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chromium / chromium / src / 844158bb22c9b0008e11689bf3370f14295cfe65 / . / cc / output / software_renderer.cc
blob: 7c53b51347e17a59c32d9ff7e95d866773f04376 [file] [log] [blame]
// Copyright 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "cc/output/software_renderer.h"
#include "base/memory/ptr_util.h"
#include "base/trace_event/trace_event.h"
#include "cc/base/math_util.h"
#include "cc/output/copy_output_request.h"
#include "cc/output/output_surface.h"
#include "cc/output/output_surface_frame.h"
#include "cc/output/render_surface_filters.h"
#include "cc/output/renderer_settings.h"
#include "cc/output/software_output_device.h"
#include "cc/quads/debug_border_draw_quad.h"
#include "cc/quads/picture_draw_quad.h"
#include "cc/quads/render_pass_draw_quad.h"
#include "cc/quads/solid_color_draw_quad.h"
#include "cc/quads/texture_draw_quad.h"
#include "cc/quads/tile_draw_quad.h"
#include "cc/resources/scoped_resource.h"
#include "skia/ext/opacity_filter_canvas.h"
#include "third_party/skia/include/core/SkCanvas.h"
#include "third_party/skia/include/core/SkColor.h"
#include "third_party/skia/include/core/SkImageFilter.h"
#include "third_party/skia/include/core/SkMatrix.h"
#include "third_party/skia/include/core/SkPath.h"
#include "third_party/skia/include/core/SkPoint.h"
#include "third_party/skia/include/core/SkShader.h"
#include "third_party/skia/include/effects/SkLayerRasterizer.h"
#include "ui/gfx/geometry/rect_conversions.h"
#include "ui/gfx/skia_util.h"
#include "ui/gfx/transform.h"
namespace cc {
namespace {
static inline bool IsScalarNearlyInteger(SkScalar scalar) {
return SkScalarNearlyZero(scalar - SkScalarRoundToScalar(scalar));
}
bool IsScaleAndIntegerTranslate(const SkMatrix& matrix) {
return IsScalarNearlyInteger(matrix[SkMatrix::kMTransX]) &&
IsScalarNearlyInteger(matrix[SkMatrix::kMTransY]) &&
SkScalarNearlyZero(matrix[SkMatrix::kMSkewX]) &&
SkScalarNearlyZero(matrix[SkMatrix::kMSkewY]) &&
SkScalarNearlyZero(matrix[SkMatrix::kMPersp0]) &&
SkScalarNearlyZero(matrix[SkMatrix::kMPersp1]) &&
SkScalarNearlyZero(matrix[SkMatrix::kMPersp2] - 1.0f);
}
} // anonymous namespace
SoftwareRenderer::SoftwareRenderer(const RendererSettings* settings,
OutputSurface* output_surface,
ResourceProvider* resource_provider)
: DirectRenderer(settings, output_surface, resource_provider),
output_device_(output_surface->software_device()) {
}
SoftwareRenderer::~SoftwareRenderer() {}
bool SoftwareRenderer::CanPartialSwap() {
return true;
}
ResourceFormat SoftwareRenderer::BackbufferFormat() const {
return resource_provider_->best_texture_format();
}
void SoftwareRenderer::BeginDrawingFrame() {
TRACE_EVENT0("cc", "SoftwareRenderer::BeginDrawingFrame");
root_canvas_ = output_device_->BeginPaint(current_frame()->root_damage_rect);
}
void SoftwareRenderer::FinishDrawingFrame() {
TRACE_EVENT0("cc", "SoftwareRenderer::FinishDrawingFrame");
current_framebuffer_lock_ = nullptr;
current_framebuffer_canvas_.reset();
current_canvas_ = nullptr;
root_canvas_ = nullptr;
output_device_->EndPaint();
}
void SoftwareRenderer::SwapBuffers(std::vector<ui::LatencyInfo> latency_info) {
DCHECK(visible_);
TRACE_EVENT0("cc", "SoftwareRenderer::SwapBuffers");
OutputSurfaceFrame output_frame;
output_frame.latency_info = std::move(latency_info);
output_surface_->SwapBuffers(std::move(output_frame));
}
bool SoftwareRenderer::FlippedFramebuffer() const {
return false;
}
void SoftwareRenderer::EnsureScissorTestEnabled() {
is_scissor_enabled_ = true;
SetClipRect(scissor_rect_);
}
void SoftwareRenderer::EnsureScissorTestDisabled() {
// There is no explicit notion of enabling/disabling scissoring in software
// rendering, but the underlying effect we want is to clear any existing
// clipRect on the current SkCanvas. This is done by setting clipRect to
// the viewport's dimensions.
