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//-----------------------------------------------------------------------------
//  tstrokedeformations.cpp
//
//  Revision History:
//  16/07/2002  m_lengthOfDeformation is almost TConsts::epsilon
//-----------------------------------------------------------------------------

#include "tstrokedeformations.h"
#include "tcurveutil.h"
#include "tmathutil.h"
#include "tstroke.h"

using namespace std;

//=============================================================================

namespace
{
const double nine_inv = 1.0 / 9.0;

/*!
           _____|  r
          /     |\  inner
      __/          \___|
                       | r 
                          outer

                    {  1  if  r <= r
                    {              inner
                    {
 bowl potential(r)= {  cos( (r - r ) / (r  - r ) * pi_2 )  if   r < r  <= r
                    {             i      o    i                  i         o
                    {
                    {  0  if  r > r
                                   o
    
   */
struct bowlPotential {
	double m_radiusInner;
	double m_radiusOuter;

	bowlPotential(double radiusInner,
				  double radiusOuter)
		: m_radiusInner(radiusInner), m_radiusOuter(radiusOuter)
	{
		assert(m_radiusInner > 0);
		assert(m_radiusOuter >= m_radiusInner);
	}

	virtual double value(double radiusToTest)
	{
		assert(radiusToTest >= 0);
		if (radiusToTest <= m_radiusInner)
			return 1.0;
		if (radiusToTest > m_radiusOuter)
			return 0.0;

		return 0.5 * (1.0 + cos((radiusToTest - m_radiusInner) / (m_radiusOuter - m_radiusInner) * TConsts::pi));
	}

	virtual double gradient(double radiusToTest)
	{
		assert(radiusToTest >= 0);
		if (radiusToTest <= m_radiusInner || radiusToTest > m_radiusOuter)
			return 0.0;

		double den = TConsts::pi / (m_radiusOuter - m_radiusInner);

		return -0.5 * den * sin(den * (radiusToTest - m_radiusInner));
	}

	virtual ~bowlPotential() {}
};

double wyvillPotential(double r, double R)
{

	if (0.0 == R)
		return 0.0;

	if (0 > r || r >= R)
		return 0.0;

	double ratio2 = sq(r / R);
	double ratio4 = sq(ratio2);
	double ratio6 = ratio2 * ratio4;

	return 1.0 + (17.0 * ratio4 - (4.0 * ratio6 + 22.0 * ratio2)) * nine_inv;
}

/*
  */
double derivateOfWyvillPotential(double r, double R)
{
	if (0.0 == R)
		return 0.0;
	if (0 > r || r > R)
		return 0.0;

	double inv_of_R = 1.0 / R;
	double ratio = r / R;
	double ratio2 = sq(ratio);
	double ratio3 = ratio * ratio2;
	double ratio5 = ratio3 * ratio2;

	return inv_of_R * nine_inv * (68.0 * ratio3 - (24.0 * ratio5 + 66.0 * ratio));
}

const double c_maxLenghtOfGaussian = 3.0;

/*
  */
double gaussianPotential(double x)
{
	return exp(-sq(x));
}

/*
  */
double derivateOfGaussianPotential(double x)
{
	return -2 * x * exp(-sq(x));
}

/* 
  Check if vector distance is in segment.
  bool  pointProjectionIsInSegment( const TPointD& p, const TSegment& seg )
  {
    TPointD 
      a ( p - seg.getP0()),
      b ( seg.getP1() - seg.getP0());
    
    double  b2 = b*b;
    
    if( ! isAlmostZero(b2) )
    {
      b2 = a * b / b2;
      if (  0 <= b2 && b2 <= 1.0 ) return true; 
    }
    
    return false;
  }
	*/

double normOfGradientOfWyvillPotential(double r, double R)
{
	TPointD grad;

	grad.x = 1.0;
	grad.y = derivateOfWyvillPotential(r, R);

	return norm(grad);
}

} // end of unnamed namespace

//=============================================================================

struct TStrokePointDeformation::Imp {
	TPointD m_circleCenter;
	double m_circleRadius;
	TPointD *m_vect;

	bowlPotential *m_potential;

	Imp(const TPointD &center,
		double radius)
		: m_circleCenter(center), m_circleRadius(radius), m_vect(0)
	{
		m_potential = new bowlPotential(0.3 * m_circleRadius, m_circleRadius);
	}

	Imp(const TPointD &vect,
		const TPointD &center,
		double radius)
		: m_circleCenter(center), m_circleRadius(radius), m_vect(new TPointD(vect))
	{
		m_potential = new bowlPotential(0.3 * m_circleRadius, m_circleRadius);
	}

