shader/binning.wgsl - external/github.com/linebender/vello - Git at Google

 // SPDX-License-Identifier: Apache-2.0 OR MIT OR Unlicense

 // The binning stage

 #import config
 #import drawtag
 #import bbox
 #import bump

 @group(0) @binding(0)
 var<uniform> config: Config;

 @group(0) @binding(1)
 var<storage> draw_monoids: array<DrawMonoid>;

 @group(0) @binding(2)
 var<storage> path_bbox_buf: array<PathBbox>;

 @group(0) @binding(3)
 var<storage> clip_bbox_buf: array<vec4<f32>>;

 @group(0) @binding(4)
 var<storage, read_write> intersected_bbox: array<vec4<f32>>;

 @group(0) @binding(5)
 var<storage, read_write> bump: BumpAllocators;

 @group(0) @binding(6)
 var<storage, read_write> bin_data: array<u32>;

 // TODO: put in common place
 struct BinHeader {
     element_count: u32,
     chunk_offset: u32,
 }

 @group(0) @binding(7)
 var<storage, read_write> bin_header: array<BinHeader>;

 // conversion factors from coordinates to bin
 let SX = 0.00390625;
 let SY = 0.00390625;
 //let SX = 1.0 / f32(N_TILE_X * TILE_WIDTH);
 //let SY = 1.0 / f32(N_TILE_Y * TILE_HEIGHT);

 let WG_SIZE = 256u;
 let N_SLICE = 8u;
 //let N_SLICE = WG_SIZE / 32u;
 let N_SUBSLICE = 4u;

 var<workgroup> sh_bitmaps: array<array<atomic<u32>, N_TILE>, N_SLICE>;
 // store count values packed two u16's to a u32
 var<workgroup> sh_count: array<array<u32, N_TILE>, N_SUBSLICE>;
 var<workgroup> sh_chunk_offset: array<u32, N_TILE>;

 @compute @workgroup_size(256)
 fn main(
     @builtin(global_invocation_id) global_id: vec3<u32>,
     @builtin(local_invocation_id) local_id: vec3<u32>,
     @builtin(workgroup_id) wg_id: vec3<u32>,
 ) {
     for (var i = 0u; i < N_SLICE; i += 1u) {
         atomicStore(&sh_bitmaps[i][local_id.x], 0u);
     }
     workgroupBarrier();

     // Read inputs and determine coverage of bins
     let element_ix = global_id.x;
     var x0 = 0;
     var y0 = 0;
     var x1 = 0;
     var y1 = 0;
     if element_ix < config.n_drawobj {
         let draw_monoid = draw_monoids[element_ix];
         var clip_bbox = vec4(-1e9, -1e9, 1e9, 1e9);
         if draw_monoid.clip_ix > 0u {
             clip_bbox = clip_bbox_buf[draw_monoid.clip_ix - 1u];
         }
         // For clip elements, clip_box is the bbox of the clip path,
         // intersected with enclosing clips.
         // For other elements, it is the bbox of the enclosing clips.
         // TODO check this is true

         let path_bbox = path_bbox_buf[draw_monoid.path_ix];
         let pb = vec4<f32>(vec4(path_bbox.x0, path_bbox.y0, path_bbox.x1, path_bbox.y1));
         let bbox_raw = bbox_intersect(clip_bbox, pb);
         // TODO(naga): clunky expression a workaround for broken lhs swizzle
         let bbox = vec4(bbox_raw.xy, max(bbox_raw.xy, bbox_raw.zw));

         intersected_bbox[element_ix] = bbox;
         x0 = i32(floor(bbox.x * SX));
         y0 = i32(floor(bbox.y * SY));
         x1 = i32(ceil(bbox.z * SX));
         y1 = i32(ceil(bbox.w * SY));
     }
     let width_in_bins = i32((config.width_in_tiles + N_TILE_X - 1u) / N_TILE_X);
     let height_in_bins = i32((config.height_in_tiles + N_TILE_Y - 1u) / N_TILE_Y);
     x0 = clamp(x0, 0, width_in_bins);
     y0 = clamp(y0, 0, height_in_bins);
     x1 = clamp(x1, 0, width_in_bins);
     y1 = clamp(y1, 0, height_in_bins);
     if x0 == x1 {
         y1 = y0;
     }
     var x = x0;
     var y = y0;
     let my_slice = local_id.x / 32u;
     let my_mask = 1u << (local_id.x & 31u);
     while y < y1 {
         atomicOr(&sh_bitmaps[my_slice][y * width_in_bins + x], my_mask);
         x += 1;
         if x == x1 {
             x = x0;
             y += 1;
         }
     }

