render: provide shadow texture atlas frame for each shadow casting light

This commit is contained in:
SeanOMik 2024-07-11 18:27:26 -04:00
parent a4ce4cb432
commit cc1c482c40
Signed by: SeanOMik
GPG Key ID: FEC9E2FC15235964
5 changed files with 115 additions and 75 deletions

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@ -14,8 +14,7 @@ use crate::render::{
}; };
use super::{ use super::{
BasePassSlots, LightBasePassSlots, LightCullComputePassSlots, MeshBufferStorage, RenderAssets, BasePassSlots, LightBasePassSlots, LightCullComputePassSlots, MeshBufferStorage, RenderAssets, RenderMeshes, ShadowMapsPassSlots
RenderMeshes, ShadowMapsPassSlots,
}; };
#[derive(Debug, Hash, Clone, Default, PartialEq, RenderGraphLabel)] #[derive(Debug, Hash, Clone, Default, PartialEq, RenderGraphLabel)]
@ -160,7 +159,7 @@ impl Node for MeshPass {
binding: 3, binding: 3,
visibility: wgpu::ShaderStages::VERTEX_FRAGMENT, visibility: wgpu::ShaderStages::VERTEX_FRAGMENT,
ty: wgpu::BindingType::Buffer { ty: wgpu::BindingType::Buffer {
ty: wgpu::BufferBindingType::Uniform, ty: wgpu::BufferBindingType::Storage { read_only: true },
has_dynamic_offset: false, has_dynamic_offset: false,
min_binding_size: None, min_binding_size: None,
}, },

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@ -1,4 +1,4 @@
use std::{collections::VecDeque, mem, num::NonZeroU64, ops::Deref, rc::Rc, sync::{Arc, RwLock, RwLockReadGuard, RwLockWriteGuard}}; use std::{collections::VecDeque, mem, num::NonZeroU64, rc::Rc, sync::{Arc, RwLock, RwLockReadGuard, RwLockWriteGuard}};
use lyra_ecs::{ use lyra_ecs::{
query::{filter::Has, Entities}, AtomicRef, Component, Entity, ResourceData query::{filter::Has, Entities}, AtomicRef, Component, Entity, ResourceData
@ -29,15 +29,20 @@ pub enum ShadowMapsPassSlots {
#[derive(Debug, Clone, Hash, PartialEq, RenderGraphLabel)] #[derive(Debug, Clone, Hash, PartialEq, RenderGraphLabel)]
pub struct ShadowMapsPassLabel; pub struct ShadowMapsPassLabel;
#[derive(Clone, Copy)]
struct LightDepthMap { struct LightDepthMap {
light_projection_buffer: Arc<wgpu::Buffer>, //light_projection_buffer: Arc<wgpu::Buffer>,
bindgroup: wgpu::BindGroup, //bindgroup: wgpu::BindGroup,
atlas_index: u64, atlas_index: u64,
uniform_index: u64,
} }
pub struct ShadowMapsPass { pub struct ShadowMapsPass {
bgl: Arc<wgpu::BindGroupLayout>, bgl: Arc<wgpu::BindGroupLayout>,
atlas_size_buffer: Arc<wgpu::Buffer>, atlas_size_buffer: Arc<wgpu::Buffer>,
light_uniforms_buffer: Arc<wgpu::Buffer>,
light_uniforms_index: u64,
uniforms_bg: Arc<wgpu::BindGroup>,
/// depth maps for a light owned by an entity. /// depth maps for a light owned by an entity.
