content/child/touch_fling_gesture_curve.cc - platform/external/chromium_org - Git at Google

 // Copyright 2014 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 "content/child/touch_fling_gesture_curve.h"

 #include <cmath>

 #include "base/debug/trace_event.h"
 #include "base/logging.h"
 #include "third_party/WebKit/public/platform/WebFloatPoint.h"
 #include "third_party/WebKit/public/platform/WebFloatSize.h"
 #include "third_party/WebKit/public/platform/WebGestureCurve.h"
 #include "third_party/WebKit/public/platform/WebGestureCurveTarget.h"
 #include "third_party/WebKit/public/platform/WebSize.h"

 using blink::WebFloatPoint;
 using blink::WebFloatSize;
 using blink::WebGestureCurve;
 using blink::WebGestureCurveTarget;
 using blink::WebSize;

 namespace {

 const char* kCurveName = "TouchFlingGestureCurve";

 inline double position(double t, float* p) {
   return p[0] * exp(-p[2] * t) - p[1] * t - p[0];
 }

 inline double velocity(double t, float* p) {
   return -p[0] * p[2] * exp(-p[2] * t) - p[1];
 }

 inline double timeAtVelocity(double v, float* p) {
     DCHECK(p[0]);
     DCHECK(p[2]);
     return -log((v + p[1]) / (-p[0] * p[2])) / p[2];
 }

 } // namespace


 namespace content {

 // This curve implementation is based on the notion of a single, absolute
 // curve, which starts at a large velocity and smoothly decreases to
 // zero. For a given input velocity, we find where on the curve this
 // velocity occurs, and start the animation at this point---denoted by
 // (time_offset_, position_offset_).
 //
 // This has the effect of automatically determining an animation duration
 // that scales with input velocity, as faster initial velocities start
 // earlier on the curve and thus take longer to reach the end. No
 // complicated time scaling is required.
 //
 // Since the starting velocity is implicitly determined by our starting
 // point, we only store the relative magnitude and direction of both
 // initial x- and y-velocities, and use this to scale the computed
 // displacement at any point in time. This guarantees that fling
 // trajectories are straight lines when viewed in x-y space. Initial
 // velocities that lie outside the max velocity are constrained to start
 // at zero (and thus are implicitly scaled).
 //
 // The curve is modelled as a 4th order polynomial, starting at t = 0,
 // and ending at t = curve_duration_. Attempts to generate
 // position/velocity estimates outside this range are undefined.

 WebGestureCurve* TouchFlingGestureCurve::Create(
     const WebFloatPoint& initial_velocity,
     float p0,
     float p1,
     float p2,
     const WebSize& cumulative_scroll) {
   return new TouchFlingGestureCurve(initial_velocity, p0, p1, p2,
                                     cumulative_scroll);
 }

 TouchFlingGestureCurve::TouchFlingGestureCurve(
     const WebFloatPoint& initial_velocity,
     float alpha,
     float beta,
     float gamma,
     const WebSize& cumulative_scroll)
     : cumulative_scroll_(WebFloatSize(cumulative_scroll.width,
                                       cumulative_scroll.height)) {
   DCHECK(initial_velocity != WebFloatPoint());

   coefficients_[0] = alpha;
   coefficients_[1] = beta;
   coefficients_[2] = gamma;

   // Curve ends when velocity reaches zero.
   curve_duration_ = timeAtVelocity(0, coefficients_);
   DCHECK(curve_duration_ > 0);

   float max_start_velocity = std::max(fabs(initial_velocity.x),
                                       fabs(initial_velocity.y));

   // Force max_start_velocity to lie in the range v(0) to v(curve_duration),
   // and assume that the curve parameters define a monotonically decreasing
   // velocity, or else bisection search may fail.
   if (max_start_velocity > velocity(0, coefficients_))
     max_start_velocity = velocity(0, coefficients_);

   if (max_start_velocity < 0)
     max_start_velocity = 0;

