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bevy_pbr2: Add support for not casting/receiving shadows (#2726)
# Objective Allow marking meshes as not casting / receiving shadows. ## Solution - Added `NotShadowCaster` and `NotShadowReceiver` zero-sized type components. - Extract these components into `bool`s in `ExtractedMesh` - Only generate `DrawShadowMesh` `Drawable`s for meshes _without_ `NotShadowCaster` - Add a `u32` bit `flags` member to `MeshUniform` with one flag indicating whether the mesh is a shadow receiver - If a mesh does _not_ have the `NotShadowReceiver` component, then it is a shadow receiver, and so the bit in the `MeshUniform` is set, otherwise it is not set. - Added an example illustrating the functionality. NOTE: I wanted to have the default state of a mesh as being a shadow caster and shadow receiver, hence the `Not*` components. However, I am on the fence about this. I don't want to have a negative performance impact, nor have people wondering why their custom meshes don't have shadows because they forgot to add `ShadowCaster` and `ShadowReceiver` components, but I also really don't like the double negatives the `Not*` approach incurs. What do you think? Co-authored-by: Carter Anderson <mcanders1@gmail.com>
This commit is contained in:
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6 changed files with 286 additions and 35 deletions
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@ -199,6 +199,10 @@ path = "examples/3d/render_to_texture.rs"
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name = "shadow_biases_pipelined"
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path = "examples/3d/shadow_biases_pipelined.rs"
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[[example]]
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name = "shadow_caster_receiver_pipelined"
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path = "examples/3d/shadow_caster_receiver_pipelined.rs"
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[[example]]
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name = "spawner"
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path = "examples/3d/spawner.rs"
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182
examples/3d/shadow_caster_receiver_pipelined.rs
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182
examples/3d/shadow_caster_receiver_pipelined.rs
Normal file
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@ -0,0 +1,182 @@
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use bevy::{
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ecs::prelude::*,
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input::Input,
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math::{EulerRot, Mat4, Vec3},
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pbr2::{
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DirectionalLight, DirectionalLightBundle, NotShadowCaster, NotShadowReceiver, PbrBundle,
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PointLight, PointLightBundle, StandardMaterial,
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},
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prelude::{App, Assets, Handle, KeyCode, Transform},
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render2::{
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camera::{OrthographicProjection, PerspectiveCameraBundle},
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color::Color,
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mesh::{shape, Mesh},
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},
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PipelinedDefaultPlugins,
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};
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fn main() {
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println!(
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"Controls:
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C - toggle shadow casters (i.e. casters become not, and not casters become casters)
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R - toggle shadow receivers (i.e. receivers become not, and not receivers become receivers)
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L - switch between directional and point lights"
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);
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App::new()
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.add_plugins(PipelinedDefaultPlugins)
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.add_startup_system(setup)
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.add_system(toggle_light)
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.add_system(toggle_shadows)
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.run();
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}
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/// set up a 3D scene to test shadow biases and perspective projections
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fn setup(
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mut commands: Commands,
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mut meshes: ResMut<Assets<Mesh>>,
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mut materials: ResMut<Assets<StandardMaterial>>,
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) {
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let spawn_plane_depth = 500.0f32;
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let spawn_height = 2.0;
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let sphere_radius = 0.25;
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let white_handle = materials.add(StandardMaterial {
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base_color: Color::WHITE,
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perceptual_roughness: 1.0,
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..Default::default()
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});
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let sphere_handle = meshes.add(Mesh::from(shape::Icosphere {
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radius: sphere_radius,
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..Default::default()
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}));
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// sphere - initially a caster
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commands.spawn_bundle(PbrBundle {
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mesh: sphere_handle.clone(),
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material: materials.add(Color::RED.into()),
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transform: Transform::from_xyz(-1.0, spawn_height, 0.0),
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..Default::default()
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});
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// sphere - initially not a caster
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commands
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.spawn_bundle(PbrBundle {
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mesh: sphere_handle,
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material: materials.add(Color::BLUE.into()),
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transform: Transform::from_xyz(1.0, spawn_height, 0.0),
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..Default::default()
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})
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.insert(NotShadowCaster);
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// floating plane - initially not a shadow receiver and not a caster
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commands
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.spawn_bundle(PbrBundle {
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mesh: meshes.add(Mesh::from(shape::Plane { size: 20.0 })),
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material: materials.add(Color::GREEN.into()),
