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

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

 // The coarse rasterization stage.

 #import config
 #import bump
 #import drawtag
 #import ptcl
 #import tile

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

 @group(0) @binding(1)
 var<storage> scene: array<u32>;

 @group(0) @binding(2)
 var<storage> draw_monoids: array<DrawMonoid>;

 // TODO: dedup
 struct BinHeader {
     element_count: u32,
     chunk_offset: u32,
 }

 @group(0) @binding(3)
 var<storage> bin_headers: array<BinHeader>;

 @group(0) @binding(4)
 var<storage> info_bin_data: array<u32>;

 @group(0) @binding(5)
 var<storage> paths: array<Path>;

 @group(0) @binding(6)
 var<storage> tiles: array<Tile>;

 @group(0) @binding(7)
 var<storage, read_write> bump: BumpAllocators;

 @group(0) @binding(8)
 var<storage, read_write> ptcl: array<u32>;


 // Much of this code assumes WG_SIZE == N_TILE. If these diverge, then
 // a fair amount of fixup is needed.
 let WG_SIZE = 256u;
 //let N_SLICE = WG_SIZE / 32u;
 let N_SLICE = 8u;

 var<workgroup> sh_bitmaps: array<array<atomic<u32>, N_TILE>, N_SLICE>;
 var<workgroup> sh_part_count: array<u32, WG_SIZE>;
 var<workgroup> sh_part_offsets: array<u32, WG_SIZE>;
 var<workgroup> sh_drawobj_ix: array<u32, WG_SIZE>;
 var<workgroup> sh_tile_stride: array<u32, WG_SIZE>;
 var<workgroup> sh_tile_width: array<u32, WG_SIZE>;
 var<workgroup> sh_tile_x0y0: array<u32, WG_SIZE>;
 var<workgroup> sh_tile_count: array<u32, WG_SIZE>;
 var<workgroup> sh_tile_base: array<u32, WG_SIZE>;

 // helper functions for writing ptcl

 var<private> cmd_offset: u32;
 var<private> cmd_limit: u32;

 // Make sure there is space for a command of given size, plus a jump if needed
 fn alloc_cmd(size: u32) {
     if cmd_offset + size >= cmd_limit {
         // We might be able to save a little bit of computation here
         // by setting the initial value of the bump allocator.
         let ptcl_dyn_start = config.width_in_tiles * config.height_in_tiles * PTCL_INITIAL_ALLOC;
         let new_cmd = ptcl_dyn_start + atomicAdd(&bump.ptcl, PTCL_INCREMENT);
         // TODO: robust memory
         ptcl[cmd_offset] = CMD_JUMP;
         ptcl[cmd_offset + 1u] = new_cmd;
         cmd_offset = new_cmd;
         cmd_limit = cmd_offset + (PTCL_INCREMENT - PTCL_HEADROOM);
     }
 }

 fn write_path(tile: Tile, linewidth: f32) {
     // TODO: take flags
     alloc_cmd(3u);
     if linewidth < 0.0 {
         if tile.segments != 0u {
             let fill = CmdFill(tile.segments, tile.backdrop);
             ptcl[cmd_offset] = CMD_FILL;
             ptcl[cmd_offset + 1u] = fill.tile;
             ptcl[cmd_offset + 2u] = u32(fill.backdrop);
             cmd_offset += 3u;
         } else {
             ptcl[cmd_offset] = CMD_SOLID;
             cmd_offset += 1u;
         }
     } else {
         let stroke = CmdStroke(tile.segments, 0.5 * linewidth);
         ptcl[cmd_offset] = CMD_STROKE;
         ptcl[cmd_offset + 1u] = stroke.tile;
         ptcl[cmd_offset + 2u] = bitcast<u32>(stroke.half_width);
         cmd_offset += 3u;
     }
 }

 fn write_color(color: CmdColor) {
     alloc_cmd(2u);
     ptcl[cmd_offset] = CMD_COLOR;
     ptcl[cmd_offset + 1u] = color.rgba_color;
     cmd_offset += 2u;
 }