   // We keep track of relative magnitudes and directions of the
   // velocity/displacement components here.
   displacement_ratio_ = WebFloatPoint(initial_velocity.x / max_start_velocity,
                                       initial_velocity.y / max_start_velocity);

   // Compute time-offset for start velocity.
   time_offset_ = timeAtVelocity(max_start_velocity, coefficients_);

   // Compute curve position at offset time
   position_offset_ = position(time_offset_, coefficients_);
   TRACE_EVENT_ASYNC_BEGIN1("input", "GestureAnimation", this, "curve",
       kCurveName);
 }

 TouchFlingGestureCurve::~TouchFlingGestureCurve() {
   TRACE_EVENT_ASYNC_END0("input", "GestureAnimation", this);
 }

 bool TouchFlingGestureCurve::apply(double time, WebGestureCurveTarget* target) {
   // If the fling has yet to start, simply return and report true to prevent
   // fling termination.
   if (time <= 0)
     return true;

   float displacement;
   float speed;
   if (time + time_offset_ < curve_duration_) {
     displacement =
         position(time + time_offset_, coefficients_) - position_offset_;
     speed = velocity(time + time_offset_, coefficients_);
   } else {
     displacement = position(curve_duration_, coefficients_) - position_offset_;
     speed = 0.f;
   }

   // Keep track of integer portion of scroll thus far, and prepare increment.
   WebFloatSize scroll(displacement * displacement_ratio_.x,
                       displacement * displacement_ratio_.y);
   WebFloatSize scroll_increment(scroll.width - cumulative_scroll_.width,
                                 scroll.height - cumulative_scroll_.height);
   WebFloatSize scroll_velocity(speed * displacement_ratio_.x,
                                speed * displacement_ratio_.y);
   cumulative_scroll_ = scroll;

   if (time + time_offset_ < curve_duration_ ||
       scroll_increment != WebFloatSize()) {
     // scrollBy() could delete this curve if the animation is over, so don't
     // touch any member variables after making that call.
     return target->scrollBy(scroll_increment, scroll_velocity);
   }

   return false;
 }

 } // namespace content
	// Copyright 2014 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 "content/child/touch_fling_gesture_curve.h"

	#include <cmath>

	#include "base/debug/trace_event.h"
	#include "base/logging.h"
	#include "third_party/WebKit/public/platform/WebFloatPoint.h"
	#include "third_party/WebKit/public/platform/WebFloatSize.h"
	#include "third_party/WebKit/public/platform/WebGestureCurve.h"
	#include "third_party/WebKit/public/platform/WebGestureCurveTarget.h"
	#include "third_party/WebKit/public/platform/WebSize.h"

	using blink::WebFloatPoint;
	using blink::WebFloatSize;
	using blink::WebGestureCurve;
	using blink::WebGestureCurveTarget;
	using blink::WebSize;

	namespace {

	const char* kCurveName = "TouchFlingGestureCurve";

	inline double position(double t, float* p) {
	return p[0] * exp(-p[2] * t) - p[1] * t - p[0];
	}

	inline double velocity(double t, float* p) {
	return -p[0] * p[2] * exp(-p[2] * t) - p[1];
	}

	inline double timeAtVelocity(double v, float* p) {
	DCHECK(p[0]);
	DCHECK(p[2]);
	return -log((v + p[1]) / (-p[0] * p[2])) / p[2];
	}

	} // namespace


	namespace content {

	// This curve implementation is based on the notion of a single, absolute
	// curve, which starts at a large velocity and smoothly decreases to
	// zero. For a given input velocity, we find where on the curve this
	// velocity occurs, and start the animation at this point---denoted by
	// (time_offset_, position_offset_).
	//
	// This has the effect of automatically determining an animation duration
	// that scales with input velocity, as faster initial velocities start
	// earlier on the curve and thus take longer to reach the end. No
	// complicated time scaling is required.
	//
	// Since the starting velocity is implicitly determined by our starting
	// point, we only store the relative magnitude and direction of both
	// initial x- and y-velocities, and use this to scale the computed
	// displacement at any point in time. This guarantees that fling
	// trajectories are straight lines when viewed in x-y space. Initial
	// velocities that lie outside the max velocity are constrained to start
	// at zero (and thus are implicitly scaled).
	//
	// The curve is modelled as a 4th order polynomial, starting at t = 0,
	// and ending at t = curve_duration_. Attempts to generate
	// position/velocity estimates outside this range are undefined.

