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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 19:33:14 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 19:33:14 +0000
commit36d22d82aa202bb199967e9512281e9a53db42c9 (patch)
tree105e8c98ddea1c1e4784a60a5a6410fa416be2de /gfx/wr/webrender/res/brush_image.glsl
parentInitial commit. (diff)
downloadfirefox-esr-36d22d82aa202bb199967e9512281e9a53db42c9.tar.xz
firefox-esr-36d22d82aa202bb199967e9512281e9a53db42c9.zip
Adding upstream version 115.7.0esr.upstream/115.7.0esrupstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'gfx/wr/webrender/res/brush_image.glsl')
-rw-r--r--gfx/wr/webrender/res/brush_image.glsl393
1 files changed, 393 insertions, 0 deletions
diff --git a/gfx/wr/webrender/res/brush_image.glsl b/gfx/wr/webrender/res/brush_image.glsl
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+/* This Source Code Form is subject to the terms of the Mozilla Public
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
+
+#define VECS_PER_SPECIFIC_BRUSH 3
+
+#include shared,prim_shared,brush
+
+// Interpolated UV coordinates to sample.
+varying highp vec2 v_uv;
+
+#ifdef WR_FEATURE_ALPHA_PASS
+flat varying mediump vec4 v_color;
+flat varying mediump vec2 v_mask_swizzle;
+flat varying mediump vec2 v_tile_repeat;
+#endif
+
+// Normalized bounds of the source image in the texture.
+flat varying highp vec4 v_uv_bounds;
+// Normalized bounds of the source image in the texture, adjusted to avoid
+// sampling artifacts.
+flat varying highp vec4 v_uv_sample_bounds;
+
+// Flag to allow perspective interpolation of UV.
+// Packed in to vector to work around bug 1630356.
+flat varying mediump vec2 v_perspective;
+
+#ifdef WR_VERTEX_SHADER
+
+// Must match the AlphaType enum.
+#define BLEND_MODE_ALPHA 0
+#define BLEND_MODE_PREMUL_ALPHA 1
+
+struct ImageBrushData {
+ vec4 color;
+ vec4 background_color;
+ vec2 stretch_size;
+};
+
+ImageBrushData fetch_image_data(int address) {
+ vec4[3] raw_data = fetch_from_gpu_cache_3(address);
+ ImageBrushData data = ImageBrushData(
+ raw_data[0],
+ raw_data[1],
+ raw_data[2].xy
+ );
+ return data;
+}
+
+void brush_vs(
+ VertexInfo vi,
+ int prim_address,
+ RectWithEndpoint prim_rect,
+ RectWithEndpoint segment_rect,
+ ivec4 prim_user_data,
+ int specific_resource_address,
+ mat4 transform,
+ PictureTask pic_task,
+ int brush_flags,
+ vec4 segment_data
+) {
+ ImageBrushData image_data = fetch_image_data(prim_address);
+
+ // If this is in WR_FEATURE_TEXTURE_RECT mode, the rect and size use
+ // non-normalized texture coordinates.
+#ifdef WR_FEATURE_TEXTURE_RECT
+ vec2 texture_size = vec2(1, 1);
+#else
+ vec2 texture_size = vec2(TEX_SIZE(sColor0));
+#endif
+
+ ImageSource res = fetch_image_source(specific_resource_address);
+ vec2 uv0 = res.uv_rect.p0;
+ vec2 uv1 = res.uv_rect.p1;
+
+ RectWithEndpoint local_rect = prim_rect;
+ vec2 stretch_size = image_data.stretch_size;
+ if (stretch_size.x < 0.0) {
+ stretch_size = rect_size(local_rect);
+ }
+
+ // If this segment should interpolate relative to the
+ // segment, modify the parameters for that.
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_RELATIVE) != 0) {
+ local_rect = segment_rect;
+ stretch_size = rect_size(local_rect);
+
+ if ((brush_flags & BRUSH_FLAG_TEXEL_RECT) != 0) {
+ // If the extra data is a texel rect, modify the UVs.
+ vec2 uv_size = res.uv_rect.p1 - res.uv_rect.p0;
+ uv0 = res.uv_rect.p0 + segment_data.xy * uv_size;
+ uv1 = res.uv_rect.p0 + segment_data.zw * uv_size;
+ }
+
+ #ifdef WR_FEATURE_REPETITION
+ // TODO(bug 1609893): Move this logic to the CPU as well as other sources of
+ // branchiness in this shader.