depth_maps: FxHashMap<Entity, LightDepthMap>, depth_maps: FxHashMap<Entity, LightDepthMap>,
@ -63,8 +68,8 @@ impl ShadowMapsPass {
binding: 0, binding: 0,
visibility: wgpu::ShaderStages::VERTEX_FRAGMENT, visibility: wgpu::ShaderStages::VERTEX_FRAGMENT,
ty: wgpu::BindingType::Buffer { ty: wgpu::BindingType::Buffer {
ty: wgpu::BufferBindingType::Uniform, ty: wgpu::BufferBindingType::Storage { read_only: true },
has_dynamic_offset: false, has_dynamic_offset: true,
min_binding_size: Some( min_binding_size: Some(
NonZeroU64::new(mem::size_of::<LightShadowUniform>() as _).unwrap(), NonZeroU64::new(mem::size_of::<LightShadowUniform>() as _).unwrap(),
), ),
@ -101,8 +106,32 @@ impl ShadowMapsPass {
..Default::default() ..Default::default()
}); });
let uniforms_buffer =
device.create_buffer(&wgpu::BufferDescriptor {
label: Some("buffer_shadow_maps_light"),
usage: wgpu::BufferUsages::STORAGE | wgpu::BufferUsages::COPY_DST,
size: device.limits().max_storage_buffer_binding_size as u64,
mapped_at_creation: false,
});
let uniforms_bg = device.create_bind_group(&wgpu::BindGroupDescriptor {
label: Some("bind_group_shadows"),
layout: &bgl,
entries: &[wgpu::BindGroupEntry {
binding: 0,
resource: wgpu::BindingResource::Buffer(wgpu::BufferBinding {
buffer: &uniforms_buffer,
offset: 0,
size: Some(NonZeroU64::new(mem::size_of::<LightShadowUniform>() as _).unwrap()),
}),
}],
});
Self { Self {
bgl, bgl,
light_uniforms_buffer: Arc::new(uniforms_buffer),
light_uniforms_index: 0,
uniforms_bg: Arc::new(uniforms_bg),
atlas_size_buffer: Arc::new(atlas_size_buffer), atlas_size_buffer: Arc::new(atlas_size_buffer),
depth_maps: Default::default(), depth_maps: Default::default(),
transform_buffers: None, transform_buffers: None,
@ -116,7 +145,7 @@ impl ShadowMapsPass {
} }
/// Create a depth map and return the id of the depth map in the texture atlas. /// Create a depth map and return the id of the depth map in the texture atlas.
fn create_depth_map(&mut self, device: &wgpu::Device, entity: Entity, light_pos: Transform) -> u64 { fn create_depth_map(&mut self, device: &wgpu::Device, queue: &wgpu::Queue, entity: Entity, light_pos: Transform) -> LightDepthMap {
const NEAR_PLANE: f32 = 0.1; const NEAR_PLANE: f32 = 0.1;
const FAR_PLANE: f32 = 45.0; const FAR_PLANE: f32 = 45.0;
@ -137,38 +166,23 @@ impl ShadowMapsPass {
atlas_frame, atlas_frame,
}; };
let light_projection_buffer = let uniform_index = self.light_uniforms_index;
device.create_buffer_init(&wgpu::util::BufferInitDescriptor { self.light_uniforms_index += 1;
label: Some("buffer_shadow_maps_light"),
usage: wgpu::BufferUsages::UNIFORM | wgpu::BufferUsages::COPY_DST,
contents: bytemuck::bytes_of(&uniform),
});
let bg = device.create_bind_group(&wgpu::BindGroupDescriptor { //self.light_uniforms_buffer
label: Some("shadow_maps_bind_group"), let offset = uniform_index_offset(&device.limits(), uniform_index);
layout: &self.bgl, queue.write_buffer(&self.light_uniforms_buffer, offset as u64, bytemuck::bytes_of(&uniform));
entries: &[
wgpu::BindGroupEntry {
binding: 0,
resource: wgpu::BindingResource::Buffer(wgpu::BufferBinding {
buffer: &light_projection_buffer,
offset: 0,
size: None,
}),
}
],
});
let v = LightDepthMap {
atlas_index,
uniform_index,
};
self.depth_maps.insert( self.depth_maps.insert(
entity, entity,
LightDepthMap { v,
light_projection_buffer: Arc::new(light_projection_buffer),
bindgroup: bg,
atlas_index
},
); );
atlas_index v
} }
fn transform_buffers(&self) -> AtomicRef<TransformBuffers> { fn transform_buffers(&self) -> AtomicRef<TransformBuffers> {
@ -211,10 +225,10 @@ impl Node for ShadowMapsPass {
Some(SlotValue::Sampler(self.atlas_sampler.clone())), Some(SlotValue::Sampler(self.atlas_sampler.clone())),
); );
node.add_sampler_slot( node.add_buffer_slot(
