mirror of
https://git.sr.ht/~eliasnaur/gio
synced 2026-07-01 07:35:40 +00:00
gpu/shaders: update piet-gpu
Changes: - faster implementation of RGBA output - fix stroked clips and images Signed-off-by: Elias Naur <mail@eliasnaur.com>
This commit is contained in:
+3
-3
File diff suppressed because one or more lines are too long
@@ -48,13 +48,13 @@ void main() {
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if (element_ix < conf.n_elements) {
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AnnotatedTag tag = Annotated_tag(conf.anno_alloc, ref);
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switch (tag.tag) {
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case Annotated_Image:
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case Annotated_BeginClip:
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case Annotated_Color:
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if (fill_mode_from_flags(tag.flags) != MODE_NONZERO) {
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break;
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}
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// Fall through.
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case Annotated_Image:
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case Annotated_BeginClip:
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PathRef path_ref = PathRef(conf.tile_alloc.offset + element_ix * Path_size);
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Path path = Path_read(conf.tile_alloc, path_ref);
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sh_row_width[th_ix] = path.bbox.z - path.bbox.x;
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+37
-44
@@ -91,6 +91,23 @@ bool alloc_cmd(inout Alloc cmd_alloc, inout CmdRef cmd_ref, inout uint cmd_limit
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return true;
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}
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void write_fill(Alloc alloc, inout CmdRef cmd_ref, uint flags, Tile tile, float linewidth) {
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if (fill_mode_from_flags(flags) == MODE_NONZERO) {
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if (tile.tile.offset != 0) {
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CmdFill cmd_fill = CmdFill(tile.tile.offset, tile.backdrop);
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Cmd_Fill_write(alloc, cmd_ref, cmd_fill);
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cmd_ref.offset += 4 + CmdFill_size;
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} else {
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Cmd_Solid_write(alloc, cmd_ref);
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cmd_ref.offset += 4;
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}
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} else {
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CmdStroke cmd_stroke = CmdStroke(tile.tile.offset, 0.5 * linewidth);
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Cmd_Stroke_write(alloc, cmd_ref, cmd_stroke);
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cmd_ref.offset += 4 + CmdStroke_size;
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}
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}
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void main() {
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if (mem_error != NO_ERROR) {
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return;
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@@ -135,6 +152,12 @@ void main() {
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uint part_start_ix = 0;
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uint ready_ix = 0;
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// Leave room for the fine rasterizer scratch allocation.
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Alloc scratch_alloc = slice_mem(cmd_alloc, 0, Alloc_size);
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cmd_ref.offset += Alloc_size;
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uint num_begin_slots = 0;
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uint begin_slot = 0;
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while (true) {
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for (uint i = 0; i < N_SLICE; i++) {
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sh_bitmaps[i][th_ix] = 0;
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@@ -320,20 +343,7 @@ void main() {
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if (!alloc_cmd(cmd_alloc, cmd_ref, cmd_limit)) {
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break;
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}
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if (fill_mode_from_flags(tag.flags) == MODE_NONZERO) {
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if (tile.tile.offset != 0) {
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CmdFill cmd_fill = CmdFill(tile.tile.offset, tile.backdrop);
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Cmd_Fill_write(cmd_alloc, cmd_ref, cmd_fill);
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cmd_ref.offset += 4 + CmdFill_size;
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} else {
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Cmd_Solid_write(cmd_alloc, cmd_ref);
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cmd_ref.offset += 4;
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}
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} else {
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CmdStroke cmd_stroke = CmdStroke(tile.tile.offset, 0.5 * fill.linewidth);
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Cmd_Stroke_write(cmd_alloc, cmd_ref, cmd_stroke);
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cmd_ref.offset += 4 + CmdStroke_size;
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}
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write_fill(cmd_alloc, cmd_ref, tag.flags, tile, fill.linewidth);
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Cmd_Color_write(cmd_alloc, cmd_ref, CmdColor(fill.rgba_color));
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cmd_ref.offset += 4 + CmdColor_size;
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break;
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@@ -344,20 +354,7 @@ void main() {
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if (!alloc_cmd(cmd_alloc, cmd_ref, cmd_limit)) {
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break;
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}
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if (fill_mode_from_flags(tag.flags) == MODE_NONZERO) {
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if (tile.tile.offset != 0) {
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CmdFill cmd_fill = CmdFill(tile.tile.offset, tile.backdrop);
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Cmd_Fill_write(cmd_alloc, cmd_ref, cmd_fill);
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cmd_ref.offset += 4 + CmdFill_size;
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} else {
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Cmd_Solid_write(cmd_alloc, cmd_ref);
