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mod.rs
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mod.rs
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mod graph_runner;
mod render_device;
use bevy_derive::{Deref, DerefMut};
use bevy_utils::tracing::{error, info, info_span};
pub use graph_runner::*;
pub use render_device::*;
use crate::{
render_graph::RenderGraph,
settings::{WgpuSettings, WgpuSettingsPriority},
view::{ExtractedWindows, ViewTarget},
};
use bevy_ecs::prelude::*;
use bevy_time::TimeSender;
use bevy_utils::Instant;
use std::sync::Arc;
use wgpu::{Adapter, AdapterInfo, CommandEncoder, Instance, Queue, RequestAdapterOptions};
/// Updates the [`RenderGraph`] with all of its nodes and then runs it to render the entire frame.
pub fn render_system(world: &mut World) {
world.resource_scope(|world, mut graph: Mut<RenderGraph>| {
graph.update(world);
});
let graph = world.resource::<RenderGraph>();
let render_device = world.resource::<RenderDevice>();
let render_queue = world.resource::<RenderQueue>();
if let Err(e) = RenderGraphRunner::run(
graph,
render_device.clone(), // TODO: is this clone really necessary?
&render_queue.0,
world,
) {
error!("Error running render graph:");
{
let mut src: &dyn std::error::Error = &e;
loop {
error!("> {}", src);
match src.source() {
Some(s) => src = s,
None => break,
}
}
}
panic!("Error running render graph: {e}");
}
{
let _span = info_span!("present_frames").entered();
// Remove ViewTarget components to ensure swap chain TextureViews are dropped.
// If all TextureViews aren't dropped before present, acquiring the next swap chain texture will fail.
let view_entities = world
.query_filtered::<Entity, With<ViewTarget>>()
.iter(world)
.collect::<Vec<_>>();
for view_entity in view_entities {
world.entity_mut(view_entity).remove::<ViewTarget>();
}
let mut windows = world.resource_mut::<ExtractedWindows>();
for window in windows.values_mut() {
if let Some(texture_view) = window.swap_chain_texture.take() {
if let Some(surface_texture) = texture_view.take_surface_texture() {
surface_texture.present();
}
}
}
#[cfg(feature = "tracing-tracy")]
bevy_utils::tracing::event!(
bevy_utils::tracing::Level::INFO,
message = "finished frame",
tracy.frame_mark = true
);
}
// update the time and send it to the app world
let time_sender = world.resource::<TimeSender>();
time_sender.0.try_send(Instant::now()).expect(
"The TimeSender channel should always be empty during render. You might need to add the bevy::core::time_system to your app.",
);
}
/// This queue is used to enqueue tasks for the GPU to execute asynchronously.
#[derive(Resource, Clone, Deref, DerefMut)]
pub struct RenderQueue(pub Arc<Queue>);
/// The handle to the physical device being used for rendering.
/// See [`wgpu::Adapter`] for more info.
#[derive(Resource, Clone, Debug, Deref, DerefMut)]
pub struct RenderAdapter(pub Arc<Adapter>);
/// The GPU instance is used to initialize the [`RenderQueue`] and [`RenderDevice`],
/// as well as to create [`WindowSurfaces`](crate::view::window::WindowSurfaces).
#[derive(Resource, Deref, DerefMut)]
pub struct RenderInstance(pub Instance);
/// The `AdapterInfo` of the adapter in use by the renderer.
#[derive(Resource, Clone, Deref, DerefMut)]
pub struct RenderAdapterInfo(pub AdapterInfo);
const GPU_NOT_FOUND_ERROR_MESSAGE: &str = if cfg!(target_os = "linux") {
"Unable to find a GPU! Make sure you have installed required drivers! For extra information, see: https://github.com/bevyengine/bevy/blob/latest/docs/linux_dependencies.md"
} else {
"Unable to find a GPU! Make sure you have installed required drivers!"
};
/// Initializes the renderer by retrieving and preparing the GPU instance, device and queue
/// for the specified backend.
pub async fn initialize_renderer(
instance: &Instance,
options: &WgpuSettings,
request_adapter_options: &RequestAdapterOptions<'_>,
) -> (RenderDevice, RenderQueue, RenderAdapterInfo, RenderAdapter) {
let adapter = instance
.request_adapter(request_adapter_options)
.await
.expect(GPU_NOT_FOUND_ERROR_MESSAGE);
let adapter_info = adapter.get_info();
info!("{:?}", adapter_info);
#[cfg(feature = "wgpu_trace")]
let trace_path = {
let path = std::path::Path::new("wgpu_trace");
// ignore potential error, wgpu will log it
let _ = std::fs::create_dir(path);
Some(path)
};
#[cfg(not(feature = "wgpu_trace"))]
let trace_path = None;
// Maybe get features and limits based on what is supported by the adapter/backend
let mut features = wgpu::Features::empty();
let mut limits = options.limits.clone();
if matches!(options.priority, WgpuSettingsPriority::Functionality) {
features = adapter.features() | wgpu::Features::TEXTURE_ADAPTER_SPECIFIC_FORMAT_FEATURES;
if adapter_info.device_type == wgpu::DeviceType::DiscreteGpu {
// `MAPPABLE_PRIMARY_BUFFERS` can have a significant, negative performance impact for
// discrete GPUs due to having to transfer data across the PCI-E bus and so it
// should not be automatically enabled in this case. It is however beneficial for
// integrated GPUs.