 fn write_grad(ty: u32, index: u32, info_offset: u32) {
     alloc_cmd(3u);
     ptcl[cmd_offset] = ty;
     ptcl[cmd_offset + 1u] = index;
     ptcl[cmd_offset + 2u] = info_offset;
     cmd_offset += 3u;
 }

 fn write_begin_clip() {
     alloc_cmd(1u);
     ptcl[cmd_offset] = CMD_BEGIN_CLIP;
     cmd_offset += 1u;
 }

 fn write_end_clip(end_clip: CmdEndClip) {
     alloc_cmd(3u);
     ptcl[cmd_offset] = CMD_END_CLIP;
     ptcl[cmd_offset + 1u] = end_clip.blend;
     ptcl[cmd_offset + 2u] = bitcast<u32>(end_clip.alpha);
     cmd_offset += 3u;
 }

 @compute @workgroup_size(256)
 fn main(
     @builtin(local_invocation_id) local_id: vec3<u32>,
     @builtin(workgroup_id) wg_id: vec3<u32>,
 ) {
     let width_in_bins = (config.width_in_tiles + N_TILE_X - 1u) / N_TILE_X;
     let bin_ix = width_in_bins * wg_id.y + wg_id.x;
     let n_partitions = (config.n_drawobj + N_TILE - 1u) / N_TILE;

     // Coordinates of the top left of this bin, in tiles.
     let bin_tile_x = N_TILE_X * wg_id.x;
     let bin_tile_y = N_TILE_Y * wg_id.y;

     let tile_x = local_id.x % N_TILE_X;
     let tile_y = local_id.x / N_TILE_X;
     let this_tile_ix = (bin_tile_y + tile_y) * config.width_in_tiles + bin_tile_x + tile_x;
     cmd_offset = this_tile_ix * PTCL_INITIAL_ALLOC;
     cmd_limit = cmd_offset + (PTCL_INITIAL_ALLOC - PTCL_HEADROOM);

     // clip state
     var clip_zero_depth = 0u;
     var clip_depth = 0u;

     var partition_ix = 0u;
     var rd_ix = 0u;
     var wr_ix = 0u;
     var part_start_ix = 0u;
     var ready_ix = 0u;

     // blend state
     var render_blend_depth = 0u;
     var max_blend_depth = 0u;

     while true {
         for (var i = 0u; i < N_SLICE; i += 1u) {
             atomicStore(&sh_bitmaps[i][local_id.x], 0u);
         }

         while true {
             if ready_ix == wr_ix && partition_ix < n_partitions {
                 part_start_ix = ready_ix;
                 var count = 0u;
                 if partition_ix + local_id.x < n_partitions {
                     let in_ix = (partition_ix + local_id.x) * N_TILE + bin_ix;
                     let bin_header = bin_headers[in_ix];
                     count = bin_header.element_count;
                     sh_part_offsets[local_id.x] = bin_header.chunk_offset;
                 }
                 // prefix sum the element counts
                 for (var i = 0u; i < firstTrailingBit(WG_SIZE); i += 1u) {
                     sh_part_count[local_id.x] = count;
                     workgroupBarrier();
                     if local_id.x >= (1u << i) {
                         count += sh_part_count[local_id.x - (1u << i)];
                     }
                     workgroupBarrier();
                 }
                 sh_part_count[local_id.x] = part_start_ix + count;
                 workgroupBarrier();
                 ready_ix = sh_part_count[WG_SIZE - 1u];
                 partition_ix += WG_SIZE;
             }
             // use binary search to find draw object to read
             var ix = rd_ix + local_id.x;
             if ix >= wr_ix && ix < ready_ix {
                 var part_ix = 0u;
                 for (var i = 0u; i < firstTrailingBit(WG_SIZE); i += 1u) {
                     let probe = part_ix + ((N_TILE / 2u) >> i);
                     if ix >= sh_part_count[probe - 1u] {
                         part_ix = probe;
                     }
                 }
                 ix -= select(part_start_ix, sh_part_count[part_ix - 1u], part_ix > 0u);
                 let offset = config.bin_data_start + sh_part_offsets[part_ix];
                 sh_drawobj_ix[local_id.x] = info_bin_data[offset + ix];
             }
             wr_ix = min(rd_ix + N_TILE, ready_ix);
             if wr_ix - rd_ix >= N_TILE || (wr_ix >= ready_ix && partition_ix >= n_partitions) {
                 break;
             }
         }
         // At this point, sh_drawobj_ix[0.. wr_ix - rd_ix] contains merged binning results.
         var tag = DRAWTAG_NOP;
         var drawobj_ix: u32;
         if local_id.x + rd_ix < wr_ix {
             drawobj_ix = sh_drawobj_ix[local_id.x];
             tag = scene[config.drawtag_base + drawobj_ix];
         }