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cmd_ref.offset += 4;
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}
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} else {
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CmdStroke cmd_stroke = CmdStroke(tile.tile.offset, 0.5 * fill_img.linewidth);
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Cmd_Stroke_write(cmd_alloc, cmd_ref, cmd_stroke);
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cmd_ref.offset += 4 + CmdStroke_size;
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}
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write_fill(cmd_alloc, cmd_ref, tag.flags, tile, fill_img.linewidth);
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Cmd_Image_write(cmd_alloc, cmd_ref, CmdImage(fill_img.index, fill_img.offset));
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cmd_ref.offset += 4 + CmdImage_size;
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break;
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@@ -373,27 +370,14 @@ void main() {
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if (!alloc_cmd(cmd_alloc, cmd_ref, cmd_limit)) {
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break;
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}
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if (fill_mode_from_flags(tag.flags) == MODE_NONZERO) {
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if (tile.tile.offset != 0) {
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CmdFill cmd_fill = CmdFill(tile.tile.offset, tile.backdrop);
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Cmd_Fill_write(cmd_alloc, cmd_ref, cmd_fill);
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cmd_ref.offset += 4 + CmdFill_size;
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} else {
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// TODO: here is where a bunch of optimization magic should happen
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float alpha = tile.backdrop == 0 ? 0.0 : 1.0;
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Cmd_Alpha_write(cmd_alloc, cmd_ref, CmdAlpha(alpha));
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cmd_ref.offset += 4 + CmdAlpha_size;
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}
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} else {
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CmdStroke cmd_stroke = CmdStroke(tile.tile.offset, 0.5 * begin_clip.linewidth);
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Cmd_Stroke_write(cmd_alloc, cmd_ref, cmd_stroke);
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cmd_ref.offset += 4 + CmdStroke_size;
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}
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write_fill(cmd_alloc, cmd_ref, tag.flags, tile, begin_clip.linewidth);
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Cmd_BeginClip_write(cmd_alloc, cmd_ref);
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cmd_ref.offset += 4;
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if (clip_depth < 32) {
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clip_one_mask &= ~(1 << clip_depth);
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}
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begin_slot++;
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num_begin_slots = max(num_begin_slots, begin_slot);
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}
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clip_depth++;
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break;
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@@ -405,6 +389,7 @@ void main() {
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}
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Cmd_Solid_write(cmd_alloc, cmd_ref);
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cmd_ref.offset += 4;
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begin_slot--;
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Cmd_EndClip_write(cmd_alloc, cmd_ref);
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cmd_ref.offset += 4;
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}
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@@ -432,5 +417,13 @@ void main() {
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}
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if (bin_tile_x + tile_x < conf.width_in_tiles && bin_tile_y + tile_y < conf.height_in_tiles) {
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Cmd_End_write(cmd_alloc, cmd_ref);
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if (num_begin_slots > 0) {
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// Write scratch allocation: one state per BeginClip per rasterizer chunk.
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uint scratch_size = num_begin_slots * TILE_WIDTH_PX * TILE_HEIGHT_PX * CLIP_STATE_SIZE * 4;
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MallocResult scratch = malloc(scratch_size);
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// Ignore scratch.failed; we don't use the allocation and kernel4
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// checks for memory overflow before using it.
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alloc_write(scratch_alloc, scratch_alloc.offset, scratch.alloc);
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}
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}
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}
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+37
-77
@@ -13,9 +13,12 @@
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#include "mem.h"
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#include "setup.h"
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#define CHUNK 8
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#define CHUNK_DY (TILE_HEIGHT_PX / CHUNK)
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layout(local_size_x = TILE_WIDTH_PX, local_size_y = CHUNK_DY) in;
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#define CHUNK_X 2
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#define CHUNK_Y 4
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#define CHUNK CHUNK_X * CHUNK_Y
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#define CHUNK_DX (TILE_WIDTH_PX / CHUNK_X)
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#define CHUNK_DY (TILE_HEIGHT_PX / CHUNK_Y)
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layout(local_size_x = CHUNK_DX, local_size_y = CHUNK_DY) in;
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layout(set = 0, binding = 1) readonly buffer ConfigBuf {
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Config conf;
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@@ -32,36 +35,6 @@ layout(rgba8, set = 0, binding = 3) uniform readonly image2D images[1];
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#include "ptcl.h"
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#include "tile.h"
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#define BLEND_STACK_SIZE 4
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// Layout of a clip scratch frame:
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// Each frame is WIDTH * HEIGHT ClipStates, then a link reference.
