mirror of
https://github.com/bevyengine/bevy
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6b40b6749e
# Objective Right now, all assets in the main world get extracted and prepared in the render world (if the asset's using the RenderAssetPlugin). This is unfortunate for two cases: 1. **TextureAtlas** / **FontAtlas**: This one's huge. The individual `Image` assets that make up the atlas are cloned and prepared individually when there's no reason for them to be. The atlas textures are built on the CPU in the main world. *There can be hundreds of images that get prepared for rendering only not to be used.* 2. If one loads an Image and needs to transform it in a system before rendering it, kind of like the [decompression example](https://github.com/bevyengine/bevy/blob/main/examples/asset/asset_decompression.rs#L120), there's a price paid for extracting & preparing the asset that's not intended to be rendered yet. ------ * References #10520 * References #1782 ## Solution This changes the `RenderAssetPersistencePolicy` enum to bitflags. I felt that the objective with the parameter is so similar in nature to wgpu's [`TextureUsages`](https://docs.rs/wgpu/latest/wgpu/struct.TextureUsages.html) and [`BufferUsages`](https://docs.rs/wgpu/latest/wgpu/struct.BufferUsages.html), that it may as well be just like that. ```rust // This asset only needs to be in the main world. Don't extract and prepare it. RenderAssetUsages::MAIN_WORLD // Keep this asset in the main world and RenderAssetUsages::MAIN_WORLD | RenderAssetUsages::RENDER_WORLD // This asset is only needed in the render world. Remove it from the asset server once extracted. RenderAssetUsages::RENDER_WORLD ``` ### Alternate Solution I considered introducing a third field to `RenderAssetPersistencePolicy` enum: ```rust enum RenderAssetPersistencePolicy { /// Keep the asset in the main world after extracting to the render world. Keep, /// Remove the asset from the main world after extracting to the render world. Unload, /// This doesn't need to be in the render world at all. NoExtract, // <----- } ``` Functional, but this seemed like shoehorning. Another option is renaming the enum to something like: ```rust enum RenderAssetExtractionPolicy { /// Extract the asset and keep it in the main world. Extract, /// Remove the asset from the main world after extracting to the render world. ExtractAndUnload, /// This doesn't need to be in the render world at all. NoExtract, } ``` I think this last one could be a good option if the bitflags are too clunky. ## Migration Guide * `RenderAssetPersistencePolicy::Keep` → `RenderAssetUsage::MAIN_WORLD | RenderAssetUsage::RENDER_WORLD` (or `RenderAssetUsage::default()`) * `RenderAssetPersistencePolicy::Unload` → `RenderAssetUsage::RENDER_WORLD` * For types implementing the `RenderAsset` trait, change `fn persistence_policy(&self) -> RenderAssetPersistencePolicy` to `fn asset_usage(&self) -> RenderAssetUsages`. * Change any references to `cpu_persistent_access` (`RenderAssetPersistencePolicy`) to `asset_usage` (`RenderAssetUsage`). This applies to `Image`, `Mesh`, and a few other types.
394 lines
15 KiB
Rust
394 lines
15 KiB
Rust
//! This example shows how to manually render 2d items using "mid level render apis" with a custom
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//! pipeline for 2d meshes.
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//! It doesn't use the [`Material2d`] abstraction, but changes the vertex buffer to include vertex color.
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//! Check out the "mesh2d" example for simpler / higher level 2d meshes.
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//!
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//! [`Material2d`]: bevy::sprite::Material2d
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use bevy::{
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core_pipeline::core_2d::Transparent2d,
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prelude::*,
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render::{
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mesh::{Indices, MeshVertexAttribute},
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render_asset::RenderAssetUsages,
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render_asset::RenderAssets,
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render_phase::{AddRenderCommand, DrawFunctions, RenderPhase, SetItemPipeline},
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render_resource::{
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BlendState, ColorTargetState, ColorWrites, Face, FragmentState, FrontFace,
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MultisampleState, PipelineCache, PolygonMode, PrimitiveState, PrimitiveTopology,
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RenderPipelineDescriptor, SpecializedRenderPipeline, SpecializedRenderPipelines,
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TextureFormat, VertexBufferLayout, VertexFormat, VertexState, VertexStepMode,
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},
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texture::BevyDefault,
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view::{ExtractedView, ViewTarget, VisibleEntities},
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Extract, Render, RenderApp, RenderSet,
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},
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sprite::{
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extract_mesh2d, DrawMesh2d, Material2dBindGroupId, Mesh2dHandle, Mesh2dPipeline,
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Mesh2dPipelineKey, Mesh2dTransforms, MeshFlags, RenderMesh2dInstance,
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RenderMesh2dInstances, SetMesh2dBindGroup, SetMesh2dViewBindGroup,
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},
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utils::FloatOrd,
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};
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use std::f32::consts::PI;
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fn main() {
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App::new()
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.add_plugins((DefaultPlugins, ColoredMesh2dPlugin))
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.add_systems(Startup, star)
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.run();
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}
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fn star(
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mut commands: Commands,
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// We will add a new Mesh for the star being created
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mut meshes: ResMut<Assets<Mesh>>,
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) {
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// Let's define the mesh for the object we want to draw: a nice star.