         var tile_count = 0u;
         // I think this predicate is the same as the last, maybe they can be combined
         if tag != DRAWTAG_NOP {
             let path_ix = draw_monoids[drawobj_ix].path_ix;
             let path = paths[path_ix];
             let stride = path.bbox.z - path.bbox.x;
             sh_tile_stride[local_id.x] = stride;
             let dx = i32(path.bbox.x) - i32(bin_tile_x);
             let dy = i32(path.bbox.y) - i32(bin_tile_y);
             let x0 = clamp(dx, 0, i32(N_TILE_X));
             let y0 = clamp(dy, 0, i32(N_TILE_Y));
             let x1 = clamp(i32(path.bbox.z) - i32(bin_tile_x), 0, i32(N_TILE_X));
             let y1 = clamp(i32(path.bbox.w) - i32(bin_tile_y), 0, i32(N_TILE_Y));
             sh_tile_width[local_id.x] = u32(x1 - x0);
             sh_tile_x0y0[local_id.x] = u32(x0) | u32(y0 << 16u);
             tile_count = u32(x1 - x0) * u32(y1 - y0);
             // base relative to bin
             let base = path.tiles - u32(dy * i32(stride) + dx);
             sh_tile_base[local_id.x] = base;
             // TODO: there's a write_tile_alloc here in the source, not sure what it's supposed to do
         }

         // Prefix sum of tile counts
         sh_tile_count[local_id.x] = tile_count;
         for (var i = 0u; i < firstTrailingBit(N_TILE); i += 1u) {
             workgroupBarrier();
             if local_id.x >= (1u << i) {
                 tile_count += sh_tile_count[local_id.x - (1u << i)];
             }
             workgroupBarrier();
             sh_tile_count[local_id.x] = tile_count;
         }
         workgroupBarrier();
         let total_tile_count = sh_tile_count[N_TILE - 1u];
         // Parallel iteration over all tiles
         for (var ix = local_id.x; ix < total_tile_count; ix += N_TILE) {
             // Binary search to find draw object which contains this tile
             var el_ix = 0u;
             for (var i = 0u; i < firstTrailingBit(N_TILE); i += 1u) {
                 let probe = el_ix + ((N_TILE / 2u) >> i);
                 if ix >= sh_tile_count[probe - 1u] {
                     el_ix = probe;
                 }
             }
             drawobj_ix = sh_drawobj_ix[el_ix];
             tag = scene[config.drawtag_base + drawobj_ix];
             let seq_ix = ix - select(0u, sh_tile_count[el_ix - 1u], el_ix > 0u);
             let width = sh_tile_width[el_ix];
             let x0y0 = sh_tile_x0y0[el_ix];
             let x = (x0y0 & 0xffffu) + seq_ix % width;
             let y = (x0y0 >> 16u) + seq_ix / width;
             let tile_ix = sh_tile_base[el_ix] + sh_tile_stride[el_ix] * y + x;
             let tile = tiles[tile_ix];
             let is_clip = (tag & 1u) != 0u;
             var is_blend = false;
             if is_clip {
                 let BLEND_CLIP = (128u << 8u) | 3u;
                 let scene_offset = draw_monoids[drawobj_ix].scene_offset;
                 let dd = config.drawdata_base + scene_offset;
                 let blend = scene[dd];
                 is_blend = blend != BLEND_CLIP;
             }
             let include_tile = tile.segments != 0u || (tile.backdrop == 0) == is_clip || is_blend;
             if include_tile {
                 let el_slice = el_ix / 32u;
                 let el_mask = 1u << (el_ix & 31u);
                 atomicOr(&sh_bitmaps[el_slice][y * N_TILE_X + x], el_mask);
             }
         }
         workgroupBarrier();
         // At this point bit drawobj % 32 is set in sh_bitmaps[drawobj / 32][y * N_TILE_X + x]
         // if drawobj touches tile (x, y).

