use crate::{ AmbientLight, Clusters, CubemapVisibleEntities, DirectionalLight, DirectionalLightShadowMap, DrawMesh, MeshPipeline, NotShadowCaster, PointLight, PointLightShadowMap, SetMeshBindGroup, VisiblePointLights, SHADOW_SHADER_HANDLE, }; use bevy_asset::Handle; use bevy_core::FloatOrd; use bevy_core_pipeline::Transparent3d; use bevy_ecs::{ prelude::*, system::{lifetimeless::*, SystemParamItem}, }; use bevy_math::{const_vec3, Mat4, UVec3, UVec4, Vec2, Vec3, Vec4, Vec4Swizzles}; use bevy_render::{ camera::{Camera, CameraProjection}, color::Color, mesh::Mesh, render_asset::RenderAssets, render_graph::{Node, NodeRunError, RenderGraphContext, SlotInfo, SlotType}, render_phase::{ CachedPipelinePhaseItem, DrawFunctionId, DrawFunctions, EntityPhaseItem, EntityRenderCommand, PhaseItem, RenderCommandResult, RenderPhase, SetItemPipeline, TrackedRenderPass, }, render_resource::{std140::AsStd140, *}, renderer::{RenderContext, RenderDevice, RenderQueue}, texture::*, view::{ExtractedView, ViewUniform, ViewUniformOffset, ViewUniforms, VisibleEntities}, }; use bevy_transform::components::GlobalTransform; use bevy_utils::{tracing::warn, HashMap}; use std::num::NonZeroU32; #[derive(Debug, Hash, PartialEq, Eq, Clone, SystemLabel)] pub enum RenderLightSystems { ExtractClusters, ExtractLights, PrepareClusters, PrepareLights, QueueShadows, } pub struct ExtractedAmbientLight { color: Color, brightness: f32, } #[derive(Component)] pub struct ExtractedPointLight { color: Color, /// luminous intensity in lumens per steradian intensity: f32, range: f32, radius: f32, transform: GlobalTransform, shadows_enabled: bool, shadow_depth_bias: f32, shadow_normal_bias: f32, } pub type ExtractedPointLightShadowMap = PointLightShadowMap; #[derive(Component)] pub struct ExtractedDirectionalLight { color: Color, illuminance: f32, direction: Vec3, projection: Mat4, shadows_enabled: bool, shadow_depth_bias: f32, shadow_normal_bias: f32, near: f32, far: f32, } pub type ExtractedDirectionalLightShadowMap = DirectionalLightShadowMap; #[repr(C)] #[derive(Copy, Clone, AsStd140, Default, Debug)] pub struct GpuPointLight { // The lower-right 2x2 values of the projection matrix 22 23 32 33 projection_lr: Vec4, color_inverse_square_range: Vec4, position_radius: Vec4, flags: u32, shadow_depth_bias: f32, shadow_normal_bias: f32, } #[derive(AsStd140)] pub struct GpuPointLights { data: [GpuPointLight; MAX_POINT_LIGHTS], } // NOTE: These must match the bit flags in bevy_pbr2/src/render/pbr.frag! bitflags::bitflags! { #[repr(transparent)] struct PointLightFlags: u32 { const SHADOWS_ENABLED = (1 << 0); const NONE = 0; const UNINITIALIZED = 0xFFFF; } } #[repr(C)] #[derive(Copy, Clone, AsStd140, Default, Debug)] pub struct GpuDirectionalLight { view_projection: Mat4, color: Vec4, dir_to_light: Vec3, flags: u32, shadow_depth_bias: f32, shadow_normal_bias: f32, } // NOTE: These must match the bit flags in bevy_pbr2/src/render/pbr.frag! bitflags::bitflags! { #[repr(transparent)] struct DirectionalLightFlags: u32 { const SHADOWS_ENABLED = (1 << 0); const NONE = 0; const UNINITIALIZED = 0xFFFF; } } #[repr(C)] #[derive(Copy, Clone, Debug, AsStd140)] pub struct GpuLights { // TODO: this comes first to work around a WGSL alignment issue. We need to solve this issue before releasing the renderer rework directional_lights: [GpuDirectionalLight; MAX_DIRECTIONAL_LIGHTS], ambient_color: Vec4, // xyz are x/y/z cluster dimensions and w is the number of clusters cluster_dimensions: UVec4, // xy are vec2(cluster_dimensions.xy) / vec2(view.width, view.height) // z is cluster_dimensions.z / log(far / near) // w is cluster_dimensions.z * log(near) / log(far / near) cluster_factors: Vec4, n_directional_lights: u32, } // NOTE: this must be kept in sync with the same constants in pbr.frag pub const MAX_POINT_LIGHTS: usize = 256; // FIXME: How should we handle shadows for clustered forward? Limiting to maximum 10 // point light shadow maps for now #[cfg(feature = "webgl")] pub const MAX_POINT_LIGHT_SHADOW_MAPS: usize = 1; #[cfg(not(feature = "webgl"))] pub const MAX_POINT_LIGHT_SHADOW_MAPS: usize = 10; pub const MAX_DIRECTIONAL_LIGHTS: usize = 1; pub const POINT_SHADOW_LAYERS: u32 = (6 * MAX_POINT_LIGHT_SHADOW_MAPS) as u32; pub const DIRECTIONAL_SHADOW_LAYERS: u32 = MAX_DIRECTIONAL_LIGHTS as u32; pub const SHADOW_FORMAT: TextureFormat = TextureFormat::Depth32Float; pub struct ShadowPipeline { pub view_layout: BindGroupLayout, pub mesh_layout: BindGroupLayout, pub point_light_sampler: Sampler, pub directional_light_sampler: Sampler, } // TODO: this pattern for initializing the shaders / pipeline isn't ideal. this should be handled by the asset system impl FromWorld for ShadowPipeline { fn from_world(world: &mut World) -> Self { let world = world.cell(); let render_device = world.get_resource::().unwrap(); let view_layout = render_device.create_bind_group_layout(&BindGroupLayoutDescriptor { entries: &[ // View BindGroupLayoutEntry { binding: 0, visibility: ShaderStages::VERTEX | ShaderStages::FRAGMENT, ty: BindingType::Buffer { ty: BufferBindingType::Uniform, has_dynamic_offset: true, min_binding_size: BufferSize::new(ViewUniform::std140_size_static() as u64), }, count: None, }, ], label: Some("shadow_view_layout"), }); let mesh_pipeline = world.get_resource::().unwrap(); ShadowPipeline { view_layout, mesh_layout: mesh_pipeline.mesh_layout.clone(), point_light_sampler: render_device.create_sampler(&SamplerDescriptor { address_mode_u: AddressMode::ClampToEdge, address_mode_v: AddressMode::ClampToEdge, address_mode_w: AddressMode::ClampToEdge, mag_filter: FilterMode::Linear, min_filter: FilterMode::Linear, mipmap_filter: FilterMode::Nearest, compare: Some(CompareFunction::GreaterEqual), ..Default::default() }), directional_light_sampler: render_device.create_sampler(&SamplerDescriptor { address_mode_u: AddressMode::ClampToEdge, address_mode_v: AddressMode::ClampToEdge, address_mode_w: AddressMode::ClampToEdge, mag_filter: FilterMode::Linear, min_filter: FilterMode::Linear, mipmap_filter: FilterMode::Nearest, compare: Some(CompareFunction::GreaterEqual), ..Default::default() }), } } } bitflags::bitflags! { #[repr(transparent)] pub struct ShadowPipelineKey: u32 { const NONE = 0; const VERTEX_TANGENTS = (1 << 0); const PRIMITIVE_TOPOLOGY_RESERVED_BITS = ShadowPipelineKey::PRIMITIVE_TOPOLOGY_MASK_BITS << ShadowPipelineKey::PRIMITIVE_TOPOLOGY_SHIFT_BITS; } } impl ShadowPipelineKey { const PRIMITIVE_TOPOLOGY_MASK_BITS: u32 = 0b111; const PRIMITIVE_TOPOLOGY_SHIFT_BITS: u32 = 32 - 3; pub fn from_primitive_topology(primitive_topology: PrimitiveTopology) -> Self { let primitive_topology_bits = ((primitive_topology as u32) & Self::PRIMITIVE_TOPOLOGY_MASK_BITS) << Self::PRIMITIVE_TOPOLOGY_SHIFT_BITS; Self::from_bits(primitive_topology_bits).unwrap() } pub fn primitive_topology(&self) -> PrimitiveTopology { let primitive_topology_bits = (self.bits >> Self::PRIMITIVE_TOPOLOGY_SHIFT_BITS) & Self::PRIMITIVE_TOPOLOGY_MASK_BITS; match primitive_topology_bits { x if x == PrimitiveTopology::PointList as u32 => PrimitiveTopology::PointList, x if x == PrimitiveTopology::LineList as u32 => PrimitiveTopology::LineList, x if x == PrimitiveTopology::LineStrip as u32 => PrimitiveTopology::LineStrip, x if x == PrimitiveTopology::TriangleList as u32 => PrimitiveTopology::TriangleList, x if x == PrimitiveTopology::TriangleStrip as u32 => PrimitiveTopology::TriangleStrip, _ => PrimitiveTopology::default(), } } } impl SpecializedPipeline for ShadowPipeline { type Key = ShadowPipelineKey; fn specialize(&self, key: Self::Key) -> RenderPipelineDescriptor { let (vertex_array_stride, vertex_attributes) = if key.contains(ShadowPipelineKey::VERTEX_TANGENTS) { ( 48, vec![ // Position (GOTCHA! Vertex_Position isn't first in the buffer due to how Mesh sorts attributes (alphabetically)) VertexAttribute { format: VertexFormat::Float32x3, offset: 12, shader_location: 0, }, // Normal VertexAttribute { format: VertexFormat::Float32x3, offset: 0, shader_location: 1, }, // Uv (GOTCHA! uv is no longer third in the buffer due to how Mesh sorts attributes (alphabetically)) VertexAttribute { format: VertexFormat::Float32x2, offset: 40, shader_location: 2, }, // Tangent VertexAttribute { format: VertexFormat::Float32x4, offset: 24, shader_location: 3, }, ], ) } else { ( 32, vec![ // Position (GOTCHA! Vertex_Position isn't first in the buffer due to how Mesh sorts attributes (alphabetically)) VertexAttribute { format: VertexFormat::Float32x3, offset: 12, shader_location: 0, }, // Normal VertexAttribute { format: VertexFormat::Float32x3, offset: 0, shader_location: 1, }, // Uv VertexAttribute { format: VertexFormat::Float32x2, offset: 24, shader_location: 2, }, ], ) }; RenderPipelineDescriptor { vertex: VertexState { shader: SHADOW_SHADER_HANDLE.typed::(), entry_point: "vertex".into(), shader_defs: vec![], buffers: vec![VertexBufferLayout { array_stride: vertex_array_stride, step_mode: VertexStepMode::Vertex, attributes: vertex_attributes, }], }, fragment: None, layout: Some(vec![self.view_layout.clone(), self.mesh_layout.clone()]), primitive: PrimitiveState { topology: key.primitive_topology(), strip_index_format: None, front_face: FrontFace::Ccw, cull_mode: None, unclipped_depth: false, polygon_mode: PolygonMode::Fill, conservative: false, }, depth_stencil: Some(DepthStencilState { format: SHADOW_FORMAT, depth_write_enabled: true, depth_compare: CompareFunction::GreaterEqual, stencil: StencilState { front: StencilFaceState::IGNORE, back: StencilFaceState::IGNORE, read_mask: 0, write_mask: 0, }, bias: DepthBiasState { constant: 0, slope_scale: 0.0, clamp: 0.0, }, }), multisample: MultisampleState::default(), label: Some("shadow_pipeline".into()), } } } #[derive(Component)] pub struct ExtractedClusterConfig { /// Special near value for cluster calculations near: f32, /// Number of clusters in x / y / z in the view frustum axis_slices: UVec3, } #[derive(Component)] pub struct ExtractedClustersPointLights { data: Vec, } pub fn extract_clusters(mut commands: Commands, views: Query<(Entity, &Clusters), With>) { for (entity, clusters) in views.iter() { commands.get_or_spawn(entity).insert_bundle(( ExtractedClustersPointLights { data: clusters.lights.clone(), }, ExtractedClusterConfig { near: clusters.near, axis_slices: clusters.axis_slices, }, )); } } pub fn extract_lights( mut commands: Commands, ambient_light: Res, point_light_shadow_map: Res, directional_light_shadow_map: Res, global_point_lights: Res, // visible_point_lights: Query<&VisiblePointLights>, mut point_lights: Query<(&PointLight, &mut CubemapVisibleEntities, &GlobalTransform)>, mut directional_lights: Query<( Entity, &DirectionalLight, &mut VisibleEntities, &GlobalTransform, )>, ) { commands.insert_resource(ExtractedAmbientLight { color: ambient_light.color, brightness: ambient_light.brightness, }); commands.insert_resource::(point_light_shadow_map.clone()); commands.insert_resource::( directional_light_shadow_map.clone(), ); // This is the point light shadow map texel size for one face of the cube as a distance of 1.0 // world unit from the light. // point_light_texel_size = 2.0 * 1.0 * tan(PI / 4.0) / cube face width in texels // PI / 4.0 is half the cube face fov, tan(PI / 4.0) = 1.0, so this simplifies to: // point_light_texel_size = 2.0 / cube face width in texels // NOTE: When using various PCF kernel sizes, this will need to be adjusted, according to: // https://catlikecoding.com/unity/tutorials/custom-srp/point-and-spot-shadows/ let point_light_texel_size = 2.0 / point_light_shadow_map.size as f32; for entity in global_point_lights.iter().copied() { if let Ok((point_light, cubemap_visible_entities, transform)) = point_lights.get_mut(entity) { let render_cubemap_visible_entities = std::mem::take(cubemap_visible_entities.into_inner()); commands.get_or_spawn(entity).insert_bundle(( ExtractedPointLight { color: point_light.color, // NOTE: Map from luminous power in lumens to luminous intensity in lumens per steradian // for a point light. See https://google.github.io/filament/Filament.html#mjx-eqn-pointLightLuminousPower // for details. intensity: point_light.intensity / (4.0 * std::f32::consts::PI), range: point_light.range, radius: point_light.radius, transform: *transform, shadows_enabled: point_light.shadows_enabled, shadow_depth_bias: point_light.shadow_depth_bias, // The factor of SQRT_2 is for the worst-case diagonal offset shadow_normal_bias: point_light.shadow_normal_bias * point_light_texel_size * std::f32::consts::SQRT_2, }, render_cubemap_visible_entities, )); } } for (entity, directional_light, visible_entities, transform) in directional_lights.iter_mut() { // Calulate the directional light shadow map texel size using the largest x,y dimension of // the orthographic projection divided by the shadow map resolution // NOTE: When using various PCF kernel sizes, this will need to be adjusted, according to: // https://catlikecoding.com/unity/tutorials/custom-srp/directional-shadows/ let largest_dimension = (directional_light.shadow_projection.right - directional_light.shadow_projection.left) .max( directional_light.shadow_projection.top - directional_light.shadow_projection.bottom, ); let directional_light_texel_size = largest_dimension / directional_light_shadow_map.size as f32; let render_visible_entities = std::mem::take(visible_entities.into_inner()); commands.get_or_spawn(entity).insert_bundle(( ExtractedDirectionalLight { color: directional_light.color, illuminance: directional_light.illuminance, direction: transform.forward(), projection: directional_light.shadow_projection.get_projection_matrix(), shadows_enabled: directional_light.shadows_enabled, shadow_depth_bias: directional_light.shadow_depth_bias, // The factor of SQRT_2 is for the worst-case diagonal offset shadow_normal_bias: directional_light.shadow_normal_bias * directional_light_texel_size * std::f32::consts::SQRT_2, near: directional_light.shadow_projection.near, far: directional_light.shadow_projection.far, }, render_visible_entities, )); } } pub(crate) const POINT_LIGHT_NEAR_Z: f32 = 0.1f32; // Can't do `Vec3::Y * -1.0` because mul isn't const const NEGATIVE_X: Vec3 = const_vec3!