ShadowMapsPassSlots::ShadowLightUniformsBuffer, ShadowMapsPassSlots::ShadowLightUniformsBuffer,
SlotAttribute::Output, SlotAttribute::Output,
Some(SlotValue::Lazy), Some(SlotValue::Buffer(self.light_uniforms_buffer.clone())),
); );
node.add_buffer_slot( node.add_buffer_slot(
@ -230,7 +244,7 @@ impl Node for ShadowMapsPass {
&mut self, &mut self,
graph: &mut crate::render::graph::RenderGraph, graph: &mut crate::render::graph::RenderGraph,
world: &mut lyra_ecs::World, world: &mut lyra_ecs::World,
_: &mut crate::render::graph::RenderGraphContext, context: &mut crate::render::graph::RenderGraphContext,
) { ) {
self.render_meshes = world.try_get_resource_data::<RenderMeshes>(); self.render_meshes = world.try_get_resource_data::<RenderMeshes>();
self.transform_buffers = world.try_get_resource_data::<TransformBuffers>(); self.transform_buffers = world.try_get_resource_data::<TransformBuffers>();
@ -245,7 +259,7 @@ impl Node for ShadowMapsPass {
if !self.depth_maps.contains_key(&entity) { if !self.depth_maps.contains_key(&entity) {
// TODO: dont pack the textures as they're added // TODO: dont pack the textures as they're added
let atlas_index = self.create_depth_map(graph.device(), entity, *pos); let atlas_index = self.create_depth_map(graph.device(), &context.queue, entity, *pos);
index_components_queue.push_back((entity, atlas_index)); index_components_queue.push_back((entity, atlas_index));
debug!("Created depth map for {:?} light entity", entity); debug!("Created depth map for {:?} light entity", entity);
@ -253,17 +267,13 @@ impl Node for ShadowMapsPass {
} }
// now consume from the queue adding the components to the entities // now consume from the queue adding the components to the entities
while let Some((entity, atlas_id)) = index_components_queue.pop_front() { while let Some((entity, depth)) = index_components_queue.pop_front() {
world.insert(entity, LightShadowMapId(atlas_id)); world.insert(entity, LightShadowMapId {
atlas_index: depth.atlas_index,
uniform_index: depth.uniform_index,
});
} }
// update the light projection buffer slot
let (_, dir_depth_map) = self.depth_maps.iter().next().unwrap();
let val = graph
.slot_value_mut(ShadowMapsPassSlots::ShadowLightUniformsBuffer)
.unwrap();
*val = SlotValue::Buffer(dir_depth_map.light_projection_buffer.clone());
if self.pipeline.is_none() { if self.pipeline.is_none() {
let shader = Rc::new(Shader { let shader = Rc::new(Shader {
label: Some("shader_shadows".into()), label: Some("shader_shadows".into()),
@ -348,6 +358,7 @@ impl Node for ShadowMapsPass {
}); });
pass.set_pipeline(&pipeline); pass.set_pipeline(&pipeline);
let viewport = atlas.texture_viewport(dir_depth_map.atlas_index); let viewport = atlas.texture_viewport(dir_depth_map.atlas_index);
debug!("Rendering shadow map to viewport: {viewport:?}, uniform index: {}", dir_depth_map.uniform_index);
// only render to the light's map in the atlas // only render to the light's map in the atlas
pass.set_viewport(viewport.offset.x as _, viewport.offset.y as _, viewport.size.x as _, viewport.size.y as _, 0.0, 1.0); pass.set_viewport(viewport.offset.x as _, viewport.offset.y as _, viewport.size.x as _, viewport.size.y as _, 0.0, 1.0);
// only clear the light map in the atlas // only clear the light map in the atlas
@ -362,7 +373,9 @@ impl Node for ShadowMapsPass {
} }
let buffers = buffers.unwrap(); let buffers = buffers.unwrap();
pass.set_bind_group(0, &dir_depth_map.bindgroup, &[]); let uniform_index = uniform_index_offset(&context.device.limits(), dir_depth_map.uniform_index);
//debug!("Uniform offset: {uniform_index}");
pass.set_bind_group(0, &self.uniforms_bg, &[uniform_index]);
// Get the bindgroup for job's transform and bind to it using an offset. // Get the bindgroup for job's transform and bind to it using an offset.