         // Write per-tile command list for this tile
         var slice_ix = 0u;
         var bitmap = atomicLoad(&sh_bitmaps[0u][local_id.x]);
         while true {
             if bitmap == 0u {
                 slice_ix += 1u;
                 // potential optimization: make iteration limit dynamic
                 if slice_ix == N_SLICE {
                     break;
                 }
                 bitmap = atomicLoad(&sh_bitmaps[slice_ix][local_id.x]);
                 if bitmap == 0u {
                     continue;
                 }
             }
             let el_ix = slice_ix * 32u + firstTrailingBit(bitmap);
             drawobj_ix = sh_drawobj_ix[el_ix];
             // clear LSB of bitmap, using bit magic
             bitmap &= bitmap - 1u;
             let drawtag = scene[config.drawtag_base + drawobj_ix];
             let dm = draw_monoids[drawobj_ix];
             let dd = config.drawdata_base + dm.scene_offset;
             let di = dm.info_offset;
             if clip_zero_depth == 0u {
                 let tile_ix = sh_tile_base[el_ix] + sh_tile_stride[el_ix] * tile_y + tile_x;
                 let tile = tiles[tile_ix];
                 switch drawtag {
                     // DRAWTAG_FILL_COLOR
                     case 0x44u: {
                         let linewidth = bitcast<f32>(info_bin_data[di]);
                         write_path(tile, linewidth);
                         let rgba_color = scene[dd];
                         write_color(CmdColor(rgba_color));
                     }
                     // DRAWTAG_FILL_LIN_GRADIENT
                     case 0x114u: {
                         let linewidth = bitcast<f32>(info_bin_data[di]);
                         write_path(tile, linewidth);
                         let index = scene[dd];
                         let info_offset = di + 1u;
                         write_grad(CMD_LIN_GRAD, index, info_offset);
                     }
                     // DRAWTAG_FILL_RAD_GRADIENT
                     case 0x2dcu: {
                         let linewidth = bitcast<f32>(info_bin_data[di]);
                         write_path(tile, linewidth);
                         let index = scene[dd];
                         let info_offset = di + 1u;
                         write_grad(CMD_RAD_GRAD, index, info_offset);
                     }
                     // DRAWTAG_BEGIN_CLIP
                     case 0x9u: {
                         if tile.segments == 0u && tile.backdrop == 0 {
                             clip_zero_depth = clip_depth + 1u;
                         } else {
                             write_begin_clip();
                             render_blend_depth += 1u;
                             max_blend_depth = max(max_blend_depth, render_blend_depth);
                         }
                         clip_depth += 1u;
                     }
                     // DRAWTAG_END_CLIP
                     case 0x21u: {
                         clip_depth -= 1u;
                         write_path(tile, -1.0);
                         let blend = scene[dd];
                         let alpha = bitcast<f32>(scene[dd + 1u]);
                         write_end_clip(CmdEndClip(blend, alpha));
                         render_blend_depth -= 1u;
                     }
                     default: {}
                 }
             } else {
                 // In "clip zero" state, suppress all drawing
                 switch drawtag {
                     // DRAWTAG_BEGIN_CLIP
                     case 0x9u: {
                         clip_depth += 1u;
                     }
                     // DRAWTAG_END_CLIP
                     case 0x21u: {
                         if clip_depth == clip_zero_depth {
                             clip_zero_depth = 0u;
                         }
                         clip_depth -= 1u;
                     }
                     default: {}
                 }
             }
         }

         rd_ix += N_TILE;
         if rd_ix >= ready_ix && partition_ix >= n_partitions {
             break;
         }
         workgroupBarrier();
     }
     if bin_tile_x < config.width_in_tiles && bin_tile_y < config.height_in_tiles {
         //ptcl[cmd_offset] = CMD_END;
         // TODO: blend stack allocation
     }
 }
	// SPDX-License-Identifier: Apache-2.0 OR MIT OR Unlicense

	// The coarse rasterization stage.