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transform: Transform::from_xyz(0.0, 1.0, -10.0),
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..Default::default()
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})
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.insert_bundle((NotShadowCaster, NotShadowReceiver));
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// lower ground plane - initially a shadow receiver
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commands.spawn_bundle(PbrBundle {
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mesh: meshes.add(Mesh::from(shape::Plane { size: 20.0 })),
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material: white_handle,
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..Default::default()
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});
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println!("Using DirectionalLight");
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commands.spawn_bundle(PointLightBundle {
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transform: Transform::from_xyz(5.0, 5.0, 0.0),
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point_light: PointLight {
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intensity: 0.0,
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range: spawn_plane_depth,
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color: Color::WHITE,
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..Default::default()
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},
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..Default::default()
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});
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let theta = std::f32::consts::FRAC_PI_4;
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let light_transform = Mat4::from_euler(EulerRot::ZYX, 0.0, std::f32::consts::FRAC_PI_2, -theta);
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commands.spawn_bundle(DirectionalLightBundle {
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directional_light: DirectionalLight {
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illuminance: 100000.0,
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shadow_projection: OrthographicProjection {
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left: -10.0,
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right: 10.0,
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bottom: -10.0,
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top: 10.0,
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near: -50.0,
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far: 50.0,
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..Default::default()
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},
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..Default::default()
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},
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transform: Transform::from_matrix(light_transform),
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..Default::default()
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});
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// camera
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commands.spawn_bundle(PerspectiveCameraBundle {
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transform: Transform::from_xyz(-5.0, 5.0, 5.0)
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.looking_at(Vec3::new(-1.0, 1.0, 0.0), Vec3::Y),
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..Default::default()
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});
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}
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fn toggle_light(
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input: Res<Input<KeyCode>>,
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mut point_lights: Query<&mut PointLight>,
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mut directional_lights: Query<&mut DirectionalLight>,
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) {
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if input.just_pressed(KeyCode::L) {
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for mut light in point_lights.iter_mut() {
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light.intensity = if light.intensity == 0.0 {
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println!("Using PointLight");
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100000000.0
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} else {
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0.0
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};
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}
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for mut light in directional_lights.iter_mut() {
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light.illuminance = if light.illuminance == 0.0 {
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println!("Using DirectionalLight");
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100000.0
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} else {
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0.0
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};
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}
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}
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}
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fn toggle_shadows(
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mut commands: Commands,
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input: Res<Input<KeyCode>>,
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queries: QuerySet<(
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Query<Entity, (With<Handle<Mesh>>, With<NotShadowCaster>)>,
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Query<Entity, (With<Handle<Mesh>>, With<NotShadowReceiver>)>,
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Query<Entity, (With<Handle<Mesh>>, Without<NotShadowCaster>)>,
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Query<Entity, (With<Handle<Mesh>>, Without<NotShadowReceiver>)>,
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)>,
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) {
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if input.just_pressed(KeyCode::C) {
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println!("Toggling casters");
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for entity in queries.q0().iter() {
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commands.entity(entity).remove::<NotShadowCaster>();
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}
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for entity in queries.q2().iter() {
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commands.entity(entity).insert(NotShadowCaster);
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}
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}
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if input.just_pressed(KeyCode::R) {
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println!("Toggling receivers");
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for entity in queries.q1().iter() {
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commands.entity(entity).remove::<NotShadowReceiver>();
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}
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for entity in queries.q3().iter() {
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commands.entity(entity).insert(NotShadowReceiver);
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}
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}
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}
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@ -107,6 +107,7 @@ Example | File | Description
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`pbr` | [`3d/pbr.rs`](./3d/pbr.rs) | Demonstrates use of Physically Based Rendering (PBR) properties
