Screens
Screens are typically the base of all Graphical User Interfaces (GUIs) in Minecraft: taking in user input, verifying it on the server, and syncing the resulting action back to the client. They can be combined with menus to create an communication network for inventory-like views, or they can be standalone which modders can handle through their own network implementations.
Screens are made up of numerous parts, making it difficult to fully understand what a 'screen' actually is in Minecraft. As such, this document will go over each of the screen's components and how it is applied before discussing the screen itself.
Relative Coordinates
Whenever anything is rendered, there needs to be some identifier which specifies where it will appear. With numerous abstractions, most of Minecraft's rendering calls take x, y, and z values in a coordinate plane. X values increase from left to right, y from top to bottom, and z from far to near. However, the coordinates are not fixed to a specified range. Their range can change depending on the size of the screen and the “GUI scale” specified within the game’s options. As such, extra care must be taken to ensure the coordinates values passed to rendering calls scale properly—are relativized correctly—to the changeable screen size.
Information on how to relativize your coordinates is in the screen section.
If you choose to use fixed coordinates or incorrectly scale the screen, the rendered objects may look strange or misplaced. An easy way to check if you relativized your coordinates correctly is to click the 'Gui Scale' button in your video settings. This value is used as the divisor to the width and height of your display when determining the scale at which a GUI should render.
Gui Graphics
Any GUI rendered by Minecraft is typically done using GuiGraphics
. GuiGraphics
is the first parameter to almost all rendering methods; it contains basic methods to render commonly used objects. These fall into five categories: colored rectangles, strings, textures, items, and tooltips. There is also an additional method for rendering a snippet of a component (#enableScissor
/ #disableScissor
). GuiGraphics
also exposes the PoseStack
which applies the transformations necessary to properly render where the component should be rendered. Additionally, colors are in the ARGB format.
Colored Rectangles
Colored rectangles are drawn through a position color shader. All fill methods can take in an optional RenderType
to specify how the rectangle should be rendered. There are three types of colored rectangles that can be drawn.
First, there is a colored horizontal and vertical one-pixel wide line, #hLine
and #vLine
respectively. #hLine
takes in two x coordinates defining the left and right (inclusively), the top y coordinate, and the color. #vLine
takes in the left x coordinate, two y coordinates defining the top and bottom (inclusively), and the color.
Second, there is the #fill
method, which draws a rectangle to the screen. The line methods internally call this method. This takes in the left x coordinate, the top y coordinate, the right x coordinate, the bottom y coordinate, and the color. #fillRenderType
also does the same; however, it draws the vertices without correcting the coordinate locations.
Finally, there is the #fillGradient
method, which draws a rectangle with a vertical gradient. This takes in the right x coordinate, the bottom y coordinate, the left x coordinate, the top y coordinate, the z coordinate, and the bottom and top colors.
Strings
Strings are drawn through its Font
, typically consisting of their own shaders for normal, see through, and offset mode. There are two alignment of strings that can be rendered, each with a back shadow: a left-aligned string (#drawString
) and a center-aligned string (#drawCenteredString
). These both take in the font the string will be rendered in, the string to draw, the x coordinate representing the left or center of the string respectively, the top y coordinate, and the color.
If the text should be wrapped within a given bounds, then #drawWordWrap
can be used instead. This renders a left-aligned string by default.
Strings should typically be passed in as Component
s as they handle a variety of usecases, including the two other overloads of the method.
Textures
Textures are drawn through blitting, hence the method name #blit
, which, for this purpose, copies the bits of an image and draws them directly to the screen. These are drawn through a position texture shader.
Each #blit
method takes in a ResourceLocation
, which represents the absolute location of the texture:
// Points to 'assets/examplemod/textures/gui/container/example_container.png'
private static final ResourceLocation TEXTURE = ResourceLocation.fromNamespaceAndPath("examplemod", "textures/gui/container/example_container.png");
While there are many different #blit
overloads, we will only discuss two of them.
The first #blit
takes in six integers and assumes the texture being rendered is on a 256 x 256 PNG file. It takes in the left x and top y screen coordinate, the left x and top y coordinate within the PNG, and the width and height of the image to render.
The size of the PNG file must be specified so that the coordinates can be normalized to obtain the associated UV values.
The second #blit
which the first calls expands this to seven integers and two floats for the PNG coordinates, only assuming the image is on a PNG file. It takes in the left x and top y screen coordinate, the z coordinate (referred to as the blit offset), the left x and top y coordinate within the PNG, the width and height of the image to render, and the width and height of the PNG file.
blitSprite
#blitSprite
is a special implementation of #blit
where the texture is written to the GUI texture atlas. Most textures that overlay the background, such as the 'burn progress' overlay in furnace GUIs, are sprites. All sprite textures are relative to textures/gui/sprites
and do not need to specify the file extension.