if (!current_canvas_)
return;
is_scissor_enabled_ = false;
SkISize size = current_canvas_->getBaseLayerSize();
SetClipRect(gfx::Rect(size.width(), size.height()));
}
void SoftwareRenderer::BindFramebufferToOutputSurface() {
DCHECK(!output_surface_->HasExternalStencilTest());
current_framebuffer_lock_ = nullptr;
current_framebuffer_canvas_.reset();
current_canvas_ = root_canvas_;
}
bool SoftwareRenderer::BindFramebufferToTexture(
const ScopedResource* texture) {
DCHECK(texture->id());
// Explicitly release lock, otherwise we can crash when try to lock
// same texture again.
current_framebuffer_lock_ = nullptr;
current_framebuffer_lock_ =
base::MakeUnique<ResourceProvider::ScopedWriteLockSoftware>(
resource_provider_, texture->id());
current_framebuffer_canvas_ =
base::MakeUnique<SkCanvas>(current_framebuffer_lock_->sk_bitmap());
current_canvas_ = current_framebuffer_canvas_.get();
return true;
}
void SoftwareRenderer::SetScissorTestRect(const gfx::Rect& scissor_rect) {
is_scissor_enabled_ = true;
scissor_rect_ = scissor_rect;
SetClipRect(scissor_rect);
}
void SoftwareRenderer::SetClipRect(const gfx::Rect& rect) {
if (!current_canvas_)
return;
// Skia applies the current matrix to clip rects so we reset it temporary.
SkMatrix current_matrix = current_canvas_->getTotalMatrix();
current_canvas_->resetMatrix();
// TODO(fmalita) stop using kReplace (see crbug.com/673851)
current_canvas_->clipRect(gfx::RectToSkRect(rect),
SkClipOp::kReplace_deprecated);
current_canvas_->setMatrix(current_matrix);
}
void SoftwareRenderer::ClearCanvas(SkColor color) {
if (!current_canvas_)
return;
current_canvas_->clear(color);
}
void SoftwareRenderer::ClearFramebuffer() {
if (current_frame()->current_render_pass->has_transparent_background) {
ClearCanvas(SkColorSetARGB(0, 0, 0, 0));
} else {
#ifndef NDEBUG
// On DEBUG builds, opaque render passes are cleared to blue
// to easily see regions that were not drawn on the screen.
ClearCanvas(SkColorSetARGB(255, 0, 0, 255));
#endif
}
}
void SoftwareRenderer::PrepareSurfaceForPass(
SurfaceInitializationMode initialization_mode,
const gfx::Rect& render_pass_scissor) {
switch (initialization_mode) {
case SURFACE_INITIALIZATION_MODE_PRESERVE:
EnsureScissorTestDisabled();
return;
case SURFACE_INITIALIZATION_MODE_FULL_SURFACE_CLEAR:
EnsureScissorTestDisabled();
ClearFramebuffer();
break;
case SURFACE_INITIALIZATION_MODE_SCISSORED_CLEAR:
SetScissorTestRect(render_pass_scissor);
ClearFramebuffer();
break;
}
}
bool SoftwareRenderer::IsSoftwareResource(ResourceId resource_id) const {
switch (resource_provider_->GetResourceType(resource_id)) {
case ResourceProvider::RESOURCE_TYPE_GPU_MEMORY_BUFFER:
case ResourceProvider::RESOURCE_TYPE_GL_TEXTURE:
return false;
case ResourceProvider::RESOURCE_TYPE_BITMAP:
return true;
}
LOG(FATAL) << "Invalid resource type.";
return false;
}
void SoftwareRenderer::DoDrawQuad(const DrawQuad* quad,
const gfx::QuadF* draw_region) {
if (!current_canvas_)
return;
if (draw_region) {
current_canvas_->save();
}
