: Context, args: Arguments): Array[AnyRef] = {
     val facing = checkSideForAction(args, 0)
     val sides =
       if (args.isInteger(1)) {
         Iterable(checkSideForFace(args, 1, facing))
       }
       else {
         ForgeDirection.VALID_DIRECTIONS.filter(_ != facing.getOpposite).toIterable
       }
     val sneaky = args.isBoolean(2) && args.checkBoolean(2)
     val duration =
       if (args.isDouble(3)) args.checkDouble(3)
       else 0.0

     def triggerDelay() {
       context.pause(Settings.get.useDelay)
       robot.animateSwing(Settings.get.useDelay)
     }
     def activationResult(activationType: ActivationType.Value) =
       activationType match {
         case ActivationType.BlockActivated =>
           triggerDelay()
           (true, "block_activated")
         case ActivationType.ItemPlaced =>
           triggerDelay()
           (true, "item_placed")
         case ActivationType.ItemUsed =>
           triggerDelay()
           (true, "item_used")
         case _ => (false, "")
       }

     for (side <- sides) {
       val player = robot.player(facing, side)
       player.setSneaking(sneaky)

       def interact(entity: Entity) = {
         beginConsumeDrops(entity)
         val result = player.interactWith(entity)
         endConsumeDrops(entity)
         result
       }
       val (success, what) = Option(pick(player, Settings.get.useAndPlaceRange)) match {
         case Some(hit) if hit.typeOfHit == EnumMovingObjectType.ENTITY && interact(hit.entityHit) =>
           triggerDelay()
           (true, "item_interacted")
         case Some(hit) if hit.typeOfHit == EnumMovingObjectType.TILE =>
           val (bx, by, bz, hx, hy, hz) = clickParamsFromHit(hit)
           activationResult(player.activateBlockOrUseItem(bx, by, bz, hit.sideHit, hx, hy, hz, duration))
         case _ =>
           (if (Settings.get.canPlaceInAir) {
             val (bx, by, bz, hx, hy, hz) = clickParamsFromFacing(facing, side)
             player.activateBlockOrUseItem(bx, by, bz, side.getOpposite.ordinal, hx, hy, hz, duration)
           } else ActivationType.None) match {
             case ActivationType.None =>
               if (player.useEquippedItem(duration)) {
                 triggerDelay()
                 (true, "item_used")
               }
               else (false, "air")
             case activationType => activationResult(activationType)
           }
       }

       player.setSneaking(false)
       if (success) {
         return result(true, what)
       }
     }

     result(false)
   }

   @LuaCallback("durability")
   def durability(context: Context, args: Arguments): Array[AnyRef] = {
     Option(robot.getStackInSlot(0)) match {
       case Some(item) =>
         if (item.isItemStackDamageable) {
           result(item.getMaxDamage - item.getItemDamage)
         }
         else result(Unit, "tool cannot be damaged")
       case _ => result(Unit, "no tool equipped")
     }
   }

   // ----------------------------------------------------------------------- //

   @LuaCallback("move")
   def move(context: Context, args: Arguments): Array[AnyRef] = {
     val direction = checkSideForMovement(args, 0)
     val (something, what) = blockContent(direction)
     if (something) {
       result(false, what)
     }
     else {
       if (!robot.computer.node.tryChangeBuffer(-Settings.get.robotMoveCost)) {
         result(false, "not enough energy")
       }
       else if (robot.move(direction)) {
         context.pause(Settings.get.moveDelay)
         result(true)
       }
       else {
         robot.computer.node.changeBuffer(Settings.get.robotMoveCost)
         result(false, "impossible move")
       }
     }
   }

   @LuaCallback("turn")
   def turn(context: Context, args: Arguments): Array[AnyRef] = {
     val clockwise = args.checkBoolean(0)
     if (robot.computer.node.tryChangeBuffer(-Settings.get.robotTurnCost)) {
       if (clockwise) robot.rotate(ForgeDirection.UP)
       else robot.rotate(ForgeDirection.DOWN)
       robot.animateTurn(clockwise, Settings.get.turnDelay)
       context.pause(Settings.get.turnDelay)
       result(true)
     }
     else {
       result(false, "not enough energy")
     }
   }