     workgroupBarrier();
     // Allocate output segments
     var element_count = 0u;
     for (var i = 0u; i < N_SUBSLICE; i += 1u) {
         element_count += countOneBits(atomicLoad(&sh_bitmaps[i * 2u][local_id.x]));
         let element_count_lo = element_count;
         element_count += countOneBits(atomicLoad(&sh_bitmaps[i * 2u + 1u][local_id.x]));
         let element_count_hi = element_count;
         let element_count_packed = element_count_lo | (element_count_hi << 16u);
         sh_count[i][local_id.x] = element_count_packed;
     }
     // element_count is the number of draw objects covering this thread's bin
     let chunk_offset = atomicAdd(&bump.binning, element_count);
     sh_chunk_offset[local_id.x] = chunk_offset;
     bin_header[global_id.x].element_count = element_count;
     bin_header[global_id.x].chunk_offset = chunk_offset;
     workgroupBarrier();

     // loop over bbox of bins touched by this draw object
     x = x0;
     y = y0;
     while y < y1 {
         let bin_ix = y * width_in_bins + x;
         let out_mask = atomicLoad(&sh_bitmaps[my_slice][bin_ix]);
         // I think this predicate will always be true...
         if (out_mask & my_mask) != 0u {
             var idx = countOneBits(out_mask & (my_mask - 1u));
             if my_slice > 0u {
                 let count_ix = my_slice - 1u;
                 let count_packed = sh_count[count_ix / 2u][bin_ix];
                 idx += (count_packed >> (16u * (count_ix & 1u))) & 0xffffu;
             }
             let offset = config.bin_data_start + sh_chunk_offset[bin_ix];
             bin_data[offset + idx] = element_ix;
         }
         x += 1;
         if x == x1 {
             x = x0;
             y += 1;
         }
     }
 }
	// SPDX-License-Identifier: Apache-2.0 OR MIT OR Unlicense

	// The binning stage

	#import config
	#import drawtag
	#import bbox
	#import bump

	@group(0) @binding(0)
	var<uniform> config: Config;

	@group(0) @binding(1)
	var<storage> draw_monoids: array<DrawMonoid>;

	@group(0) @binding(2)
	var<storage> path_bbox_buf: array<PathBbox>;

	@group(0) @binding(3)
	var<storage> clip_bbox_buf: array<vec4<f32>>;

	@group(0) @binding(4)
	var<storage, read_write> intersected_bbox: array<vec4<f32>>;

	@group(0) @binding(5)
	var<storage, read_write> bump: BumpAllocators;

	@group(0) @binding(6)
	var<storage, read_write> bin_data: array<u32>;

	// TODO: put in common place
	struct BinHeader {
	element_count: u32,
	chunk_offset: u32,
	}

	@group(0) @binding(7)
	var<storage, read_write> bin_header: array<BinHeader>;

	// conversion factors from coordinates to bin
	let SX = 0.00390625;
	let SY = 0.00390625;
	//let SX = 1.0 / f32(N_TILE_X * TILE_WIDTH);
	//let SY = 1.0 / f32(N_TILE_Y * TILE_HEIGHT);

	let WG_SIZE = 256u;
	let N_SLICE = 8u;
	//let N_SLICE = WG_SIZE / 32u;
	let N_SUBSLICE = 4u;

	var<workgroup> sh_bitmaps: array<array<atomic<u32>, N_TILE>, N_SLICE>;
	// store count values packed two u16's to a u32
	var<workgroup> sh_count: array<array<u32, N_TILE>, N_SUBSLICE>;
	var<workgroup> sh_chunk_offset: array<u32, N_TILE>;

	@compute @workgroup_size(256)
	fn main(
	@builtin(global_invocation_id) global_id: vec3<u32>,
	@builtin(local_invocation_id) local_id: vec3<u32>,
	@builtin(workgroup_id) wg_id: vec3<u32>,
	) {
	for (var i = 0u; i < N_SLICE; i += 1u) {
	atomicStore(&sh_bitmaps[i][local_id.x], 0u);
	}
	workgroupBarrier();