// Points to 'assets/examplemod/textures/gui/sprites/container/example_container/example_sprite.png'
private static final ResourceLocation SPRITE = ResourceLocation.fromNamespaceAndPath("examplemod", "container/example_container/example_sprite");
One set of #blitSprite
methods have the same parameters as #blit
, except for the x and y coordinate within the sprite.
The other #blitSprite
methods take in more texture information to allow for rendering part of the sprite. These methods take in the texture width and height, the x and y coordinate in the sprite, the left x and top y screen coordinate, the z coordinate (referred to as the blit offset), and the width and height of the image to render.
If the sprite size does not match the texture size, then the sprite can be scaled in one of three ways: stretch
, tile
, and nine_slice
. stretch
stretches the image from the texture size to the screen size. tile
renders the texture over and over again until it reaches the screen size. nine_slice
divides the texture into one center, four edges, and four corners to tile the texture to the required screen size.
This is set by adding the gui.scaling
JSON object in an mcmeta file with the same name of the texture file.
// For some texture file example_sprite.png
// In example_sprite.png.mcmeta
// Stretch example
{
"gui": {
"scaling": {
"type": "stretch"
}
}
}
// Tile example
{
"gui": {
"scaling": {
"type": "tile",
// The size to begin tiling at
// This is usually the size of the texture
"width": 40,
"height": 40
}
}
}
// Nine slice example
{
"gui": {
"scaling": {
"type": "nine_slice",
// The size to begin tiling at
// This is usually the size of the texture
"width": 40,
"height": 40,
"border": {
// The padding of the texture that will be sliced into the border texture
"left": 1,
"right": 1,
"top": 1,
"bottom": 1
}
}
}
}
Blit Offset
The z coordinate when rendering a texture is typically set to the blit offset. The offset is responsible for properly layering renders when viewing a screen. Renders with a smaller z coordinate are rendered in the background and vice versa where renders with a larger z coordinate are rendered in the foreground. The z offset can be set directly on the PoseStack
itself via #translate
. Some basic offset logic is applied internally in some methods of GuiGraphics
(e.g. item rendering).
When setting the blit offset, you must reset it after rendering your object. Otherwise, other objects within the screen may be rendered in an incorrect layer causing graphical issues. It is recommended to push the current pose before translating and then popping after all rendering at the offset is completed.
Renderable
Renderable
s are essentially objects that are rendered. These include screens, buttons, chat boxes, lists, etc. Renderable
s only have one method: #render
. This takes in the GuiGraphics
used to render things to the screen, the x and y positions of the mouse scaled to the relative screen size, and the tick delta (how many ticks have passed since the last frame).
Some common renderables are screens and 'widgets': interactable elements which typically render on the screen such as Button
, its subtype ImageButton
, and EditBox
which is used to input text on the screen.
GuiEventListener
Any screen rendered in Minecraft implements GuiEventListener
. GuiEventListener
s are responsible for handling user interaction with the screen. These include inputs from the mouse (movement, clicked, released, dragged, scrolled, mouseover) and keyboard (pressed, released, typed). Each method returns whether the associated action affected the screen successfully. Widgets like buttons, chat boxes, lists, etc. also implement this interface.
ContainerEventHandler
Almost synonymous with GuiEventListener
s are their subtype: ContainerEventHandler
s. These are responsible for handling user interaction on screens which contain widgets, managing which is currently focused and how the associated interactions are applied. ContainerEventHandler
s add three additional features: interactable children, dragging, and focusing.
Event handlers hold children which are used to determine the interaction order of elements. During the mouse event handlers (excluding dragging), the first child in the list that the mouse hovers over has their logic executed.
Dragging an element with the mouse, implemented via #mouseClicked
and #mouseReleased
, provides more precisely executed logic.
Focusing allows for a specific child to be checked first and handled during an event's execution, such as during keyboard events or dragging the mouse. Focus is typically set through #setFocused
. In addition, interactable children can be cycled using #nextFocusPath
, selecting the child based upon the FocusNavigationEvent
passed in.
Screens implement ContainerEventHandler
through AbstractContainerEventHandler
, which adds in the setter and getter logic for dragging and focusing children.