([-1.0, 0.0, 0.0]); const NEGATIVE_Y: Vec3 = const_vec3!([0.0, -1.0, 0.0]); const NEGATIVE_Z: Vec3 = const_vec3!([0.0, 0.0, -1.0]); pub(crate) struct CubeMapFace { pub(crate) target: Vec3, pub(crate) up: Vec3, } // see https://www.khronos.org/opengl/wiki/Cubemap_Texture pub(crate) const CUBE_MAP_FACES: [CubeMapFace; 6] = [ // 0 GL_TEXTURE_CUBE_MAP_POSITIVE_X CubeMapFace { target: NEGATIVE_X, up: NEGATIVE_Y, }, // 1 GL_TEXTURE_CUBE_MAP_NEGATIVE_X CubeMapFace { target: Vec3::X, up: NEGATIVE_Y, }, // 2 GL_TEXTURE_CUBE_MAP_POSITIVE_Y CubeMapFace { target: NEGATIVE_Y, up: Vec3::Z, }, // 3 GL_TEXTURE_CUBE_MAP_NEGATIVE_Y CubeMapFace { target: Vec3::Y, up: NEGATIVE_Z, }, // 4 GL_TEXTURE_CUBE_MAP_POSITIVE_Z CubeMapFace { target: NEGATIVE_Z, up: NEGATIVE_Y, }, // 5 GL_TEXTURE_CUBE_MAP_NEGATIVE_Z CubeMapFace { target: Vec3::Z, up: NEGATIVE_Y, }, ]; fn face_index_to_name(face_index: usize) -> &'static str { match face_index { 0 => "+x", 1 => "-x", 2 => "+y", 3 => "-y", 4 => "+z", 5 => "-z", _ => "invalid", } } #[derive(Component)] pub struct ShadowView { pub depth_texture_view: TextureView, pub pass_name: String, } #[derive(Component)] pub struct ViewShadowBindings { pub point_light_depth_texture: Texture, pub point_light_depth_texture_view: TextureView, pub directional_light_depth_texture: Texture, pub directional_light_depth_texture_view: TextureView, } #[derive(Component)] pub struct ViewLightEntities { pub lights: Vec, } #[derive(Component)] pub struct ViewLightsUniformOffset { pub offset: u32, } #[derive(Default)] pub struct GlobalLightMeta { pub gpu_point_lights: UniformVec, pub entity_to_index: HashMap, } #[derive(Default)] pub struct LightMeta { pub view_gpu_lights: DynamicUniformVec, pub shadow_view_bind_group: Option, } #[derive(Component)] pub enum LightEntity { Directional { light_entity: Entity, }, Point { light_entity: Entity, face_index: usize, }, } pub fn calculate_cluster_factors( near: f32, far: f32, z_slices: f32, is_orthographic: bool, ) -> Vec2 { if is_orthographic { Vec2::new(-near, z_slices / (-far - -near)) } else { let z_slices_of_ln_zfar_over_znear = (z_slices - 1.0) / (far / near).ln(); Vec2::new( z_slices_of_ln_zfar_over_znear, near.ln() * z_slices_of_ln_zfar_over_znear, ) } } #[allow(clippy::too_many_arguments)] pub fn prepare_lights( mut commands: Commands, mut texture_cache: ResMut, render_device: Res, render_queue: Res, mut global_light_meta: ResMut, mut light_meta: ResMut, views: Query< (Entity, &ExtractedView, &ExtractedClusterConfig), With>, >, ambient_light: Res, point_light_shadow_map: Res, directional_light_shadow_map: Res, point_lights: Query<(Entity, &ExtractedPointLight)>, directional_lights: Query<(Entity, &ExtractedDirectionalLight)>, ) { light_meta.view_gpu_lights.clear(); // Pre-calculate for PointLights let cube_face_projection = Mat4::perspective_infinite_reverse_rh(std::f32::consts::FRAC_PI_2, 1.0, POINT_LIGHT_NEAR_Z); let cube_face_rotations = CUBE_MAP_FACES .iter() .map(|CubeMapFace { target, up }| GlobalTransform::identity().looking_at(*target, *up)) .collect::>(); global_light_meta.gpu_point_lights.clear(); global_light_meta.entity_to_index.clear(); let mut point_lights: Vec<_> = point_lights.iter().collect::>(); // Sort point lights with shadows enabled first, then by a stable key so that the index can be used // to render at most `MAX_POINT_LIGHT_SHADOW_MAPS` point light shadows. point_lights.sort_by(|(entity_1, light_1), (entity_2, light_2)| { light_1 .shadows_enabled .cmp(&light_2.shadows_enabled) .reverse() .then_with(|| entity_1.cmp(entity_2)) }); if global_light_meta.entity_to_index.capacity() < point_lights.len() { global_light_meta .entity_to_index .reserve(point_lights.len()); } let mut gpu_point_lights = [GpuPointLight::default(); MAX_POINT_LIGHTS]; for (index, &(entity, light)) in point_lights.iter().enumerate().take(MAX_POINT_LIGHTS) { let mut flags = PointLightFlags::NONE; // Lights are sorted, shadow enabled lights