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https://github.com/bevyengine/bevy
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# Objective Adds a new `Readback` component to request for readback of a `Handle<Image>` or `Handle<ShaderStorageBuffer>` to the CPU in a future frame. ## Solution We track the `Readback` component and allocate a target buffer to write the gpu resource into and map it back asynchronously, which then fires a trigger on the entity in the main world. This proccess is asynchronous, and generally takes a few frames. ## Showcase ```rust let mut buffer = ShaderStorageBuffer::from(vec![0u32; 16]); buffer.buffer_description.usage |= BufferUsages::COPY_SRC; let buffer = buffers.add(buffer); commands .spawn(Readback::buffer(buffer.clone())) .observe(|trigger: Trigger<ReadbackComplete>| { info!("Buffer data from previous frame {:?}", trigger.event()); }); ``` --------- Co-authored-by: Kristoffer Søholm <k.soeholm@gmail.com> Co-authored-by: IceSentry <IceSentry@users.noreply.github.com>
221 lines
7.9 KiB
Rust
221 lines
7.9 KiB
Rust
//! Simple example demonstrating the use of the [`Readback`] component to read back data from the GPU
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//! using both a storage buffer and texture.
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use bevy::{
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prelude::*,
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render::{
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extract_resource::{ExtractResource, ExtractResourcePlugin},
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gpu_readback::{Readback, ReadbackComplete},
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render_asset::{RenderAssetUsages, RenderAssets},
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render_graph,
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render_graph::{RenderGraph, RenderLabel},
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render_resource::{
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binding_types::{storage_buffer, texture_storage_2d},
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*,
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},
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renderer::{RenderContext, RenderDevice},
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storage::{GpuShaderStorageBuffer, ShaderStorageBuffer},
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texture::GpuImage,
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Render, RenderApp, RenderSet,
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},
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};
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/// This example uses a shader source file from the assets subdirectory
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const SHADER_ASSET_PATH: &str = "shaders/gpu_readback.wgsl";
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// The length of the buffer sent to the gpu
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const BUFFER_LEN: usize = 16;
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fn main() {
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App::new()
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.add_plugins((
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DefaultPlugins,
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GpuReadbackPlugin,
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ExtractResourcePlugin::<ReadbackBuffer>::default(),
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ExtractResourcePlugin::<ReadbackImage>::default(),
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))
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.insert_resource(ClearColor(Color::BLACK))
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.add_systems(Startup, setup)
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.run();
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}
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// We need a plugin to organize all the systems and render node required for this example
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struct GpuReadbackPlugin;
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impl Plugin for GpuReadbackPlugin {
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fn build(&self, _app: &mut App) {}
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fn finish(&self, app: &mut App) {
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let render_app = app.sub_app_mut(RenderApp);
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render_app.init_resource::<ComputePipeline>().add_systems(
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Render,
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prepare_bind_group
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.in_set(RenderSet::PrepareBindGroups)
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// We don't need to recreate the bind group every frame
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.run_if(not(resource_exists::<GpuBufferBindGroup>)),
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);
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// Add the compute node as a top level node to the render graph
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// This means it will only execute once per frame
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render_app
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.world_mut()
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.resource_mut::<RenderGraph>()
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.add_node(ComputeNodeLabel, ComputeNode::default());
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}
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}
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#[derive(Resource, ExtractResource, Clone)]
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struct ReadbackBuffer(Handle<ShaderStorageBuffer>);
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#[derive(Resource, ExtractResource, Clone)]
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struct ReadbackImage(Handle<Image>);
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fn setup(
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mut commands: Commands,
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mut images: ResMut<Assets<Image>>,
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mut buffers: ResMut<Assets<ShaderStorageBuffer>>,
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) {
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// Create a storage buffer with some data
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let buffer = vec![0u32; BUFFER_LEN];
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let mut buffer = ShaderStorageBuffer::from(buffer);
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// We need to enable the COPY_SRC usage so we can copy the buffer to the cpu
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buffer.buffer_description.usage |= BufferUsages::COPY_SRC;
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let buffer = buffers.add(buffer);
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// Create a storage texture with some data
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let size = Extent3d {
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width: BUFFER_LEN as u32,
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height: 1,
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..default()
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};
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let mut image = Image::new_fill(
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size,
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TextureDimension::D2,
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&[0, 0, 0, 0],
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TextureFormat::R32Uint,
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RenderAssetUsages::RENDER_WORLD,
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);
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// We also need to enable the COPY_SRC, as well as STORAGE_BINDING so we can use it in the
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// compute shader
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image.texture_descriptor.usage |= TextureUsages::COPY_SRC | TextureUsages::STORAGE_BINDING;
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let image = images.add(image);
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// Spawn the readback components. For each frame, the data will be read back from the GPU
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// asynchronously and trigger the `ReadbackComplete` event on this entity. Despawn the entity
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// to stop reading back the data.
