experimental/skottie/SkottieAnimator.cpp - platform/external/skia - Gitiles

 /*
  * 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 "SkottieAnimator.h"

 namespace skottie {

 namespace {

 SkScalar lerp_scalar(float v0, float v1, float t) {
     SkASSERT(t >= 0 && t <= 1);
     return v0 * (1 - t) + v1 * t;
 }

 static inline SkPoint ParsePoint(const Json::Value& v, const SkPoint& defaultValue) {
     if (!v.isObject())
         return defaultValue;

     const auto& vx = v["x"];
     const auto& vy = v["y"];

     // Some BM versions seem to store x/y as single-element arrays.
     return SkPoint::Make(ParseScalar(vx.isArray() ? vx[0] : vx, defaultValue.x()),
                          ParseScalar(vy.isArray() ? vy[0] : vy, defaultValue.y()));
 }

 } // namespace

 bool KeyframeIntervalBase::parse(const Json::Value& k, KeyframeIntervalBase* prev) {
     SkASSERT(k.isObject());

     fT0 = fT1 = ParseScalar(k["t"], SK_ScalarMin);
     if (fT0 == SK_ScalarMin) {
         return false;
     }

     if (prev) {
         if (prev->fT1 >= fT0) {
             LOG("!! Dropping out-of-order key frame (t: %f < t: %f)\n", fT0, prev->fT1);
             return false;
         }
         // Back-fill t1 in prev interval.  Note: we do this even if we end up discarding
         // the current interval (to support "t"-only final frames).
         prev->fT1 = fT0;
     }

     fHold = ParseBool(k["h"], false);

     if (!fHold) {
         // default is linear lerp
         static constexpr SkPoint kDefaultC0 = { 0, 0 },
                                  kDefaultC1 = { 1, 1 };
         const auto c0 = ParsePoint(k["i"], kDefaultC0),
                    c1 = ParsePoint(k["o"], kDefaultC1);

         if (c0 != kDefaultC0 || c1 != kDefaultC1) {
             fCubicMap = skstd::make_unique<SkCubicMap>();
             // TODO: why do we have to plug these inverted?
             fCubicMap->setPts(c1, c0);
         }
     }

     return true;
 }

 float KeyframeIntervalBase::localT(float t) const {
     SkASSERT(this->isValid());
     SkASSERT(!this->isHold());
     SkASSERT(t > fT0 && t < fT1);

     auto lt = (t - fT0) / (fT1 - fT0);

     return fCubicMap ? fCubicMap->computeYFromX(lt) : lt;
 }

 template <>
 void KeyframeInterval<ScalarValue>::lerp(float t, ScalarValue* v) const {
     const auto lt = this->localT(t);
     *v = lerp_scalar(fV0, fV1, lt);
 }

 template <>
 void KeyframeInterval<VectorValue>::lerp(float t, VectorValue* v) const {
     SkASSERT(fV0.size() == fV1.size());
     SkASSERT(v->size() == 0);

     const auto lt = this->localT(t);

     v->reserve(fV0.size());
     for (size_t i = 0; i < fV0.size(); ++i) {
         v->push_back(lerp_scalar(fV0[i], fV1[i], lt));
     }
 }

 template <>
 void KeyframeInterval<ShapeValue>::lerp(float t, ShapeValue* v) const {
     SkASSERT(fV0.countVerbs() == fV1.countVerbs());
     SkASSERT(v->isEmpty());

     const auto lt = this->localT(t);
     SkAssertResult(fV1.interpolate(fV0, lt, v));
     v->setIsVolatile(true);
 }

 } // namespace skottie
	/*
	* 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 "SkottieAnimator.h"

	namespace skottie {

	namespace {

	SkScalar lerp_scalar(float v0, float v1, float t) {
	SkASSERT(t >= 0 && t <= 1);
	return v0 * (1 - t) + v1 * t;
	}

	static inline SkPoint ParsePoint(const Json::Value& v, const SkPoint& defaultValue) {
	if (!v.isObject())
	return defaultValue;

	const auto& vx = v["x"];
	const auto& vy = v["y"];

	// Some BM versions seem to store x/y as single-element arrays.
	return SkPoint::Make(ParseScalar(vx.isArray() ? vx[0] : vx, defaultValue.x()),
	ParseScalar(vy.isArray() ? vy[0] : vy, defaultValue.y()));
	}

	} // namespace

	bool KeyframeIntervalBase::parse(const Json::Value& k, KeyframeIntervalBase* prev) {
	SkASSERT(k.isObject());

	fT0 = fT1 = ParseScalar(k["t"], SK_ScalarMin);
	if (fT0 == SK_ScalarMin) {
	return false;
	}

	if (prev) {
	if (prev->fT1 >= fT0) {
	LOG("!! Dropping out-of-order key frame (t: %f < t: %f)\n", fT0, prev->fT1);
	return false;
	}
	// Back-fill t1 in prev interval. Note: we do this even if we end up discarding
	// the current interval (to support "t"-only final frames).
	prev->fT1 = fT0;
	}

	fHold = ParseBool(k["h"], false);

	if (!fHold) {
	// default is linear lerp
	static constexpr SkPoint kDefaultC0 = { 0, 0 },
	kDefaultC1 = { 1, 1 };
	const auto c0 = ParsePoint(k["i"], kDefaultC0),
	c1 = ParsePoint(k["o"], kDefaultC1);

	if (c0 != kDefaultC0 \|\| c1 != kDefaultC1) {
	fCubicMap = skstd::make_unique<SkCubicMap>();
	// TODO: why do we have to plug these inverted?
	fCubicMap->setPts(c1, c0);
	}
	}

	return true;
	}

	float KeyframeIntervalBase::localT(float t) const {
	SkASSERT(this->isValid());
	SkASSERT(!this->isHold());
	SkASSERT(t > fT0 && t < fT1);

	auto lt = (t - fT0) / (fT1 - fT0);

	return fCubicMap ? fCubicMap->computeYFromX(lt) : lt;
	}

	template <>
	void KeyframeInterval<ScalarValue>::lerp(float t, ScalarValue* v) const {
	const auto lt = this->localT(t);
	*v = lerp_scalar(fV0, fV1, lt);
	}

	template <>
	void KeyframeInterval<VectorValue>::lerp(float t, VectorValue* v) const {
	SkASSERT(fV0.size() == fV1.size());
	SkASSERT(v->size() == 0);

	const auto lt = this->localT(t);

	v->reserve(fV0.size());
	for (size_t i = 0; i < fV0.size(); ++i) {
	v->push_back(lerp_scalar(fV0[i], fV1[i], lt));
	}
	}

	template <>
	void KeyframeInterval<ShapeValue>::lerp(float t, ShapeValue* v) const {
	SkASSERT(fV0.countVerbs() == fV1.countVerbs());
	SkASSERT(v->isEmpty());

	const auto lt = this->localT(t);
	SkAssertResult(fV1.interpolate(fV0, lt, v));
	v->setIsVolatile(true);
	}

	} // namespace skottie