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`pbr_pipelined` | [`3d/pbr_pipelined.rs`](./3d/pbr_pipelined.rs) | Demonstrates use of Physically Based Rendering (PBR) properties
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`render_to_texture` | [`3d/render_to_texture.rs`](./3d/render_to_texture.rs) | Shows how to render to texture
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`shadow_caster_receiver_pipelined` | [`3d/shadow_caster_receiver_pipelined.rs`](./3d/shadow_caster_receiver_pipelined.rs) | Demonstrates how to prevent meshes from casting/receiving shadows in a 3d scene
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`shadow_biases_pipelined` | [`3d/shadow_biases_pipelined.rs`](./3d/shadow_biases_pipelined.rs) | Demonstrates how shadow biases affect shadows in a 3d scene
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`spawner` | [`3d/spawner.rs`](./3d/spawner.rs) | Renders a large number of cubes with changing position and material
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`texture` | [`3d/texture.rs`](./3d/texture.rs) | Shows configuration of texture materials
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@ -151,3 +151,8 @@ impl Default for AmbientLight {
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}
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}
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}
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/// Add this component to make a `Mesh` not cast shadows
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pub struct NotShadowCaster;
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/// Add this component to make a `Mesh` not receive shadows
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pub struct NotShadowReceiver;
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@ -1,7 +1,7 @@
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mod light;
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pub use light::*;
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use crate::{StandardMaterial, StandardMaterialUniformData};
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use crate::{NotShadowCaster, NotShadowReceiver, StandardMaterial, StandardMaterialUniformData};
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use bevy_asset::{Assets, Handle};
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use bevy_core_pipeline::Transparent3dPhase;
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use bevy_ecs::{prelude::*, system::SystemState};
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@ -120,11 +120,11 @@ impl FromWorld for PbrShaders {
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let mesh_layout = render_device.create_bind_group_layout(&BindGroupLayoutDescriptor {
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entries: &[BindGroupLayoutEntry {
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binding: 0,
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visibility: ShaderStage::VERTEX,
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visibility: ShaderStage::VERTEX | ShaderStage::FRAGMENT,
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ty: BindingType::Buffer {
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ty: BufferBindingType::Uniform,
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has_dynamic_offset: true,
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min_binding_size: BufferSize::new(Mat4::std140_size_static() as u64),
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min_binding_size: BufferSize::new(80),
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},
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count: None,
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}],
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@ -374,6 +374,8 @@ struct ExtractedMesh {
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mesh: Handle<Mesh>,
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transform_binding_offset: u32,
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material_handle: Handle<StandardMaterial>,
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casts_shadows: bool,
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receives_shadows: bool,
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}
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pub struct ExtractedMeshes {
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@ -385,10 +387,23 @@ pub fn extract_meshes(
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meshes: Res<Assets<Mesh>>,
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materials: Res<Assets<StandardMaterial>>,
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images: Res<Assets<Image>>,
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query: Query<(&GlobalTransform, &Handle<Mesh>, &Handle<StandardMaterial>)>,
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query: Query<(
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&GlobalTransform,
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&Handle<Mesh>,
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&Handle<StandardMaterial>,
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Option<&NotShadowCaster>,
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Option<&NotShadowReceiver>,
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)>,
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) {
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let mut extracted_meshes = Vec::new();
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for (transform, mesh_handle, material_handle) in query.iter() {
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for (
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transform,
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mesh_handle,
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material_handle,
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maybe_not_shadow_caster,
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maybe_not_shadow_receiver,
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) in query.iter()
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{
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if !meshes.contains(mesh_handle) {
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continue;
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}
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@ -419,6 +434,10 @@ pub fn extract_meshes(
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mesh: mesh_handle.clone_weak(),
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transform_binding_offset: 0,
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material_handle: material_handle.clone_weak(),
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// NOTE: Double-negative is so that meshes cast and receive shadows by default
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// Not not shadow caster means that this mesh is a shadow caster
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casts_shadows: maybe_not_shadow_caster.is_none(),
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receives_shadows: maybe_not_shadow_receiver.is_none(),
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});
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} else {
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continue;
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@ -435,9 +454,25 @@ struct MeshDrawInfo {
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material_bind_group_key: FrameSlabMapKey<BufferId, BindGroup>,
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}
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#[derive(Debug, AsStd140)]
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pub struct MeshUniform {
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model: Mat4,
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flags: u32,
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}
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// NOTE: These must match the bit flags in bevy_pbr2/src/render/pbr.wgsl!
