test/benchmark/cluster-lights.wgsl - tint - Git at Google

 struct Camera {
   projection : mat4x4<f32>;
   inverseProjection : mat4x4<f32>;
   view : mat4x4<f32>;
   position : vec3<f32>;
   time : f32;
   outputSize : vec2<f32>;
   zNear : f32;
   zFar : f32;
 }

 @group(0) @binding(0) var<uniform> camera : Camera;

 struct ClusterBounds {
   minAABB : vec3<f32>;
   maxAABB : vec3<f32>;
 }

 struct Clusters {
   bounds : array<ClusterBounds, 27648>;
 }

 @group(0) @binding(1) var<storage, read> clusters : Clusters;

 struct ClusterLights {
   offset : u32;
   count : u32;
 }

 struct ClusterLightGroup {
   offset : atomic<u32>;
   lights : array<ClusterLights, 27648>;
   indices : array<u32, 1769472>;
 }

 @group(0) @binding(2) var<storage, read_write> clusterLights : ClusterLightGroup;

 struct Light {
   position : vec3<f32>;
   range : f32;
   color : vec3<f32>;
   intensity : f32;
 }

 struct GlobalLights {
   ambient : vec3<f32>;
   dirColor : vec3<f32>;
   dirIntensity : f32;
   dirDirection : vec3<f32>;
   lightCount : u32;
   lights : array<Light>;
 }

 @group(0) @binding(3) var<storage, read> globalLights : GlobalLights;

 let tileCount = vec3(32u, 18u, 48u);

 fn linearDepth(depthSample : f32) -> f32 {
   return ((camera.zFar * camera.zNear) / fma(depthSample, (camera.zNear - camera.zFar), camera.zFar));
 }

 fn getTile(fragCoord : vec4<f32>) -> vec3<u32> {
   let sliceScale = (f32(tileCount.z) / log2((camera.zFar / camera.zNear)));
   let sliceBias = -(((f32(tileCount.z) * log2(camera.zNear)) / log2((camera.zFar / camera.zNear))));
   let zTile = u32(max(((log2(linearDepth(fragCoord.z)) * sliceScale) + sliceBias), 0.0));
   return vec3(u32((fragCoord.x / (camera.outputSize.x / f32(tileCount.x)))), u32((fragCoord.y / (camera.outputSize.y / f32(tileCount.y)))), zTile);
 }

 fn getClusterIndex(fragCoord : vec4<f32>) -> u32 {
   let tile = getTile(fragCoord);
   return ((tile.x + (tile.y * tileCount.x)) + ((tile.z * tileCount.x) * tileCount.y));
 }

 fn sqDistPointAABB(point : vec3<f32>, minAABB : vec3<f32>, maxAABB : vec3<f32>) -> f32 {
   var sqDist = 0.0;
   for(var i : i32 = 0; (i < 3); i = (i + 1)) {
     let v = point[i];
     if ((v < minAABB[i])) {
       sqDist = (sqDist + ((minAABB[i] - v) * (minAABB[i] - v)));
     }
     if ((v > maxAABB[i])) {
       sqDist = (sqDist + ((v - maxAABB[i]) * (v - maxAABB[i])));
     }
   }
   return sqDist;
 }

 @stage(compute) @workgroup_size(4, 2, 4)
 fn computeMain(@builtin(global_invocation_id) global_id : vec3<u32>) {
   let tileIndex = ((global_id.x + (global_id.y * tileCount.x)) + ((global_id.z * tileCount.x) * tileCount.y));
   var clusterLightCount = 0u;
   var cluserLightIndices : array<u32, 256>;
   for(var i = 0u; (i < globalLights.lightCount); i = (i + 1u)) {
     let range = globalLights.lights[i].range;
     var lightInCluster : bool = (range <= 0.0);
     if (!(lightInCluster)) {
       let lightViewPos = (camera.view * vec4(globalLights.lights[i].position, 1.0));
       let sqDist = sqDistPointAABB(lightViewPos.xyz, clusters.bounds[tileIndex].minAABB, clusters.bounds[tileIndex].maxAABB);
       lightInCluster = (sqDist <= (range * range));
     }
     if (lightInCluster) {
       cluserLightIndices[clusterLightCount] = i;
       clusterLightCount = (clusterLightCount + 1u);
     }
     if ((clusterLightCount == 256u)) {
       break;
     }
   }
   let lightCount = clusterLightCount;
   var offset = atomicAdd(&(clusterLights.offset), lightCount);
   if ((offset >= 1769472u)) {
     return;
   }
   for(var i = 0u; (i < clusterLightCount); i = (i + 1u)) {
     clusterLights.indices[(offset + i)] = cluserLightIndices[i];
   }
   clusterLights.lights[tileIndex].offset = offset;
   clusterLights.lights[tileIndex].count = clusterLightCount;
 }
	struct Camera {
	projection : mat4x4<f32>;
	inverseProjection : mat4x4<f32>;
	view : mat4x4<f32>;
	position : vec3<f32>;
	time : f32;
	outputSize : vec2<f32>;
	zNear : f32;
	zFar : f32;
	}