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struct ClipState {
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uint srgb;
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float area;
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};
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// Link offset and frame size in 32-bit words.
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#define CLIP_STATE_SIZE 2
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#define CLIP_LINK_OFFSET (TILE_WIDTH_PX * TILE_HEIGHT_PX * CLIP_STATE_SIZE)
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#define CLIP_BUF_SIZE (CLIP_LINK_OFFSET + 1)
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shared MallocResult sh_clip_alloc;
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// Allocate a scratch buffer for clipping.
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MallocResult alloc_clip_buf(uint link) {
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if (gl_LocalInvocationID.x == 0 && gl_LocalInvocationID.y == 0) {
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MallocResult m = malloc(CLIP_BUF_SIZE * 4);
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if (!m.failed) {
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write_mem(m.alloc, (m.alloc.offset >> 2) + CLIP_LINK_OFFSET, link);
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}
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sh_clip_alloc = m;
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}
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barrier();
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return sh_clip_alloc;
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}
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vec3 tosRGB(vec3 rgb) {
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bvec3 cutoff = greaterThanEqual(rgb, vec3(0.0031308));
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vec3 below = vec3(12.92)*rgb;
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@@ -90,10 +63,14 @@ uint packsRGB(vec4 rgba) {
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return packUnorm4x8(rgba.wzyx);
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}
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uvec2 chunk_offset(uint i) {
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return uvec2(i % CHUNK_X * CHUNK_DX, i / CHUNK_X * CHUNK_DY);
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}
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vec4[CHUNK] fillImage(uvec2 xy, CmdImage cmd_img) {
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vec4 rgba[CHUNK];
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for (uint i = 0; i < CHUNK; i++) {
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ivec2 uv = ivec2(xy.x, xy.y + i * CHUNK_DY) + cmd_img.offset;
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ivec2 uv = ivec2(xy + chunk_offset(i)) + cmd_img.offset;
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#ifdef ENABLE_IMAGE_INDICES
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vec4 fg_rgba = imageLoad(images[cmd_img.index], uv);
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#else
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@@ -114,23 +91,24 @@ void main() {
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Alloc cmd_alloc = slice_mem(conf.ptcl_alloc, tile_ix * PTCL_INITIAL_ALLOC, PTCL_INITIAL_ALLOC);
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CmdRef cmd_ref = CmdRef(cmd_alloc.offset);
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uvec2 xy_uint = uvec2(gl_GlobalInvocationID.x, gl_LocalInvocationID.y + TILE_HEIGHT_PX * gl_WorkGroupID.y);
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// Read scrach space allocation, written first in the command list.
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Alloc scratch_alloc = alloc_read(cmd_alloc, cmd_ref.offset);
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cmd_ref.offset += Alloc_size;
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uvec2 xy_uint = uvec2(gl_LocalInvocationID.x + TILE_WIDTH_PX * gl_WorkGroupID.x, gl_LocalInvocationID.y + TILE_HEIGHT_PX * gl_WorkGroupID.y);
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vec2 xy = vec2(xy_uint);
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vec4 rgba[CHUNK];
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ClipState blend_stack[BLEND_STACK_SIZE][CHUNK];
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uint blend_spill = 0;
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uint blend_sp = 0;
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Alloc clip_tos = new_alloc(0, 0);
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for (uint i = 0; i < CHUNK; i++) {
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rgba[i] = vec4(0.0);
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#ifdef ENABLE_IMAGE_INDICES
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if (xy_uint.x < 1024 && xy_uint.y < 1024) {
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rgba[i] = imageLoad(images[gl_WorkGroupID.x / 64], ivec2(xy_uint.x, xy_uint.y + CHUNK_DY * i)/4);
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rgba[i] = imageLoad(images[gl_WorkGroupID.x / 64], ivec2(xy_uint + chunk_offset(i))/4);
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}
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#endif
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}
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float area[CHUNK];
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uint clip_depth = 0;
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while (true) {