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bitflags::bitflags! {
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#[repr(transparent)]
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struct MeshFlags: u32 {
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const SHADOW_RECEIVER = (1 << 0);
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const NONE = 0;
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const UNINITIALIZED = 0xFFFF;
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}
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}
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#[derive(Default)]
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pub struct MeshMeta {
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transform_uniforms: DynamicUniformVec<Mat4>,
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transform_uniforms: DynamicUniformVec<MeshUniform>,
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material_bind_groups: FrameSlabMap<BufferId, BindGroup>,
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mesh_transform_bind_group: FrameSlabMap<BufferId, BindGroup>,
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mesh_transform_bind_group_key: Option<FrameSlabMapKey<BufferId, BindGroup>>,
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@ -453,8 +488,15 @@ pub fn prepare_meshes(
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.transform_uniforms
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.reserve_and_clear(extracted_meshes.meshes.len(), &render_device);
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for extracted_mesh in extracted_meshes.meshes.iter_mut() {
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extracted_mesh.transform_binding_offset =
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mesh_meta.transform_uniforms.push(extracted_mesh.transform);
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let flags = if extracted_mesh.receives_shadows {
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MeshFlags::SHADOW_RECEIVER
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} else {
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MeshFlags::NONE
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};
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extracted_mesh.transform_binding_offset = mesh_meta.transform_uniforms.push(MeshUniform {
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model: extracted_mesh.transform,
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flags: flags.bits,
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});
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}
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mesh_meta
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@ -694,12 +736,14 @@ pub fn queue_meshes(
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for view_light_entity in view_lights.lights.iter().copied() {
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let mut shadow_phase = view_light_shadow_phases.get_mut(view_light_entity).unwrap();
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// TODO: this should only queue up meshes that are actually visible by each "light view"
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for i in 0..extracted_meshes.meshes.len() {
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shadow_phase.add(Drawable {
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draw_function: draw_shadow_mesh,
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draw_key: i,
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sort_key: 0, // TODO: sort back-to-front
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})
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for (i, mesh) in extracted_meshes.meshes.iter().enumerate() {
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if mesh.casts_shadows {
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shadow_phase.add(Drawable {
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draw_function: draw_shadow_mesh,
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draw_key: i,
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sort_key: 0, // TODO: sort back-to-front
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});
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}
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}
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}
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}
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@ -4,14 +4,19 @@ struct View {
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view_proj: mat4x4<f32>;
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world_position: vec3<f32>;
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};
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[[group(0), binding(0)]]
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var view: View;
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[[block]]
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struct Mesh {
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transform: mat4x4<f32>;
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model: mat4x4<f32>;
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// 'flags' is a bit field indicating various options. u32 is 32 bits so we have up to 32 options.