	#import config
	#import bump
	#import drawtag
	#import ptcl
	#import tile

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

	@group(0) @binding(1)
	var<storage> scene: array<u32>;

	@group(0) @binding(2)
	var<storage> draw_monoids: array<DrawMonoid>;

	// TODO: dedup
	struct BinHeader {
	element_count: u32,
	chunk_offset: u32,
	}

	@group(0) @binding(3)
	var<storage> bin_headers: array<BinHeader>;

	@group(0) @binding(4)
	var<storage> info_bin_data: array<u32>;

	@group(0) @binding(5)
	var<storage> paths: array<Path>;

	@group(0) @binding(6)
	var<storage> tiles: array<Tile>;

	@group(0) @binding(7)
	var<storage, read_write> bump: BumpAllocators;

	@group(0) @binding(8)
	var<storage, read_write> ptcl: array<u32>;



	// Much of this code assumes WG_SIZE == N_TILE. If these diverge, then
	// a fair amount of fixup is needed.
	let WG_SIZE = 256u;
	//let N_SLICE = WG_SIZE / 32u;
	let N_SLICE = 8u;

	var<workgroup> sh_bitmaps: array<array<atomic<u32>, N_TILE>, N_SLICE>;
	var<workgroup> sh_part_count: array<u32, WG_SIZE>;
	var<workgroup> sh_part_offsets: array<u32, WG_SIZE>;
	var<workgroup> sh_drawobj_ix: array<u32, WG_SIZE>;
	var<workgroup> sh_tile_stride: array<u32, WG_SIZE>;
	var<workgroup> sh_tile_width: array<u32, WG_SIZE>;
	var<workgroup> sh_tile_x0y0: array<u32, WG_SIZE>;
	var<workgroup> sh_tile_count: array<u32, WG_SIZE>;
	var<workgroup> sh_tile_base: array<u32, WG_SIZE>;

	// helper functions for writing ptcl

	var<private> cmd_offset: u32;
	var<private> cmd_limit: u32;

	// Make sure there is space for a command of given size, plus a jump if needed
	fn alloc_cmd(size: u32) {
	if cmd_offset + size >= cmd_limit {
	// We might be able to save a little bit of computation here
	// by setting the initial value of the bump allocator.
	let ptcl_dyn_start = config.width_in_tiles * config.height_in_tiles * PTCL_INITIAL_ALLOC;
	let new_cmd = ptcl_dyn_start + atomicAdd(&bump.ptcl, PTCL_INCREMENT);
	// TODO: robust memory
	ptcl[cmd_offset] = CMD_JUMP;
	ptcl[cmd_offset + 1u] = new_cmd;
	cmd_offset = new_cmd;
	cmd_limit = cmd_offset + (PTCL_INCREMENT - PTCL_HEADROOM);
	}
	}

	fn write_path(tile: Tile, linewidth: f32) {
	// TODO: take flags
	alloc_cmd(3u);
	if linewidth < 0.0 {
	if tile.segments != 0u {
	let fill = CmdFill(tile.segments, tile.backdrop);
	ptcl[cmd_offset] = CMD_FILL;
	ptcl[cmd_offset + 1u] = fill.tile;
	ptcl[cmd_offset + 2u] = u32(fill.backdrop);
	cmd_offset += 3u;
	} else {
	ptcl[cmd_offset] = CMD_SOLID;
	cmd_offset += 1u;
	}
	} else {
	let stroke = CmdStroke(tile.segments, 0.5 * linewidth);
	ptcl[cmd_offset] = CMD_STROKE;
	ptcl[cmd_offset + 1u] = stroke.tile;
	ptcl[cmd_offset + 2u] = bitcast<u32>(stroke.half_width);
	cmd_offset += 3u;
	}
	}

	fn write_color(color: CmdColor) {
	alloc_cmd(2u);
	ptcl[cmd_offset] = CMD_COLOR;
	ptcl[cmd_offset + 1u] = color.rgba_color;
	cmd_offset += 2u;
	}