let bindgroup = transforms.bind_group(job.transform_id); let bindgroup = transforms.bind_group(job.transform_id);
@ -395,7 +408,7 @@ impl Node for ShadowMapsPass {
#[repr(C)] #[repr(C)]
#[derive(Debug, Copy, Clone, bytemuck::Pod, bytemuck::Zeroable)] #[derive(Debug, Copy, Clone, bytemuck::Pod, bytemuck::Zeroable)]
struct LightShadowUniform { pub struct LightShadowUniform {
space_mat: glam::Mat4, space_mat: glam::Mat4,
atlas_frame: AtlasViewport, // 2xUVec2 (4xf32), so no padding needed atlas_frame: AtlasViewport, // 2xUVec2 (4xf32), so no padding needed
} }
@ -405,13 +418,18 @@ struct LightShadowUniform {
/// An entity owns a light. If that light casts shadows, this will contain the ID of the shadow /// An entity owns a light. If that light casts shadows, this will contain the ID of the shadow
/// map inside of the [`TextureAtlas`]. /// map inside of the [`TextureAtlas`].
#[derive(Debug, Default, Copy, Clone, Component)] #[derive(Debug, Default, Copy, Clone, Component)]
pub struct LightShadowMapId(u64); pub struct LightShadowMapId {
atlas_index: u64,
uniform_index: u64,
}
impl Deref for LightShadowMapId { impl LightShadowMapId {
type Target = u64; pub fn atlas_index(&self) -> u64 {
self.atlas_index
}
fn deref(&self) -> &Self::Target { pub fn uniform_index(&self) -> u64 {
&self.0 self.uniform_index
} }
} }
@ -428,3 +446,8 @@ impl LightShadowMapAtlas {
self.0.write().unwrap() self.0.write().unwrap()
} }
} }
fn uniform_index_offset(limits: &wgpu::Limits, uniform_idx: u64) -> u32 {
let t = uniform_idx as u32 % (limits.max_storage_buffer_binding_size / mem::size_of::<LightShadowUniform>() as u32);
t * limits.min_uniform_buffer_offset_alignment
}

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@ -12,6 +12,8 @@ use crate::math::Transform;
use self::directional::DirectionalLight; use self::directional::DirectionalLight;
use super::graph::LightShadowMapId;
const MAX_LIGHT_COUNT: usize = 16; const MAX_LIGHT_COUNT: usize = 16;
/// A struct that stores a list of lights in a wgpu::Buffer. /// A struct that stores a list of lights in a wgpu::Buffer.
