Source/platform/graphics/PathTraversalState.cpp - platform/external/chromium_org/third_party/WebKit - Git at Google

 /*
  * Copyright (C) 2006, 2007 Eric Seidel <eric@webkit.org>
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Library General Public
  * License as published by the Free Software Foundation; either
  * version 2 of the License, or (at your option) any later version.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Library General Public License for more details.
  *
  * You should have received a copy of the GNU Library General Public License
  * along with this library; see the file COPYING.LIB.  If not, write to
  * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
  * Boston, MA 02110-1301, USA.
  */

 #include "config.h"
 #include "platform/graphics/PathTraversalState.h"

 #include "wtf/MathExtras.h"
 #include "wtf/Vector.h"

 namespace WebCore {

 static const float kPathSegmentLengthTolerance = 0.00001f;

 static inline FloatPoint midPoint(const FloatPoint& first, const FloatPoint& second)
 {
     return FloatPoint((first.x() + second.x()) / 2.0f, (first.y() + second.y()) / 2.0f);
 }

 static inline float distanceLine(const FloatPoint& start, const FloatPoint& end)
 {
     return sqrtf((end.x() - start.x()) * (end.x() - start.x()) + (end.y() - start.y()) * (end.y() - start.y()));
 }

 struct QuadraticBezier {
     QuadraticBezier() { }
     QuadraticBezier(const FloatPoint& s, const FloatPoint& c, const FloatPoint& e)
         : start(s)
         , control(c)
         , end(e)
     {
     }

     float approximateDistance() const
     {
         return distanceLine(start, control) + distanceLine(control, end);
     }

     void split(QuadraticBezier& left, QuadraticBezier& right) const
     {
         left.control = midPoint(start, control);
         right.control = midPoint(control, end);

         FloatPoint leftControlToRightControl = midPoint(left.control, right.control);
         left.end = leftControlToRightControl;
         right.start = leftControlToRightControl;

         left.start = start;
         right.end = end;
     }

     FloatPoint start;
     FloatPoint control;
     FloatPoint end;
 };

 struct CubicBezier {
     CubicBezier() { }
     CubicBezier(const FloatPoint& s, const FloatPoint& c1, const FloatPoint& c2, const FloatPoint& e)
         : start(s)
         , control1(c1)
         , control2(c2)
         , end(e)
     {
     }

     float approximateDistance() const
     {
         return distanceLine(start, control1) + distanceLine(control1, control2) + distanceLine(control2, end);
     }

     void split(CubicBezier& left, CubicBezier& right) const
     {
         FloatPoint startToControl1 = midPoint(control1, control2);

         left.start = start;
         left.control1 = midPoint(start, control1);
         left.control2 = midPoint(left.control1, startToControl1);

         right.control2 = midPoint(control2, end);
         right.control1 = midPoint(right.control2, startToControl1);
         right.end = end;

         FloatPoint leftControl2ToRightControl1 = midPoint(left.control2, right.control1);
         left.end = leftControl2ToRightControl1;
         right.start = leftControl2ToRightControl1;
     }

     FloatPoint start;
     FloatPoint control1;
     FloatPoint control2;
     FloatPoint end;
 };

 // FIXME: This function is possibly very slow due to the ifs required for proper path measuring
 // A simple speed-up would be to use an additional boolean template parameter to control whether
 // to use the "fast" version of this function with no PathTraversalState updating, vs. the slow
 // version which does update the PathTraversalState. We'll have to shark it to see if that's necessary.
 // Another check which is possible up-front (to send us down the fast path) would be to check if
 // approximateDistance() + current total distance > desired distance
 template<class CurveType>
 static float curveLength(PathTraversalState& traversalState, CurveType curve)
 {
     static const unsigned curveStackDepthLimit = 20;

     Vector<CurveType> curveStack;
     curveStack.append(curve);

     float totalLength = 0;
     do {
         float length = curve.approximateDistance();
         if ((length - distanceLine(curve.start, curve.end)) > kPathSegmentLengthTolerance && curveStack.size() <= curveStackDepthLimit) {
             CurveType leftCurve;
             CurveType rightCurve;
             curve.split(leftCurve, rightCurve);
             curve = leftCurve;
             curveStack.append(rightCurve);
         } else {
             totalLength += length;
             if (traversalState.m_action == PathTraversalState::TraversalPointAtLength || traversalState.m_action == PathTraversalState::TraversalNormalAngleAtLength) {
                 traversalState.m_previous = curve.start;
                 traversalState.m_current = curve.end;
                 if (traversalState.m_totalLength + totalLength > traversalState.m_desiredLength)
                     return totalLength;
             }
             curve = curveStack.last();
             curveStack.removeLast();
         }
     } while (!curveStack.isEmpty());

