skia2/experimental/skottie/SkottieProperties.cpp
Florin Malita cf8ed52895 [skottie] Parser cleanup
Consolidate parsing utils into their own CU.

TBR=

Change-Id: Idbf6db5220135ba91df6ebefce3a241c6ec4af15
Reviewed-on: https://skia-review.googlesource.com/99721
Reviewed-by: Florin Malita <fmalita@chromium.org>
Commit-Queue: Florin Malita <fmalita@chromium.org>
2018-01-25 21:23:18 +00:00

194 lines
5.6 KiB
C++

/*
* Copyright 2017 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkottieProperties.h"
#include "SkColor.h"
#include "SkJSONCPP.h"
#include "SkPath.h"
#include "SkSGColor.h"
#include "SkSGGradient.h"
#include "SkSGPath.h"
#include "SkSGRect.h"
#include "SkSGTransform.h"
#include <cmath>
namespace skottie {
namespace {
SkColor VecToColor(const float* v, size_t size) {
// best effort to turn this into a color
const auto r = size > 0 ? v[0] : 0,
g = size > 1 ? v[1] : 0,
b = size > 2 ? v[2] : 0,
a = size > 3 ? v[3] : 1;
return SkColorSetARGB(SkTPin<SkScalar>(a, 0, 1) * 255,
SkTPin<SkScalar>(r, 0, 1) * 255,
SkTPin<SkScalar>(g, 0, 1) * 255,
SkTPin<SkScalar>(b, 0, 1) * 255);
}
} // namespace
template <>
size_t ValueTraits<ScalarValue>::Cardinality(const ScalarValue&) {
return 1;
}
template <>
template <>
SkScalar ValueTraits<ScalarValue>::As<SkScalar>(const ScalarValue& v) {
return v;
}
template <>
size_t ValueTraits<VectorValue>::Cardinality(const VectorValue& vec) {
return vec.size();
}
template <>
template <>
SkColor ValueTraits<VectorValue>::As<SkColor>(const VectorValue& vec) {
return VecToColor(vec.data(), vec.size());
}
template <>
template <>
SkPoint ValueTraits<VectorValue>::As<SkPoint>(const VectorValue& vec) {
// best effort to turn this into a point
const auto x = vec.size() > 0 ? vec[0] : 0,
y = vec.size() > 1 ? vec[1] : 0;
return SkPoint::Make(x, y);
}
template <>
template <>
SkSize ValueTraits<VectorValue>::As<SkSize>(const VectorValue& vec) {
const auto pt = ValueTraits::As<SkPoint>(vec);
return SkSize::Make(pt.x(), pt.y());
}
template <>
size_t ValueTraits<ShapeValue>::Cardinality(const ShapeValue& path) {
return SkTo<size_t>(path.countVerbs());
}
template <>
template <>
SkPath ValueTraits<ShapeValue>::As<SkPath>(const ShapeValue& path) {
return path;
}
CompositeRRect::CompositeRRect(sk_sp<sksg::RRect> wrapped_node)
: fRRectNode(std::move(wrapped_node)) {}
void CompositeRRect::apply() {
// BM "position" == "center position"
auto rr = SkRRect::MakeRectXY(SkRect::MakeXYWH(fPosition.x() - fSize.width() / 2,
fPosition.y() - fSize.height() / 2,
fSize.width(), fSize.height()),
fRadius.width(),
fRadius.height());
fRRectNode->setRRect(rr);
}
CompositeTransform::CompositeTransform(sk_sp<sksg::Matrix> matrix)
: fMatrixNode(std::move(matrix)) {}
void CompositeTransform::apply() {
SkMatrix t = SkMatrix::MakeTrans(-fAnchorPoint.x(), -fAnchorPoint.y());
t.postScale(fScale.x() / 100, fScale.y() / 100); // 100% based
t.postRotate(fRotation);
t.postTranslate(fPosition.x(), fPosition.y());
// TODO: skew
fMatrixNode->setMatrix(t);
}
CompositePolyStar::CompositePolyStar(sk_sp<sksg::Path> wrapped_node, Type t)
: fPathNode(std::move(wrapped_node))
, fType(t) {}
void CompositePolyStar::apply() {
const auto count = SkScalarTruncToInt(fPointCount);
const auto arc = SK_ScalarPI * 2 / count;
const auto pt_on_circle = [](const SkPoint& c, SkScalar r, SkScalar a) {
return SkPoint::Make(c.x() + r * std::cos(a),
c.y() + r * std::sin(a));
};
// TODO: inner/outer "roundness"?
SkPath poly;
auto angle = SkDegreesToRadians(fRotation);
poly.moveTo(pt_on_circle(fPosition, fOuterRadius, angle));
for (int i = 0; i < count; ++i) {
if (fType == Type::kStar) {
poly.lineTo(pt_on_circle(fPosition, fInnerRadius, angle + arc * 0.5f));
}
angle += arc;
poly.lineTo(pt_on_circle(fPosition, fOuterRadius, angle));
}
poly.close();
fPathNode->setPath(poly);
}
CompositeGradient::CompositeGradient(sk_sp<sksg::Gradient> grad, size_t stopCount)
: fGradient(std::move(grad))
, fStopCount(stopCount) {}
void CompositeGradient::apply() {
this->onApply();
// |fColorStops| holds |fStopCount| x [ pos, r, g, g ] + ? x [ pos, alpha ]
if (fColorStops.size() < fStopCount * 4 || ((fColorStops.size() - fStopCount * 4) % 2)) {
SkDebugf("!! Invalid gradient stop array size: %zu", fColorStops.size());
return;
}
std::vector<sksg::Gradient::ColorStop> stops;
// TODO: merge/lerp opacity stops
const auto csEnd = fColorStops.cbegin() + fStopCount * 4;
for (auto cs = fColorStops.cbegin(); cs != csEnd; cs += 4) {
stops.push_back({ *cs, VecToColor(&*(cs + 1), 3) });
}
fGradient->setColorStops(std::move(stops));
}
CompositeLinearGradient::CompositeLinearGradient(sk_sp<sksg::LinearGradient> grad, size_t stopCount)
: INHERITED(std::move(grad), stopCount) {}
void CompositeLinearGradient::onApply() {
auto* grad = static_cast<sksg::LinearGradient*>(fGradient.get());
grad->setStartPoint(this->startPoint());
grad->setEndPoint(this->endPoint());
}
CompositeRadialGradient::CompositeRadialGradient(sk_sp<sksg::RadialGradient> grad, size_t stopCount)
: INHERITED(std::move(grad), stopCount) {}
void CompositeRadialGradient::onApply() {
auto* grad = static_cast<sksg::RadialGradient*>(fGradient.get());
grad->setStartCenter(this->startPoint());
grad->setEndCenter(this->startPoint());
grad->setStartRadius(0);
grad->setEndRadius(SkPoint::Distance(this->startPoint(), this->endPoint()));
}
} // namespace skottie