   // ----------------------------------------------------------------------- //

   private def beginConsumeDrops(entity: Entity) {
     entity.captureDrops = true
   }

   private def endConsumeDrops(entity: Entity) {
     entity.captureDrops = false
     for (drop <- entity.capturedDrops) {
       val stack = drop.getEntityItem
       player.inventory.addItemStackToInventory(stack)
       if (stack.stackSize > 0) {
         player.dropPlayerItemWithRandomChoice(stack, inPlace = false)
       }
     }
     entity.capturedDrops.clear()
   }

   // ----------------------------------------------------------------------- //

   private def blockContent(side: ForgeDirection) = {
     player.closestEntity[Entity](side) match {
       case Some(_@(_: EntityLivingBase | _: EntityMinecart)) =>
         (true, "entity")
       case _ =>
         val (bx, by, bz) = (x + side.offsetX, y + side.offsetY, z + side.offsetZ)
         val id = world.getBlockId(bx, by, bz)
         val block = Block.blocksList(id)
         if (id == 0 || block == null || block.isAirBlock(world, bx, by, bz)) {
           (false, "air")
         }
         else if (FluidRegistry.lookupFluidForBlock(block) != null || block.isInstanceOf[BlockFluid]) {
           (false, "liquid")
         }
         else if (block.isBlockReplaceable(world, bx, by, bz)) {
           (false, "replaceable")
         }
         else {
           (true, "solid")
         }
     }
   }

   private def clickParamsFromFacing(facing: ForgeDirection, side: ForgeDirection) = {
     (x + facing.offsetX + side.offsetX,
       y + facing.offsetY + side.offsetY,
       z + facing.offsetZ + side.offsetZ,
       0.5f - side.offsetX * 0.5f,
       0.5f - side.offsetY * 0.5f,
       0.5f - side.offsetZ * 0.5f)
   }

   private def pick(player: Player, range: Double) = {
     val origin = world.getWorldVec3Pool.getVecFromPool(
       player.posX + player.facing.offsetX * 0.5,
       player.posY + player.facing.offsetY * 0.5,
       player.posZ + player.facing.offsetZ * 0.5)
     val blockCenter = origin.addVector(
       player.facing.offsetX * 0.5,
       player.facing.offsetY * 0.5,
       player.facing.offsetZ * 0.5)
     val target = blockCenter.addVector(
       player.side.offsetX * range,
       player.side.offsetY * range,
       player.side.offsetZ * range)
     val hit = world.clip(origin, target)
     player.closestEntity[Entity]() match {
       case Some(entity@(_: EntityLivingBase | _: EntityMinecart)) if hit == null || player.getPosition(1).distanceTo(hit.hitVec) > player.getDistanceToEntity(entity) => new MovingObjectPosition(entity)
       case _ => hit
     }
   }

   private def clickParamsFromHit(hit: MovingObjectPosition) = {
     (hit.blockX, hit.blockY, hit.blockZ,
       (hit.hitVec.xCoord - hit.blockX).toFloat,
       (hit.hitVec.yCoord - hit.blockY).toFloat,
       (hit.hitVec.zCoord - hit.blockZ).toFloat)
   }

   // ----------------------------------------------------------------------- //

   private def haveSameItemType(stackA: ItemStack, stackB: ItemStack) =
     stackA.getItem == stackB.getItem &&
       (!stackA.getHasSubtypes || stackA.getItemDamage == stackB.getItemDamage)

   private def stackInSlot(slot: Int) = Option(robot.getStackInSlot(slot))

   // ----------------------------------------------------------------------- //

   private def checkOptionalItemCount(args: Arguments, n: Int) =
     if (args.count > n && args.checkAny(n) != null) {
       math.max(args.checkInteger(n), math.min(0, robot.getInventoryStackLimit))
     }
     else robot.getInventoryStackLimit

   private def checkSlot(args: Arguments, n: Int) = {
     val slot = args.checkInteger(n) - 1
     if (slot < 0 || slot > 15) {
       throw new IllegalArgumentException("invalid slot")
     }
     actualSlot(slot)
   }

   private def checkSideForAction(args: Arguments, n: Int) = checkSide(args, n, ForgeDirection.SOUTH, ForgeDirection.UP, ForgeDirection.DOWN)