TRACE_EVENT0("cc", "SoftwareRenderer::DoDrawQuad");
gfx::Transform quad_rect_matrix;
QuadRectTransform(&quad_rect_matrix,
quad->shared_quad_state->quad_to_target_transform,
gfx::RectF(quad->rect));
gfx::Transform contents_device_transform =
current_frame()->window_matrix * current_frame()->projection_matrix *
quad_rect_matrix;
contents_device_transform.FlattenTo2d();
SkMatrix sk_device_matrix;
gfx::TransformToFlattenedSkMatrix(contents_device_transform,
&sk_device_matrix);
current_canvas_->setMatrix(sk_device_matrix);
current_paint_.reset();
if (settings_->force_antialiasing ||
!IsScaleAndIntegerTranslate(sk_device_matrix)) {
// TODO(danakj): Until we can enable AA only on exterior edges of the
// layer, disable AA if any interior edges are present. crbug.com/248175
bool all_four_edges_are_exterior = quad->IsTopEdge() &&
quad->IsLeftEdge() &&
quad->IsBottomEdge() &&
quad->IsRightEdge();
if (settings_->allow_antialiasing &&
(settings_->force_antialiasing || all_four_edges_are_exterior))
current_paint_.setAntiAlias(true);
current_paint_.setFilterQuality(kLow_SkFilterQuality);
}
if (quad->ShouldDrawWithBlending() ||
quad->shared_quad_state->blend_mode != SkBlendMode::kSrcOver) {
current_paint_.setAlpha(quad->shared_quad_state->opacity * 255);
current_paint_.setBlendMode(quad->shared_quad_state->blend_mode);
} else {
current_paint_.setBlendMode(SkBlendMode::kSrc);
}
if (draw_region) {
gfx::QuadF local_draw_region(*draw_region);
SkPath draw_region_clip_path;
local_draw_region -=
gfx::Vector2dF(quad->visible_rect.x(), quad->visible_rect.y());
local_draw_region.Scale(1.0f / quad->visible_rect.width(),
1.0f / quad->visible_rect.height());
local_draw_region -= gfx::Vector2dF(0.5f, 0.5f);
SkPoint clip_points[4];
QuadFToSkPoints(local_draw_region, clip_points);
draw_region_clip_path.addPoly(clip_points, 4, true);
current_canvas_->clipPath(draw_region_clip_path);
}
switch (quad->material) {
case DrawQuad::DEBUG_BORDER:
DrawDebugBorderQuad(DebugBorderDrawQuad::MaterialCast(quad));
break;
case DrawQuad::PICTURE_CONTENT:
DrawPictureQuad(PictureDrawQuad::MaterialCast(quad));
break;
case DrawQuad::RENDER_PASS:
DrawRenderPassQuad(RenderPassDrawQuad::MaterialCast(quad));
break;
case DrawQuad::SOLID_COLOR:
DrawSolidColorQuad(SolidColorDrawQuad::MaterialCast(quad));
break;
case DrawQuad::TEXTURE_CONTENT:
DrawTextureQuad(TextureDrawQuad::MaterialCast(quad));
break;
case DrawQuad::TILED_CONTENT:
DrawTileQuad(TileDrawQuad::MaterialCast(quad));
break;
case DrawQuad::SURFACE_CONTENT:
// Surface content should be fully resolved to other quad types before
// reaching a direct renderer.
NOTREACHED();
break;
case DrawQuad::INVALID:
case DrawQuad::YUV_VIDEO_CONTENT:
case DrawQuad::STREAM_VIDEO_CONTENT:
DrawUnsupportedQuad(quad);
NOTREACHED();
break;
}
current_canvas_->resetMatrix();
if (draw_region) {
current_canvas_->restore();
}
}
void SoftwareRenderer::DrawDebugBorderQuad(const DebugBorderDrawQuad* quad) {
// We need to apply the matrix manually to have pixel-sized stroke width.