are first if light.shadows_enabled && index < MAX_POINT_LIGHT_SHADOW_MAPS { flags |= PointLightFlags::SHADOWS_ENABLED; } gpu_point_lights[index] = GpuPointLight { projection_lr: Vec4::new( cube_face_projection.z_axis.z, cube_face_projection.z_axis.w, cube_face_projection.w_axis.z, cube_face_projection.w_axis.w, ), // premultiply color by intensity // we don't use the alpha at all, so no reason to multiply only [0..3] color_inverse_square_range: (Vec4::from_slice(&light.color.as_linear_rgba_f32()) * light.intensity) .xyz() .extend(1.0 / (light.range * light.range)), position_radius: light.transform.translation.extend(light.radius), flags: flags.bits, shadow_depth_bias: light.shadow_depth_bias, shadow_normal_bias: light.shadow_normal_bias, }; global_light_meta.entity_to_index.insert(entity, index); } global_light_meta.gpu_point_lights.push(GpuPointLights { data: gpu_point_lights, }); global_light_meta .gpu_point_lights .write_buffer(&render_device, &render_queue); // set up light data for each view for (entity, extracted_view, clusters) in views.iter() { let point_light_depth_texture = texture_cache.get( &render_device, TextureDescriptor { size: Extent3d { width: point_light_shadow_map.size as u32, height: point_light_shadow_map.size as u32, depth_or_array_layers: POINT_SHADOW_LAYERS, }, mip_level_count: 1, sample_count: 1, dimension: TextureDimension::D2, format: SHADOW_FORMAT, label: Some("point_light_shadow_map_texture"), usage: TextureUsages::RENDER_ATTACHMENT | TextureUsages::TEXTURE_BINDING, }, ); let directional_light_depth_texture = texture_cache.get( &render_device, TextureDescriptor { size: Extent3d { width: (directional_light_shadow_map.size as u32) .min(render_device.limits().max_texture_dimension_2d), height: (directional_light_shadow_map.size as u32) .min(render_device.limits().max_texture_dimension_2d), depth_or_array_layers: DIRECTIONAL_SHADOW_LAYERS, }, mip_level_count: 1, sample_count: 1, dimension: TextureDimension::D2, format: SHADOW_FORMAT, label: Some("directional_light_shadow_map_texture"), usage: TextureUsages::RENDER_ATTACHMENT | TextureUsages::TEXTURE_BINDING, }, ); let mut view_lights = Vec::new(); let is_orthographic = extracted_view.projection.w_axis.w == 1.0; let cluster_factors_zw = calculate_cluster_factors( clusters.near, extracted_view.far, clusters.axis_slices.z as f32, is_orthographic, ); let n_clusters = clusters.axis_slices.x * clusters.axis_slices.y * clusters.axis_slices.z; let mut gpu_lights = GpuLights { directional_lights: [GpuDirectionalLight::default(); MAX_DIRECTIONAL_LIGHTS], ambient_color: Vec4::from_slice(&ambient_light.color.as_linear_rgba_f32()) * ambient_light.brightness, cluster_factors: Vec4::new( clusters.axis_slices.x as f32 / extracted_view.width as f32, clusters.axis_slices.y as f32 / extracted_view.height as f32, cluster_factors_zw.x, cluster_factors_zw.y, ), cluster_dimensions: clusters.axis_slices.extend(n_clusters), n_directional_lights: directional_lights.iter().len() as u32, }; // TODO: this should select lights based on relevance to the view instead of the first ones that show up in a query for &(light_entity, light) in point_lights .iter() // Lights are sorted, shadow enabled lights are first .take(MAX_POINT_LIGHT_SHADOW_MAPS) .filter(|(_, light)| light.shadows_enabled) { let light_index = *global_light_meta .entity_to_index .get(&light_entity) .unwrap(); // ignore scale because we don't want to effectively scale light radius and range // by applying those as a view transform to shadow map rendering of objects // and ignore rotation because we want the shadow map projections to align with the axes let view_translation = GlobalTransform::from_translation(light.transform.translation); for (face_index, view_rotation) in cube_face_rotations.iter().enumerate() { let depth_texture_view = point_light_depth_texture .texture .create_view(&TextureViewDescriptor { label: Some("point_light_shadow_map_texture_view"), format: None, dimension: Some(TextureViewDimension::D2), aspect: TextureAspect::All, base_mip_level: 0, mip_level_count: None, base_array_layer: (light_index * 6 + face_index) as u32, array_layer_count: NonZeroU32::new(1), }); let view_light_entity = commands .spawn() .insert_bundle(( ShadowView { depth_texture_view, pass_name: format!