	~Imp()
	{
		delete m_vect;
		delete m_potential;
	}
};

TStrokePointDeformation::TStrokePointDeformation(const TPointD &center,
												 double radius)
												 : m_imp(new Imp(center, radius))
{
}

//-----------------------------------------------------------------------------

TStrokePointDeformation::TStrokePointDeformation(const TPointD &vect,
												 const TPointD &center,
												 double radius)
												 : m_imp(new Imp(vect, center, radius))
{
}

//-----------------------------------------------------------------------------

TStrokePointDeformation::~TStrokePointDeformation()
{
}

//-----------------------------------------------------------------------------

TThickPoint TStrokePointDeformation::getDisplacementForControlPoint(const TStroke &stroke, UINT n) const
{
	// riferimento ad un punto ciccione della stroke
	TPointD pntOfStroke(convert(stroke.getControlPoint(n)));

	double d = tdistance(pntOfStroke, m_imp->m_circleCenter);

	if (m_imp->m_vect)
		return m_imp->m_potential->value(d) * TThickPoint(*m_imp->m_vect, 0);
	else {
		double outVal = m_imp->m_potential->value(d);

		return TThickPoint(outVal, outVal, 0);
	}
}

TThickPoint TStrokePointDeformation::getDisplacementForControlPointLen(const TStroke &stroke, double cpLen) const
{
	assert(0);
	return TThickPoint();
}

//-----------------------------------------------------------------------------

TThickPoint TStrokePointDeformation::getDisplacement(const TStroke &stroke, double w) const
{
	// riferimento ad un punto ciccione della stroke
	TThickPoint
		thickPnt = m_imp->m_vect ? stroke.getControlPointAtParameter(w) : stroke.getThickPoint(w);

	assert(thickPnt != TConsts::natp);

	TPointD pntOfStroke(convert(thickPnt));

	double d = tdistance(pntOfStroke, m_imp->m_circleCenter);

	if (m_imp->m_vect)
		return m_imp->m_potential->value(d) * TThickPoint(*m_imp->m_vect, 0);
	else {
		double outVal = m_imp->m_potential->value(d);

		return TThickPoint(outVal, outVal, 0);
	}
}

//-----------------------------------------------------------------------------

double TStrokePointDeformation::getDelta(const TStroke &stroke, double w) const
{
	// reference to a thickpoint
	TThickPoint
		thickPnt = m_imp->m_vect ? stroke.getControlPointAtParameter(w) : stroke.getThickPoint(w);

	assert(thickPnt != TConsts::natp);

	TPointD
		pntOfStroke = convert(thickPnt);

	double d = tdistance(pntOfStroke, m_imp->m_circleCenter);

	return m_imp->m_potential->gradient(d);
}

//-----------------------------------------------------------------------------

double TStrokePointDeformation::getMaxDiff() const
{
	return 0.005;
}

//=============================================================================

TStrokeParamDeformation::TStrokeParamDeformation(const TStroke *ref,
												 const TPointD &vect,
												 double s,
												 double l)
	: m_pRef(ref), m_startParameter(s), m_lengthOfDeformation(l), m_vect(new TPointD(vect))
{
	assert(m_lengthOfDeformation >= 0);
	if (isAlmostZero(m_lengthOfDeformation))
		m_lengthOfDeformation = TConsts::epsilon;
}

//-----------------------------------------------------------------------------

TStrokeParamDeformation::TStrokeParamDeformation(const TStroke *ref,
												 double s,
												 double l)
	: m_pRef(ref), m_startParameter(s), m_lengthOfDeformation(l), m_vect(0)
{
	assert(m_lengthOfDeformation >= 0);
	if (isAlmostZero(m_lengthOfDeformation))
		m_lengthOfDeformation = TConsts::epsilon;
}