   private def checkSideForMovement(args: Arguments, n: Int) = checkSide(args, n, ForgeDirection.SOUTH, ForgeDirection.NORTH, ForgeDirection.UP, ForgeDirection.DOWN)

   private def checkSideForFace(args: Arguments, n: Int, facing: ForgeDirection) = checkSide(args, n, ForgeDirection.VALID_DIRECTIONS.filter(_ != robot.toLocal(facing).getOpposite): _*)

   private def checkSide(args: Arguments, n: Int, allowed: ForgeDirection*) = {
     val side = args.checkInteger(n)
     if (side < 0 || side > 5) {
       throw new IllegalArgumentException("invalid side")
     }
     val direction = ForgeDirection.getOrientation(side)
     if (allowed.isEmpty || (allowed contains direction)) robot.toGlobal(direction)
     else throw new IllegalArgumentException("unsupported side")
   }
 }
	package li.cil.oc.server.component

	import li.cil.oc.Settings
	import li.cil.oc.api.network.{RobotContext, LuaCallback, Arguments, Context}
	import li.cil.oc.common.tileentity
	import li.cil.oc.server.component.robot.{Player, ActivationType}
	import li.cil.oc.server.{PacketSender => ServerPacketSender}
	import net.minecraft.block.{BlockFluid, Block}
	import net.minecraft.entity.item.{EntityMinecart, EntityMinecartContainer, EntityItem}
	import net.minecraft.entity.{EntityLivingBase, Entity}
	import net.minecraft.inventory.{IInventory, ISidedInventory}
	import net.minecraft.item.{ItemStack, ItemBlock}
	import net.minecraft.tileentity.TileEntityChest
	import net.minecraft.util.{MovingObjectPosition, EnumMovingObjectType}
	import net.minecraftforge.common.ForgeDirection
	import net.minecraftforge.fluids.FluidRegistry
	import scala.Some
	import scala.collection.convert.WrapAsScala._

	class Robot(val robot: tileentity.Robot) extends Computer(robot) with RobotContext {
	def actualSlot(n: Int) = robot.actualSlot(n)

	def world = robot.world

	def x = robot.x

	def y = robot.y

	def z = robot.z

	// ----------------------------------------------------------------------- //

	override def isRobot = true

	def selectedSlot = robot.selectedSlot

	def player = robot.player()

	@LuaCallback(value = "level", direct = true)
	def level(context: Context, args: Arguments): Array[AnyRef] = {
	result(robot.level + robot.xp / robot.xpForNextLevel)
	}

	// ----------------------------------------------------------------------- //

	@LuaCallback("select")
	def select(context: Context, args: Arguments): Array[AnyRef] = {
	if (args.count > 0 && args.checkAny(0) != null) {
	val slot = checkSlot(args, 0)
	if (slot != selectedSlot) {
	robot.selectedSlot = slot
	ServerPacketSender.sendRobotSelectedSlotChange(robot)
	}
	}
	result(selectedSlot - actualSlot(0) + 1)
	}

	@LuaCallback(value = "count", direct = true)
	def count(context: Context, args: Arguments): Array[AnyRef] = {
	val slot =
	if (args.count > 0 && args.checkAny(0) != null) checkSlot(args, 0)
	else selectedSlot
	result(stackInSlot(slot) match {
	case Some(stack) => stack.stackSize
	case _ => 0
	})
	}

	@LuaCallback(value = "space", direct = true)
	def space(context: Context, args: Arguments): Array[AnyRef] = {
	val slot =
	if (args.count > 0 && args.checkAny(0) != null) checkSlot(args, 0)
	else selectedSlot
	result(stackInSlot(slot) match {
	case Some(stack) => math.min(robot.getInventoryStackLimit, stack.getMaxStackSize) - stack.stackSize
	case _ => robot.getInventoryStackLimit
	})
	}

	@LuaCallback("compareTo")
	def compareTo(context: Context, args: Arguments): Array[AnyRef] = {
	val slot = checkSlot(args, 0)
	result((stackInSlot(selectedSlot), stackInSlot(slot)) match {
	case (Some(stackA), Some(stackB)) => haveSameItemType(stackA, stackB)
	case (None, None) => true
	case _ => false
	})
	}