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flags: u32;
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};
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let MESH_FLAGS_SHADOW_RECEIVER_BIT: u32 = 1u;
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[[group(0), binding(0)]]
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var view: View;
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[[group(1), binding(0)]]
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var mesh: Mesh;
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@ -30,7 +35,7 @@ struct VertexOutput {
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[[stage(vertex)]]
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fn vertex(vertex: Vertex) -> VertexOutput {
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let world_position = mesh.transform * vec4<f32>(vertex.position, 1.0);
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let world_position = mesh.model * vec4<f32>(vertex.position, 1.0);
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var out: VertexOutput;
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out.uv = vertex.uv;
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@ -38,7 +43,7 @@ fn vertex(vertex: Vertex) -> VertexOutput {
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out.clip_position = view.view_proj * world_position;
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// FIXME: The inverse transpose of the model matrix should be used to correctly handle scaling
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// of normals
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out.world_normal = mat3x3<f32>(mesh.transform.x.xyz, mesh.transform.y.xyz, mesh.transform.z.xyz) * vertex.normal;
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out.world_normal = mat3x3<f32>(mesh.model.x.xyz, mesh.model.y.xyz, mesh.model.z.xyz) * vertex.normal;
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return out;
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}
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@ -83,10 +88,17 @@ struct StandardMaterial {
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perceptual_roughness: f32;
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metallic: f32;
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reflectance: f32;
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// 'flags' is a bit field indicating various option. uint is 32 bits so we have up to 32 options.
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// 'flags' is a bit field indicating various options. u32 is 32 bits so we have up to 32 options.
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flags: u32;
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};
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let STANDARD_MATERIAL_FLAGS_BASE_COLOR_TEXTURE_BIT: u32 = 1u;
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let STANDARD_MATERIAL_FLAGS_EMISSIVE_TEXTURE_BIT: u32 = 2u;
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let STANDARD_MATERIAL_FLAGS_METALLIC_ROUGHNESS_TEXTURE_BIT: u32 = 4u;
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let STANDARD_MATERIAL_FLAGS_OCCLUSION_TEXTURE_BIT: u32 = 8u;
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let STANDARD_MATERIAL_FLAGS_DOUBLE_SIDED_BIT: u32 = 16u;
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let STANDARD_MATERIAL_FLAGS_UNLIT_BIT: u32 = 32u;
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struct PointLight {
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color: vec4<f32>;
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// projection: mat4x4<f32>;
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@ -118,13 +130,6 @@ struct Lights {
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n_directional_lights: u32;
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};
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let FLAGS_BASE_COLOR_TEXTURE_BIT: u32 = 1u;
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let FLAGS_EMISSIVE_TEXTURE_BIT: u32 = 2u;
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let FLAGS_METALLIC_ROUGHNESS_TEXTURE_BIT: u32 = 4u;