	WebGestureCurve* TouchFlingGestureCurve::Create(
	const WebFloatPoint& initial_velocity,
	float p0,
	float p1,
	float p2,
	const WebSize& cumulative_scroll) {
	return new TouchFlingGestureCurve(initial_velocity, p0, p1, p2,
	cumulative_scroll);
	}

	TouchFlingGestureCurve::TouchFlingGestureCurve(
	const WebFloatPoint& initial_velocity,
	float alpha,
	float beta,
	float gamma,
	const WebSize& cumulative_scroll)
	: cumulative_scroll_(WebFloatSize(cumulative_scroll.width,
	cumulative_scroll.height)) {
	DCHECK(initial_velocity != WebFloatPoint());

	coefficients_[0] = alpha;
	coefficients_[1] = beta;
	coefficients_[2] = gamma;

	// Curve ends when velocity reaches zero.
	curve_duration_ = timeAtVelocity(0, coefficients_);
	DCHECK(curve_duration_ > 0);

	float max_start_velocity = std::max(fabs(initial_velocity.x),
	fabs(initial_velocity.y));

	// Force max_start_velocity to lie in the range v(0) to v(curve_duration),
	// and assume that the curve parameters define a monotonically decreasing
	// velocity, or else bisection search may fail.
	if (max_start_velocity > velocity(0, coefficients_))
	max_start_velocity = velocity(0, coefficients_);

	if (max_start_velocity < 0)
	max_start_velocity = 0;

	// We keep track of relative magnitudes and directions of the
	// velocity/displacement components here.
	displacement_ratio_ = WebFloatPoint(initial_velocity.x / max_start_velocity,
	initial_velocity.y / max_start_velocity);

	// Compute time-offset for start velocity.
	time_offset_ = timeAtVelocity(max_start_velocity, coefficients_);

	// Compute curve position at offset time
	position_offset_ = position(time_offset_, coefficients_);
	TRACE_EVENT_ASYNC_BEGIN1("input", "GestureAnimation", this, "curve",
	kCurveName);
	}

	TouchFlingGestureCurve::~TouchFlingGestureCurve() {
	TRACE_EVENT_ASYNC_END0("input", "GestureAnimation", this);
	}

	bool TouchFlingGestureCurve::apply(double time, WebGestureCurveTarget* target) {
	// If the fling has yet to start, simply return and report true to prevent
	// fling termination.
	if (time <= 0)
	return true;

	float displacement;
	float speed;
	if (time + time_offset_ < curve_duration_) {
	displacement =
	position(time + time_offset_, coefficients_) - position_offset_;
	speed = velocity(time + time_offset_, coefficients_);
	} else {
	displacement = position(curve_duration_, coefficients_) - position_offset_;
	speed = 0.f;
	}

	// Keep track of integer portion of scroll thus far, and prepare increment.
	WebFloatSize scroll(displacement * displacement_ratio_.x,
	displacement * displacement_ratio_.y);
	WebFloatSize scroll_increment(scroll.width - cumulative_scroll_.width,
	scroll.height - cumulative_scroll_.height);
	WebFloatSize scroll_velocity(speed * displacement_ratio_.x,
	speed * displacement_ratio_.y);
	cumulative_scroll_ = scroll;

	if (time + time_offset_ < curve_duration_ \|\|
	scroll_increment != WebFloatSize()) {
	// scrollBy() could delete this curve if the animation is over, so don't
	// touch any member variables after making that call.
	return target->scrollBy(scroll_increment, scroll_velocity);
	}

	return false;
	}

	} // namespace content