	@LuaCallback("transferTo")
	def transferTo(context: Context, args: Arguments): Array[AnyRef] = {
	val slot = checkSlot(args, 0)
	val count = checkOptionalItemCount(args, 1)
	if (slot == selectedSlot \|\| count == 0) {
	result(true)
	}
	else result((stackInSlot(selectedSlot), stackInSlot(slot)) match {
	case (Some(from), Some(to)) =>
	if (haveSameItemType(from, to)) {
	val space = math.min(robot.getInventoryStackLimit, to.getMaxStackSize) - to.stackSize
	val amount = math.min(count, math.min(space, from.stackSize))
	if (amount > 0) {
	from.stackSize -= amount
	to.stackSize += amount
	assert(from.stackSize >= 0)
	if (from.stackSize == 0) {
	robot.setInventorySlotContents(selectedSlot, null)
	}
	true
	}
	else false
	}
	else if (count >= from.stackSize) {
	robot.setInventorySlotContents(slot, from)
	robot.setInventorySlotContents(selectedSlot, to)
	true
	}
	else false
	case (Some(from), None) =>
	robot.setInventorySlotContents(slot, robot.decrStackSize(selectedSlot, count))
	true
	case _ => false
	})
	}

	@LuaCallback("compare")
	def compare(context: Context, args: Arguments): Array[AnyRef] = {
	val side = checkSideForAction(args, 0)
	stackInSlot(selectedSlot) match {
	case Some(stack) => Option(stack.getItem) match {
	case Some(item: ItemBlock) =>
	val (bx, by, bz) = (x + side.offsetX, y + side.offsetY, z + side.offsetZ)
	val idMatches = item.getBlockID == world.getBlockId(bx, by, bz)
	val subTypeMatches = !item.getHasSubtypes \|\| item.getMetadata(stack.getItemDamage) == world.getBlockMetadata(bx, by, bz)
	return result(idMatches && subTypeMatches)
	case _ =>
	}
	case _ =>
	}
	result(false)
	}

	@LuaCallback("drop")
	def drop(context: Context, args: Arguments): Array[AnyRef] = {
	val facing = checkSideForAction(args, 0)
	val count = checkOptionalItemCount(args, 1)
	val dropped = robot.decrStackSize(selectedSlot, count)
	if (dropped != null && dropped.stackSize > 0) {
	def tryDropIntoInventory(inventory: IInventory, filter: (Int) => Boolean) = {
	var success = false
	val maxStackSize = math.min(inventory.getInventoryStackLimit, dropped.getMaxStackSize)
	val shouldTryMerge = !dropped.isItemStackDamageable && dropped.getMaxStackSize > 1 && inventory.getInventoryStackLimit > 1
	if (shouldTryMerge) {
	for (slot <- 0 until inventory.getSizeInventory if dropped.stackSize > 0 && filter(slot)) {
	val existing = inventory.getStackInSlot(slot)
	val shouldMerge = existing != null && existing.stackSize < maxStackSize &&
	existing.isItemEqual(dropped) && ItemStack.areItemStackTagsEqual(existing, dropped)
	if (shouldMerge) {
	val space = maxStackSize - existing.stackSize
	val amount = math.min(space, dropped.stackSize)
	assert(amount > 0)
	success = true
	existing.stackSize += amount
	dropped.stackSize -= amount
	}
	}
	}

	def canDropIntoSlot(slot: Int) = filter(slot) && inventory.isItemValidForSlot(slot, dropped) && inventory.getStackInSlot(slot) == null
	for (slot <- 0 until inventory.getSizeInventory if dropped.stackSize > 0 && canDropIntoSlot(slot)) {
	val amount = math.min(maxStackSize, dropped.stackSize)
	inventory.setInventorySlotContents(slot, dropped.splitStack(amount))
	success = true
	}
	if (success) {
	inventory.onInventoryChanged()
	}
	player.inventory.addItemStackToInventory(dropped)
	success
	}