	fn write_grad(ty: u32, index: u32, info_offset: u32) {
	alloc_cmd(3u);
	ptcl[cmd_offset] = ty;
	ptcl[cmd_offset + 1u] = index;
	ptcl[cmd_offset + 2u] = info_offset;
	cmd_offset += 3u;
	}

	fn write_begin_clip() {
	alloc_cmd(1u);
	ptcl[cmd_offset] = CMD_BEGIN_CLIP;
	cmd_offset += 1u;
	}

	fn write_end_clip(end_clip: CmdEndClip) {
	alloc_cmd(3u);
	ptcl[cmd_offset] = CMD_END_CLIP;
	ptcl[cmd_offset + 1u] = end_clip.blend;
	ptcl[cmd_offset + 2u] = bitcast<u32>(end_clip.alpha);
	cmd_offset += 3u;
	}

	@compute @workgroup_size(256)
	fn main(
	@builtin(local_invocation_id) local_id: vec3<u32>,
	@builtin(workgroup_id) wg_id: vec3<u32>,
	) {
	let width_in_bins = (config.width_in_tiles + N_TILE_X - 1u) / N_TILE_X;
	let bin_ix = width_in_bins * wg_id.y + wg_id.x;
	let n_partitions = (config.n_drawobj + N_TILE - 1u) / N_TILE;

	// Coordinates of the top left of this bin, in tiles.
	let bin_tile_x = N_TILE_X * wg_id.x;
	let bin_tile_y = N_TILE_Y * wg_id.y;

	let tile_x = local_id.x % N_TILE_X;
	let tile_y = local_id.x / N_TILE_X;
	let this_tile_ix = (bin_tile_y + tile_y) * config.width_in_tiles + bin_tile_x + tile_x;
	cmd_offset = this_tile_ix * PTCL_INITIAL_ALLOC;
	cmd_limit = cmd_offset + (PTCL_INITIAL_ALLOC - PTCL_HEADROOM);

	// clip state
	var clip_zero_depth = 0u;
	var clip_depth = 0u;

	var partition_ix = 0u;
	var rd_ix = 0u;
	var wr_ix = 0u;
	var part_start_ix = 0u;
	var ready_ix = 0u;

	// blend state
	var render_blend_depth = 0u;
	var max_blend_depth = 0u;

	while true {
	for (var i = 0u; i < N_SLICE; i += 1u) {
	atomicStore(&sh_bitmaps[i][local_id.x], 0u);
	}

	while true {
	if ready_ix == wr_ix && partition_ix < n_partitions {
	part_start_ix = ready_ix;
	var count = 0u;
	if partition_ix + local_id.x < n_partitions {
	let in_ix = (partition_ix + local_id.x) * N_TILE + bin_ix;
	let bin_header = bin_headers[in_ix];
	count = bin_header.element_count;
	sh_part_offsets[local_id.x] = bin_header.chunk_offset;
	}
	// prefix sum the element counts
	for (var i = 0u; i < firstTrailingBit(WG_SIZE); i += 1u) {
	sh_part_count[local_id.x] = count;
	workgroupBarrier();
	if local_id.x >= (1u << i) {
	count += sh_part_count[local_id.x - (1u << i)];
	}
	workgroupBarrier();
	}
	sh_part_count[local_id.x] = part_start_ix + count;
	workgroupBarrier();
	ready_ix = sh_part_count[WG_SIZE - 1u];
	partition_ix += WG_SIZE;
	}
	// use binary search to find draw object to read
	var ix = rd_ix + local_id.x;
	if ix >= wr_ix && ix < ready_ix {
	var part_ix = 0u;
	for (var i = 0u; i < firstTrailingBit(WG_SIZE); i += 1u) {
	let probe = part_ix + ((N_TILE / 2u) >> i);
	if ix >= sh_part_count[probe - 1u] {
	part_ix = probe;
	}
	}
	ix -= select(part_start_ix, sh_part_count[part_ix - 1u], part_ix > 0u);
	let offset = config.bin_data_start + sh_part_offsets[part_ix];
	sh_drawobj_ix[local_id.x] = info_bin_data[offset + ix];
	}
	wr_ix = min(rd_ix + N_TILE, ready_ix);
	if wr_ix - rd_ix >= N_TILE \|\| (wr_ix >= ready_ix && partition_ix >= n_partitions) {
	break;
	}
	}
	// At this point, sh_drawobj_ix[0.. wr_ix - rd_ix] contains merged binning results.
	var tag = DRAWTAG_NOP;
	var drawobj_ix: u32;
	if local_id.x + rd_ix < wr_ix {
	drawobj_ix = sh_drawobj_ix[local_id.x];
	tag = scene[config.drawtag_base + drawobj_ix];
	}

