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chromium / chromium / src / b9d6af8dfc9c1bcaabe9d67dd6c30c30b3873cbb / . / cc / output / filter_operation.cc
blob: 198057a265d9643d150ed8d66123192452813e59 [file] [log] [blame]
// Copyright 2013 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 <stddef.h>
#include <algorithm>
#include "base/trace_event/trace_event_argument.h"
#include "base/values.h"
#include "cc/base/math_util.h"
#include "cc/output/filter_operation.h"
#include "ui/gfx/animation/tween.h"
#include "ui/gfx/geometry/rect.h"
#include "ui/gfx/geometry/rect_conversions.h"
#include "ui/gfx/skia_util.h"
namespace cc {
bool FilterOperation::operator==(const FilterOperation& other) const {
if (type_ != other.type_)
return false;
if (type_ == COLOR_MATRIX)
return !memcmp(matrix_, other.matrix_, sizeof(matrix_));
if (type_ == DROP_SHADOW) {
return amount_ == other.amount_ &&
drop_shadow_offset_ == other.drop_shadow_offset_ &&
drop_shadow_color_ == other.drop_shadow_color_;
}
if (type_ == REFERENCE) {
return image_filter_.get() == other.image_filter_.get();
}
if (type_ == ALPHA_THRESHOLD) {
return region_ == other.region_ &&
amount_ == other.amount_ &&
outer_threshold_ == other.outer_threshold_;
}
return amount_ == other.amount_;
}
FilterOperation::FilterOperation() : FilterOperation(GRAYSCALE, 0.f) {}
FilterOperation::FilterOperation(FilterType type, float amount)
: type_(type),
amount_(amount),
outer_threshold_(0),
drop_shadow_offset_(0, 0),
drop_shadow_color_(0),
zoom_inset_(0) {
DCHECK_NE(type_, DROP_SHADOW);
DCHECK_NE(type_, COLOR_MATRIX);
DCHECK_NE(type_, REFERENCE);
memset(matrix_, 0, sizeof(matrix_));
}
FilterOperation::FilterOperation(FilterType type,
const gfx::Point& offset,
float stdDeviation,
SkColor color)
: type_(type),
amount_(stdDeviation),
outer_threshold_(0),
drop_shadow_offset_(offset),
drop_shadow_color_(color),
zoom_inset_(0) {
DCHECK_EQ(type_, DROP_SHADOW);
memset(matrix_, 0, sizeof(matrix_));
}
FilterOperation::FilterOperation(FilterType type, SkScalar matrix[20])
: type_(type),
amount_(0),
outer_threshold_(0),
drop_shadow_offset_(0, 0),
drop_shadow_color_(0),
zoom_inset_(0) {
DCHECK_EQ(type_, COLOR_MATRIX);
memcpy(matrix_, matrix, sizeof(matrix_));
}
FilterOperation::FilterOperation(FilterType type, float amount, int inset)
: type_(type),
amount_(amount),
outer_threshold_(0),
drop_shadow_offset_(0, 0),
drop_shadow_color_(0),
zoom_inset_(inset) {
DCHECK_EQ(type_, ZOOM);
memset(matrix_, 0, sizeof(matrix_));
}
FilterOperation::FilterOperation(FilterType type,
sk_sp<SkImageFilter> image_filter)
: type_(type),
amount_(0),
outer_threshold_(0),
drop_shadow_offset_(0, 0),
drop_shadow_color_(0),
image_filter_(std::move(image_filter)),
zoom_inset_(0) {
DCHECK_EQ(type_, REFERENCE);
memset(matrix_, 0, sizeof(matrix_));
}
FilterOperation::FilterOperation(FilterType type,
const SkRegion& region,
float inner_threshold,
float outer_threshold)
: type_(type),
amount_(inner_threshold),
outer_threshold_(outer_threshold),
drop_shadow_offset_(0, 0),
drop_shadow_color_(0),
zoom_inset_(0),
region_(region) {
DCHECK_EQ(type_, ALPHA_THRESHOLD);
memset(matrix_, 0, sizeof(matrix_));
}
FilterOperation::FilterOperation(const FilterOperation& other)
: type_(other.type_),
amount_(other.amount_),
outer_threshold_(other.outer_threshold_),
drop_shadow_offset_(other.drop_shadow_offset_),
drop_shadow_color_(other.drop_shadow_color_),
image_filter_(other.image_filter_),
zoom_inset_(other.zoom_inset_),
region_(other.region_) {
memcpy(matrix_, other.matrix_, sizeof(matrix_));
}
FilterOperation::~FilterOperation() {
}
static FilterOperation CreateNoOpFilter(FilterOperation::FilterType type) {
switch (type) {
case FilterOperation::GRAYSCALE:
return FilterOperation::CreateGrayscaleFilter(0.f);
case FilterOperation::SEPIA:
return FilterOperation::CreateSepiaFilter(0.f);
case FilterOperation::SATURATE:
return FilterOperation::CreateSaturateFilter(1.f);
case FilterOperation::HUE_ROTATE:
return FilterOperation::CreateHueRotateFilter(0.f);
case FilterOperation::INVERT:
return FilterOperation::CreateInvertFilter(0.f);
case FilterOperation::BRIGHTNESS:
return FilterOperation::CreateBrightnessFilter(1.f);
case FilterOperation::CONTRAST:
return FilterOperation::CreateContrastFilter(1.f);
case FilterOperation::OPACITY:
return FilterOperation::CreateOpacityFilter(1.f);
case FilterOperation::BLUR:
return FilterOperation::CreateBlurFilter(0.f);
case FilterOperation::DROP_SHADOW:
return FilterOperation::CreateDropShadowFilter(
gfx::Point(0, 0), 0.f, SK_ColorTRANSPARENT);
case FilterOperation::COLOR_MATRIX: {
SkScalar matrix[20];
memset(matrix, 0, 20 * sizeof(SkScalar));
matrix[0] = matrix[6] = matrix[12] = matrix[18] = 1.f;
return FilterOperation::CreateColorMatrixFilter(matrix);
}
case FilterOperation::ZOOM:
return FilterOperation::CreateZoomFilter(1.f, 0);
case FilterOperation::SATURATING_BRIGHTNESS:
return FilterOperation::CreateSaturatingBrightnessFilter(0.f);
case FilterOperation::REFERENCE:
return FilterOperation::CreateReferenceFilter(nullptr);
case FilterOperation::ALPHA_THRESHOLD:
return FilterOperation::CreateAlphaThresholdFilter(SkRegion(), 1.f, 0.f);
}
NOTREACHED();
return FilterOperation::CreateEmptyFilter();
}
static float ClampAmountForFilterType(float amount,
FilterOperation::FilterType type) {
switch (type) {
case FilterOperation::GRAYSCALE:
case FilterOperation::SEPIA:
case FilterOperation::INVERT:
case FilterOperation::OPACITY:
case FilterOperation::ALPHA_THRESHOLD:
return MathUtil::ClampToRange(amount, 0.f, 1.f);
case FilterOperation::SATURATE:
case FilterOperation::BRIGHTNESS:
case FilterOperation::CONTRAST:
case FilterOperation::BLUR:
case FilterOperation::DROP_SHADOW:
return std::max(amount, 0.f);
case FilterOperation::ZOOM:
return std::max(amount, 1.f);
case FilterOperation::HUE_ROTATE:
case FilterOperation::SATURATING_BRIGHTNESS:
return amount;
case FilterOperation::COLOR_MATRIX:
case FilterOperation::REFERENCE:
NOTREACHED();
return amount;
}
NOTREACHED();
return amount;
}
// static
FilterOperation FilterOperation::Blend(const FilterOperation* from,
const FilterOperation* to,
double progress) {
FilterOperation blended_filter = FilterOperation::CreateEmptyFilter();
if (!from && !to)
return blended_filter;
const FilterOperation& from_op = from ? *from : CreateNoOpFilter(to->type());
const FilterOperation& to_op = to ? *to : CreateNoOpFilter(from->type());
if (from_op.type() != to_op.type())
return blended_filter;
DCHECK(to_op.type() != FilterOperation::COLOR_MATRIX);
blended_filter.set_type(to_op.type());
if (to_op.type() == FilterOperation::REFERENCE) {
if (progress > 0.5)
blended_filter.set_image_filter(to_op.image_filter());
else
blended_filter.set_image_filter(from_op.image_filter());
return blended_filter;
}
blended_filter.set_amount(ClampAmountForFilterType(
gfx::Tween::FloatValueBetween(progress, from_op.amount(), to_op.amount()),
to_op.type()));
if (to_op.type() == FilterOperation::DROP_SHADOW) {
gfx::Point blended_offset(
gfx::Tween::LinearIntValueBetween(progress,
from_op.drop_shadow_offset().x(),
to_op.drop_shadow_offset().x()),
gfx::Tween::LinearIntValueBetween(progress,
from_op.drop_shadow_offset().y(),
to_op.drop_shadow_offset().y()));
blended_filter.set_drop_shadow_offset(blended_offset);
blended_filter.set_drop_shadow_color(gfx::Tween::ColorValueBetween(
progress, from_op.drop_shadow_color(), to_op.drop_shadow_color()));
} else if (to_op.type() == FilterOperation::ZOOM) {
blended_filter.set_zoom_inset(
std::max(gfx::Tween::LinearIntValueBetween(
progress, from_op.zoom_inset(), to_op.zoom_inset()),
0));
} else if (to_op.type() == FilterOperation::ALPHA_THRESHOLD) {
blended_filter.set_outer_threshold(ClampAmountForFilterType(
gfx::Tween::FloatValueBetween(progress,