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uint tag = Cmd_tag(cmd_alloc, cmd_ref).tag;
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if (tag == Cmd_End) {
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@@ -148,7 +126,7 @@ void main() {
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vec2 line_vec = seg.vector;
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for (uint k = 0; k < CHUNK; k++) {
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vec2 dpos = xy + vec2(0.5, 0.5) - seg.origin;
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dpos.y += float(k * CHUNK_DY);
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dpos += vec2(chunk_offset(k));
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float t = clamp(dot(line_vec, dpos) / dot(line_vec, line_vec), 0.0, 1.0);
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df[k] = min(df[k], length(line_vec * t - dpos));
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}
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@@ -167,7 +145,7 @@ void main() {
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do {
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TileSeg seg = TileSeg_read(new_alloc(tile_seg_ref.offset, TileSeg_size), tile_seg_ref);
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for (uint k = 0; k < CHUNK; k++) {
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vec2 my_xy = vec2(xy.x, xy.y + float(k * CHUNK_DY));
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vec2 my_xy = xy + vec2(chunk_offset(k));
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vec2 start = seg.origin - my_xy;
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vec2 end = start + seg.vector;
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vec2 window = clamp(vec2(start.y, end.y), 0.0, 1.0);
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@@ -223,47 +201,29 @@ void main() {
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cmd_ref.offset += 4 + CmdImage_size;
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break;
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case Cmd_BeginClip:
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uint blend_slot = blend_sp % BLEND_STACK_SIZE;
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if (blend_sp == blend_spill + BLEND_STACK_SIZE) {
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// spill to scratch buffer
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MallocResult m = alloc_clip_buf(clip_tos.offset);
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if (m.failed) {
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return;
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}
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clip_tos = m.alloc;
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uint base_ix = (clip_tos.offset >> 2) + CLIP_STATE_SIZE * (gl_LocalInvocationID.x + TILE_WIDTH_PX * gl_LocalInvocationID.y);
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for (uint k = 0; k < CHUNK; k++) {
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uint srgb = blend_stack[blend_slot][k].srgb;
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uint area = floatBitsToUint(blend_stack[blend_slot][k].area);
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write_mem(clip_tos, base_ix + 0 + k * CLIP_STATE_SIZE * TILE_WIDTH_PX * CHUNK_DY, srgb);
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write_mem(clip_tos, base_ix + 1 + k * CLIP_STATE_SIZE * TILE_WIDTH_PX * CHUNK_DY, area);
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}
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blend_spill++;
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}
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uint base_ix = (scratch_alloc.offset >> 2) + CLIP_STATE_SIZE * (clip_depth * TILE_WIDTH_PX * TILE_HEIGHT_PX +
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gl_LocalInvocationID.x + TILE_WIDTH_PX * gl_LocalInvocationID.y);
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for (uint k = 0; k < CHUNK; k++) {
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blend_stack[blend_slot][k] = ClipState(packsRGB(rgba[k]), clamp(abs(area[k]), 0.0, 1.0));
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uvec2 offset = chunk_offset(k);
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uint srgb = packsRGB(vec4(rgba[k]));
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float alpha = clamp(abs(area[k]), 0.0, 1.0);
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write_mem(scratch_alloc, base_ix + 0 + CLIP_STATE_SIZE * (offset.x + offset.y * TILE_WIDTH_PX), srgb);
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write_mem(scratch_alloc, base_ix + 1 + CLIP_STATE_SIZE * (offset.x + offset.y * TILE_WIDTH_PX), floatBitsToUint(alpha));
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rgba[k] = vec4(0.0);
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}
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blend_sp++;
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clip_depth++;
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cmd_ref.offset += 4;
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break;
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case Cmd_EndClip:
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blend_slot = (blend_sp - 1) % BLEND_STACK_SIZE;
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if (blend_sp == blend_spill) {
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uint base_ix = (clip_tos.offset >> 2) + CLIP_STATE_SIZE * (gl_LocalInvocationID.x + TILE_WIDTH_PX * gl_LocalInvocationID.y);
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for (uint k = 0; k < CHUNK; k++) {