     return totalLength;
 }

 PathTraversalState::PathTraversalState(PathTraversalAction action)
     : m_action(action)
     , m_success(false)
     , m_totalLength(0)
     , m_segmentIndex(0)
     , m_desiredLength(0)
     , m_normalAngle(0)
 {
 }

 float PathTraversalState::closeSubpath()
 {
     float distance = distanceLine(m_current, m_start);
     m_current = m_control1 = m_control2 = m_start;
     return distance;
 }

 float PathTraversalState::moveTo(const FloatPoint& point)
 {
     m_current = m_start = m_control1 = m_control2 = point;
     return 0;
 }

 float PathTraversalState::lineTo(const FloatPoint& point)
 {
     float distance = distanceLine(m_current, point);
     m_current = m_control1 = m_control2 = point;
     return distance;
 }

 float PathTraversalState::quadraticBezierTo(const FloatPoint& newControl, const FloatPoint& newEnd)
 {
     float distance = curveLength<QuadraticBezier>(*this, QuadraticBezier(m_current, newControl, newEnd));

     m_control1 = newControl;
     m_control2 = newEnd;

     if (m_action != TraversalPointAtLength && m_action != TraversalNormalAngleAtLength)
         m_current = newEnd;

     return distance;
 }

 float PathTraversalState::cubicBezierTo(const FloatPoint& newControl1, const FloatPoint& newControl2, const FloatPoint& newEnd)
 {
     float distance = curveLength<CubicBezier>(*this, CubicBezier(m_current, newControl1, newControl2, newEnd));

     m_control1 = newEnd;
     m_control2 = newControl2;

     if (m_action != TraversalPointAtLength && m_action != TraversalNormalAngleAtLength)
         m_current = newEnd;

     return distance;
 }

 void PathTraversalState::processSegment()
 {
     if (m_action == TraversalSegmentAtLength && m_totalLength >= m_desiredLength)
         m_success = true;

     if ((m_action == TraversalPointAtLength || m_action == TraversalNormalAngleAtLength) && m_totalLength >= m_desiredLength) {
         float slope = FloatPoint(m_current - m_previous).slopeAngleRadians();
         if (m_action == TraversalPointAtLength) {
             float offset = m_desiredLength - m_totalLength;
             m_current.move(offset * cosf(slope), offset * sinf(slope));
         } else {
             m_normalAngle = rad2deg(slope);
         }
         m_success = true;
     }
     m_previous = m_current;
 }

 }
	/*
	* Copyright (C) 2006, 2007 Eric Seidel <eric@webkit.org>
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Library General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Library General Public License for more details.
	*
	* You should have received a copy of the GNU Library General Public License
	* along with this library; see the file COPYING.LIB. If not, write to
	* the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
	* Boston, MA 02110-1301, USA.
	*/

	#include "config.h"
	#include "platform/graphics/PathTraversalState.h"

	#include "wtf/MathExtras.h"
	#include "wtf/Vector.h"

	namespace WebCore {

	static const float kPathSegmentLengthTolerance = 0.00001f;

	static inline FloatPoint midPoint(const FloatPoint& first, const FloatPoint& second)
	{
	return FloatPoint((first.x() + second.x()) / 2.0f, (first.y() + second.y()) / 2.0f);
	}

	static inline float distanceLine(const FloatPoint& start, const FloatPoint& end)
	{
	return sqrtf((end.x() - start.x()) * (end.x() - start.x()) + (end.y() - start.y()) * (end.y() - start.y()));
	}

	struct QuadraticBezier {
	QuadraticBezier() { }
	QuadraticBezier(const FloatPoint& s, const FloatPoint& c, const FloatPoint& e)
	: start(s)
	, control(c)
	, end(e)
	{
	}

	float approximateDistance() const
	{
	return distanceLine(start, control) + distanceLine(control, end);
	}

	void split(QuadraticBezier& left, QuadraticBezier& right) const
	{
	left.control = midPoint(start, control);
	right.control = midPoint(control, end);

	FloatPoint leftControlToRightControl = midPoint(left.control, right.control);
	left.end = leftControlToRightControl;
	right.start = leftControlToRightControl;

	left.start = start;
	right.end = end;
	}

	FloatPoint start;
	FloatPoint control;
	FloatPoint end;
	};

	struct CubicBezier {
	CubicBezier() { }
	CubicBezier(const FloatPoint& s, const FloatPoint& c1, const FloatPoint& c2, const FloatPoint& e)
	: start(s)
	, control1(c1)
	, control2(c2)
	, end(e)
	{
	}

	float approximateDistance() const
	{
	return distanceLine(start, control1) + distanceLine(control1, control2) + distanceLine(control2, end);
	}

	void split(CubicBezier& left, CubicBezier& right) const
	{
	FloatPoint startToControl1 = midPoint(control1, control2);

	left.start = start;
	left.control1 = midPoint(start, control1);
	left.control2 = midPoint(left.control1, startToControl1);

	right.control2 = midPoint(control2, end);
	right.control1 = midPoint(right.control2, startToControl1);
	right.end = end;