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// We will specify here what kind of topology is used to define the mesh,
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// that is, how triangles are built from the vertices. We will use a
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// triangle list, meaning that each vertex of the triangle has to be
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// specified. We set `RenderAssetUsages::RENDER_WORLD`, meaning this mesh
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// will not be accessible in future frames from the `meshes` resource, in
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// order to save on memory once it has been uploaded to the GPU.
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let mut star = Mesh::new(
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PrimitiveTopology::TriangleList,
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RenderAssetUsages::RENDER_WORLD,
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);
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// Vertices need to have a position attribute. We will use the following
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// vertices (I hope you can spot the star in the schema).
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//
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// 1
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//
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// 10 2
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// 9 0 3
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// 8 4
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// 6
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// 7 5
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//
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// These vertices are specified in 3D space.
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let mut v_pos = vec![[0.0, 0.0, 0.0]];
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for i in 0..10 {
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// The angle between each vertex is 1/10 of a full rotation.
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let a = i as f32 * PI / 5.0;
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// The radius of inner vertices (even indices) is 100. For outer vertices (odd indices) it's 200.
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let r = (1 - i % 2) as f32 * 100.0 + 100.0;
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// Add the vertex position.
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v_pos.push([r * a.sin(), r * a.cos(), 0.0]);
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}
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// Set the position attribute
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star.insert_attribute(Mesh::ATTRIBUTE_POSITION, v_pos);
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// And a RGB color attribute as well
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let mut v_color: Vec<u32> = vec![Color::BLACK.as_linear_rgba_u32()];
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v_color.extend_from_slice(&[Color::YELLOW.as_linear_rgba_u32(); 10]);
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star.insert_attribute(
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MeshVertexAttribute::new("Vertex_Color", 1, VertexFormat::Uint32),
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v_color,
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);
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// Now, we specify the indices of the vertex that are going to compose the
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// triangles in our star. Vertices in triangles have to be specified in CCW
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// winding (that will be the front face, colored). Since we are using
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// triangle list, we will specify each triangle as 3 vertices
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// First triangle: 0, 2, 1
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// Second triangle: 0, 3, 2
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// Third triangle: 0, 4, 3
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// etc
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// Last triangle: 0, 1, 10
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let mut indices = vec![0, 1, 10];
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for i in 2..=10 {
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indices.extend_from_slice(&[0, i, i - 1]);
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}
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star.set_indices(Some(Indices::U32(indices)));
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// We can now spawn the entities for the star and the camera
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commands.spawn((
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// We use a marker component to identify the custom colored meshes
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ColoredMesh2d,
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// The `Handle<Mesh>` needs to be wrapped in a `Mesh2dHandle` to use 2d rendering instead of 3d
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Mesh2dHandle(meshes.add(star)),
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// This bundle's components are needed for something to be rendered
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SpatialBundle::INHERITED_IDENTITY,
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));
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// Spawn the camera
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commands.spawn(Camera2dBundle::default());
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}
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/// A marker component for colored 2d meshes
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#[derive(Component, Default)]
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pub struct ColoredMesh2d;
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/// Custom pipeline for 2d meshes with vertex colors
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#[derive(Resource)]
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pub struct ColoredMesh2dPipeline {
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/// this pipeline wraps the standard [`Mesh2dPipeline`]
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mesh2d_pipeline: Mesh2dPipeline,
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}
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impl FromWorld for ColoredMesh2dPipeline {
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fn from_world(world: &mut World) -> Self {
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Self {
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mesh2d_pipeline: Mesh2dPipeline::from_world(world),
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}
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}
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}
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// We implement `SpecializedPipeline` to customize the default rendering from `Mesh2dPipeline`
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impl SpecializedRenderPipeline for ColoredMesh2dPipeline {
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type Key = Mesh2dPipelineKey;
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fn specialize(&self, key: Self::Key) -> RenderPipelineDescriptor {
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// Customize how to store the meshes' vertex attributes in the vertex buffer
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// Our meshes only have position and color
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let formats = vec![
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// Position
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VertexFormat::Float32x3,
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// Color
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VertexFormat::Uint32,
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];
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let vertex_layout =
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VertexBufferLayout::from_vertex_formats(VertexStepMode::Vertex, formats);
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let format = match key.contains(Mesh2dPipelineKey::HDR) {
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true => ViewTarget::TEXTURE_FORMAT_HDR,
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false => TextureFormat::bevy_default(),
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};
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RenderPipelineDescriptor {
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vertex: VertexState {
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// Use our custom shader
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shader: COLORED_MESH2D_SHADER_HANDLE,
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entry_point: "vertex".into(),
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shader_defs: vec![],
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// Use our custom vertex buffer
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buffers: vec![vertex_layout],
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},
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fragment: Some(FragmentState {
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// Use our custom shader
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shader: COLORED_MESH2D_SHADER_HANDLE,
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shader_defs: vec![],
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entry_point: "fragment".into(),
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targets: vec![Some(ColorTargetState {
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format,