SkPoint vertices[4];
gfx::RectFToSkRect(QuadVertexRect()).toQuad(vertices);
SkPoint transformed_vertices[4];
current_canvas_->getTotalMatrix().mapPoints(transformed_vertices,
vertices,
4);
current_canvas_->resetMatrix();
current_paint_.setColor(quad->color);
current_paint_.setAlpha(quad->shared_quad_state->opacity *
SkColorGetA(quad->color));
current_paint_.setStyle(SkPaint::kStroke_Style);
current_paint_.setStrokeWidth(quad->width);
current_canvas_->drawPoints(SkCanvas::kPolygon_PointMode,
4, transformed_vertices, current_paint_);
}
void SoftwareRenderer::DrawPictureQuad(const PictureDrawQuad* quad) {
SkMatrix content_matrix;
content_matrix.setRectToRect(
gfx::RectFToSkRect(quad->tex_coord_rect),
gfx::RectFToSkRect(QuadVertexRect()),
SkMatrix::kFill_ScaleToFit);
current_canvas_->concat(content_matrix);
const bool needs_transparency =
SkScalarRoundToInt(quad->shared_quad_state->opacity * 255) < 255;
const bool disable_image_filtering =
disable_picture_quad_image_filtering_ || quad->nearest_neighbor;
TRACE_EVENT0("cc", "SoftwareRenderer::DrawPictureQuad");
RasterSource::PlaybackSettings playback_settings;
playback_settings.playback_to_shared_canvas = true;
// Indicates whether content rasterization should happen through an
// ImageHijackCanvas, which causes image decodes to be managed by an
// ImageDecodeCache. PictureDrawQuads are used for resourceless software
// draws, while a GPU ImageDecodeCache may be in use by the compositor
// providing the RasterSource. So we disable the image hijack canvas to avoid
// trying to use the GPU ImageDecodeCache while doing a software draw.
playback_settings.use_image_hijack_canvas = false;
if (needs_transparency || disable_image_filtering) {
// TODO(aelias): This isn't correct in all cases. We should detect these
// cases and fall back to a persistent bitmap backing
// (http://crbug.com/280374).
// TODO(vmpstr): Fold this canvas into playback and have raster source
// accept a set of settings on playback that will determine which canvas to
// apply. (http://crbug.com/594679)
skia::OpacityFilterCanvas filtered_canvas(current_canvas_,
quad->shared_quad_state->opacity,
disable_image_filtering);
quad->raster_source->PlaybackToCanvas(
&filtered_canvas, quad->content_rect, quad->content_rect,
quad->contents_scale, playback_settings);
} else {
quad->raster_source->PlaybackToCanvas(
current_canvas_, quad->content_rect, quad->content_rect,
quad->contents_scale, playback_settings);
}
}
void SoftwareRenderer::DrawSolidColorQuad(const SolidColorDrawQuad* quad) {
gfx::RectF visible_quad_vertex_rect = MathUtil::ScaleRectProportional(
QuadVertexRect(), gfx::RectF(quad->rect), gfx::RectF(quad->visible_rect));
current_paint_.setColor(quad->color);
current_paint_.setAlpha(quad->shared_quad_state->opacity *
SkColorGetA(quad->color));
current_canvas_->drawRect(gfx::RectFToSkRect(visible_quad_vertex_rect),
current_paint_);
}
void SoftwareRenderer::DrawTextureQuad(const TextureDrawQuad* quad) {
if (!IsSoftwareResource(quad->resource_id())) {
DrawUnsupportedQuad(quad);
return;
}
// TODO(skaslev): Add support for non-premultiplied alpha.
ResourceProvider::ScopedReadLockSkImage lock(resource_provider_,
quad->resource_id());
if (!lock.valid())
return;
const SkImage* image = lock.sk_image();
gfx::RectF uv_rect = gfx::ScaleRect(
gfx::BoundingRect(quad->uv_top_left, quad->uv_bottom_right),
image->width(), image->height());
gfx::RectF visible_uv_rect = MathUtil::ScaleRectProportional(
uv_rect, gfx::RectF(quad->rect), gfx::RectF(quad->visible_rect));
SkRect sk_uv_rect = gfx::RectFToSkRect(visible_uv_rect);
gfx::RectF visible_quad_vertex_rect = MathUtil::ScaleRectProportional(
QuadVertexRect(), gfx::RectF(quad->rect), gfx::RectF(quad->visible_rect));
SkRect quad_rect = gfx::RectFToSkRect(visible_quad_vertex_rect);
if (quad->y_flipped)
current_canvas_->scale(1, -1);
bool blend_background =
quad->background_color != SK_ColorTRANSPARENT && !image->isOpaque();
bool needs_layer = blend_background && (current_paint_.getAlpha() != 0xFF);
if (needs_layer) {
current_canvas_->saveLayerAlpha(&quad_rect, current_paint_.getAlpha());
current_paint_.setAlpha(0xFF);
}
if (blend_background) {
SkPaint background_paint;
background_paint.setColor(quad->background_color);
current_canvas_->drawRect(quad_rect, background_paint);
}
current_paint_.setFilterQuality(
quad->nearest_neighbor ? kNone_SkFilterQuality : kLow_SkFilterQuality);
current_canvas_->drawImageRect(image, sk_uv_rect, quad_rect, &current_paint_);
if (needs_layer)
current_canvas_->restore();
}
void SoftwareRenderer::DrawTileQuad(const TileDrawQuad* quad) {
// |resource_provider_| can be NULL in resourceless software draws, which
// should never produce tile quads in the first place.