+ if ((brush_flags & BRUSH_FLAG_TEXEL_RECT) != 0) {
+ // Value of the stretch size with repetition. We have to compute it for
+ // both axis even if we only repeat on one axis because the value for
+ // each axis depends on what the repeated value would have been for the
+ // other axis.
+ vec2 repeated_stretch_size = stretch_size;
+ // Size of the uv rect of the segment we are considering when computing
+ // the repetitions. For the fill area it is a tad more complicated as we
+ // have to use the uv size of the top-middle segment to drive horizontal
+ // repetitions, and the size of the left-middle segment to drive vertical
+ // repetitions. So we track the reference sizes for both axis separately
+ // even though in the common case (the border segments) they are the same.
+ vec2 horizontal_uv_size = uv1 - uv0;
+ vec2 vertical_uv_size = uv1 - uv0;
+ // We use top and left sizes by default and fall back to bottom and right
+ // when a size is empty.
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_NINEPATCH_MIDDLE) != 0) {
+ repeated_stretch_size = segment_rect.p0 - prim_rect.p0;
+
+ float epsilon = 0.001;
+
+ // Adjust the the referecne uv size to compute vertical repetitions for
+ // the fill area.
+ vertical_uv_size.x = uv0.x - res.uv_rect.p0.x;
+ if (vertical_uv_size.x < epsilon || repeated_stretch_size.x < epsilon) {
+ vertical_uv_size.x = res.uv_rect.p1.x - uv1.x;
+ repeated_stretch_size.x = prim_rect.p1.x - segment_rect.p1.x;
+ }
+
+ // Adjust the the referecne uv size to compute horizontal repetitions
+ // for the fill area.
+ horizontal_uv_size.y = uv0.y - res.uv_rect.p0.y;
+ if (horizontal_uv_size.y < epsilon || repeated_stretch_size.y < epsilon) {
+ horizontal_uv_size.y = res.uv_rect.p1.y - uv1.y;
+ repeated_stretch_size.y = prim_rect.p1.y - segment_rect.p1.y;
+ }
+ }
+
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_REPEAT_X) != 0) {
+ float uv_ratio = horizontal_uv_size.x / horizontal_uv_size.y;
+ stretch_size.x = repeated_stretch_size.y * uv_ratio;
+ }
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_REPEAT_Y) != 0) {
+ float uv_ratio = vertical_uv_size.y / vertical_uv_size.x;
+ stretch_size.y = repeated_stretch_size.x * uv_ratio;
+ }
+
+ } else {
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_REPEAT_X) != 0) {
+ stretch_size.x = segment_data.z - segment_data.x;
+ }
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_REPEAT_Y) != 0) {
+ stretch_size.y = segment_data.w - segment_data.y;
+ }
+ }
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_REPEAT_X_ROUND) != 0) {
+ float segment_rect_width = segment_rect.p1.x - segment_rect.p0.x;
+ float nx = max(1.0, round(segment_rect_width / stretch_size.x));
+ stretch_size.x = segment_rect_width / nx;
+ }
+ if ((brush_flags & BRUSH_FLAG_SEGMENT_REPEAT_Y_ROUND) != 0) {
+ float segment_rect_height = segment_rect.p1.y - segment_rect.p0.y;
+ float ny = max(1.0, round(segment_rect_height / stretch_size.y));
+ stretch_size.y = segment_rect_height / ny;
+ }
+ #endif
+ }
+
+ float perspective_interpolate = (brush_flags & BRUSH_FLAG_PERSPECTIVE_INTERPOLATION) != 0 ? 1.0 : 0.0;
+ v_perspective.x = perspective_interpolate;
+
+ // Handle case where the UV coords are inverted (e.g. from an
+ // external image).
+ vec2 min_uv = min(uv0, uv1);
+ vec2 max_uv = max(uv0, uv1);
+
+ v_uv_sample_bounds = vec4(
+ min_uv + vec2(0.5),
+ max_uv - vec2(0.5)
+ ) / texture_size.xyxy;
+
+ vec2 f = (vi.local_pos - local_rect.p0) / rect_size(local_rect);
+
+#ifdef WR_FEATURE_ALPHA_PASS
+ int color_mode = prim_user_data.x & 0xffff;
+ int blend_mode = prim_user_data.x >> 16;
+
+ if (color_mode == COLOR_MODE_FROM_PASS) {
+ color_mode = uMode;
+ }
+
+#endif
+
+ // Derive the texture coordinates for this image, based on
+ // whether the source image is a local-space or screen-space
+ // image.