	world.getBlockTileEntity(x + facing.offsetX, y + facing.offsetY, z + facing.offsetZ) match {
	case chest: TileEntityChest =>
	val inventory = Block.chest.getInventory(world, chest.xCoord, chest.yCoord, chest.zCoord)
	result(tryDropIntoInventory(inventory,
	slot => inventory.isItemValidForSlot(slot, dropped)))
	case inventory: ISidedInventory =>
	result(tryDropIntoInventory(inventory,
	slot => inventory.isItemValidForSlot(slot, dropped) && inventory.canInsertItem(slot, dropped, facing.getOpposite.ordinal())))
	case inventory: IInventory =>
	result(tryDropIntoInventory(inventory,
	slot => inventory.isItemValidForSlot(slot, dropped)))
	case _ =>
	for (entity <- player.entitiesOnSide[EntityMinecartContainer](facing) if entity.isUseableByPlayer(player)) {
	if (tryDropIntoInventory(entity, slot => entity.isItemValidForSlot(slot, dropped))) {
	return result(true)
	}
	}
	player.dropPlayerItemWithRandomChoice(dropped, inPlace = false)
	context.pause(Settings.get.dropDelay)
	result(true)
	}
	}
	else result(false)
	}

	@LuaCallback("place")
	def place(context: Context, args: Arguments): Array[AnyRef] = {
	val facing = checkSideForAction(args, 0)
	val sides =
	if (args.isInteger(1)) {
	Iterable(checkSideForFace(args, 1, facing))
	}
	else {
	ForgeDirection.VALID_DIRECTIONS.filter(_ != facing.getOpposite).toIterable
	}
	val sneaky = args.isBoolean(2) && args.checkBoolean(2)
	val stack = player.robotInventory.selectedItemStack
	if (stack == null \|\| stack.stackSize == 0) {
	return result(false, "nothing selected")
	}

	for (side <- sides) {
	val player = robot.player(facing, side)
	player.setSneaking(sneaky)
	val success = Option(pick(player, Settings.get.useAndPlaceRange)) match {
	case Some(hit) if hit.typeOfHit == EnumMovingObjectType.TILE =>
	val (bx, by, bz, hx, hy, hz) = clickParamsFromHit(hit)
	player.placeBlock(stack, bx, by, bz, hit.sideHit, hx, hy, hz)
	case None if Settings.get.canPlaceInAir && player.closestEntity[Entity]().isEmpty =>
	val (bx, by, bz, hx, hy, hz) = clickParamsFromFacing(facing, side)
	player.placeBlock(stack, bx, by, bz, side.getOpposite.ordinal, hx, hy, hz)
	case _ => false
	}
	player.setSneaking(false)
	if (stack.stackSize <= 0) {
	robot.setInventorySlotContents(player.robotInventory.selectedSlot, null)
	}
	if (success) {
	context.pause(Settings.get.placeDelay)
	robot.animateSwing(Settings.get.placeDelay)
	return result(true)
	}
	}

	result(false)
	}

	@LuaCallback("suck")
	def suck(context: Context, args: Arguments): Array[AnyRef] = {
	val facing = checkSideForAction(args, 0)
	val count = checkOptionalItemCount(args, 1)

	def trySuckFromInventory(inventory: IInventory, filter: (Int) => Boolean) = {
	var success = false
	for (slot <- 0 until inventory.getSizeInventory if !success && filter(slot)) {
	val stack = inventory.getStackInSlot(slot)
	if (stack != null) {
	val maxStackSize = math.min(robot.getInventoryStackLimit, stack.getMaxStackSize)
	val amount = math.min(maxStackSize, math.min(stack.stackSize, count))
	val sucked = stack.splitStack(amount)
	success = player.inventory.addItemStackToInventory(sucked)
	stack.stackSize += sucked.stackSize
	if (stack.stackSize == 0) {
	inventory.setInventorySlotContents(slot, null)
	}
	}
	}
	if (success) {
	inventory.onInventoryChanged()
	}
	success
	}

	world.getBlockTileEntity(x + facing.offsetX, y + facing.offsetY, z + facing.offsetZ) match {
	case chest: TileEntityChest if chest.isUseableByPlayer(player) =>
	val inventory = Block.chest.getInventory(world, chest.xCoord, chest.yCoord, chest.zCoord)
	result(trySuckFromInventory(inventory, slot => true))
	case inventory: ISidedInventory if inventory.isUseableByPlayer(player) =>
	result(trySuckFromInventory(inventory,
	slot => inventory.canExtractItem(slot, inventory.getStackInSlot(slot), facing.getOpposite.ordinal())))
	case inventory: IInventory if inventory.isUseableByPlayer(player) =>
	result(trySuckFromInventory(inventory, slot => true))
	case _ =>
	for (entity <- player.entitiesOnSide[EntityMinecartContainer](facing) if entity.isUseableByPlayer(player)) {
	if (trySuckFromInventory(entity, slot => true)) {
	return result(true)
	}
	}
	for (entity <- player.entitiesOnSide[EntityItem](facing) if !entity.isDead && entity.delayBeforeCanPickup <= 0) {
	val stack = entity.getEntityItem
	val size = stack.stackSize
	entity.onCollideWithPlayer(player)
	if (stack.stackSize < size \|\| entity.isDead) {
	context.pause(Settings.get.suckDelay)
	return result(true)
	}
	}
	result(false)
	}
	}