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blend: Some(BlendState::ALPHA_BLENDING),
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write_mask: ColorWrites::ALL,
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})],
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}),
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// Use the two standard uniforms for 2d meshes
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layout: vec![
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// Bind group 0 is the view uniform
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self.mesh2d_pipeline.view_layout.clone(),
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// Bind group 1 is the mesh uniform
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self.mesh2d_pipeline.mesh_layout.clone(),
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],
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push_constant_ranges: Vec::new(),
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primitive: PrimitiveState {
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front_face: FrontFace::Ccw,
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cull_mode: Some(Face::Back),
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unclipped_depth: false,
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polygon_mode: PolygonMode::Fill,
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conservative: false,
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topology: key.primitive_topology(),
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strip_index_format: None,
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},
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depth_stencil: None,
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multisample: MultisampleState {
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count: key.msaa_samples(),
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mask: !0,
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alpha_to_coverage_enabled: false,
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},
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label: Some("colored_mesh2d_pipeline".into()),
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}
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}
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}
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// This specifies how to render a colored 2d mesh
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type DrawColoredMesh2d = (
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// Set the pipeline
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SetItemPipeline,
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// Set the view uniform as bind group 0
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SetMesh2dViewBindGroup<0>,
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// Set the mesh uniform as bind group 1
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SetMesh2dBindGroup<1>,
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// Draw the mesh
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DrawMesh2d,
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);
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// The custom shader can be inline like here, included from another file at build time
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// using `include_str!()`, or loaded like any other asset with `asset_server.load()`.
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const COLORED_MESH2D_SHADER: &str = r"
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// Import the standard 2d mesh uniforms and set their bind groups
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#import bevy_sprite::mesh2d_functions
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// The structure of the vertex buffer is as specified in `specialize()`
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struct Vertex {
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@builtin(instance_index) instance_index: u32,
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@location(0) position: vec3<f32>,
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@location(1) color: u32,
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};
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struct VertexOutput {
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// The vertex shader must set the on-screen position of the vertex
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@builtin(position) clip_position: vec4<f32>,
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// We pass the vertex color to the fragment shader in location 0
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@location(0) color: vec4<f32>,
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};
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/// Entry point for the vertex shader
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@vertex
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fn vertex(vertex: Vertex) -> VertexOutput {
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var out: VertexOutput;
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// Project the world position of the mesh into screen position
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let model = mesh2d_functions::get_model_matrix(vertex.instance_index);
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out.clip_position = mesh2d_functions::mesh2d_position_local_to_clip(model, vec4<f32>(vertex.position, 1.0));
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// Unpack the `u32` from the vertex buffer into the `vec4<f32>` used by the fragment shader
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out.color = vec4<f32>((vec4<u32>(vertex.color) >> vec4<u32>(0u, 8u, 16u, 24u)) & vec4<u32>(255u)) / 255.0;
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return out;
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}
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// The input of the fragment shader must correspond to the output of the vertex shader for all `location`s
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struct FragmentInput {
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// The color is interpolated between vertices by default
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@location(0) color: vec4<f32>,
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};
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/// Entry point for the fragment shader
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@fragment
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fn fragment(in: FragmentInput) -> @location(0) vec4<f32> {
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return in.color;
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}
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";
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/// Plugin that renders [`ColoredMesh2d`]s
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pub struct ColoredMesh2dPlugin;
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/// Handle to the custom shader with a unique random ID
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pub const COLORED_MESH2D_SHADER_HANDLE: Handle<Shader> =
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Handle::weak_from_u128(13828845428412094821);
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impl Plugin for ColoredMesh2dPlugin {
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fn build(&self, app: &mut App) {
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// Load our custom shader
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let mut shaders = app.world.resource_mut::<Assets<Shader>>();
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shaders.insert(
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COLORED_MESH2D_SHADER_HANDLE,
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Shader::from_wgsl(COLORED_MESH2D_SHADER, file!()),
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);
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// Register our custom draw function, and add our render systems
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app.get_sub_app_mut(RenderApp)
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.unwrap()
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.add_render_command::<Transparent2d, DrawColoredMesh2d>()
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.init_resource::<SpecializedRenderPipelines<ColoredMesh2dPipeline>>()
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.add_systems(
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ExtractSchedule,
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extract_colored_mesh2d.after(extract_mesh2d),
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)
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.add_systems(Render, queue_colored_mesh2d.in_set(RenderSet::QueueMeshes));
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}
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fn finish(&self, app: &mut App) {
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// Register our custom pipeline
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app.get_sub_app_mut(RenderApp)
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.unwrap()
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.init_resource::<ColoredMesh2dPipeline>();
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}
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}
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/// Extract the [`ColoredMesh2d`] marker component into the render app
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pub fn extract_colored_mesh2d(
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mut commands: Commands,
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mut previous_len: Local<usize>,
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// When extracting, you must use `Extract` to mark the `SystemParam`s
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// which should be taken from the main world.