NarratableEntry
NarratableEntry
s are elements which can be spoken about through Minecraft's accessibility narration feature. Each element can provide different narration depending on what is hovered or selected, prioritized typically by focus, hovering, and then all other cases.
NarratableEntry
s have three methods: one which determines the priority of the element (#narrationPriority
), one which determines whether to speak the narration (#isActive
), and finally one which supplies the narration to its associated output, spoken or read (#updateNarration
).
All widgets from Minecraft are NarratableEntry
s, so it typically does not need to be manually implemented if using an available subtype.
The Screen Subtype
With all of the above knowledge, a basic screen can be constructed. To make it easier to understand, the components of a screen will be mentioned in the order they are typically encountered.
First, all screens take in a Component
which represents the title of the screen. This component is typically drawn to the screen by one of its subtypes. It is only used in the base screen for the narration message.
// In some Screen subclass
public MyScreen(Component title) {
super(title);
}
Initialization
Once a screen has been initialized, the #init
method is called. The #init
method sets the initial settings inside the screen from the Minecraft
instance to the relative width and height as scaled by the game. Any setup such as adding widgets or precomputing relative coordinates should be done in this method. If the game window is resized, the screen will be reinitialized by calling the #init
method.
There are three ways to add a widget to a screen, each serving a separate purpose:
Method | Description |
---|---|
#addWidget | Adds a widget that is interactable and narrated, but not rendered. |
#addRenderableOnly | Adds a widget that will only be rendered; it is not interactable or narrated. |
#addRenderableWidget | Adds a widget that is interactable, narrated, and rendered. |
Typically, #addRenderableWidget
will be used most often.
// In some Screen subclass
@Override
protected void init() {
super.init();
// Add widgets and precomputed values
this.addRenderableWidget(new EditBox(/* ... */));
}
Ticking Screens
Screens also tick using the #tick
method to perform some level of client side logic for rendering purposes.
// In some Screen subclass
@Override
public void tick() {
super.tick();
// Execute some logic every frame
}
Input Handling
Since screens are subtypes of GuiEventListener
s, the input handlers can also be overridden, such as for handling logic on a specific key press.
Rendering the Screen
Finally, screens are rendered through the #render
method provided by being a Renderable
subtype. As mentioned, the #render
method draws the everything the screen has to render every frame, such as the background, widgets, tooltips, etc. By default, the #render
method only renders the widgets to the screen.
The two most common things rendered within a screen that is typically not handled by a subtype is the background and the tooltips.
The background can be rendered using #renderBackground
, with one method taking in a v Offset for the options background whenever a screen is rendered when the level behind it cannot be.
Tooltips are rendered through GuiGraphics#renderTooltip
or GuiGraphics#renderComponentTooltip
which can take in the text components being rendered, an optional custom tooltip component, and the x / y relative coordinates on where the tooltip should be rendered on the screen.
// In some Screen subclass
// mouseX and mouseY indicate the scaled coordinates of where the cursor is in on the screen
@Override
public void render(GuiGraphics graphics, int mouseX, int mouseY, float partialTick) {
// Background is typically rendered first
this.renderBackground(graphics);
// Render things here before widgets (background textures)
// Then the widgets if this is a direct child of the Screen
super.render(graphics, mouseX, mouseY, partialTick);
// Render things after widgets (tooltips)
}
Closing the Screen
When a screen is closed, two methods handle the teardown: #onClose
and #removed
.
#onClose
is called whenever the user makes an input to close the current screen. This method is typically used as a callback to destroy and save any internal processes in the screen itself. This includes sending packets to the server.
#removed
is called just before the screen changes and is released to the garbage collector. This handles anything that hasn't been reset back to its initial state before the screen was opened.
// In some Screen subclass
@Override
public void onClose() {
// Stop any handlers here
// Call last in case it interferes with the override
super.onClose();
}
@Override
public void removed() {
// Reset initial states here
// Call last in case it interferes with the override
super.removed()
;}
AbstractContainerScreen
If a screen is directly attached to a menu, then an AbstractContainerScreen
should be subclassed instead. An AbstractContainerScreen
acts as the renderer and input handler of a menu and contains logic for syncing and interacting with slots. As such, only two methods typically need to be overridden or implemented to have a working container screen. Once again, to make it easier to understand, the components of a container screen will be mentioned in the order they are typically encountered.