//-----------------------------------------------------------------------------
TThickPoint TStrokeParamDeformation::getDisplacementForControlPoint(const TStroke &stroke, UINT n) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double diff = stroke.getLengthAtControlPoint(n);

	diff = diff - m_startParameter;
	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		if (m_vect)
			return gaussianPotential(diff) * TThickPoint(*m_vect, 0);
		else {
			double outVal = gaussianPotential(diff);
			return TThickPoint(outVal, outVal, 0);
		}
	}

	return TThickPoint();
}

TThickPoint TStrokeParamDeformation::getDisplacementForControlPointLen(const TStroke &stroke, double cpLenDiff) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	//double  diff =  stroke.getLengthAtControlPoint(n);
	//double  diff =  cpLen;

	double diff = cpLenDiff;
	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		if (m_vect)
			return gaussianPotential(diff) * TThickPoint(*m_vect, 0);
		else {
			double outVal = gaussianPotential(diff);
			return TThickPoint(outVal, outVal, 0);
		}
	}

	return TThickPoint();
}

//-----------------------------------------------------------------------------

TThickPoint TStrokeParamDeformation::getDisplacement(const TStroke &stroke, double w) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double diff = stroke.getLength(w);

	diff = diff - m_startParameter;
	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		if (m_vect)
			return gaussianPotential(diff) * TThickPoint(*m_vect, 0);
		else {
			double outVal = gaussianPotential(diff);
			return TThickPoint(outVal, outVal, 0);
		}
	}

	return TThickPoint();
}

//-----------------------------------------------------------------------------

double TStrokeParamDeformation::getDelta(const TStroke &stroke, double w) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double diff = stroke.getLength(w);

	diff = diff - m_startParameter;
	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		return derivateOfGaussianPotential(diff);
	}

	return 0;
}

//-----------------------------------------------------------------------------

double TStrokeParamDeformation::getMaxDiff() const
{
	return 0.09;
}

//-----------------------------------------------------------------------------

TStrokeParamDeformation::~TStrokeParamDeformation()
{
	delete m_vect;
}

//=============================================================================

//=============================================================================
/*
*/
TStrokeBenderDeformation::TStrokeBenderDeformation(const TStroke *ref,
												   double s,
												   double l)
	: m_pRef(ref), m_startLength(s), m_lengthOfDeformation(l), m_vect(0), m_versus(INNER)
{
	assert(m_lengthOfDeformation >= 0);

	if (isAlmostZero(m_lengthOfDeformation))
		m_lengthOfDeformation = TConsts::epsilon;
}

//-----------------------------------------------------------------------------

TStrokeBenderDeformation::TStrokeBenderDeformation(const TStroke *ref,
												   const TPointD &vect,
												   double angle,
												   double s,
												   int innerOrOuter,
												   double l)
	: m_pRef(ref), m_startLength(s), m_lengthOfDeformation(l), m_vect(new TPointD(vect)), m_versus(innerOrOuter), m_angle(angle)
{
	assert(m_lengthOfDeformation >= 0);
	if (isAlmostZero(m_lengthOfDeformation))
		m_lengthOfDeformation = TConsts::epsilon;
}

//-----------------------------------------------------------------------------

TStrokeBenderDeformation::~TStrokeBenderDeformation()
{
	delete m_vect;
}

//-----------------------------------------------------------------------------

double TStrokeBenderDeformation::getMaxDiff() const
{
	//  return  0.09; OK per gaussiana
	return 0.4;
}

//-----------------------------------------------------------------------------

TThickPoint TStrokeBenderDeformation::getDisplacementForControlPoint(const TStroke &s, UINT n) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double strokeLengthAtParameter = s.getLengthAtControlPoint(n);
	double diff = strokeLengthAtParameter - m_startLength;

	if (m_vect) {
		double outVal = 0;

		if (fabs(diff) <= m_lengthOfDeformation && m_versus == INNER) {
			diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;
			outVal = gaussianPotential(diff);
		} else if (m_versus == OUTER) {
			double valForGaussian =
				-c_maxLenghtOfGaussian + 2 * c_maxLenghtOfGaussian / m_lengthOfDeformation * strokeLengthAtParameter;
			outVal = 1.0 - gaussianPotential(valForGaussian);
		}

		TPointD cp = convert(s.getControlPoint(n));
		TPointD p = cp;

		TRotation rot(*m_vect, outVal * rad2degree(m_angle));

		p = rot * p;

		return TThickPoint(p - cp, 0.0);
	}

	return TThickPoint();
}

TThickPoint TStrokeBenderDeformation::getDisplacementForControlPointLen(const TStroke &stroke, double cpLen) const
{
	assert(0);
	return TThickPoint();
}

//-----------------------------------------------------------------------------

TThickPoint TStrokeBenderDeformation::getDisplacement(const TStroke &s, double w) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double strokeLengthAtParameter = s.getLength(w);
	double diff = strokeLengthAtParameter - m_startLength;

	if (m_vect) {
		double outVal = 0.0;

		if (fabs(diff) <= m_lengthOfDeformation)
			if (m_versus == INNER) {
				diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;
				outVal = gaussianPotential(diff);
			} else if (m_versus == OUTER) {
				double valForGaussian =
					-c_maxLenghtOfGaussian + 2 * c_maxLenghtOfGaussian / m_lengthOfDeformation * strokeLengthAtParameter;
				outVal = 1.0 - gaussianPotential(valForGaussian);
			}

