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Version: 1.21.x

Menus

Menus are one type of backend for Graphical User Interfaces, or GUIs; they handle the logic involved in interacting with some represented data holder. Menus themselves are not data holders. They are views which allow to user to indirectly modify the internal data holder state. As such, a data holder should not be directly coupled to any menu, instead passing in the data references to invoke and modify.

Menus are created and removed dynamically and as such are not registry objects. As such, another factory object is registered instead to easily create and refer to the type of the menu. For a menu, these are MenuTypes.

MenuTypes must be registered.

A MenuType is created by passing in a MenuSupplier and a FeatureFlagSet to its constructor. A MenuSupplier represents a function which takes in the id of the container and the inventory of the player viewing the menu, and returns a newly created AbstractContainerMenu.

// For some DeferredRegister<MenuType<?>> REGISTER
public static final Supplier<MenuType<MyMenu>> MY_MENU = REGISTER.register("my_menu", () -> new MenuType<>(MyMenu::new, FeatureFlags.DEFAULT_FLAGS));

// In MyMenu, an AbstractContainerMenu subclass
public MyMenu(int containerId, Inventory playerInv) {
super(MY_MENU.get(), containerId);
// ...
}
note

The container identifier is unique for an individual player. This means that the same container id on two different players will represent two different menus, even if they are viewing the same data holder.

The MenuSupplier is usually responsible for creating a menu on the client with dummy data references used to store and interact with the synced information from the server data holder.

IContainerFactory

If additional information is needed on the client (e.g. the position of the data holder in the world), then the subclass IContainerFactory can be used instead. In addition to the container id and the player inventory, this also provides a RegistryFriendlyByteBuf which can store additional information that was sent from the server. A MenuType can be created using an IContainerFactory via IMenuTypeExtension#create.

// For some DeferredRegister<MenuType<?>> REGISTER
public static final Supplier<MenuType<MyMenuExtra>> MY_MENU_EXTRA = REGISTER.register("my_menu_extra", () -> IMenuTypeExtension.create(MyMenu::new));

// In MyMenuExtra, an AbstractContainerMenu subclass
public MyMenuExtra(int containerId, Inventory playerInv, FriendlyByteBuf extraData) {
super(MY_MENU_EXTRA.get(), containerId);
// Store extra data from buffer
// ...
}

AbstractContainerMenu

All menus are extended from AbstractContainerMenu. A menu takes in two parameters, the MenuType, which represents the type of the menu itself, and the container id, which represents the unique identifier of the menu for the current accessor.

note

The menu identifier cycles through 0-99, incrementing whenever a player opens a menu.

Each menu should contain two constructors: one used to initialize the menu on the server and one used to initialize the menu on the client. The constructor used to initialize the menu on the client is the one supplied to the MenuType. Any fields that the server menu constructor contains should have some default for the client menu constructor.

// Client menu constructor
public MyMenu(int containerId, Inventory playerInventory) { // optional FriendlyByteBuf parameter if reading data from server
this(containerId, playerInventory, /* Any default parameters here */);
}

// Server menu constructor
public MyMenu(int containerId, Inventory playerInventory, /* Any additional parameters here. */) {
// ...
}
note

If no additional data needs to be displayed in the menu, then only one constructor is necessary.

Each menu implementation must implement two methods: #stillValid and #quickMoveStack.

#stillValid and ContainerLevelAccess

#stillValid determines whether the menu should remain open for a given player. This is typically directed to the static #stillValid which takes in a ContainerLevelAccess, the player, and the Block this menu is attached to. The client menu must always return true for this method, which the static #stillValid does default to. This implementation checks whether the player is within eight blocks of where the data storage object is located.

A ContainerLevelAccess supplies the current level and block position within an enclosed scope. When constructing the menu on the server, a new access can be created by calling ContainerLevelAccess#create. The client menu constructor can pass in ContainerLevelAccess#NULL, which will do nothing.

// Client menu constructor
public MyMenuAccess(int containerId, Inventory playerInventory) {
this(containerId, playerInventory, ContainerLevelAccess.NULL);
}

// Server menu constructor
public MyMenuAccess(int containerId, Inventory playerInventory, ContainerLevelAccess access) {
// ...
}

// Assume this menu is attached to Supplier<Block> MY_BLOCK
@Override
public boolean stillValid(Player player) {
return AbstractContainerMenu.stillValid(this.access, player, MY_BLOCK.get());
}

Data Synchronization

Some data needs to be present on both the server and the client to display to the player. To do this, the menu implements a basic layer of data synchronization such that whenever the current data does not match the data last synced to the client. For players, this is checked every tick.

Minecraft supports two forms of data synchronization by default: ItemStacks via Slots and integers via DataSlots. Slots and DataSlots are views which hold references to data storages that can be be modified by the player in a screen, assuming the action is valid. These can be added to a menu within the constructor through #addSlot and #addDataSlot.

note

Since Containers used by Slots are deprecated by NeoForge in favor of using the IItemHandler capability, the rest of the explanation will revolve around using the capability variant: SlotItemHandler.