+ int raster_space = prim_user_data.y;
+ if (raster_space == RASTER_SCREEN) {
+ // Since the screen space UVs specify an arbitrary quad, do
+ // a bilinear interpolation to get the correct UV for this
+ // local position.
+ f = get_image_quad_uv(specific_resource_address, f);
+ }
+
+ // Offset and scale v_uv here to avoid doing it in the fragment shader.
+ vec2 repeat = rect_size(local_rect) / stretch_size;
+ v_uv = mix(uv0, uv1, f) - min_uv;
+ v_uv /= texture_size;
+ v_uv *= repeat.xy;
+ if (perspective_interpolate == 0.0) {
+ v_uv *= vi.world_pos.w;
+ }
+
+#ifdef WR_FEATURE_TEXTURE_RECT
+ v_uv_bounds = vec4(0.0, 0.0, vec2(textureSize(sColor0)));
+#else
+ v_uv_bounds = vec4(min_uv, max_uv) / texture_size.xyxy;
+#endif
+
+#ifdef WR_FEATURE_REPETITION
+ // Normalize UV to 0..1 scale only if using repetition. Otherwise, leave
+ // UVs unnormalized since we won't compute a modulus without repetition
+ // enabled.
+ v_uv /= (v_uv_bounds.zw - v_uv_bounds.xy);
+#endif
+
+#ifdef WR_FEATURE_ALPHA_PASS
+ v_tile_repeat = repeat.xy;
+
+ float opacity = float(prim_user_data.z) / 65535.0;
+ switch (blend_mode) {
+ case BLEND_MODE_ALPHA:
+ image_data.color.a *= opacity;
+ break;
+ case BLEND_MODE_PREMUL_ALPHA:
+ default:
+ image_data.color *= opacity;
+ break;
+ }
+
+ switch (color_mode) {
+ case COLOR_MODE_ALPHA:
+ case COLOR_MODE_BITMAP_SHADOW:
+ #ifdef SWGL_BLEND
+ swgl_blendDropShadow(image_data.color);
+ v_mask_swizzle = vec2(1.0, 0.0);
+ v_color = vec4(1.0);
+ #else
+ v_mask_swizzle = vec2(0.0, 1.0);
+ v_color = image_data.color;
+ #endif
+ break;
+ case COLOR_MODE_SUBPX_BG_PASS2:
+ case COLOR_MODE_IMAGE:
+ v_mask_swizzle = vec2(1.0, 0.0);
+ v_color = image_data.color;
+ break;
+ case COLOR_MODE_SUBPX_BG_PASS0:
+ case COLOR_MODE_COLOR_BITMAP:
+ v_mask_swizzle = vec2(1.0, 0.0);
+ v_color = vec4(image_data.color.a);
+ break;
+ case COLOR_MODE_SUBPX_BG_PASS1:
+ v_mask_swizzle = vec2(-1.0, 1.0);
+ v_color = vec4(image_data.color.a) * image_data.background_color;
+ break;
+ case COLOR_MODE_SUBPX_DUAL_SOURCE:
+ v_mask_swizzle = vec2(image_data.color.a, 0.0);
+ v_color = image_data.color;
+ break;
+ case COLOR_MODE_MULTIPLY_DUAL_SOURCE:
+ v_mask_swizzle = vec2(-image_data.color.a, image_data.color.a);
+ v_color = image_data.color;
+ break;
+ default:
+ v_mask_swizzle = vec2(0.0);
+ v_color = vec4(1.0);
+ }
+#endif
+}
+#endif
+
+#ifdef WR_FRAGMENT_SHADER
+
+vec2 compute_repeated_uvs(float perspective_divisor) {
+#ifdef WR_FEATURE_REPETITION
+ vec2 uv_size = v_uv_bounds.zw - v_uv_bounds.xy;
+
+ #ifdef WR_FEATURE_ALPHA_PASS
+ // This prevents the uv on the top and left parts of the primitive that was inflated
+ // for anti-aliasing purposes from going beyound the range covered by the regular
+ // (non-inflated) primitive.
+ vec2 local_uv = max(v_uv * perspective_divisor, vec2(0.0));
+
+ // Handle horizontal and vertical repetitions.