features -= wgpu::Features::MAPPABLE_PRIMARY_BUFFERS;
}
limits = adapter.limits();
}
// Enforce the disabled features
if let Some(disabled_features) = options.disabled_features {
features -= disabled_features;
}
// NOTE: |= is used here to ensure that any explicitly-enabled features are respected.
features |= options.features;
// Enforce the limit constraints
if let Some(constrained_limits) = options.constrained_limits.as_ref() {
// NOTE: Respect the configured limits as an 'upper bound'. This means for 'max' limits, we
// take the minimum of the calculated limits according to the adapter/backend and the
// specified max_limits. For 'min' limits, take the maximum instead. This is intended to
// err on the side of being conservative. We can't claim 'higher' limits that are supported
// but we can constrain to 'lower' limits.
limits = wgpu::Limits {
max_texture_dimension_1d: limits
.max_texture_dimension_1d
.min(constrained_limits.max_texture_dimension_1d),
max_texture_dimension_2d: limits
.max_texture_dimension_2d
.min(constrained_limits.max_texture_dimension_2d),
max_texture_dimension_3d: limits
.max_texture_dimension_3d
.min(constrained_limits.max_texture_dimension_3d),
max_texture_array_layers: limits
.max_texture_array_layers
.min(constrained_limits.max_texture_array_layers),
max_bind_groups: limits
.max_bind_groups
.min(constrained_limits.max_bind_groups),
max_dynamic_uniform_buffers_per_pipeline_layout: limits
.max_dynamic_uniform_buffers_per_pipeline_layout
.min(constrained_limits.max_dynamic_uniform_buffers_per_pipeline_layout),
max_dynamic_storage_buffers_per_pipeline_layout: limits
.max_dynamic_storage_buffers_per_pipeline_layout
.min(constrained_limits.max_dynamic_storage_buffers_per_pipeline_layout),
max_sampled_textures_per_shader_stage: limits
.max_sampled_textures_per_shader_stage
.min(constrained_limits.max_sampled_textures_per_shader_stage),
max_samplers_per_shader_stage: limits
.max_samplers_per_shader_stage
.min(constrained_limits.max_samplers_per_shader_stage),
max_storage_buffers_per_shader_stage: limits
.max_storage_buffers_per_shader_stage
.min(constrained_limits.max_storage_buffers_per_shader_stage),
max_storage_textures_per_shader_stage: limits
.max_storage_textures_per_shader_stage
.min(constrained_limits.max_storage_textures_per_shader_stage),
max_uniform_buffers_per_shader_stage: limits
.max_uniform_buffers_per_shader_stage
.min(constrained_limits.max_uniform_buffers_per_shader_stage),
max_uniform_buffer_binding_size: limits
.max_uniform_buffer_binding_size
.min(constrained_limits.max_uniform_buffer_binding_size),
max_storage_buffer_binding_size: limits
.max_storage_buffer_binding_size
.min(constrained_limits.max_storage_buffer_binding_size),
max_vertex_buffers: limits
.max_vertex_buffers
.min(constrained_limits.max_vertex_buffers),
max_vertex_attributes: limits
.max_vertex_attributes
.min(constrained_limits.max_vertex_attributes),
max_vertex_buffer_array_stride: limits
.max_vertex_buffer_array_stride
.min(constrained_limits.max_vertex_buffer_array_stride),
max_push_constant_size: limits
.max_push_constant_size
.min(constrained_limits.max_push_constant_size),
min_uniform_buffer_offset_alignment: limits
.min_uniform_buffer_offset_alignment
.max(constrained_limits.min_uniform_buffer_offset_alignment),
min_storage_buffer_offset_alignment: limits
.min_storage_buffer_offset_alignment
.max(constrained_limits.min_storage_buffer_offset_alignment),
max_inter_stage_shader_components: limits
.max_inter_stage_shader_components
.min(constrained_limits.max_inter_stage_shader_components),
max_compute_workgroup_storage_size: limits
.max_compute_workgroup_storage_size
.min(constrained_limits.max_compute_workgroup_storage_size),
max_compute_invocations_per_workgroup: limits
.max_compute_invocations_per_workgroup
.min(constrained_limits.max_compute_invocations_per_workgroup),
max_compute_workgroup_size_x: limits
.max_compute_workgroup_size_x
.min(constrained_limits.max_compute_workgroup_size_x),
max_compute_workgroup_size_y: limits
.max_compute_workgroup_size_y
.min(constrained_limits.max_compute_workgroup_size_y),
max_compute_workgroup_size_z: limits
.max_compute_workgroup_size_z
.min(constrained_limits.max_compute_workgroup_size_z),
max_compute_workgroups_per_dimension: limits
.max_compute_workgroups_per_dimension
.min(constrained_limits.max_compute_workgroups_per_dimension),
max_buffer_size: limits
.max_buffer_size
.min(constrained_limits.max_buffer_size),
};
}
let (device, queue) = adapter
.request_device(
&wgpu::DeviceDescriptor {
label: options.device_label.as_ref().map(|a| a.as_ref()),
features,
limits,
},
trace_path,
)
.await
.unwrap();
let queue = Arc::new(queue);
let adapter = Arc::new(adapter);
(
RenderDevice::from(device),
RenderQueue(queue),
RenderAdapterInfo(adapter_info),
RenderAdapter(adapter),
)
}
/// The context with all information required to interact with the GPU.
///
/// The [`RenderDevice`] is used to create render resources and the
/// the [`CommandEncoder`] is used to record a series of GPU operations.
pub struct RenderContext {
pub render_device: RenderDevice,
pub command_encoder: CommandEncoder,
}