DCHECK(resource_provider_);
DCHECK(IsSoftwareResource(quad->resource_id()));
ResourceProvider::ScopedReadLockSkImage lock(resource_provider_,
quad->resource_id());
if (!lock.valid())
return;
gfx::RectF visible_tex_coord_rect = MathUtil::ScaleRectProportional(
quad->tex_coord_rect, gfx::RectF(quad->rect),
gfx::RectF(quad->visible_rect));
gfx::RectF visible_quad_vertex_rect = MathUtil::ScaleRectProportional(
QuadVertexRect(), gfx::RectF(quad->rect), gfx::RectF(quad->visible_rect));
SkRect uv_rect = gfx::RectFToSkRect(visible_tex_coord_rect);
current_paint_.setFilterQuality(
quad->nearest_neighbor ? kNone_SkFilterQuality : kLow_SkFilterQuality);
current_canvas_->drawImageRect(lock.sk_image(), uv_rect,
gfx::RectFToSkRect(visible_quad_vertex_rect),
&current_paint_);
}
void SoftwareRenderer::DrawRenderPassQuad(const RenderPassDrawQuad* quad) {
ScopedResource* content_texture =
render_pass_textures_[quad->render_pass_id].get();
DCHECK(content_texture);
DCHECK(content_texture->id());
DCHECK(IsSoftwareResource(content_texture->id()));
ResourceProvider::ScopedReadLockSoftware lock(resource_provider_,
content_texture->id());
if (!lock.valid())
return;
SkRect dest_rect = gfx::RectFToSkRect(QuadVertexRect());
SkRect dest_visible_rect = gfx::RectFToSkRect(
MathUtil::ScaleRectProportional(QuadVertexRect(), gfx::RectF(quad->rect),
gfx::RectF(quad->visible_rect)));
// TODO(sunxd): make this never be empty.
SkRect content_rect =
quad->tex_coord_rect.IsEmpty()
? SkRect::MakeWH(quad->rect.width(), quad->rect.height())
: RectFToSkRect(quad->tex_coord_rect);
const SkBitmap* content = lock.sk_bitmap();
sk_sp<SkImage> filter_image;
const FilterOperations* filters = FiltersForPass(quad->render_pass_id);
if (filters) {
DCHECK(!filters->IsEmpty());
sk_sp<SkImageFilter> image_filter = RenderSurfaceFilters::BuildImageFilter(
*filters, gfx::SizeF(content_texture->size()));
if (image_filter) {
SkIRect result_rect;
// TODO(ajuma): Apply the filter in the same pass as the content where
// possible (e.g. when there's no origin offset). See crbug.com/308201.
filter_image =
ApplyImageFilter(image_filter.get(), quad, *content, &result_rect);
if (result_rect.isEmpty()) {
return;
}
if (filter_image) {
gfx::RectF rect = gfx::SkRectToRectF(SkRect::Make(result_rect));
dest_rect = dest_visible_rect =
gfx::RectFToSkRect(MathUtil::ScaleRectProportional(
QuadVertexRect(), gfx::RectF(quad->rect), rect));
content_rect =
SkRect::MakeWH(result_rect.width(), result_rect.height());
}
}
}
SkMatrix content_mat;
content_mat.setRectToRect(content_rect, dest_rect,
SkMatrix::kFill_ScaleToFit);
sk_sp<SkShader> shader;
if (!filter_image) {
shader =
SkShader::MakeBitmapShader(*content, SkShader::kClamp_TileMode,
SkShader::kClamp_TileMode, &content_mat);
} else {
shader = filter_image->makeShader(SkShader::kClamp_TileMode,
SkShader::kClamp_TileMode, &content_mat);
}
std::unique_ptr<ResourceProvider::ScopedReadLockSoftware> mask_lock;
if (quad->mask_resource_id()) {
mask_lock = std::unique_ptr<ResourceProvider::ScopedReadLockSoftware>(
new ResourceProvider::ScopedReadLockSoftware(resource_provider_,
quad->mask_resource_id()));
if (!mask_lock->valid())
return;
const SkBitmap* mask = mask_lock->sk_bitmap();
// Scale normalized uv rect into absolute texel coordinates.