A SlotItemHandler contains four parameters: the IItemHandler representing the inventory the stacks are within, the index of the stack this slot is specifically representing, and the x and y position of where the top-left position of the slot will render on the screen relative to AbstractContainerScreen#leftPos and #topPos. The client menu constructor should always supply an empty instance of an inventory of the same size.

In most cases, any slots the menu contains is first added, followed by the player's inventory, and finally concluded with the player's hotbar. To access any individual Slot from the menu, the index must be calculated based upon the order of which slots were added.

A DataSlot is an abstract class which should implement a getter and setter to reference the data stored in the data storage object. The client menu constructor should always supply a new instance via DataSlot#standalone.

These, along with slots, should be recreated every time a new menu is initialized.

note

Although a DataSlot stores an integer, it is effectively limited to a short (-32768 to 32767) because of how it sends the value across the network. The 16 high-order bits of the integer are ignored.

NeoForge patches the packet to provide the full integer to the client.

// Assume we have an inventory from a data object of size 5
// Assume we have a DataSlot constructed on each initialization of the server menu

// Client menu constructor
public MyMenuAccess(int containerId, Inventory playerInventory) {
this(containerId, playerInventory, new ItemStackHandler(5), DataSlot.standalone());
}

// Server menu constructor
public MyMenuAccess(int containerId, Inventory playerInventory, IItemHandler dataInventory, DataSlot dataSingle) {
// Check if the data inventory size is some fixed value
// Then, add slots for data inventory
this.addSlot(new SlotItemHandler(dataInventory, /*...*/));

// Add slots for player inventory
this.addSlot(new Slot(playerInventory, /*...*/));

// Add data slots for handled integers
this.addDataSlot(dataSingle);

// ...
}

ContainerData

If multiple integers need to be synced to the client, a ContainerData can be used to reference the integers instead. This interface functions as an index lookup such that each index represents a different integer. ContainerDatas can also be constructed in the data object itself if the ContainerData is added to the menu through #addDataSlots. The method creates a new DataSlot for the amount of data specified by the interface. The client menu constructor should always supply a new instance via SimpleContainerData.

// Assume we have a ContainerData of size 3

// Client menu constructor
public MyMenuAccess(int containerId, Inventory playerInventory) {
this(containerId, playerInventory, new SimpleContainerData(3));
}

// Server menu constructor
public MyMenuAccess(int containerId, Inventory playerInventory, ContainerData dataMultiple) {
// Check if the ContainerData size is some fixed value
checkContainerDataCount(dataMultiple, 3);

// Add data slots for handled integers
this.addDataSlots(dataMultiple);

// ...
}

#quickMoveStack

#quickMoveStack is the second method that must be implemented by any menu. This method is called whenever a stack has been shift-clicked, or quick moved, out of its current slot until the stack has been fully moved out of its previous slot or there is no other place for the stack to go. The method returns a copy of the stack in the slot being quick moved.

Stacks are typically moved between slots using #moveItemStackTo, which moves the stack into the first available slot. It takes in the stack to be moved, the first slot index (inclusive) to try and move the stack to, the last slot index (exclusive), and whether to check the slots from first to last (when false) or from last to first (when true).

Across Minecraft implementations, this method is fairly consistent in its logic:

// Assume we have a data inventory of size 5
// The inventory has 4 inputs (index 1 - 4) which outputs to a result slot (index 0)
// We also have the 27 player inventory slots and the 9 hotbar slots
// As such, the actual slots are indexed like so:
// - Data Inventory: Result (0), Inputs (1 - 4)
// - Player Inventory (5 - 31)
// - Player Hotbar (32 - 40)
@Override
public ItemStack quickMoveStack(Player player, int quickMovedSlotIndex) {
// The quick moved slot stack
ItemStack quickMovedStack = ItemStack.EMPTY;
// The quick moved slot
Slot quickMovedSlot = this.slots.get(quickMovedSlotIndex)

// If the slot is in the valid range and the slot is not empty
if (quickMovedSlot != null && quickMovedSlot.hasItem()) {
// Get the raw stack to move
ItemStack rawStack = quickMovedSlot.getItem();
// Set the slot stack to a copy of the raw stack
quickMovedStack = rawStack.copy();

/*
The following quick move logic can be simplified to if in data inventory,
try to move to player inventory/hotbar and vice versa for containers
that cannot transform data (e.g. chests).
*/

// If the quick move was performed on the data inventory result slot
if (quickMovedSlotIndex == 0) {
// Try to move the result slot into the player inventory/hotbar
if (!this.moveItemStackTo(rawStack, 5, 41, true)) {
// If cannot move, no longer quick move
return ItemStack.EMPTY;
}