		TPointD cp = convert(s.getControlPointAtParameter(w));
		TPointD p = cp;

		TRotation rot(*m_vect, outVal * rad2degree(m_angle));

		p = rot * p;

		return TThickPoint(p - cp, 0.0);
	}

	return TThickPoint();
}

//-----------------------------------------------------------------------------

double TStrokeBenderDeformation::getDelta(const TStroke &s, double w) const
{
	double totalLenght = s.getLength();

	if (totalLenght != 0) {
		double val = s.getLength(w) / totalLenght * TConsts::pi * 10.0;

		return sin(val);
	}
	return 0;
}

//=============================================================================

TStrokeTwirlDeformation::TStrokeTwirlDeformation(const TPointD &center, double radius)
	: m_center(center), m_innerRadius2(sq(radius)), m_vectorOfMovement(TPointD())
{
	m_outerRadius = 1.25 * radius;
}

//-----------------------------------------------------------------------------

TStrokeTwirlDeformation::TStrokeTwirlDeformation(const TPointD &center, double radius, const TPointD &v)
	: m_center(center), m_innerRadius2(sq(radius)), m_vectorOfMovement(v)
{
	m_outerRadius = 1.25 * radius;
}

//-----------------------------------------------------------------------------

TStrokeTwirlDeformation::~TStrokeTwirlDeformation()
{
}

//-----------------------------------------------------------------------------

TThickPoint TStrokeTwirlDeformation::getDisplacement(const TStroke &stroke, double s) const
{
	double outVal = 0;

	double distance2 = tdistance2(convert(stroke.getControlPointAtParameter(s)), m_center);

	if (distance2 <= m_innerRadius2)
		outVal = wyvillPotential(distance2, m_innerRadius2);

	return TThickPoint(m_vectorOfMovement * outVal, 0);
}

//-----------------------------------------------------------------------------

double TStrokeTwirlDeformation::getDelta(const TStroke &stroke, double s) const
{
	/*
  vector<DoublePair>  vres;
  
  if(intersect( stroke, m_center, m_outerRadius, vres))
  {
    double totalLenght = stroke.getLength();
    
    if(totalLenght != 0)
    {
      double val =  stroke.getLength(s)/totalLenght * TConsts::pi *11.0;
      
      return sin(val);
    }
  }
  */
	return 0;
}

//-----------------------------------------------------------------------------

double TStrokeTwirlDeformation::getMaxDiff() const
{
	return 0.4;
}

//-----------------------------------------------------------------------------
//  End Of File
//-----------------------------------------------------------------------------

//=============================================================================

TStrokeThicknessDeformation::TStrokeThicknessDeformation(const TStroke *ref,
														 const TPointD &vect,
														 double s,
														 double l,
														 double versus)
	: m_lengthOfDeformation(l), m_startParameter(s), m_versus(versus), m_vect(new TPointD(vect)), m_pRef(ref)
{
	assert(m_lengthOfDeformation >= 0);
	if (isAlmostZero(m_lengthOfDeformation))
		m_lengthOfDeformation = TConsts::epsilon;
}

//-----------------------------------------------------------------------------

TStrokeThicknessDeformation::TStrokeThicknessDeformation(const TStroke *ref,
														 double s,
														 double l)
	: m_lengthOfDeformation(l), m_startParameter(s), m_vect(0), m_pRef(ref)
{
	assert(m_lengthOfDeformation >= 0);
	if (isAlmostZero(m_lengthOfDeformation))
		m_lengthOfDeformation = TConsts::epsilon;
}

//-----------------------------------------------------------------------------
TThickPoint TStrokeThicknessDeformation::getDisplacementForControlPoint(const TStroke &stroke, UINT n) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double diff = stroke.getLengthAtControlPoint(n);

	diff = diff - m_startParameter;

	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		TThickPoint delta;

		if (m_vect) {
			//tsign(m_vect->y) * 0.1
			delta = TThickPoint(0, 0, m_versus * norm(*m_vect) * gaussianPotential(diff));
		} else {
			double outVal = gaussianPotential(diff);
			delta = TThickPoint(0, 0, outVal);
		}
		//TThickPoint cp = stroke.getControlPoint(n);
		//if(cp.thick + delta.thick<0.001) delta.thick = 0.001-cp.thick;
		return delta;
	}
	return TThickPoint();
}