	var tile_count = 0u;
	// I think this predicate is the same as the last, maybe they can be combined
	if tag != DRAWTAG_NOP {
	let path_ix = draw_monoids[drawobj_ix].path_ix;
	let path = paths[path_ix];
	let stride = path.bbox.z - path.bbox.x;
	sh_tile_stride[local_id.x] = stride;
	let dx = i32(path.bbox.x) - i32(bin_tile_x);
	let dy = i32(path.bbox.y) - i32(bin_tile_y);
	let x0 = clamp(dx, 0, i32(N_TILE_X));
	let y0 = clamp(dy, 0, i32(N_TILE_Y));
	let x1 = clamp(i32(path.bbox.z) - i32(bin_tile_x), 0, i32(N_TILE_X));
	let y1 = clamp(i32(path.bbox.w) - i32(bin_tile_y), 0, i32(N_TILE_Y));
	sh_tile_width[local_id.x] = u32(x1 - x0);
	sh_tile_x0y0[local_id.x] = u32(x0) \| u32(y0 << 16u);
	tile_count = u32(x1 - x0) * u32(y1 - y0);
	// base relative to bin
	let base = path.tiles - u32(dy * i32(stride) + dx);
	sh_tile_base[local_id.x] = base;
	// TODO: there's a write_tile_alloc here in the source, not sure what it's supposed to do
	}

	// Prefix sum of tile counts
	sh_tile_count[local_id.x] = tile_count;
	for (var i = 0u; i < firstTrailingBit(N_TILE); i += 1u) {
	workgroupBarrier();
	if local_id.x >= (1u << i) {
	tile_count += sh_tile_count[local_id.x - (1u << i)];
	}
	workgroupBarrier();
	sh_tile_count[local_id.x] = tile_count;
	}
	workgroupBarrier();
	let total_tile_count = sh_tile_count[N_TILE - 1u];
	// Parallel iteration over all tiles
	for (var ix = local_id.x; ix < total_tile_count; ix += N_TILE) {
	// Binary search to find draw object which contains this tile
	var el_ix = 0u;
	for (var i = 0u; i < firstTrailingBit(N_TILE); i += 1u) {
	let probe = el_ix + ((N_TILE / 2u) >> i);
	if ix >= sh_tile_count[probe - 1u] {
	el_ix = probe;
	}
	}
	drawobj_ix = sh_drawobj_ix[el_ix];
	tag = scene[config.drawtag_base + drawobj_ix];
	let seq_ix = ix - select(0u, sh_tile_count[el_ix - 1u], el_ix > 0u);
	let width = sh_tile_width[el_ix];
	let x0y0 = sh_tile_x0y0[el_ix];
	let x = (x0y0 & 0xffffu) + seq_ix % width;
	let y = (x0y0 >> 16u) + seq_ix / width;
	let tile_ix = sh_tile_base[el_ix] + sh_tile_stride[el_ix] * y + x;
	let tile = tiles[tile_ix];
	let is_clip = (tag & 1u) != 0u;
	var is_blend = false;
	if is_clip {
	let BLEND_CLIP = (128u << 8u) \| 3u;
	let scene_offset = draw_monoids[drawobj_ix].scene_offset;
	let dd = config.drawdata_base + scene_offset;
	let blend = scene[dd];
	is_blend = blend != BLEND_CLIP;
	}
	let include_tile = tile.segments != 0u \|\| (tile.backdrop == 0) == is_clip \|\| is_blend;
	if include_tile {
	let el_slice = el_ix / 32u;
	let el_mask = 1u << (el_ix & 31u);
	atomicOr(&sh_bitmaps[el_slice][y * N_TILE_X + x], el_mask);
	}
	}
	workgroupBarrier();
	// At this point bit drawobj % 32 is set in sh_bitmaps[drawobj / 32][y * N_TILE_X + x]
	// if drawobj touches tile (x, y).