	@group(0) @binding(0) var<uniform> camera : Camera;

	struct ClusterBounds {
	minAABB : vec3<f32>;
	maxAABB : vec3<f32>;
	}

	struct Clusters {
	bounds : array<ClusterBounds, 27648>;
	}

	@group(0) @binding(1) var<storage, read> clusters : Clusters;

	struct ClusterLights {
	offset : u32;
	count : u32;
	}

	struct ClusterLightGroup {
	offset : atomic<u32>;
	lights : array<ClusterLights, 27648>;
	indices : array<u32, 1769472>;
	}

	@group(0) @binding(2) var<storage, read_write> clusterLights : ClusterLightGroup;

	struct Light {
	position : vec3<f32>;
	range : f32;
	color : vec3<f32>;
	intensity : f32;
	}

	struct GlobalLights {
	ambient : vec3<f32>;
	dirColor : vec3<f32>;
	dirIntensity : f32;
	dirDirection : vec3<f32>;
	lightCount : u32;
	lights : array<Light>;
	}

	@group(0) @binding(3) var<storage, read> globalLights : GlobalLights;

	let tileCount = vec3(32u, 18u, 48u);

	fn linearDepth(depthSample : f32) -> f32 {
	return ((camera.zFar * camera.zNear) / fma(depthSample, (camera.zNear - camera.zFar), camera.zFar));
	}

	fn getTile(fragCoord : vec4<f32>) -> vec3<u32> {
	let sliceScale = (f32(tileCount.z) / log2((camera.zFar / camera.zNear)));
	let sliceBias = -(((f32(tileCount.z) * log2(camera.zNear)) / log2((camera.zFar / camera.zNear))));
	let zTile = u32(max(((log2(linearDepth(fragCoord.z)) * sliceScale) + sliceBias), 0.0));
	return vec3(u32((fragCoord.x / (camera.outputSize.x / f32(tileCount.x)))), u32((fragCoord.y / (camera.outputSize.y / f32(tileCount.y)))), zTile);
	}

	fn getClusterIndex(fragCoord : vec4<f32>) -> u32 {
	let tile = getTile(fragCoord);
	return ((tile.x + (tile.y * tileCount.x)) + ((tile.z * tileCount.x) * tileCount.y));
	}

	fn sqDistPointAABB(point : vec3<f32>, minAABB : vec3<f32>, maxAABB : vec3<f32>) -> f32 {
	var sqDist = 0.0;
	for(var i : i32 = 0; (i < 3); i = (i + 1)) {
	let v = point[i];
	if ((v < minAABB[i])) {
	sqDist = (sqDist + ((minAABB[i] - v) * (minAABB[i] - v)));
	}
	if ((v > maxAABB[i])) {
	sqDist = (sqDist + ((v - maxAABB[i]) * (v - maxAABB[i])));
	}
	}
	return sqDist;
	}

	@stage(compute) @workgroup_size(4, 2, 4)
	fn computeMain(@builtin(global_invocation_id) global_id : vec3<u32>) {
	let tileIndex = ((global_id.x + (global_id.y * tileCount.x)) + ((global_id.z * tileCount.x) * tileCount.y));
	var clusterLightCount = 0u;
	var cluserLightIndices : array<u32, 256>;
	for(var i = 0u; (i < globalLights.lightCount); i = (i + 1u)) {
	let range = globalLights.lights[i].range;
	var lightInCluster : bool = (range <= 0.0);
	if (!(lightInCluster)) {
	let lightViewPos = (camera.view * vec4(globalLights.lights[i].position, 1.0));
	let sqDist = sqDistPointAABB(lightViewPos.xyz, clusters.bounds[tileIndex].minAABB, clusters.bounds[tileIndex].maxAABB);
	lightInCluster = (sqDist <= (range * range));
	}
	if (lightInCluster) {
	cluserLightIndices[clusterLightCount] = i;
	clusterLightCount = (clusterLightCount + 1u);
	}
	if ((clusterLightCount == 256u)) {
	break;
	}
	}
	let lightCount = clusterLightCount;
	var offset = atomicAdd(&(clusterLights.offset), lightCount);
	if ((offset >= 1769472u)) {
	return;
	}
	for(var i = 0u; (i < clusterLightCount); i = (i + 1u)) {
	clusterLights.indices[(offset + i)] = cluserLightIndices[i];
	}
	clusterLights.lights[tileIndex].offset = offset;
	clusterLights.lights[tileIndex].count = clusterLightCount;
	}