from_op.outer_threshold(),
to_op.outer_threshold()),
to_op.type()));
blended_filter.set_region(to_op.region());
}
return blended_filter;
}
void FilterOperation::AsValueInto(base::trace_event::TracedValue* value) const {
value->SetInteger("type", type_);
switch (type_) {
case FilterOperation::GRAYSCALE:
case FilterOperation::SEPIA:
case FilterOperation::SATURATE:
case FilterOperation::HUE_ROTATE:
case FilterOperation::INVERT:
case FilterOperation::BRIGHTNESS:
case FilterOperation::CONTRAST:
case FilterOperation::OPACITY:
case FilterOperation::BLUR:
case FilterOperation::SATURATING_BRIGHTNESS:
value->SetDouble("amount", amount_);
break;
case FilterOperation::DROP_SHADOW:
value->SetDouble("std_deviation", amount_);
MathUtil::AddToTracedValue("offset", drop_shadow_offset_, value);
value->SetInteger("color", drop_shadow_color_);
break;
case FilterOperation::COLOR_MATRIX: {
value->BeginArray("matrix");
for (size_t i = 0; i < arraysize(matrix_); ++i)
value->AppendDouble(matrix_[i]);
value->EndArray();
break;
}
case FilterOperation::ZOOM:
value->SetDouble("amount", amount_);
value->SetDouble("inset", zoom_inset_);
break;
case FilterOperation::REFERENCE: {
int count_inputs = 0;
if (image_filter_) {
count_inputs = image_filter_->countInputs();
}
value->SetBoolean("is_null", !image_filter_);
value->SetInteger("count_inputs", count_inputs);
break;
}
case FilterOperation::ALPHA_THRESHOLD: {
value->SetDouble("inner_threshold", amount_);
value->SetDouble("outer_threshold", outer_threshold_);
std::unique_ptr<base::ListValue> region_value(new base::ListValue());
value->BeginArray("region");
for (SkRegion::Iterator it(region_); !it.done(); it.next()) {
value->AppendInteger(it.rect().x());
value->AppendInteger(it.rect().y());
value->AppendInteger(it.rect().width());
value->AppendInteger(it.rect().height());
}
value->EndArray();
}
break;
}
}
namespace {
SkVector MapStdDeviation(float std_deviation, const SkMatrix& matrix) {
// Corresponds to SpreadForStdDeviation in filter_operations.cc.
SkVector sigma = SkVector::Make(std_deviation, std_deviation);
matrix.mapVectors(&sigma, 1);
return sigma * SkIntToScalar(3);
}
gfx::Rect MapRectInternal(const FilterOperation& op,
const gfx::Rect& rect,
const SkMatrix& matrix,
SkImageFilter::MapDirection direction) {
switch (op.type()) {
case FilterOperation::BLUR: {
SkVector spread = MapStdDeviation(op.amount(), matrix);
float spread_x = std::abs(spread.x());
float spread_y = std::abs(spread.y());
gfx::Rect result = rect;
result.Inset(-spread_x, -spread_y, -spread_x, -spread_y);
return result;
}
case FilterOperation::DROP_SHADOW: {
SkVector spread = MapStdDeviation(op.amount(), matrix);
float spread_x = std::abs(spread.x());
float spread_y = std::abs(spread.y());
gfx::RectF result(rect);
result.Inset(-spread_x, -spread_y, -spread_x, -spread_y);
gfx::Point drop_shadow_offset = op.drop_shadow_offset();
SkVector mapped_drop_shadow_offset;
matrix.mapVector(drop_shadow_offset.x(), drop_shadow_offset.y(),
&mapped_drop_shadow_offset);
if (direction == SkImageFilter::kReverse_MapDirection)
mapped_drop_shadow_offset = -mapped_drop_shadow_offset;
result += gfx::Vector2dF(mapped_drop_shadow_offset.x(),
mapped_drop_shadow_offset.y());
result.Union(gfx::RectF(rect));
return gfx::ToEnclosingRect(result);
}
case FilterOperation::REFERENCE: {
if (!op.image_filter())
return rect;
return gfx::SkIRectToRect(op.image_filter()->filterBounds(
gfx::RectToSkIRect(rect), matrix, direction));
}
default:
return rect;
}
}
} // namespace
gfx::Rect FilterOperation::MapRect(const gfx::Rect& rect,
const SkMatrix& matrix) const {
return MapRectInternal(*this, rect, matrix,
SkImageFilter::kForward_MapDirection);
}
gfx::Rect FilterOperation::MapRectReverse(const gfx::Rect& rect,
const SkMatrix& matrix) const {
return MapRectInternal(*this, rect, matrix,
SkImageFilter::kReverse_MapDirection);
}
} // namespace cc