	FloatPoint leftControl2ToRightControl1 = midPoint(left.control2, right.control1);
	left.end = leftControl2ToRightControl1;
	right.start = leftControl2ToRightControl1;
	}

	FloatPoint start;
	FloatPoint control1;
	FloatPoint control2;
	FloatPoint end;
	};

	// FIXME: This function is possibly very slow due to the ifs required for proper path measuring
	// A simple speed-up would be to use an additional boolean template parameter to control whether
	// to use the "fast" version of this function with no PathTraversalState updating, vs. the slow
	// version which does update the PathTraversalState. We'll have to shark it to see if that's necessary.
	// Another check which is possible up-front (to send us down the fast path) would be to check if
	// approximateDistance() + current total distance > desired distance
	template<class CurveType>
	static float curveLength(PathTraversalState& traversalState, CurveType curve)
	{
	static const unsigned curveStackDepthLimit = 20;

	Vector<CurveType> curveStack;
	curveStack.append(curve);

	float totalLength = 0;
	do {
	float length = curve.approximateDistance();
	if ((length - distanceLine(curve.start, curve.end)) > kPathSegmentLengthTolerance && curveStack.size() <= curveStackDepthLimit) {
	CurveType leftCurve;
	CurveType rightCurve;
	curve.split(leftCurve, rightCurve);
	curve = leftCurve;
	curveStack.append(rightCurve);
	} else {
	totalLength += length;
	if (traversalState.m_action == PathTraversalState::TraversalPointAtLength \|\| traversalState.m_action == PathTraversalState::TraversalNormalAngleAtLength) {
	traversalState.m_previous = curve.start;
	traversalState.m_current = curve.end;
	if (traversalState.m_totalLength + totalLength > traversalState.m_desiredLength)
	return totalLength;
	}
	curve = curveStack.last();
	curveStack.removeLast();
	}
	} while (!curveStack.isEmpty());

	return totalLength;
	}

	PathTraversalState::PathTraversalState(PathTraversalAction action)
	: m_action(action)
	, m_success(false)
	, m_totalLength(0)
	, m_segmentIndex(0)
	, m_desiredLength(0)
	, m_normalAngle(0)
	{
	}

	float PathTraversalState::closeSubpath()
	{
	float distance = distanceLine(m_current, m_start);
	m_current = m_control1 = m_control2 = m_start;
	return distance;
	}

	float PathTraversalState::moveTo(const FloatPoint& point)
	{
	m_current = m_start = m_control1 = m_control2 = point;
	return 0;
	}

	float PathTraversalState::lineTo(const FloatPoint& point)
	{
	float distance = distanceLine(m_current, point);
	m_current = m_control1 = m_control2 = point;
	return distance;
	}

	float PathTraversalState::quadraticBezierTo(const FloatPoint& newControl, const FloatPoint& newEnd)
	{
	float distance = curveLength<QuadraticBezier>(*this, QuadraticBezier(m_current, newControl, newEnd));

	m_control1 = newControl;
	m_control2 = newEnd;

	if (m_action != TraversalPointAtLength && m_action != TraversalNormalAngleAtLength)
	m_current = newEnd;

	return distance;
	}

	float PathTraversalState::cubicBezierTo(const FloatPoint& newControl1, const FloatPoint& newControl2, const FloatPoint& newEnd)
	{
	float distance = curveLength<CubicBezier>(*this, CubicBezier(m_current, newControl1, newControl2, newEnd));

	m_control1 = newEnd;
	m_control2 = newControl2;

	if (m_action != TraversalPointAtLength && m_action != TraversalNormalAngleAtLength)
	m_current = newEnd;

	return distance;
	}

	void PathTraversalState::processSegment()
	{
	if (m_action == TraversalSegmentAtLength && m_totalLength >= m_desiredLength)
	m_success = true;

	if ((m_action == TraversalPointAtLength \|\| m_action == TraversalNormalAngleAtLength) && m_totalLength >= m_desiredLength) {
	float slope = FloatPoint(m_current - m_previous).slopeAngleRadians();
	if (m_action == TraversalPointAtLength) {
	float offset = m_desiredLength - m_totalLength;
	m_current.move(offset * cosf(slope), offset * sinf(slope));
	} else {
	m_normalAngle = rad2deg(slope);
	}
	m_success = true;
	}
	m_previous = m_current;
	}

	}