	// ----------------------------------------------------------------------- //

	@LuaCallback("detect")
	def detect(context: Context, args: Arguments): Array[AnyRef] = {
	val side = checkSideForAction(args, 0)
	val (something, what) = blockContent(side)
	result(something, what)
	}

	// ----------------------------------------------------------------------- //

	@LuaCallback("swing")
	def swing(context: Context, args: Arguments): Array[AnyRef] = {
	// Swing the equipped tool (left click).
	val facing = checkSideForAction(args, 0)
	val sides =
	if (args.isInteger(1)) {
	Iterable(checkSideForFace(args, 1, facing))
	}
	else {
	ForgeDirection.VALID_DIRECTIONS.filter(_ != facing.getOpposite).toIterable
	}

	def triggerDelay(delay: Double = Settings.get.swingDelay) = {
	context.pause(delay)
	robot.animateSwing(Settings.get.swingDelay)
	}
	def attack(entity: Entity) = {
	beginConsumeDrops(entity)
	player.attackTargetEntityWithCurrentItem(entity)
	// Mine carts have to be hit quickly in succession to break, so we click
	// until it breaks. But avoid an infinite loop... you never know.
	entity match {
	case _: EntityMinecart => for (_ <- 0 until 10 if !entity.isDead) {
	player.attackTargetEntityWithCurrentItem(entity)
	}
	case _ =>
	}
	endConsumeDrops(entity)
	triggerDelay()
	(true, "entity")
	}
	def click(x: Int, y: Int, z: Int, side: Int) = {
	val breakTime = player.clickBlock(x, y, z, side)
	val broke = breakTime > 0
	if (broke) {
	// Subtract one tick because we take one to trigger the action - a bit
	// more than one tick avoid floating point inaccuracy incurring another
	// tick of delay.
	triggerDelay(breakTime - 0.055)
	}
	(broke, "block")
	}

	for (side <- sides) {
	val player = robot.player(facing, side)
	val (success, what) = Option(pick(player, Settings.get.swingRange)) match {
	case Some(hit) =>
	hit.typeOfHit match {
	case EnumMovingObjectType.ENTITY =>
	attack(hit.entityHit)
	case EnumMovingObjectType.TILE =>
	click(hit.blockX, hit.blockY, hit.blockZ, hit.sideHit)
	}
	case _ => // Retry with full block bounds, disregarding swing range.
	player.closestEntity[EntityLivingBase]() match {
	case Some(entity) =>
	attack(entity)
	case _ =>
	if (world.extinguishFire(player, x, y, z, facing.ordinal)) {
	triggerDelay()
	(true, "fire")
	}
	else (false, "air")
	}
	}
	if (success) {
	return result(true, what)
	}
	}

	result(false)
	}

	@LuaCallback("use")
	def use(context: Context, args: Arguments): Array[AnyRef] = {
	val facing = checkSideForAction(args, 0)
	val sides =
	if (args.isInteger(1)) {
	Iterable(checkSideForFace(args, 1, facing))
	}
	else {
	ForgeDirection.VALID_DIRECTIONS.filter(_ != facing.getOpposite).toIterable
	}
	val sneaky = args.isBoolean(2) && args.checkBoolean(2)
	val duration =
	if (args.isDouble(3)) args.checkDouble(3)
	else 0.0

	def triggerDelay() {
	context.pause(Settings.get.useDelay)
	robot.animateSwing(Settings.get.useDelay)
	}
	def activationResult(activationType: ActivationType.Value) =
	activationType match {
	case ActivationType.BlockActivated =>
	triggerDelay()
	(true, "block_activated")
	case ActivationType.ItemPlaced =>
	triggerDelay()
	(true, "item_placed")
	case ActivationType.ItemUsed =>
	triggerDelay()
	(true, "item_used")
	case _ => (false, "")
	}