( "shadow pass point light {} {}", light_index, face_index_to_name(face_index) ), }, ExtractedView { width: point_light_shadow_map.size as u32, height: point_light_shadow_map.size as u32, transform: view_translation * *view_rotation, projection: cube_face_projection, near: POINT_LIGHT_NEAR_Z, far: light.range, }, RenderPhase::::default(), LightEntity::Point { light_entity, face_index, }, )) .id(); view_lights.push(view_light_entity); } } for (i, (light_entity, light)) in directional_lights .iter() .enumerate() .take(MAX_DIRECTIONAL_LIGHTS) { // direction is negated to be ready for N.L let dir_to_light = -light.direction; // convert from illuminance (lux) to candelas // // exposure is hard coded at the moment but should be replaced // by values coming from the camera // see: https://google.github.io/filament/Filament.html#imagingpipeline/physicallybasedcamera/exposuresettings const APERTURE: f32 = 4.0; const SHUTTER_SPEED: f32 = 1.0 / 250.0; const SENSITIVITY: f32 = 100.0; let ev100 = f32::log2(APERTURE * APERTURE / SHUTTER_SPEED) - f32::log2(SENSITIVITY / 100.0); let exposure = 1.0 / (f32::powf(2.0, ev100) * 1.2); let intensity = light.illuminance * exposure; // NOTE: A directional light seems to have to have an eye position on the line along the direction of the light // through the world origin. I (Rob Swain) do not yet understand why it cannot be translated away from this. let view = Mat4::look_at_rh(Vec3::ZERO, light.direction, Vec3::Y); // NOTE: This orthographic projection defines the volume within which shadows from a directional light can be cast let projection = light.projection; let mut flags = DirectionalLightFlags::NONE; if light.shadows_enabled { flags |= DirectionalLightFlags::SHADOWS_ENABLED; } gpu_lights.directional_lights[i] = GpuDirectionalLight { // premultiply color by intensity // we don't use the alpha at all, so no reason to multiply only [0..3] color: Vec4::from_slice(&light.color.as_linear_rgba_f32()) * intensity, dir_to_light, // NOTE: * view is correct, it should not be view.inverse() here view_projection: projection * view, flags: flags.bits, shadow_depth_bias: light.shadow_depth_bias, shadow_normal_bias: light.shadow_normal_bias, }; if light.shadows_enabled { let depth_texture_view = directional_light_depth_texture .texture .create_view(&TextureViewDescriptor { label: Some("directional_light_shadow_map_texture_view"), format: None, dimension: Some(TextureViewDimension::D2), aspect: TextureAspect::All, base_mip_level: 0, mip_level_count: None, base_array_layer: i as u32, array_layer_count: NonZeroU32::new(1), }); let view_light_entity = commands .spawn() .insert_bundle(( ShadowView { depth_texture_view, pass_name: format!("shadow pass directional light {}", i), }, ExtractedView { width: directional_light_shadow_map.size as u32, height: directional_light_shadow_map.size as u32, transform: GlobalTransform::from_matrix(view.inverse()), projection, near: light.near, far: light.far, }, RenderPhase::::default(), LightEntity::Directional { light_entity }, )) .id(); view_lights.push(view_light_entity); } } let point_light_depth_texture_view = point_light_depth_texture .texture .create_view(&TextureViewDescriptor { label: Some("point_light_shadow_map_array_texture_view"), format: None, #[cfg(not(feature = "webgl"))] dimension: Some(TextureViewDimension::CubeArray), #[cfg(feature = "webgl")] dimension: Some(TextureViewDimension::Cube), aspect: TextureAspect::All, base_mip_level: 0, mip_level_count: None, base_array_layer: 0, array_layer_count: None, }); let directional_light_depth_texture_view = directional_light_depth_texture .texture .create_view(&TextureViewDescriptor { label: Some("directional_light_shadow_map_array_texture_view"), format: None, #[cfg(not(feature = "webgl"))] dimension: Some(TextureViewDimension::D2Array), #[cfg(feature = "webgl")] dimension: Some(TextureViewDimension::D2), aspect: TextureAspect::All, base_mip_level: 0, mip_level_count: None, base_array_layer: 0, array_layer_count: None, }); commands.entity(entity).insert_bundle(( ViewShadowBindings { point_light_depth_texture: point_light_depth_texture.texture, point_light_depth_texture_view, directional_light_depth_texture: directional_light_depth_texture.texture, directional_light_depth_texture_view, }, ViewLightEntities { lights: view_lights, }, ViewLightsUniformOffset { offset: light_meta.view_gpu_lights.push(gpu_lights), }, )); } light_meta .view_gpu_lights .write_buffer(&render_device, &render_queue); } const CLUSTER_OFFSET_MASK: u32 = (1 << 24) - 1; const CLUSTER_COUNT_SIZE: u32 = 8; const CLUSTER_COUNT_MASK: u32 = (1 << 8) - 1; const POINT_LIGHT_INDEX_MASK: u32 = (1 << 8) - 1; // NOTE: With uniform buffer max binding size as 16384 bytes // that means we can fit say 256 point lights in one