TThickPoint TStrokeThicknessDeformation::getDisplacementForControlPointLen(const TStroke &stroke, double diff) const
{

	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		TThickPoint delta;

		if (m_vect) {
			//tsign(m_vect->y) * 0.1
			delta = TThickPoint(0, 0, m_versus * norm(*m_vect) * gaussianPotential(diff));
		} else {
			double outVal = gaussianPotential(diff);
			delta = TThickPoint(0, 0, outVal);
		}
		//TThickPoint cp = stroke.getControlPoint(n);
		//if(cp.thick + delta.thick<0.001) delta.thick = 0.001-cp.thick;
		return delta;
	}
	return TThickPoint();
}

TThickPoint TStrokeThicknessDeformation::getDisplacement(const TStroke &stroke, double w) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double diff = stroke.getLength(w);

	diff = diff - m_startParameter;

	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		if (m_vect)
			return gaussianPotential(diff) * TThickPoint(*m_vect, 0);
		else {
			double outVal = gaussianPotential(diff);
			return TThickPoint(0, 0, outVal);
		}
	}

	return TThickPoint();
}

//-----------------------------------------------------------------------------

double TStrokeThicknessDeformation::getDelta(const TStroke &stroke, double w) const
{
	// potenziale exp^(-x^2) limitato tra [-c_maxLenghtOfGaussian,c_maxLenghtOfGaussian]
	double diff = stroke.getLength(w);

	diff = diff - m_startParameter;

	if (fabs(diff) <= m_lengthOfDeformation) {
		// modulo il vettore spostamento in funzione  del potenziale
		//  il termine (1.0/m_lengthOfDeformation) * 3 scala
		//  il punto in diff su un sistema di coordinate
		//  normalizzato, associato con la curva exp^(-x^2)
		diff *= (1.0 / m_lengthOfDeformation) * c_maxLenghtOfGaussian;

		return derivateOfGaussianPotential(diff);
	}

	return 0;
}

//-----------------------------------------------------------------------------

double TStrokeThicknessDeformation::getMaxDiff() const
{
	return 0.09;
}

//-----------------------------------------------------------------------------

TStrokeThicknessDeformation::~TStrokeThicknessDeformation()
{
	delete m_vect;
}

//=============================================================================

TPointDeformation::TPointDeformation(const TStroke *stroke,
									 const TPointD &center,
									 double radius)
	: m_strokeRef(stroke), m_center(center), m_radius(radius)
{
	assert(m_strokeRef);
}

//-----------------------------------------------------------------------------

TPointDeformation::TPointDeformation()
{
}

//-----------------------------------------------------------------------------

TPointDeformation::~TPointDeformation()
{
}

//-----------------------------------------------------------------------------

TThickPoint TPointDeformation::getDisplacement(double s) const
{
	// riferimento ad un punto ciccione della stroke
	TThickPoint
		thickPnt = m_strokeRef->getPointAtLength(s);

	assert(thickPnt != TConsts::natp);

	TPointD pntOfStroke(convert(thickPnt));

	double d = tdistance(pntOfStroke, m_center);

	double outVal = wyvillPotential(d, m_radius);

	return TThickPoint(outVal, outVal, 0);
}

//-----------------------------------------------------------------------------

// return ratio: (number of Control Point)/length
double TPointDeformation::getCPDensity(double s) const
{
	// reference to a thickpoint
	TThickPoint
		thickPnt = m_strokeRef->getThickPointAtLength(s);

	assert(thickPnt != TConsts::natp);

	TPointD
		pntOfStroke = convert(thickPnt);

	double d = tdistance(pntOfStroke, m_center);

	return normOfGradientOfWyvillPotential(d, m_radius);
}

//-----------------------------------------------------------------------------

double TPointDeformation::getCPCountInRange(double s0, double s1) const
{
	if (s1 < s0)
		swap(s1, s0);

	double step = (s1 - s0) * 0.1;

	double cpCount = 0.0;

	for (double s = s0; s < s1; s += step)
		cpCount += getCPDensity(s);

	cpCount += getCPDensity(s1);

	return cpCount;
}

//-----------------------------------------------------------------------------

double TPointDeformation::getMinCPDensity() const
{
	return 0.3;
}

//-----------------------------------------------------------------------------
//  End Of File
//-----------------------------------------------------------------------------