	for (side <- sides) {
	val player = robot.player(facing, side)
	player.setSneaking(sneaky)

	def interact(entity: Entity) = {
	beginConsumeDrops(entity)
	val result = player.interactWith(entity)
	endConsumeDrops(entity)
	result
	}
	val (success, what) = Option(pick(player, Settings.get.useAndPlaceRange)) match {
	case Some(hit) if hit.typeOfHit == EnumMovingObjectType.ENTITY && interact(hit.entityHit) =>
	triggerDelay()
	(true, "item_interacted")
	case Some(hit) if hit.typeOfHit == EnumMovingObjectType.TILE =>
	val (bx, by, bz, hx, hy, hz) = clickParamsFromHit(hit)
	activationResult(player.activateBlockOrUseItem(bx, by, bz, hit.sideHit, hx, hy, hz, duration))
	case _ =>
	(if (Settings.get.canPlaceInAir) {
	val (bx, by, bz, hx, hy, hz) = clickParamsFromFacing(facing, side)
	player.activateBlockOrUseItem(bx, by, bz, side.getOpposite.ordinal, hx, hy, hz, duration)
	} else ActivationType.None) match {
	case ActivationType.None =>
	if (player.useEquippedItem(duration)) {
	triggerDelay()
	(true, "item_used")
	}
	else (false, "air")
	case activationType => activationResult(activationType)
	}
	}

	player.setSneaking(false)
	if (success) {
	return result(true, what)
	}
	}

	result(false)
	}

	@LuaCallback("durability")
	def durability(context: Context, args: Arguments): Array[AnyRef] = {
	Option(robot.getStackInSlot(0)) match {
	case Some(item) =>
	if (item.isItemStackDamageable) {
	result(item.getMaxDamage - item.getItemDamage)
	}
	else result(Unit, "tool cannot be damaged")
	case _ => result(Unit, "no tool equipped")
	}
	}

	// ----------------------------------------------------------------------- //

	@LuaCallback("move")
	def move(context: Context, args: Arguments): Array[AnyRef] = {
	val direction = checkSideForMovement(args, 0)
	val (something, what) = blockContent(direction)
	if (something) {
	result(false, what)
	}
	else {
	if (!robot.computer.node.tryChangeBuffer(-Settings.get.robotMoveCost)) {
	result(false, "not enough energy")
	}
	else if (robot.move(direction)) {
	context.pause(Settings.get.moveDelay)
	result(true)
	}
	else {
	robot.computer.node.changeBuffer(Settings.get.robotMoveCost)
	result(false, "impossible move")
	}
	}
	}

	@LuaCallback("turn")
	def turn(context: Context, args: Arguments): Array[AnyRef] = {
	val clockwise = args.checkBoolean(0)
	if (robot.computer.node.tryChangeBuffer(-Settings.get.robotTurnCost)) {
	if (clockwise) robot.rotate(ForgeDirection.UP)
	else robot.rotate(ForgeDirection.DOWN)
	robot.animateTurn(clockwise, Settings.get.turnDelay)
	context.pause(Settings.get.turnDelay)
	result(true)
	}
	else {
	result(false, "not enough energy")
	}
	}

	// ----------------------------------------------------------------------- //

	private def beginConsumeDrops(entity: Entity) {
	entity.captureDrops = true
	}

	private def endConsumeDrops(entity: Entity) {
	entity.captureDrops = false
	for (drop <- entity.capturedDrops) {
	val stack = drop.getEntityItem
	player.inventory.addItemStackToInventory(stack)
	if (stack.stackSize > 0) {
	player.dropPlayerItemWithRandomChoice(stack, inPlace = false)
	}
	}
	entity.capturedDrops.clear()
	}