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commands.spawn(Readback::buffer(buffer.clone())).observe(
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|trigger: Trigger<ReadbackComplete>| {
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// This matches the type which was used to create the `ShaderStorageBuffer` above,
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// and is a convenient way to interpret the data.
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let data: Vec<u32> = trigger.event().to_shader_type();
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info!("Buffer {:?}", data);
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},
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);
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// This is just a simple way to pass the buffer handle to the render app for our compute node
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commands.insert_resource(ReadbackBuffer(buffer));
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// Textures can also be read back from the GPU. Pay careful attention to the format of the
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// texture, as it will affect how the data is interpreted.
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commands.spawn(Readback::texture(image.clone())).observe(
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|trigger: Trigger<ReadbackComplete>| {
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// You probably want to interpret the data as a color rather than a `ShaderType`,
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// but in this case we know the data is a single channel storage texture, so we can
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// interpret it as a `Vec<u32>`
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let data: Vec<u32> = trigger.event().to_shader_type();
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info!("Image {:?}", data);
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},
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);
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commands.insert_resource(ReadbackImage(image));
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}
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#[derive(Resource)]
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struct GpuBufferBindGroup(BindGroup);
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fn prepare_bind_group(
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mut commands: Commands,
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pipeline: Res<ComputePipeline>,
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render_device: Res<RenderDevice>,
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buffer: Res<ReadbackBuffer>,
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image: Res<ReadbackImage>,
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buffers: Res<RenderAssets<GpuShaderStorageBuffer>>,
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images: Res<RenderAssets<GpuImage>>,
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) {
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let buffer = buffers.get(&buffer.0).unwrap();
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let image = images.get(&image.0).unwrap();
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let bind_group = render_device.create_bind_group(
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None,
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&pipeline.layout,
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&BindGroupEntries::sequential((
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buffer.buffer.as_entire_buffer_binding(),
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image.texture_view.into_binding(),
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)),
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);
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commands.insert_resource(GpuBufferBindGroup(bind_group));
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}
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#[derive(Resource)]
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struct ComputePipeline {
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layout: BindGroupLayout,
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pipeline: CachedComputePipelineId,
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}
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impl FromWorld for ComputePipeline {
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fn from_world(world: &mut World) -> Self {
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let render_device = world.resource::<RenderDevice>();
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let layout = render_device.create_bind_group_layout(
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None,
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&BindGroupLayoutEntries::sequential(
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ShaderStages::COMPUTE,
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(
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storage_buffer::<Vec<u32>>(false),
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texture_storage_2d(TextureFormat::R32Uint, StorageTextureAccess::WriteOnly),
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),
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),
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);
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let shader = world.load_asset(SHADER_ASSET_PATH);
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let pipeline_cache = world.resource::<PipelineCache>();
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let pipeline = pipeline_cache.queue_compute_pipeline(ComputePipelineDescriptor {
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label: Some("GPU readback compute shader".into()),
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layout: vec![layout.clone()],
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push_constant_ranges: Vec::new(),
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shader: shader.clone(),
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shader_defs: Vec::new(),
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entry_point: "main".into(),
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});
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ComputePipeline { layout, pipeline }
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}
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}
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/// Label to identify the node in the render graph
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#[derive(Debug, Hash, PartialEq, Eq, Clone, RenderLabel)]
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struct ComputeNodeLabel;
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/// The node that will execute the compute shader
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#[derive(Default)]
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struct ComputeNode {}
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impl render_graph::Node for ComputeNode {
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fn run(
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&self,
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_graph: &mut render_graph::RenderGraphContext,
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render_context: &mut RenderContext,
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world: &World,
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) -> Result<(), render_graph::NodeRunError> {
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let pipeline_cache = world.resource::<PipelineCache>();
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let pipeline = world.resource::<ComputePipeline>();
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let bind_group = world.resource::<GpuBufferBindGroup>();
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if let Some(init_pipeline) = pipeline_cache.get_compute_pipeline(pipeline.pipeline) {
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let mut pass =
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render_context
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.command_encoder()
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.begin_compute_pass(&ComputePassDescriptor {
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label: Some("GPU readback compute pass"),
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..default()
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});
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pass.set_bind_group(0, &bind_group.0, &[]);
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pass.set_pipeline(init_pipeline);
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pass.dispatch_workgroups(BUFFER_LEN as u32, 1, 1);
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}
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Ok(())
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}
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}
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