// Perform logic on result slot quick move
slot.onQuickCraft(rawStack, quickMovedStack);
}
// Else if the quick move was performed on the player inventory or hotbar slot
else if (quickMovedSlotIndex >= 5 && quickMovedSlotIndex < 41) {
// Try to move the inventory/hotbar slot into the data inventory input slots
if (!this.moveItemStackTo(rawStack, 1, 5, false)) {
// If cannot move and in player inventory slot, try to move to hotbar
if (quickMovedSlotIndex < 32) {
if (!this.moveItemStackTo(rawStack, 32, 41, false)) {
// If cannot move, no longer quick move
return ItemStack.EMPTY;
}
}
// Else try to move hotbar into player inventory slot
else if (!this.moveItemStackTo(rawStack, 5, 32, false)) {
// If cannot move, no longer quick move
return ItemStack.EMPTY;
}
}
}
// Else if the quick move was performed on the data inventory input slots, try to move to player inventory/hotbar
else if (!this.moveItemStackTo(rawStack, 5, 41, false)) {
// If cannot move, no longer quick move
return ItemStack.EMPTY;
}

if (rawStack.isEmpty()) {
// If the raw stack has completely moved out of the slot, set the slot to the empty stack
quickMovedSlot.set(ItemStack.EMPTY);
} else {
// Otherwise, notify the slot that that the stack count has changed
quickMovedSlot.setChanged();
}

/*
The following if statement and Slot#onTake call can be removed if the
menu does not represent a container that can transform stacks (e.g.
chests).
*/
if (rawStack.getCount() == quickMovedStack.getCount()) {
// If the raw stack was not able to be moved to another slot, no longer quick move
return ItemStack.EMPTY;
}
// Execute logic on what to do post move with the remaining stack
quickMovedSlot.onTake(player, rawStack);
}

return quickMovedStack; // Return the slot stack
}

Opening a Menu

Once a menu type has been registered, the menu itself has been finished, and a screen has been attached, a menu can then be opened by the player. Menus can be opened by calling IPlayerExtension#openMenu on the logical server. The method takes in the MenuProvider of the server side menu and optionally a Consumer<RegistryFriendlyByteBuf> if extra data needs to be synced to the client.

note

IPlayerExtension#openMenu with the Consumer<RegistryFriendlyByteBuf> parameter should only be used if a menu type was created using an IContainerFactory.

A MenuProvider is an interface that contains two methods: #createMenu, which creates the server instance of the menu, and #getDisplayName, which returns a component containing the title of the menu to pass to the screen. The #createMenu method contains three parameter: the container id of the menu, the inventory of the player who opened the menu, and the player who opened the menu.

A MenuProvider can easily be created using SimpleMenuProvider, which takes in a method reference to create the server menu and the title of the menu.

// In some implementation with access to the Player on the logical server (e.g. ServerPlayer instance)
// Assume we have ServerPlayer serverPlayer
serverPlayer.openMenu(new SimpleMenuProvider(
(containerId, playerInventory, player) -> new MyMenu(containerId, playerInventory),
Component.translatable("menu.title.examplemod.mymenu")
));

Common Implementations

Menus are typically opened on a player interaction of some kind (e.g. when a block or entity is right-clicked).

Block Implementation

Blocks typically implement a menu by overriding BlockBehaviour#useWithoutItem, returning InteractionResult#SUCCESS for the interaction.

The MenuProvider should be implemented by overriding BlockBehaviour#getMenuProvider. Vanilla methods use this to view the menu in spectator mode.

// In some Block subclass
@Override
public MenuProvider getMenuProvider(BlockState state, Level level, BlockPos pos) {
return new SimpleMenuProvider(/* ... */);
}

@Override
public InteractionResult useWithoutItem(BlockState state, Level level, BlockPos pos, Player player, InteractionHand hand, BlockHitResult result) {
if (!level.isClientSide && player instanceof ServerPlayer serverPlayer) {
serverPlayer.openMenu(state.getMenuProvider(level, pos));
}

return InteractionResult.SUCCESS;
}
note

This is the simplest way to implement the logic, not the only way. If you want the block to only open the menu under certain conditions, then some data will need to be synced to the client beforehand to return InteractionResult#PASS or #FAIL if the conditions are not met.

Mob Implementation

Mobs typically implement a menu by overriding Mob#mobInteract. This is done similarly to the block implementation with the only difference being that the Mob itself should implement MenuProvider to support spectator mode viewing.

public class MyMob extends Mob implements MenuProvider {
// ...

@Override
public InteractionResult mobInteract(Player player, InteractionHand hand) {
if (!this.level.isClientSide && player instanceof ServerPlayer serverPlayer) {
serverPlayer.openMenu(this);
}

return InteractionResult.SUCCESS;
}
}
note

Once again, this is the simplest way to implement the logic, not the only way.