@ -166,18 +168,21 @@ impl LightUniformBuffers {
let _ = world_tick; let _ = world_tick;
let mut lights = vec![]; let mut lights = vec![];
for (point_light, transform) in world.view_iter::<(&PointLight, &Transform)>() { for (point_light, transform, shadow_map_id) in world.view_iter::<(&PointLight, &Transform, Option<&LightShadowMapId>)>() {
let uniform = LightUniform::from_point_light_bundle(&point_light, &transform); let shadow_map_id = shadow_map_id.map(|m| m.clone());
let uniform = LightUniform::from_point_light_bundle(&point_light, &transform, shadow_map_id);
lights.push(uniform); lights.push(uniform);
} }
for (spot_light, transform) in world.view_iter::<(&SpotLight, &Transform)>() { for (spot_light, transform, shadow_map_id) in world.view_iter::<(&SpotLight, &Transform, Option<&LightShadowMapId>)>() {
let uniform = LightUniform::from_spot_light_bundle(&spot_light, &transform); let shadow_map_id = shadow_map_id.map(|m| m.clone());
let uniform = LightUniform::from_spot_light_bundle(&spot_light, &transform, shadow_map_id);
lights.push(uniform); lights.push(uniform);
} }
for (dir_light, transform) in world.view_iter::<(&DirectionalLight, &Transform)>() { for (dir_light, transform, shadow_map_id) in world.view_iter::<(&DirectionalLight, &Transform, Option<&LightShadowMapId>)>() {
let uniform = LightUniform::from_directional_bundle(&dir_light, &transform); let shadow_map_id = shadow_map_id.map(|m| m.clone());
let uniform = LightUniform::from_directional_bundle(&dir_light, &transform, shadow_map_id);
lights.push(uniform); lights.push(uniform);
} }
@ -216,10 +221,11 @@ pub(crate) struct LightUniform {
pub spot_cutoff_rad: f32, pub spot_cutoff_rad: f32,
pub spot_outer_cutoff_rad: f32, pub spot_outer_cutoff_rad: f32,
pub light_shadow_uniform_index: i32,
} }
impl LightUniform { impl LightUniform {
pub fn from_point_light_bundle(light: &PointLight, transform: &Transform) -> Self { pub fn from_point_light_bundle(light: &PointLight, transform: &Transform, map_id: Option<LightShadowMapId>) -> Self {
Self { Self {
light_type: LightType::Point as u32, light_type: LightType::Point as u32,
enabled: light.enabled as u32, enabled: light.enabled as u32,
@ -233,11 +239,12 @@ impl LightUniform {
spot_cutoff_rad: 0.0, spot_cutoff_rad: 0.0,
spot_outer_cutoff_rad: 0.0, spot_outer_cutoff_rad: 0.0,
light_shadow_uniform_index: map_id.map(|m| m.uniform_index() as i32).unwrap_or(-1),
} }
} }
pub fn from_directional_bundle(light: &DirectionalLight, transform: &Transform) -> Self { pub fn from_directional_bundle(light: &DirectionalLight, transform: &Transform, map_id: Option<LightShadowMapId>) -> Self {
Self { Self {
light_type: LightType::Directional as u32, light_type: LightType::Directional as u32,
enabled: light.enabled as u32, enabled: light.enabled as u32,
@ -251,11 +258,12 @@ impl LightUniform {
spot_cutoff_rad: 0.0, spot_cutoff_rad: 0.0,
spot_outer_cutoff_rad: 0.0, spot_outer_cutoff_rad: 0.0,
light_shadow_uniform_index: map_id.map(|m| m.uniform_index() as i32).unwrap_or(-1),
} }
} }
// Create the SpotLightUniform from an ECS bundle // Create the SpotLightUniform from an ECS bundle
pub fn from_spot_light_bundle(light: &SpotLight, transform: &Transform) -> Self { pub fn from_spot_light_bundle(light: &SpotLight, transform: &Transform, map_id: Option<LightShadowMapId>) -> Self {
Self { Self {
light_type: LightType::Spotlight as u32, light_type: LightType::Spotlight as u32,
enabled: light.enabled as u32, enabled: light.enabled as u32,
@ -269,6 +277,7 @@ impl LightUniform {
spot_cutoff_rad: light.cutoff.to_radians(), spot_cutoff_rad: light.cutoff.to_radians(),
