modules/skottie/src/SkottieAdapter.cpp - skia - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkottieAdapter.h"

 #include "SkMatrix.h"
 #include "SkPath.h"
 #include "SkRRect.h"
 #include "SkSGGradient.h"
 #include "SkSGPath.h"
 #include "SkSGRect.h"
 #include "SkSGTransform.h"
 #include "SkSGTrimEffect.h"
 #include "SkTo.h"
 #include "SkottieValue.h"

 #include <cmath>
 #include <utility>

 namespace skottie {

 RRectAdapter::RRectAdapter(sk_sp<sksg::RRect> wrapped_node)
     : fRRectNode(std::move(wrapped_node)) {}

 void RRectAdapter::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);
 }

 TransformAdapter::TransformAdapter(sk_sp<sksg::Matrix> matrix)
     : fMatrixNode(std::move(matrix)) {}

 void TransformAdapter::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);
 }

 PolyStarAdapter::PolyStarAdapter(sk_sp<sksg::Path> wrapped_node, Type t)
     : fPathNode(std::move(wrapped_node))
     , fType(t) {}

 void PolyStarAdapter::apply() {
     static constexpr int kMaxPointCount = 100000;
     const auto count = SkToUInt(SkTPin(SkScalarRoundToInt(fPointCount), 0, kMaxPointCount));
     const auto arc   = sk_ieee_float_divide(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));
     poly.incReserve(fType == Type::kStar ? count * 2 : count);

     for (unsigned 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);
 }

 GradientAdapter::GradientAdapter(sk_sp<sksg::Gradient> grad, size_t stopCount)
     : fGradient(std::move(grad))
     , fStopCount(stopCount) {}

 void GradientAdapter::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) {
         const auto pos = cs[0];
         const VectorValue rgb({ cs[1], cs[2], cs[3] });

         stops.push_back({ pos, ValueTraits<VectorValue>::As<SkColor>(rgb) });
     }

     fGradient->setColorStops(std::move(stops));
 }

 LinearGradientAdapter::LinearGradientAdapter(sk_sp<sksg::LinearGradient> grad, size_t stopCount)
     : INHERITED(std::move(grad), stopCount) {}

 void LinearGradientAdapter::onApply() {
     auto* grad = static_cast<sksg::LinearGradient*>(fGradient.get());
     grad->setStartPoint(this->startPoint());
     grad->setEndPoint(this->endPoint());
 }

 RadialGradientAdapter::RadialGradientAdapter(sk_sp<sksg::RadialGradient> grad, size_t stopCount)
     : INHERITED(std::move(grad), stopCount) {}

 void RadialGradientAdapter::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()));
 }

 TrimEffectAdapter::TrimEffectAdapter(sk_sp<sksg::TrimEffect> trimEffect)
     : fTrimEffect(std::move(trimEffect)) {
     SkASSERT(fTrimEffect);
 }

 void TrimEffectAdapter::apply() {
     // BM semantics: start/end are percentages, offset is "degrees" (?!).
     const auto  start = fStart  / 100,
                   end = fEnd    / 100,
                offset = fOffset / 360;

     auto startT = SkTMin(start, end) + offset,
           stopT = SkTMax(start, end) + offset;
     auto   mode = SkTrimPathEffect::Mode::kNormal;

     if (stopT - startT < 1) {
         startT -= SkScalarFloorToScalar(startT);
         stopT  -= SkScalarFloorToScalar(stopT);

         if (startT > stopT) {
             using std::swap;
             swap(startT, stopT);
             mode = SkTrimPathEffect::Mode::kInverted;
         }
     } else {
         startT = 0;
         stopT  = 1;
     }

     fTrimEffect->setStart(startT);
     fTrimEffect->setStop(stopT);
     fTrimEffect->setMode(mode);
 }

 } // namespace skottie
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkottieAdapter.h"

	#include "SkMatrix.h"
	#include "SkPath.h"
	#include "SkRRect.h"
	#include "SkSGGradient.h"
	#include "SkSGPath.h"
	#include "SkSGRect.h"
	#include "SkSGTransform.h"
	#include "SkSGTrimEffect.h"
	#include "SkTo.h"
	#include "SkottieValue.h"

	#include <cmath>
	#include <utility>

	namespace skottie {

	RRectAdapter::RRectAdapter(sk_sp<sksg::RRect> wrapped_node)
	: fRRectNode(std::move(wrapped_node)) {}

	void RRectAdapter::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);
	}

	TransformAdapter::TransformAdapter(sk_sp<sksg::Matrix> matrix)
	: fMatrixNode(std::move(matrix)) {}

	void TransformAdapter::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);
	}

	PolyStarAdapter::PolyStarAdapter(sk_sp<sksg::Path> wrapped_node, Type t)
	: fPathNode(std::move(wrapped_node))
	, fType(t) {}

	void PolyStarAdapter::apply() {
	static constexpr int kMaxPointCount = 100000;
	const auto count = SkToUInt(SkTPin(SkScalarRoundToInt(fPointCount), 0, kMaxPointCount));
	const auto arc = sk_ieee_float_divide(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));
	poly.incReserve(fType == Type::kStar ? count * 2 : count);

	for (unsigned 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);
	}

	GradientAdapter::GradientAdapter(sk_sp<sksg::Gradient> grad, size_t stopCount)
	: fGradient(std::move(grad))
	, fStopCount(stopCount) {}

	void GradientAdapter::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) {
	const auto pos = cs[0];
	const VectorValue rgb({ cs[1], cs[2], cs[3] });

	stops.push_back({ pos, ValueTraits<VectorValue>::As<SkColor>(rgb) });
	}

	fGradient->setColorStops(std::move(stops));
	}

	LinearGradientAdapter::LinearGradientAdapter(sk_sp<sksg::LinearGradient> grad, size_t stopCount)
	: INHERITED(std::move(grad), stopCount) {}

	void LinearGradientAdapter::onApply() {
	auto* grad = static_cast<sksg::LinearGradient*>(fGradient.get());
	grad->setStartPoint(this->startPoint());
	grad->setEndPoint(this->endPoint());
	}

	RadialGradientAdapter::RadialGradientAdapter(sk_sp<sksg::RadialGradient> grad, size_t stopCount)
	: INHERITED(std::move(grad), stopCount) {}

	void RadialGradientAdapter::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()));
	}

	TrimEffectAdapter::TrimEffectAdapter(sk_sp<sksg::TrimEffect> trimEffect)
	: fTrimEffect(std::move(trimEffect)) {
	SkASSERT(fTrimEffect);
	}

	void TrimEffectAdapter::apply() {
	// BM semantics: start/end are percentages, offset is "degrees" (?!).
	const auto start = fStart / 100,
	end = fEnd / 100,
	offset = fOffset / 360;

	auto startT = SkTMin(start, end) + offset,
	stopT = SkTMax(start, end) + offset;
	auto mode = SkTrimPathEffect::Mode::kNormal;

	if (stopT - startT < 1) {
	startT -= SkScalarFloorToScalar(startT);
	stopT -= SkScalarFloorToScalar(stopT);

	if (startT > stopT) {
	using std::swap;
	swap(startT, stopT);
	mode = SkTrimPathEffect::Mode::kInverted;
	}
	} else {
	startT = 0;
	stopT = 1;
	}

	fTrimEffect->setStart(startT);
	fTrimEffect->setStop(stopT);
	fTrimEffect->setMode(mode);
	}

	} // namespace skottie