+ vec2 repeated_uv = fract(local_uv) * uv_size + v_uv_bounds.xy;
+
+ // This takes care of the bottom and right inflated parts.
+ // We do it after the modulo because the latter wraps around the values exactly on
+ // the right and bottom edges, which we do not want.
+ if (local_uv.x >= v_tile_repeat.x) {
+ repeated_uv.x = v_uv_bounds.z;
+ }
+ if (local_uv.y >= v_tile_repeat.y) {
+ repeated_uv.y = v_uv_bounds.w;
+ }
+ #else
+ vec2 repeated_uv = fract(v_uv * perspective_divisor) * uv_size + v_uv_bounds.xy;
+ #endif
+
+ return repeated_uv;
+#else
+ return v_uv * perspective_divisor + v_uv_bounds.xy;
+#endif
+}
+
+Fragment brush_fs() {
+ float perspective_divisor = mix(gl_FragCoord.w, 1.0, v_perspective.x);
+ vec2 repeated_uv = compute_repeated_uvs(perspective_divisor);
+
+ // Clamp the uvs to avoid sampling artifacts.
+ vec2 uv = clamp(repeated_uv, v_uv_sample_bounds.xy, v_uv_sample_bounds.zw);
+
+ vec4 texel = TEX_SAMPLE(sColor0, uv);
+
+ Fragment frag;
+
+#ifdef WR_FEATURE_ALPHA_PASS
+ #ifdef WR_FEATURE_ANTIALIASING
+ float alpha = antialias_brush();
+ #else
+ float alpha = 1.0;
+ #endif
+ #ifndef WR_FEATURE_DUAL_SOURCE_BLENDING
+ texel.rgb = texel.rgb * v_mask_swizzle.x + texel.aaa * v_mask_swizzle.y;
+ #endif
+
+ vec4 alpha_mask = texel * alpha;
+ frag.color = v_color * alpha_mask;
+
+ #ifdef WR_FEATURE_DUAL_SOURCE_BLENDING
+ frag.blend = alpha_mask * v_mask_swizzle.x + alpha_mask.aaaa * v_mask_swizzle.y;
+ #endif
+#else
+ frag.color = texel;
+#endif
+
+ return frag;
+}
+
+#if defined(SWGL_DRAW_SPAN) && (!defined(WR_FEATURE_ALPHA_PASS) || !defined(WR_FEATURE_DUAL_SOURCE_BLENDING))
+void swgl_drawSpanRGBA8() {
+ if (!swgl_isTextureRGBA8(sColor0)) {
+ return;
+ }
+
+ #ifdef WR_FEATURE_ALPHA_PASS
+ if (v_mask_swizzle != vec2(1.0, 0.0)) {
+ return;
+ }
+ #endif
+
+ float perspective_divisor = mix(swgl_forceScalar(gl_FragCoord.w), 1.0, v_perspective.x);
+
+ #ifdef WR_FEATURE_REPETITION
+ // Get the UVs before any repetition, scaling, or offsetting has occurred...
+ vec2 uv = v_uv * perspective_divisor;
+ #else
+ vec2 uv = compute_repeated_uvs(perspective_divisor);
+ #endif
+
+ #ifdef WR_FEATURE_ALPHA_PASS
+ if (v_color != vec4(1.0)) {
+ #ifdef WR_FEATURE_REPETITION
+ swgl_commitTextureRepeatColorRGBA8(sColor0, uv, v_tile_repeat, v_uv_bounds, v_uv_sample_bounds, v_color);
+ #else
+ swgl_commitTextureColorRGBA8(sColor0, uv, v_uv_sample_bounds, v_color);
+ #endif
+ return;
+ }
+ // No color scaling required, so just fall through to a normal textured span...
+ #endif
+
+ #ifdef WR_FEATURE_REPETITION
+ #ifdef WR_FEATURE_ALPHA_PASS
+ swgl_commitTextureRepeatRGBA8(sColor0, uv, v_tile_repeat, v_uv_bounds, v_uv_sample_bounds);
+ #else
+ swgl_commitTextureRepeatRGBA8(sColor0, uv, vec2(0.0), v_uv_bounds, v_uv_sample_bounds);
+ #endif
+ #else
+ swgl_commitTextureRGBA8(sColor0, uv, v_uv_sample_bounds);
+ #endif
+}
+#endif
+
+#endif