An AbstractContainerScreen
typically requires three parameters: the container menu being opened (represented by the generic T
), the player inventory (only for the display name), and the title of the screen itself. Within here, a number of positioning fields can be set:
Field | Description |
---|---|
imageWidth | The width of the texture used for the background. This is typically inside a PNG of 256 x 256 and defaults to 176. |
imageHeight | The width of the texture used for the background. This is typically inside a PNG of 256 x 256 and defaults to 166. |
titleLabelX | The relative x coordinate of where the screen title will be rendered. |
titleLabelY | The relative y coordinate of where the screen title will be rendered. |
inventoryLabelX | The relative x coordinate of where the player inventory name will be rendered. |
inventoryLabelY | The relative y coordinate of where the player inventory name will be rendered. |
In a previous section, it mentioned that precomputed relative coordinates should be set in the #init
method. This still remains true, as the values mentioned here are not precomputed coordinates but static values and relativized coordinates.
The image values are static and non changing as they represent the background texture size. To make things easier when rendering, two additional values (leftPos
and topPos
) are precomputed in the #init
method which marks the top left corner of where the background will be rendered. The label coordinates are relative to these values.
The leftPos
and topPos
is also used as a convenient way to render the background as they already represent the position to pass into the #blit
method.
// In some AbstractContainerScreen subclass
public MyContainerScreen(MyMenu menu, Inventory playerInventory, Component title) {
super(menu, playerInventory, title);
this.titleLabelX = 10;
this.inventoryLabelX = 10;
/*
* If the 'imageHeight' is changed, 'inventoryLabelY' must also be
* changed as the value depends on the 'imageHeight' value.
*/
}
Menu Access
As the menu is passed into the screen, any values that were within the menu and synced (either through slots, data slots, or a custom system) can now be accessed through the menu
field.
Container Tick
Container screens tick within the #tick
method when the player is alive and looking at the screen via #containerTick
. This essentially takes the place of #tick
within container screens, with its most common usage being to tick the recipe book.
// In some AbstractContainerScreen subclass
@Override
protected void containerTick() {
super.containerTick();
// Tick things here
}
Rendering the Container Screen
The container screen is rendered across three methods: #renderBg
, which renders the background textures, #renderLabels
, which renders any text on top of the background, and #render
which encompass the previous two methods in addition to providing a grayed out background and tooltips.
Starting with #render
, the most common override (and typically the only case) adds the background, calls the super to render the container screen, and finally renders the tooltips on top of it.
// In some AbstractContainerScreen subclass
@Override
public void render(GuiGraphics graphics, int mouseX, int mouseY, float partialTick) {
this.renderBackground(graphics);
super.render(graphics, mouseX, mouseY, partialTick);
/*
* This method is added by the container screen to render
* the tooltip of the hovered slot.
*/
this.renderTooltip(graphics, mouseX, mouseY);
}
Within the super, #renderBg
is called to render the background of the screen. The most standard representation uses three method calls: two for setup and one to draw the background texture.
// In some AbstractContainerScreen subclass
// The location of the background texture (assets/<namespace>/<path>)
private static final ResourceLocation BACKGROUND_LOCATION = ResourceLocation.fromNamespaceAndPath(MOD_ID, "textures/gui/container/my_container_screen.png");
@Override
protected void renderBg(GuiGraphics graphics, float partialTick, int mouseX, int mouseY) {
/*
* Renders the background texture to the screen. 'leftPos' and
* 'topPos' should already represent the top left corner of where
* the texture should be rendered as it was precomputed from the
* 'imageWidth' and 'imageHeight'. The two zeros represent the
* integer u/v coordinates inside the 256 x 256 PNG file.
*/
graphics.blit(BACKGROUND_LOCATION, this.leftPos, this.topPos, 0, 0, this.imageWidth, this.imageHeight);
}
Finally, #renderLabels
is called to render any text above the background, but below the tooltips. This simply calls uses the font to draw the associated components.
// In some AbstractContainerScreen subclass
@Override
protected void renderLabels(GuiGraphics graphics, int mouseX, int mouseY) {
super.renderLabels(graphics, mouseX, mouseY);
// Assume we have some Component 'label'
// 'label' is drawn at 'labelX' and 'labelY'
graphics.drawString(this.font, this.label, this.labelX, this.labelY, 0x404040);
}
When rendering the label, you do not need to specify the leftPos
and topPos
offset. Those have already been translated within the PoseStack
so everything within this method is drawn relative to those coordinates.
Registering an AbstractContainerScreen
To use an AbstractContainerScreen
with a menu, it needs to be registered. This can be done by calling register
within the RegisterMenuScreensEvent
on the mod event bus.
// Event is listened to on the mod event bus
private void registerScreens(RegisterMenuScreensEvent event) {
event.register(MY_MENU.get(), MyContainerScreen::new);
}