spot_outer_cutoff_rad: light.outer_cutoff.to_radians(), spot_outer_cutoff_rad: light.outer_cutoff.to_radians(),
light_shadow_uniform_index: map_id.map(|m| m.uniform_index() as i32).unwrap_or(-1),
} }
} }
} }

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@ -54,6 +54,7 @@ struct Light {
spot_cutoff: f32, spot_cutoff: f32,
spot_outer_cutoff: f32, spot_outer_cutoff: f32,
light_shadow_uniform_index: i32,
}; };
struct Lights { struct Lights {
@ -85,9 +86,7 @@ fn vs_main(
// the normal mat is actually only a mat3x3, but there's a bug in wgpu: https://github.com/gfx-rs/wgpu-rs/issues/36 // the normal mat is actually only a mat3x3, but there's a bug in wgpu: https://github.com/gfx-rs/wgpu-rs/issues/36
let normal_mat4 = u_model_transform_data.normal_matrix; let normal_mat4 = u_model_transform_data.normal_matrix;
let normal_mat = mat3x3(normal_mat4[0].xyz, normal_mat4[1].xyz, normal_mat4[2].xyz); let normal_mat = mat3x3(normal_mat4[0].xyz, normal_mat4[1].xyz, normal_mat4[2].xyz);
out.world_normal = normalize(normal_mat * model.normal, ); out.world_normal = normalize(normal_mat * model.normal);
out.frag_pos_light_space = u_light_shadow.light_space_matrix * world_position;
return out; return out;
} }
@ -114,10 +113,15 @@ struct LightShadowMapUniform {
atlas_frame: TextureAtlasFrame, atlas_frame: TextureAtlasFrame,
} }
struct LightShadowMapUniformAligned {
@size(256)
inner: LightShadowMapUniform
}
@group(4) @binding(0) @group(4) @binding(0)
var<storage, read_write> u_light_indices: array<u32>; var<storage, read_write> u_light_indices: array<u32>;
@group(4) @binding(1) @group(4) @binding(1)
var t_light_grid: texture_storage_2d<rg32uint, read_write>; // vec2<u32> var t_light_grid: texture_storage_2d<rg32uint, read_write>; // rg32uint = vec2<u32>
@group(5) @binding(0) @group(5) @binding(0)
var t_shadow_maps_atlas: texture_depth_2d; var t_shadow_maps_atlas: texture_depth_2d;
@ -126,7 +130,7 @@ var s_shadow_maps_atlas: sampler;
@group(5) @binding(2) @group(5) @binding(2)
var<uniform> u_shadow_maps_atlas_size: vec2<u32>; var<uniform> u_shadow_maps_atlas_size: vec2<u32>;
@group(5) @binding(3) @group(5) @binding(3)
var<uniform> u_light_shadow: LightShadowMapUniform; var<storage, read> u_light_shadow: array<LightShadowMapUniformAligned>;
@fragment @fragment
fn fs_main(in: VertexOutput) -> @location(0) vec4<f32> { fn fs_main(in: VertexOutput) -> @location(0) vec4<f32> {
@ -148,13 +152,18 @@ fn fs_main(in: VertexOutput) -> @location(0) vec4<f32> {
let light_offset = tile.x; let light_offset = tile.x;
let light_count = tile.y; let light_count = tile.y;
let atlas_dimensions: vec2<i32> = textureDimensions(t_shadow_maps_atlas);
for (var i = 0u; i < light_count; i++) { for (var i = 0u; i < light_count; i++) {
let light_index = u_light_indices[light_offset + i]; let light_index = u_light_indices[light_offset + i];
let light: Light = u_lights.data[light_index]; let light: Light = u_lights.data[light_index];
if (light.light_ty == LIGHT_TY_DIRECTIONAL) { if (light.light_ty == LIGHT_TY_DIRECTIONAL) {
let light_dir = normalize(-light.direction); let light_dir = normalize(-light.direction);
let shadow = calc_shadow(in.world_normal, light_dir, in.frag_pos_light_space, u_light_shadow.atlas_frame); let shadow_u: LightShadowMapUniform = u_light_shadow[light.light_shadow_uniform_index].inner;
let frag_pos_light_space = shadow_u.light_space_matrix * vec4<f32>(in.world_position, 1.0);
let shadow = calc_shadow(in.world_normal, light_dir, frag_pos_light_space, atlas_dimensions, shadow_u.atlas_frame);