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let FLAGS_OCCLUSION_TEXTURE_BIT: u32 = 8u;
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let FLAGS_DOUBLE_SIDED_BIT: u32 = 16u;
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let FLAGS_UNLIT_BIT: u32 = 32u;
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|
||||
[[group(0), binding(1)]]
|
||||
var lights: Lights;
|
||||
|
@ -463,22 +468,22 @@ struct FragmentInput {
|
|||
[[stage(fragment)]]
|
||||
fn fragment(in: FragmentInput) -> [[location(0)]] vec4<f32> {
|
||||
var output_color: vec4<f32> = material.base_color;
|
||||
if ((material.flags & FLAGS_BASE_COLOR_TEXTURE_BIT) != 0u) {
|
||||
if ((material.flags & STANDARD_MATERIAL_FLAGS_BASE_COLOR_TEXTURE_BIT) != 0u) {
|
||||
output_color = output_color * textureSample(base_color_texture, base_color_sampler, in.uv);
|
||||
}
|
||||
|
||||
// // NOTE: Unlit bit not set means == 0 is true, so the true case is if lit
|
||||
if ((material.flags & FLAGS_UNLIT_BIT) == 0u) {
|
||||
if ((material.flags & STANDARD_MATERIAL_FLAGS_UNLIT_BIT) == 0u) {
|
||||
// TODO use .a for exposure compensation in HDR
|
||||
var emissive: vec4<f32> = material.emissive;
|
||||
if ((material.flags & FLAGS_EMISSIVE_TEXTURE_BIT) != 0u) {
|
||||
if ((material.flags & STANDARD_MATERIAL_FLAGS_EMISSIVE_TEXTURE_BIT) != 0u) {
|
||||
emissive = vec4<f32>(emissive.rgb * textureSample(emissive_texture, emissive_sampler, in.uv).rgb, 1.0);
|
||||
}
|
||||
|
||||
// calculate non-linear roughness from linear perceptualRoughness
|
||||
var metallic: f32 = material.metallic;
|
||||
var perceptual_roughness: f32 = material.perceptual_roughness;
|
||||
if ((material.flags & FLAGS_METALLIC_ROUGHNESS_TEXTURE_BIT) != 0u) {
|
||||
if ((material.flags & STANDARD_MATERIAL_FLAGS_METALLIC_ROUGHNESS_TEXTURE_BIT) != 0u) {
|
||||
let metallic_roughness = textureSample(metallic_roughness_texture, metallic_roughness_sampler, in.uv);
|
||||
// Sampling from GLTF standard channels for now
|
||||
metallic = metallic * metallic_roughness.b;
|
||||
|
@ -487,7 +492,7 @@ fn fragment(in: FragmentInput) -> [[location(0)]] vec4<f32> {
|
|||
let roughness = perceptualRoughnessToRoughness(perceptual_roughness);
|
||||
|
||||
var occlusion: f32 = 1.0;
|
||||
if ((material.flags & FLAGS_OCCLUSION_TEXTURE_BIT) != 0u) {
|
||||
if ((material.flags & STANDARD_MATERIAL_FLAGS_OCCLUSION_TEXTURE_BIT) != 0u) {
|
||||
occlusion = textureSample(occlusion_texture, occlusion_sampler, in.uv).r;
|
||||
}
|
||||
|
||||
|
@ -500,7 +505,7 @@ fn fragment(in: FragmentInput) -> [[location(0)]] vec4<f32> {
|
|||
// vec3 B = cross(N, T) * v_WorldTangent.w;
|
||||
// # endif
|
||||
|
||||
if ((material.flags & FLAGS_DOUBLE_SIDED_BIT) != 0u) {
|
||||
if ((material.flags & STANDARD_MATERIAL_FLAGS_DOUBLE_SIDED_BIT) != 0u) {
|
||||
if (!in.is_front) {
|
||||
N = -N;
|
||||
}
|
||||
|
@ -543,13 +548,23 @@ fn fragment(in: FragmentInput) -> [[location(0)]] vec4<f32> {
|
|||
let n_directional_lights = i32(lights.n_directional_lights);
|
||||
for (var i: i32 = 0; i < n_point_lights; i = i + 1) {
|
||||
let light = lights.point_lights[i];
|
||||
let shadow = fetch_point_shadow(i, in.world_position, in.world_normal);
|
||||
var shadow: f32;
|
||||
if ((mesh.flags & MESH_FLAGS_SHADOW_RECEIVER_BIT) != 0u) {
|
||||
shadow = fetch_point_shadow(i, in.world_position, in.world_normal);
|
||||
} else {
|
||||
shadow = 1.0;
|
||||
}
|
||||
let light_contrib = point_light(in.world_position.xyz, light, roughness, NdotV, N, V, R, F0, diffuse_color);
|
||||
light_accum = light_accum + light_contrib * shadow;
|
||||
}
|
||||
for (var i: i32 = 0; i < n_directional_lights; i = i + 1) {
|
||||
let light = lights.directional_lights[i];
|
||||
let shadow = fetch_directional_shadow(i, in.world_position, in.world_normal);
|
||||
var shadow: f32;
|
||||
if ((mesh.flags & MESH_FLAGS_SHADOW_RECEIVER_BIT) != 0u) {
|
||||
shadow = fetch_directional_shadow(i, in.world_position, in.world_normal);
|
||||
} else {
|
||||
shadow = 1.0;
|
||||
}
|
||||
let light_contrib = directional_light(light, roughness, NdotV, N, V, R, F0, diffuse_color);
|
||||
light_accum = light_accum + light_contrib * shadow;
|
||||
}
|
||||
|
|
Loading…
Reference in a new issue