SkRect mask_rect = gfx::RectFToSkRect(
gfx::ScaleRect(quad->mask_uv_rect, quad->mask_texture_size.width(),
quad->mask_texture_size.height()));
SkMatrix mask_mat;
mask_mat.setRectToRect(mask_rect, dest_rect, SkMatrix::kFill_ScaleToFit);
SkPaint mask_paint;
mask_paint.setShader(
SkShader::MakeBitmapShader(*mask, SkShader::kClamp_TileMode,
SkShader::kClamp_TileMode, &mask_mat));
SkLayerRasterizer::Builder builder;
builder.addLayer(mask_paint);
current_paint_.setRasterizer(builder.detach());
}
// If we have a background filter shader, render its results first.
sk_sp<SkShader> background_filter_shader =
GetBackgroundFilterShader(quad, SkShader::kClamp_TileMode);
if (background_filter_shader) {
SkPaint paint;
paint.setShader(std::move(background_filter_shader));
paint.setRasterizer(current_paint_.refRasterizer());
current_canvas_->drawRect(dest_visible_rect, paint);
}
current_paint_.setShader(std::move(shader));
current_canvas_->drawRect(dest_visible_rect, current_paint_);
}
void SoftwareRenderer::DrawUnsupportedQuad(const DrawQuad* quad) {
#ifdef NDEBUG
current_paint_.setColor(SK_ColorWHITE);
#else
current_paint_.setColor(SK_ColorMAGENTA);
#endif
current_paint_.setAlpha(quad->shared_quad_state->opacity * 255);
current_canvas_->drawRect(gfx::RectFToSkRect(QuadVertexRect()),
current_paint_);
}
void SoftwareRenderer::CopyCurrentRenderPassToBitmap(
std::unique_ptr<CopyOutputRequest> request) {
gfx::Rect copy_rect = current_frame()->current_render_pass->output_rect;
if (request->has_area())
copy_rect.Intersect(request->area());
gfx::Rect window_copy_rect = MoveFromDrawToWindowSpace(copy_rect);
std::unique_ptr<SkBitmap> bitmap(new SkBitmap);
bitmap->setInfo(SkImageInfo::MakeN32Premul(window_copy_rect.width(),
window_copy_rect.height()));
current_canvas_->readPixels(
bitmap.get(), window_copy_rect.x(), window_copy_rect.y());
request->SendBitmapResult(std::move(bitmap));
}
void SoftwareRenderer::DidChangeVisibility() {
if (visible_)
output_surface_->EnsureBackbuffer();
else
output_surface_->DiscardBackbuffer();
}
bool SoftwareRenderer::ShouldApplyBackgroundFilters(
const RenderPassDrawQuad* quad,
const FilterOperations* background_filters) const {
if (!background_filters)
return false;
DCHECK(!background_filters->IsEmpty());
// TODO(hendrikw): Look into allowing background filters to see pixels from
// other render targets. See crbug.com/314867.
return true;
}
// If non-null, auto_bounds will be filled with the automatically-computed
// destination bounds. If null, the output will be the same size as the
// input bitmap.
sk_sp<SkImage> SoftwareRenderer::ApplyImageFilter(
SkImageFilter* filter,
const RenderPassDrawQuad* quad,
const SkBitmap& to_filter,
SkIRect* auto_bounds) const {
if (!filter)
return nullptr;
SkMatrix local_matrix;
local_matrix.setTranslate(quad->filters_origin.x(), quad->filters_origin.y());
local_matrix.postScale(quad->filters_scale.x(), quad->filters_scale.y());
SkIRect dst_rect;
if (auto_bounds) {
dst_rect =
filter->filterBounds(gfx::RectToSkIRect(quad->rect), local_matrix,
SkImageFilter::kForward_MapDirection);
*auto_bounds = dst_rect;
} else {
dst_rect = to_filter.bounds();
}
SkImageInfo dst_info =
SkImageInfo::MakeN32Premul(dst_rect.width(), dst_rect.height());
sk_sp<SkSurface> surface = SkSurface::MakeRaster(dst_info);
if (!surface) {
return nullptr;
}
SkPaint paint;
// Treat subnormal float values as zero for performance.