light_res += blinn_phong_dir_light(in.world_position, in.world_normal, light, u_material, specular_color, shadow); light_res += blinn_phong_dir_light(in.world_position, in.world_normal, light, u_material, specular_color, shadow);
} else if (light.light_ty == LIGHT_TY_POINT) { } else if (light.light_ty == LIGHT_TY_POINT) {
light_res += blinn_phong_point_light(in.world_position, in.world_normal, light, u_material, specular_color); light_res += blinn_phong_point_light(in.world_position, in.world_normal, light, u_material, specular_color);
@ -167,7 +176,7 @@ fn fs_main(in: VertexOutput) -> @location(0) vec4<f32> {
return vec4<f32>(light_object_res, object_color.a); return vec4<f32>(light_object_res, object_color.a);
} }
fn calc_shadow(normal: vec3<f32>, light_dir: vec3<f32>, frag_pos_light_space: vec4<f32>, atlas_region: TextureAtlasFrame) -> f32 { fn calc_shadow(normal: vec3<f32>, light_dir: vec3<f32>, frag_pos_light_space: vec4<f32>, atlas_dimensions: vec2<i32>, atlas_region: TextureAtlasFrame) -> f32 {
var proj_coords = frag_pos_light_space.xyz / frag_pos_light_space.w; var proj_coords = frag_pos_light_space.xyz / frag_pos_light_space.w;
// for some reason the y component is clipped after transforming // for some reason the y component is clipped after transforming
proj_coords.y = -proj_coords.y; proj_coords.y = -proj_coords.y;
@ -181,8 +190,8 @@ fn calc_shadow(normal: vec3<f32>, light_dir: vec3<f32>, frag_pos_light_space: ve
let xy_remapped = proj_coords.xy * 0.5 + 0.5; let xy_remapped = proj_coords.xy * 0.5 + 0.5;
// no need to get the y since the maps are square // no need to get the y since the maps are square
let atlas_start = f32(atlas_region.offset.x) / f32(u_shadow_maps_atlas_size.x); let atlas_start = f32(atlas_region.offset.x) / f32(atlas_dimensions.x);
let atlas_end = f32(atlas_region.offset.x + atlas_region.size.x) / f32(u_shadow_maps_atlas_size.x); let atlas_end = f32(atlas_region.offset.x + atlas_region.size.x) / f32(atlas_dimensions.x);
// lerp the tex coords to the shadow map for this light. // lerp the tex coords to the shadow map for this light.
proj_coords.x = mix(atlas_start, atlas_end, xy_remapped.x); proj_coords.x = mix(atlas_start, atlas_end, xy_remapped.x);
proj_coords.y = mix(atlas_start, atlas_end, xy_remapped.y); proj_coords.y = mix(atlas_start, atlas_end, xy_remapped.y);
@ -195,7 +204,7 @@ fn calc_shadow(normal: vec3<f32>, light_dir: vec3<f32>, frag_pos_light_space: ve
// must manually apply offset to the texture coords since `textureSampleLevel` requires a // must manually apply offset to the texture coords since `textureSampleLevel` requires a
// const value. // const value.
let offset_coords = proj_coords.xy + (vec2<f32>(atlas_region.offset) / vec2<f32>(u_shadow_maps_atlas_size)); let offset_coords = proj_coords.xy + (vec2<f32>(atlas_region.offset) / vec2<f32>(atlas_dimensions));
let closest_depth = textureSampleLevel(t_shadow_maps_atlas, s_shadow_maps_atlas, offset_coords, 0.0); let closest_depth = textureSampleLevel(t_shadow_maps_atlas, s_shadow_maps_atlas, offset_coords, 0.0);
let current_depth = proj_coords.z; let current_depth = proj_coords.z;

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@ -14,7 +14,7 @@ struct LightShadowMapUniform {
} }
@group(0) @binding(0) @group(0) @binding(0)
var<uniform> u_light_shadow: LightShadowMapUniform; var<storage, read> u_light_shadow: LightShadowMapUniform;
@group(1) @binding(0) @group(1) @binding(0)
var<uniform> u_model_transform_data: TransformData; var<uniform> u_model_transform_data: TransformData;