	// Read inputs and determine coverage of bins
	let element_ix = global_id.x;
	var x0 = 0;
	var y0 = 0;
	var x1 = 0;
	var y1 = 0;
	if element_ix < config.n_drawobj {
	let draw_monoid = draw_monoids[element_ix];
	var clip_bbox = vec4(-1e9, -1e9, 1e9, 1e9);
	if draw_monoid.clip_ix > 0u {
	clip_bbox = clip_bbox_buf[draw_monoid.clip_ix - 1u];
	}
	// For clip elements, clip_box is the bbox of the clip path,
	// intersected with enclosing clips.
	// For other elements, it is the bbox of the enclosing clips.
	// TODO check this is true

	let path_bbox = path_bbox_buf[draw_monoid.path_ix];
	let pb = vec4<f32>(vec4(path_bbox.x0, path_bbox.y0, path_bbox.x1, path_bbox.y1));
	let bbox_raw = bbox_intersect(clip_bbox, pb);
	// TODO(naga): clunky expression a workaround for broken lhs swizzle
	let bbox = vec4(bbox_raw.xy, max(bbox_raw.xy, bbox_raw.zw));

	intersected_bbox[element_ix] = bbox;
	x0 = i32(floor(bbox.x * SX));
	y0 = i32(floor(bbox.y * SY));
	x1 = i32(ceil(bbox.z * SX));
	y1 = i32(ceil(bbox.w * SY));
	}
	let width_in_bins = i32((config.width_in_tiles + N_TILE_X - 1u) / N_TILE_X);
	let height_in_bins = i32((config.height_in_tiles + N_TILE_Y - 1u) / N_TILE_Y);
	x0 = clamp(x0, 0, width_in_bins);
	y0 = clamp(y0, 0, height_in_bins);
	x1 = clamp(x1, 0, width_in_bins);
	y1 = clamp(y1, 0, height_in_bins);
	if x0 == x1 {
	y1 = y0;
	}
	var x = x0;
	var y = y0;
	let my_slice = local_id.x / 32u;
	let my_mask = 1u << (local_id.x & 31u);
	while y < y1 {
	atomicOr(&sh_bitmaps[my_slice][y * width_in_bins + x], my_mask);
	x += 1;
	if x == x1 {
	x = x0;
	y += 1;
	}
	}

	workgroupBarrier();
	// Allocate output segments
	var element_count = 0u;
	for (var i = 0u; i < N_SUBSLICE; i += 1u) {
	element_count += countOneBits(atomicLoad(&sh_bitmaps[i * 2u][local_id.x]));
	let element_count_lo = element_count;
	element_count += countOneBits(atomicLoad(&sh_bitmaps[i * 2u + 1u][local_id.x]));
	let element_count_hi = element_count;
	let element_count_packed = element_count_lo \| (element_count_hi << 16u);
	sh_count[i][local_id.x] = element_count_packed;
	}
	// element_count is the number of draw objects covering this thread's bin
	let chunk_offset = atomicAdd(&bump.binning, element_count);
	sh_chunk_offset[local_id.x] = chunk_offset;
	bin_header[global_id.x].element_count = element_count;
	bin_header[global_id.x].chunk_offset = chunk_offset;
	workgroupBarrier();

	// loop over bbox of bins touched by this draw object
	x = x0;
	y = y0;
	while y < y1 {
	let bin_ix = y * width_in_bins + x;
	let out_mask = atomicLoad(&sh_bitmaps[my_slice][bin_ix]);
	// I think this predicate will always be true...
	if (out_mask & my_mask) != 0u {
	var idx = countOneBits(out_mask & (my_mask - 1u));
	if my_slice > 0u {
	let count_ix = my_slice - 1u;
	let count_packed = sh_count[count_ix / 2u][bin_ix];
	idx += (count_packed >> (16u * (count_ix & 1u))) & 0xffffu;
	}
	let offset = config.bin_data_start + sh_chunk_offset[bin_ix];
	bin_data[offset + idx] = element_ix;
	}
	x += 1;
	if x == x1 {
	x = x0;
	y += 1;
	}
	}
	}