	// Write per-tile command list for this tile
	var slice_ix = 0u;
	var bitmap = atomicLoad(&sh_bitmaps[0u][local_id.x]);
	while true {
	if bitmap == 0u {
	slice_ix += 1u;
	// potential optimization: make iteration limit dynamic
	if slice_ix == N_SLICE {
	break;
	}
	bitmap = atomicLoad(&sh_bitmaps[slice_ix][local_id.x]);
	if bitmap == 0u {
	continue;
	}
	}
	let el_ix = slice_ix * 32u + firstTrailingBit(bitmap);
	drawobj_ix = sh_drawobj_ix[el_ix];
	// clear LSB of bitmap, using bit magic
	bitmap &= bitmap - 1u;
	let drawtag = scene[config.drawtag_base + drawobj_ix];
	let dm = draw_monoids[drawobj_ix];
	let dd = config.drawdata_base + dm.scene_offset;
	let di = dm.info_offset;
	if clip_zero_depth == 0u {
	let tile_ix = sh_tile_base[el_ix] + sh_tile_stride[el_ix] * tile_y + tile_x;
	let tile = tiles[tile_ix];
	switch drawtag {
	// DRAWTAG_FILL_COLOR
	case 0x44u: {
	let linewidth = bitcast<f32>(info_bin_data[di]);
	write_path(tile, linewidth);
	let rgba_color = scene[dd];
	write_color(CmdColor(rgba_color));
	}
	// DRAWTAG_FILL_LIN_GRADIENT
	case 0x114u: {
	let linewidth = bitcast<f32>(info_bin_data[di]);
	write_path(tile, linewidth);
	let index = scene[dd];
	let info_offset = di + 1u;
	write_grad(CMD_LIN_GRAD, index, info_offset);
	}
	// DRAWTAG_FILL_RAD_GRADIENT
	case 0x2dcu: {
	let linewidth = bitcast<f32>(info_bin_data[di]);
	write_path(tile, linewidth);
	let index = scene[dd];
	let info_offset = di + 1u;
	write_grad(CMD_RAD_GRAD, index, info_offset);
	}
	// DRAWTAG_BEGIN_CLIP
	case 0x9u: {
	if tile.segments == 0u && tile.backdrop == 0 {
	clip_zero_depth = clip_depth + 1u;
	} else {
	write_begin_clip();
	render_blend_depth += 1u;
	max_blend_depth = max(max_blend_depth, render_blend_depth);
	}
	clip_depth += 1u;
	}
	// DRAWTAG_END_CLIP
	case 0x21u: {
	clip_depth -= 1u;
	write_path(tile, -1.0);
	let blend = scene[dd];
	let alpha = bitcast<f32>(scene[dd + 1u]);
	write_end_clip(CmdEndClip(blend, alpha));
	render_blend_depth -= 1u;
	}
	default: {}
	}
	} else {
	// In "clip zero" state, suppress all drawing
	switch drawtag {
	// DRAWTAG_BEGIN_CLIP
	case 0x9u: {
	clip_depth += 1u;
	}
	// DRAWTAG_END_CLIP
	case 0x21u: {
	if clip_depth == clip_zero_depth {
	clip_zero_depth = 0u;
	}
	clip_depth -= 1u;
	}
	default: {}
	}
	}
	}

	rd_ix += N_TILE;
	if rd_ix >= ready_ix && partition_ix >= n_partitions {
	break;
	}
	workgroupBarrier();
	}
	if bin_tile_x < config.width_in_tiles && bin_tile_y < config.height_in_tiles {
	//ptcl[cmd_offset] = CMD_END;
	// TODO: blend stack allocation
	}
	}