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query: Extract<
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Query<(Entity, &ViewVisibility, &GlobalTransform, &Mesh2dHandle), With<ColoredMesh2d>>,
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>,
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mut render_mesh_instances: ResMut<RenderMesh2dInstances>,
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) {
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let mut values = Vec::with_capacity(*previous_len);
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for (entity, view_visibility, transform, handle) in &query {
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if !view_visibility.get() {
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continue;
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}
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let transforms = Mesh2dTransforms {
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transform: (&transform.affine()).into(),
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flags: MeshFlags::empty().bits(),
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};
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values.push((entity, ColoredMesh2d));
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render_mesh_instances.insert(
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entity,
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RenderMesh2dInstance {
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mesh_asset_id: handle.0.id(),
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transforms,
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material_bind_group_id: Material2dBindGroupId::default(),
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automatic_batching: false,
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},
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);
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}
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*previous_len = values.len();
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commands.insert_or_spawn_batch(values);
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}
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/// Queue the 2d meshes marked with [`ColoredMesh2d`] using our custom pipeline and draw function
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#[allow(clippy::too_many_arguments)]
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pub fn queue_colored_mesh2d(
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transparent_draw_functions: Res<DrawFunctions<Transparent2d>>,
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colored_mesh2d_pipeline: Res<ColoredMesh2dPipeline>,
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mut pipelines: ResMut<SpecializedRenderPipelines<ColoredMesh2dPipeline>>,
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pipeline_cache: Res<PipelineCache>,
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msaa: Res<Msaa>,
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render_meshes: Res<RenderAssets<Mesh>>,
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render_mesh_instances: Res<RenderMesh2dInstances>,
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mut views: Query<(
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&VisibleEntities,
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&mut RenderPhase<Transparent2d>,
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&ExtractedView,
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)>,
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) {
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if render_mesh_instances.is_empty() {
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return;
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}
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// Iterate each view (a camera is a view)
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for (visible_entities, mut transparent_phase, view) in &mut views {
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let draw_colored_mesh2d = transparent_draw_functions.read().id::<DrawColoredMesh2d>();
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let mesh_key = Mesh2dPipelineKey::from_msaa_samples(msaa.samples())
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| Mesh2dPipelineKey::from_hdr(view.hdr);
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// Queue all entities visible to that view
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for visible_entity in &visible_entities.entities {
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if let Some(mesh_instance) = render_mesh_instances.get(visible_entity) {
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let mesh2d_handle = mesh_instance.mesh_asset_id;
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let mesh2d_transforms = &mesh_instance.transforms;
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// Get our specialized pipeline
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let mut mesh2d_key = mesh_key;
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if let Some(mesh) = render_meshes.get(mesh2d_handle) {
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mesh2d_key |=
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Mesh2dPipelineKey::from_primitive_topology(mesh.primitive_topology);
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}
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let pipeline_id =
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pipelines.specialize(&pipeline_cache, &colored_mesh2d_pipeline, mesh2d_key);
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let mesh_z = mesh2d_transforms.transform.translation.z;
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transparent_phase.add(Transparent2d {
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entity: *visible_entity,
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draw_function: draw_colored_mesh2d,
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pipeline: pipeline_id,
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// The 2d render items are sorted according to their z value before rendering,
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// in order to get correct transparency
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sort_key: FloatOrd(mesh_z),
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// This material is not batched
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batch_range: 0..1,
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dynamic_offset: None,
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});
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}
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}
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}
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}
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