uniform // buffer, which means the count can be at most 256 so it // needs 8 bits. // The array of indices can also use u8 and that means the // offset in to the array of indices needs to be able to address // 16384 values. log2(16384) = 14 bits. // This means we can pack the offset into the upper 24 bits of a u32 // and the count into the lower 8 bits. // NOTE: This assumes CPU and GPU endianness are the same which is true // for all common and tested x86/ARM CPUs and AMD/NVIDIA/Intel/Apple/etc GPUs fn pack_offset_and_count(offset: usize, count: usize) -> u32 { ((offset as u32 & CLUSTER_OFFSET_MASK) << CLUSTER_COUNT_SIZE) | (count as u32 & CLUSTER_COUNT_MASK) } #[derive(Component, Default)] pub struct ViewClusterBindings { n_indices: usize, // NOTE: UVec4 is because all arrays in Std140 layout have 16-byte alignment pub cluster_light_index_lists: UniformVec<[UVec4; Self::MAX_UNIFORM_ITEMS]>, n_offsets: usize, // NOTE: UVec4 is because all arrays in Std140 layout have 16-byte alignment pub cluster_offsets_and_counts: UniformVec<[UVec4; Self::MAX_UNIFORM_ITEMS]>, } impl ViewClusterBindings { pub const MAX_OFFSETS: usize = 16384 / 4; const MAX_UNIFORM_ITEMS: usize = Self::MAX_OFFSETS / 4; const MAX_INDICES: usize = 16384; pub fn reserve_and_clear(&mut self) { self.cluster_light_index_lists.clear(); self.cluster_light_index_lists .push([UVec4::ZERO; Self::MAX_UNIFORM_ITEMS]); self.cluster_offsets_and_counts.clear(); self.cluster_offsets_and_counts .push([UVec4::ZERO; Self::MAX_UNIFORM_ITEMS]); } pub fn push_offset_and_count(&mut self, offset: usize, count: usize) { let array_index = self.n_offsets >> 2; // >> 2 is equivalent to / 4 if array_index >= Self::MAX_UNIFORM_ITEMS { warn!("cluster offset and count out of bounds!"); return; } let component = self.n_offsets & ((1 << 2) - 1); let packed = pack_offset_and_count(offset, count); self.cluster_offsets_and_counts.get_mut(0)[array_index][component] = packed; self.n_offsets += 1; } pub fn n_indices(&self) -> usize { self.n_indices } pub fn push_index(&mut self, index: usize) { let array_index = self.n_indices >> 4; // >> 4 is equivalent to / 16 let component = (self.n_indices >> 2) & ((1 << 2) - 1); let sub_index = self.n_indices & ((1 << 2) - 1); let index = index as u32 & POINT_LIGHT_INDEX_MASK; self.cluster_light_index_lists.get_mut(0)[array_index][component] |= index << (8 * sub_index); self.n_indices += 1; } } pub fn prepare_clusters( mut commands: Commands, render_device: Res, render_queue: Res, global_light_meta: Res, views: Query< ( Entity, &ExtractedClusterConfig, &ExtractedClustersPointLights, ), With>, >, ) { for (entity, cluster_config, extracted_clusters) in views.iter() { let mut view_clusters_bindings = ViewClusterBindings::default(); view_clusters_bindings.reserve_and_clear(); let mut indices_full = false; let mut cluster_index = 0; for _y in 0..cluster_config.axis_slices.y { for _x in 0..cluster_config.axis_slices.x { for _z in 0..cluster_config.axis_slices.z { let offset = view_clusters_bindings.n_indices(); let cluster_lights = &extracted_clusters.data[cluster_index]; let count = cluster_lights.len(); view_clusters_bindings.push_offset_and_count(offset, count); if !indices_full { for entity in cluster_lights.iter() { if let Some(light_index) = global_light_meta.entity_to_index.get(entity) { if view_clusters_bindings.n_indices() >= ViewClusterBindings::MAX_INDICES { warn!("Cluster light index lists is full! The PointLights in the view are affecting too many clusters."); indices_full = true; break; } view_clusters_bindings.push_index(*light_index); } } } cluster_index += 1; } } } view_clusters_bindings .cluster_light_index_lists .write_buffer(&render_device, &render_queue); view_clusters_bindings .cluster_offsets_and_counts .write_buffer(&render_device, &render_queue); commands.get_or_spawn(entity).insert(view_clusters_bindings); } } pub fn queue_shadow_view_bind_group( render_device: Res, shadow_pipeline: Res, mut light_meta: ResMut, view_uniforms: Res, ) { if let Some(view_binding) = view_uniforms.uniforms.binding() { light_meta.shadow_view_bind_group = Some(render_device.create_bind_group(&BindGroupDescriptor { entries: &[BindGroupEntry { binding: 0, resource: view_binding, }], label: Some("shadow_view_bind_group"), layout: &shadow_pipeline.view_layout, })); } } #[allow(clippy::too_many_arguments)] pub fn queue_shadows( shadow_draw_functions: Res>, shadow_pipeline: Res, casting_meshes: Query<&Handle, Without>, render_meshes: Res>, mut pipelines: ResMut>, mut pipeline_cache: ResMut, view_lights: Query<&ViewLightEntities>, mut view_light_shadow_phases: Query<(&LightEntity, &mut RenderPhase)>, point_light_entities: Query<&CubemapVisibleEntities, With>, directional_light_entities: Query<&VisibleEntities, With>, ) { for view_lights in view_lights.iter() { let draw_shadow_mesh = shadow_draw_functions .read() .get_id::() .unwrap(); for view_light_entity in view_lights.lights.iter().copied() { let (light_entity, mut shadow_phase) = view_light_shadow_phases.get_mut(view_light_entity).unwrap(); let visible_entities = match light_entity { LightEntity::Directional { light_entity } => directional_light_entities .get(*light_entity) .expect("Failed to get directional light visible entities"), LightEntity::Point { light_entity, face_index, } => point_light_entities .get(*light_entity) .expect("Failed to get point light visible entities") .get(*face_index), }; // NOTE: Lights with shadow mapping disabled will have no visible entities // so no meshes will be queued for entity in visible_entities.iter().copied() { let mut key = ShadowPipelineKey::empty(); if let Ok(mesh_handle) = casting_meshes.get(entity) { if let Some(mesh) = render_meshes.get(mesh_handle) { if mesh.has_tangents { key |= ShadowPipelineKey::VERTEX_TANGENTS; } key |= ShadowPipelineKey::from_primitive_topology(mesh.primitive_topology); } let pipeline_id = pipelines.specialize(&mut pipeline_cache, &shadow_pipeline, key); shadow_phase.add(Shadow { draw_function: draw_shadow_mesh, pipeline: pipeline_id, entity, distance: 0.0, // TODO: sort back-to-front }); } } } } } pub struct Shadow { pub distance: f32, pub entity: Entity, pub pipeline: CachedPipelineId, pub draw_function: DrawFunctionId, } impl PhaseItem for Shadow { type SortKey = FloatOrd; #[inline] fn sort_key(&self) -> Self::SortKey { FloatOrd(self.distance) } #[inline] fn draw_function(&self) -> DrawFunctionId { self.draw_function } } impl EntityPhaseItem for Shadow { fn entity(&self) -> Entity { self.entity } } impl CachedPipelinePhaseItem for Shadow { #[inline] fn cached_pipeline(&self) -> CachedPipelineId { self.pipeline } } pub struct ShadowPassNode { main_view_query: QueryState<&'static ViewLightEntities>, view_light_query: QueryState<(&'static ShadowView, &'static RenderPhase)>, } impl ShadowPassNode { pub const IN_VIEW: &'static str = "view"; pub fn new(world: &mut World) -> Self { Self { main_view_query: QueryState::new(world), view_light_query: QueryState::new(world), } } } impl Node for ShadowPassNode { fn input(&self) -> Vec { vec![SlotInfo::new(ShadowPassNode::IN_VIEW, SlotType::Entity)] } fn update(&mut self, world: &mut World) { self.main_view_query.update_archetypes(world); self.view_light_query.update_archetypes(world); } fn run( &self, graph: &mut RenderGraphContext, render_context: &mut RenderContext, world: &World, ) -> Result<(), NodeRunError> { let view_entity = graph.get_input_entity(Self::IN_VIEW)?; if let Ok(view_lights) = self.main_view_query.get_manual(world, view_entity) { for view_light_entity in view_lights.lights.iter().copied() { let (view_light, shadow_phase) = self .view_light_query .get_manual(world, view_light_entity) .unwrap(); let pass_descriptor = RenderPassDescriptor { label: Some(&view_light.pass_name), color_attachments: &[], depth_stencil_attachment: Some(RenderPassDepthStencilAttachment { view: &view_light.depth_texture_view, depth_ops: Some(Operations { load: LoadOp::Clear(0.0), store: true, }), stencil_ops: None, }), }; let draw_functions = world.get_resource::>().unwrap(); let render_pass = render_context .command_encoder .begin_render_pass(&pass_descriptor); let mut draw_functions = draw_functions.write(); let mut tracked_pass = TrackedRenderPass::new(render_pass); for item in &shadow_phase.items { let draw_function = draw_functions.get_mut(item.draw_function).unwrap(); draw_function.draw(world, &mut tracked_pass, view_light_entity, item); } } } Ok(()) } } pub type DrawShadowMesh = ( SetItemPipeline, SetShadowViewBindGroup<0>, SetMeshBindGroup<1>, DrawMesh, ); pub struct SetShadowViewBindGroup; impl EntityRenderCommand for SetShadowViewBindGroup { type Param = (SRes, SQuery>); #[inline] fn render<'w>( view: Entity, _item: Entity, (light_meta, view_query): SystemParamItem<'w, '_, Self::Param>, pass: &mut TrackedRenderPass<'w>, ) -> RenderCommandResult { let view_uniform_offset = view_query.get(view).unwrap(); pass.set_bind_group( I, light_meta .into_inner() .shadow_view_bind_group .as_ref() .unwrap(), &[view_uniform_offset.offset], ); RenderCommandResult::Success } }