	// ----------------------------------------------------------------------- //

	private def blockContent(side: ForgeDirection) = {
	player.closestEntity[Entity](side) match {
	case Some(_@(_: EntityLivingBase \| _: EntityMinecart)) =>
	(true, "entity")
	case _ =>
	val (bx, by, bz) = (x + side.offsetX, y + side.offsetY, z + side.offsetZ)
	val id = world.getBlockId(bx, by, bz)
	val block = Block.blocksList(id)
	if (id == 0 \|\| block == null \|\| block.isAirBlock(world, bx, by, bz)) {
	(false, "air")
	}
	else if (FluidRegistry.lookupFluidForBlock(block) != null \|\| block.isInstanceOf[BlockFluid]) {
	(false, "liquid")
	}
	else if (block.isBlockReplaceable(world, bx, by, bz)) {
	(false, "replaceable")
	}
	else {
	(true, "solid")
	}
	}
	}

	private def clickParamsFromFacing(facing: ForgeDirection, side: ForgeDirection) = {
	(x + facing.offsetX + side.offsetX,
	y + facing.offsetY + side.offsetY,
	z + facing.offsetZ + side.offsetZ,
	0.5f - side.offsetX * 0.5f,
	0.5f - side.offsetY * 0.5f,
	0.5f - side.offsetZ * 0.5f)
	}

	private def pick(player: Player, range: Double) = {
	val origin = world.getWorldVec3Pool.getVecFromPool(
	player.posX + player.facing.offsetX * 0.5,
	player.posY + player.facing.offsetY * 0.5,
	player.posZ + player.facing.offsetZ * 0.5)
	val blockCenter = origin.addVector(
	player.facing.offsetX * 0.5,
	player.facing.offsetY * 0.5,
	player.facing.offsetZ * 0.5)
	val target = blockCenter.addVector(
	player.side.offsetX * range,
	player.side.offsetY * range,
	player.side.offsetZ * range)
	val hit = world.clip(origin, target)
	player.closestEntity[Entity]() match {
	case Some(entity@(_: EntityLivingBase \| _: EntityMinecart)) if hit == null \|\| player.getPosition(1).distanceTo(hit.hitVec) > player.getDistanceToEntity(entity) => new MovingObjectPosition(entity)
	case _ => hit
	}
	}

	private def clickParamsFromHit(hit: MovingObjectPosition) = {
	(hit.blockX, hit.blockY, hit.blockZ,
	(hit.hitVec.xCoord - hit.blockX).toFloat,
	(hit.hitVec.yCoord - hit.blockY).toFloat,
	(hit.hitVec.zCoord - hit.blockZ).toFloat)
	}

	// ----------------------------------------------------------------------- //

	private def haveSameItemType(stackA: ItemStack, stackB: ItemStack) =
	stackA.getItem == stackB.getItem &&
	(!stackA.getHasSubtypes \|\| stackA.getItemDamage == stackB.getItemDamage)

	private def stackInSlot(slot: Int) = Option(robot.getStackInSlot(slot))

	// ----------------------------------------------------------------------- //

	private def checkOptionalItemCount(args: Arguments, n: Int) =
	if (args.count > n && args.checkAny(n) != null) {
	math.max(args.checkInteger(n), math.min(0, robot.getInventoryStackLimit))
	}
	else robot.getInventoryStackLimit

	private def checkSlot(args: Arguments, n: Int) = {
	val slot = args.checkInteger(n) - 1
	if (slot < 0 \|\| slot > 15) {
	throw new IllegalArgumentException("invalid slot")
	}
	actualSlot(slot)
	}

	private def checkSideForAction(args: Arguments, n: Int) = checkSide(args, n, ForgeDirection.SOUTH, ForgeDirection.UP, ForgeDirection.DOWN)

	private def checkSideForMovement(args: Arguments, n: Int) = checkSide(args, n, ForgeDirection.SOUTH, ForgeDirection.NORTH, ForgeDirection.UP, ForgeDirection.DOWN)

	private def checkSideForFace(args: Arguments, n: Int, facing: ForgeDirection) = checkSide(args, n, ForgeDirection.VALID_DIRECTIONS.filter(_ != robot.toLocal(facing).getOpposite): _*)

	private def checkSide(args: Arguments, n: Int, allowed: ForgeDirection*) = {
	val side = args.checkInteger(n)
	if (side < 0 \|\| side > 5) {
	throw new IllegalArgumentException("invalid side")
	}
	val direction = ForgeDirection.getOrientation(side)
	if (allowed.isEmpty \|\| (allowed contains direction)) robot.toGlobal(direction)
	else throw new IllegalArgumentException("unsupported side")
	}
	}