ScopedSubnormalFloatDisabler disabler;
paint.setImageFilter(filter->makeWithLocalMatrix(local_matrix));
surface->getCanvas()->translate(-dst_rect.x(), -dst_rect.y());
surface->getCanvas()->drawBitmap(to_filter, quad->rect.x(), quad->rect.y(),
&paint);
return surface->makeImageSnapshot();
}
SkBitmap SoftwareRenderer::GetBackdropBitmap(
const gfx::Rect& bounding_rect) const {
SkBitmap bitmap;
bitmap.setInfo(SkImageInfo::MakeN32Premul(bounding_rect.width(),
bounding_rect.height()));
current_canvas_->readPixels(&bitmap, bounding_rect.x(), bounding_rect.y());
return bitmap;
}
gfx::Rect SoftwareRenderer::GetBackdropBoundingBoxForRenderPassQuad(
const RenderPassDrawQuad* quad,
const gfx::Transform& contents_device_transform,
const FilterOperations* background_filters,
gfx::Rect* unclipped_rect) const {
DCHECK(ShouldApplyBackgroundFilters(quad, background_filters));
gfx::Rect backdrop_rect = gfx::ToEnclosingRect(
MathUtil::MapClippedRect(contents_device_transform, QuadVertexRect()));
SkMatrix matrix;
matrix.setScale(quad->filters_scale.x(), quad->filters_scale.y());
backdrop_rect = background_filters->MapRectReverse(backdrop_rect, matrix);
*unclipped_rect = backdrop_rect;
backdrop_rect.Intersect(MoveFromDrawToWindowSpace(
current_frame()->current_render_pass->output_rect));
return backdrop_rect;
}
sk_sp<SkShader> SoftwareRenderer::GetBackgroundFilterShader(
const RenderPassDrawQuad* quad,
SkShader::TileMode content_tile_mode) const {
const FilterOperations* background_filters =
BackgroundFiltersForPass(quad->render_pass_id);
if (!ShouldApplyBackgroundFilters(quad, background_filters))
return nullptr;
gfx::Transform quad_rect_matrix;
QuadRectTransform(&quad_rect_matrix,
quad->shared_quad_state->quad_to_target_transform,
gfx::RectF(quad->rect));
gfx::Transform contents_device_transform =
current_frame()->window_matrix * current_frame()->projection_matrix *
quad_rect_matrix;
contents_device_transform.FlattenTo2d();
gfx::Rect unclipped_rect;
gfx::Rect backdrop_rect = GetBackdropBoundingBoxForRenderPassQuad(
quad, contents_device_transform, background_filters, &unclipped_rect);
// Figure out the transformations to move it back to pixel space.
gfx::Transform contents_device_transform_inverse;
if (!contents_device_transform.GetInverse(&contents_device_transform_inverse))
return nullptr;
SkMatrix filter_backdrop_transform =
contents_device_transform_inverse.matrix();
filter_backdrop_transform.preTranslate(backdrop_rect.x(), backdrop_rect.y());
// Draw what's behind, and apply the filter to it.
SkBitmap backdrop_bitmap = GetBackdropBitmap(backdrop_rect);
gfx::Vector2dF clipping_offset =
(unclipped_rect.top_right() - backdrop_rect.top_right()) +
(backdrop_rect.bottom_left() - unclipped_rect.bottom_left());
sk_sp<SkImageFilter> filter = RenderSurfaceFilters::BuildImageFilter(
*background_filters,
gfx::SizeF(backdrop_bitmap.width(), backdrop_bitmap.height()),
clipping_offset);
sk_sp<SkImage> filter_backdrop_image =
ApplyImageFilter(filter.get(), quad, backdrop_bitmap, nullptr);
if (!filter_backdrop_image)
return nullptr;
return filter_backdrop_image->makeShader(content_tile_mode, content_tile_mode,
&filter_backdrop_transform);
}
} // namespace cc