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uint srgb = read_mem(clip_tos, base_ix + 0 + k * CLIP_STATE_SIZE * TILE_WIDTH_PX * CHUNK_DY);
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uint area = read_mem(clip_tos, base_ix + 1 + k * CLIP_STATE_SIZE * TILE_WIDTH_PX * CHUNK_DY);
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ClipState state = ClipState(srgb, uintBitsToFloat(area));
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blend_stack[blend_slot][k] = state;
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}
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clip_tos.offset = read_mem(clip_tos, (clip_tos.offset >> 2) + CLIP_LINK_OFFSET);
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blend_spill--;
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}
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blend_sp--;
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clip_depth--;
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base_ix = (scratch_alloc.offset >> 2) + CLIP_STATE_SIZE * (clip_depth * TILE_WIDTH_PX * TILE_HEIGHT_PX +
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gl_LocalInvocationID.x + TILE_WIDTH_PX * gl_LocalInvocationID.y);
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for (uint k = 0; k < CHUNK; k++) {
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vec4 bg = unpacksRGB(blend_stack[blend_slot][k].srgb);
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vec4 fg = rgba[k] * area[k] * blend_stack[blend_slot][k].area;
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uvec2 offset = chunk_offset(k);
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uint srgb = read_mem(scratch_alloc, base_ix + 0 + CLIP_STATE_SIZE * (offset.x + offset.y * TILE_WIDTH_PX));
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uint alpha = read_mem(scratch_alloc, base_ix + 1 + CLIP_STATE_SIZE * (offset.x + offset.y * TILE_WIDTH_PX));
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vec4 bg = unpacksRGB(srgb);
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vec4 fg = rgba[k] * area[k] * uintBitsToFloat(alpha);
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rgba[k] = bg * (1.0 - fg.a) + fg;
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}
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cmd_ref.offset += 4;
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@@ -276,6 +236,6 @@ void main() {
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}
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for (uint i = 0; i < CHUNK; i++) {
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imageStore(image, ivec2(xy_uint.x, xy_uint.y + CHUNK_DY * i), vec4(tosRGB(rgba[i].rgb), rgba[i].a));
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imageStore(image, ivec2(xy_uint + chunk_offset(i)), vec4(tosRGB(rgba[i].rgb), rgba[i].a));
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}
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}
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+23
-1
@@ -21,7 +21,11 @@ layout(set = 0, binding = 0) buffer Memory {
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#define ERR_OUT_OF_BOUNDS 2
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#define ERR_UNALIGNED_ACCESS 3
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#ifdef MEM_DEBUG
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#define Alloc_size 16
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#else
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#define Alloc_size 8
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#endif
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// Alloc represents a memory allocation.
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struct Alloc {
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@@ -39,7 +43,7 @@ struct MallocResult {
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bool failed;
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};
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// new_alloc synthesizes an Alloc when its offset and size are derived.
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// new_alloc synthesizes an Alloc from an offset and size.
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Alloc new_alloc(uint offset, uint size) {
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Alloc a;
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a.offset = offset;
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@@ -118,3 +122,21 @@ Alloc slice_mem(Alloc a, uint offset, uint size) {
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#endif
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return new_alloc(a.offset + offset, size);
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||||
}
|
||||
|
||||
// alloc_write writes alloc to memory at offset bytes.
|
||||
void alloc_write(Alloc a, uint offset, Alloc alloc) {
|
||||
write_mem(a, offset >> 2, alloc.offset);
|
||||
#ifdef MEM_DEBUG
|
||||
write_mem(a, (offset >> 2) + 1, alloc.size);
|
||||
#endif
|
||||
}
|
||||
|
||||
// alloc_read reads an Alloc from memory at offset bytes.
|
||||
Alloc alloc_read(Alloc a, uint offset) {
|
||||
Alloc alloc;
|
||||
alloc.offset = read_mem(a, offset >> 2);
|
||||
#ifdef MEM_DEBUG
|
||||
alloc.size = read_mem(a, (offset >> 2) + 1);
|
||||
#endif
|
||||
return alloc;
|
||||
}
|
||||
|
||||
+4
-1
@@ -42,7 +42,10 @@ struct Config {
|
||||
#define MODE_NONZERO 0
|
||||
#define MODE_STROKE 1
|
||||
|
||||
// Size of kernel4 clip state, in words.
|
||||
#define CLIP_STATE_SIZE 2
|
||||
|
||||
// fill_mode_from_flags extracts the fill mode from tag flags.
|
||||
uint fill_mode_from_flags(uint flags) {
|
||||
return flags & 0x1;
|
||||
return flags & 0x1;
|
||||
}
|
||||
|
||||
Reference in New Issue
Block a user