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//#include "tsystem.h"
#include "tmachine.h"
#include "tcurves.h"
#include "tcommon.h"
#include "tregion.h"
//#include "tregionutil.h"
#include "tstopwatch.h"

#include "tstroke.h"
#include "tstrokeutil.h"
#include "tvectorimageP.h"
#include "tdebugmessage.h"
#include "tthreadmessage.h"
#include "tl2lautocloser.h"
#include <vector>

#include "tcurveutil.h"

#include <algorithm>

#if !defined(TNZ_LITTLE_ENDIAN)
TNZ_LITTLE_ENDIAN undefined !!
#endif

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

#ifdef IS_DOTNET
#define NULL_ITER list<IntersectedStroke>::iterator()
#else
#define NULL_ITER 0
#endif

	using namespace std;

typedef TVectorImage::IntersectionBranch IntersectionBranch;
//-----------------------------------------------------------------------------

inline double myRound(double x)
{
	return (1.0 / REGION_COMPUTING_PRECISION) * ((TINT32)(x * REGION_COMPUTING_PRECISION));
}

inline TThickPoint myRound(const TThickPoint &p)
{
	return TThickPoint(myRound(p.x), myRound(p.y), p.thick);
}

void roundStroke(TStroke *s)
{
	int size = s->getControlPointCount();

	for (int j = 0; j < (int)s->getControlPointCount(); j++) {
		TThickPoint p = s->getControlPoint(j);
		s->setControlPoint(j, myRound(p));
	}
	if (size > 3)
	//! it can happen that a stroke has a first or last quadratic degenerated:(3 equal control points).
	// in that case, if the stroke has an intersection in an endpoint, the resulting w could not be  0 or 1 as expected.
	// since the w==0 and w==1 are used in the region computing to determine if the intersection is an endpoint,
	//

	{
		if (s->getControlPoint(0) == s->getControlPoint(1) && s->getControlPoint(0) == s->getControlPoint(2)) {
			s->setControlPoint(2, s->getControlPoint(3));
			s->setControlPoint(1, s->getControlPoint(3));
		}
		if (s->getControlPoint(size - 1) == s->getControlPoint(size - 2) && s->getControlPoint(size - 1) == s->getControlPoint(size - 3)) {
			s->setControlPoint(size - 2, s->getControlPoint(size - 4));
			s->setControlPoint(size - 3, s->getControlPoint(size - 4));
		}
	}
}

//-----------------------------------------------------------------------------
class VIListElem
{
public:
	VIListElem *m_prev;
	VIListElem *m_next;

	VIListElem() : m_prev(0), m_next(0) {}
	inline VIListElem *next() { return m_next; }
	inline VIListElem *prev() { return m_prev; }
};

template <class T>
class VIList
{
	int m_size;
	T *m_begin, *m_end;

public:
	VIList() : m_begin(0), m_end(0), m_size(0) {}

	inline T *first() const { return m_begin; };
	inline T *last() const { return m_end; };

	void clear();
	void pushBack(T *elem);
	void insert(T *before, T *elem);
	T *erase(T *element);
	T *getElemAt(int pos);
	int getPosOf(T *elem);
	inline int size() { return m_size; }
	inline bool empty() { return size() == 0; }
};

class Intersection : public VIListElem
{
public:
	//Intersection* m_prev, *m_next;
	TPointD m_intersection;
	int m_numInter;
	//bool m_isNotErasable;
	VIList<IntersectedStroke> m_strokeList;

	Intersection() : m_numInter(0), m_strokeList() {}

	inline Intersection *next() { return (Intersection *)VIListElem::next(); };
	inline Intersection *prev() { return (Intersection *)VIListElem::prev(); };
	//inline Intersection* operator++() {return next();}
};

class IntersectedStrokeEdges
{
public:
	int m_index;
	list<TEdge *> m_edgeList;
	IntersectedStrokeEdges(int index) : m_index(index), m_edgeList() {}
	~IntersectedStrokeEdges()
	{
		assert(m_index >= 0); /*clearPointerContainer(m_edgeList);*/
		m_edgeList.clear();
		m_index = -1;
	}
};

class IntersectionData
{
public:
	UINT maxAutocloseId;
	VIList<Intersection> m_intList;
	map<int, VIStroke *> m_autocloseMap;
	vector<IntersectedStrokeEdges> m_intersectedStrokeArray;

	IntersectionData()
		: maxAutocloseId(1), m_intList()
	{
	}

	~IntersectionData();
};

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

class IntersectedStroke : public VIListElem
{
	/*double m_w;
TStroke *m_s;
UINT m_index;*/
	//IntersectedStroke* m_prev, *m_next;
public:
	TEdge m_edge;
	Intersection *m_nextIntersection;
	IntersectedStroke *m_nextStroke;
	bool m_visited, m_gettingOut; //, m_dead;

	IntersectedStroke()
		: m_visited(false), m_nextIntersection(0), m_nextStroke(0){};

	IntersectedStroke(Intersection *nextIntersection,
					  IntersectedStroke *nextStroke)
		/*: m_w(-1.0)
	 , m_s(NULL)
	 , m_index(0)*/
		: m_edge(),
		  m_nextIntersection(nextIntersection),
		  m_nextStroke(nextStroke),
		  m_visited(false)
	//, m_dead(false)
	{
	}

	IntersectedStroke(const IntersectedStroke &s)
		: m_edge(s.m_edge, false), m_nextIntersection(s.m_nextIntersection), m_nextStroke(s.m_nextStroke), m_visited(s.m_visited), m_gettingOut(s.m_gettingOut)
	//, m_dead(s.m_dead)
	{
	}

	inline IntersectedStroke *next() { return (IntersectedStroke *)VIListElem::next(); };
};

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

template <class T>
void VIList<T>::clear()
{
	while (m_begin) {
		T *aux = m_begin;
		m_begin = m_begin->next();
		delete aux;
	}
	m_end = 0;
	m_size = 0;
}

template <class T>
void VIList<T>::pushBack(T *elem)
{

	if (!m_begin) {
		assert(!m_end);
		elem->m_next = elem->m_prev = 0;
		m_begin = m_end = elem;
	} else {
		assert(m_end);
		assert(m_end->m_next == 0);
		m_end->m_next = elem;
		elem->m_prev = m_end;
		elem->m_next = 0;
		m_end = elem;
	}
	m_size++;
}

template <class T>
void VIList<T>::insert(T *before, T *elem)
{
	assert(before && elem);

	elem->m_prev = before->m_prev;
	elem->m_next = before;

	if (!before->m_prev)
		before->m_prev = m_begin = elem;
	else {
		before->m_prev->m_next = elem;
		before->m_prev = elem;
	}
	m_size++;
}

template <class T>
T *VIList<T>::erase(T *element)
{
	T *ret;

	assert(m_size > 0);
	if (!element->m_prev) {
		assert(m_begin == element);
		if (!element->m_next)
			ret = m_begin = m_end = 0;
		else {
			m_begin = (T *)m_begin->m_next;
			m_begin->m_prev = 0;
			ret = m_begin;
		}
	} else if (!element->m_next) {
		assert(m_end == element);
		m_end = (T *)m_end->m_prev;
		m_end->m_next = 0;
		ret = 0;
	} else {
		element->m_prev->m_next = element->m_next;
		element->m_next->m_prev = element->m_prev;
		ret = (T *)element->m_next;
	}
	m_size--;
	delete element;
	return ret;
}

template <class T>
T *VIList<T>::getElemAt(int pos)
{
	assert(pos < m_size);
	T *p = m_begin;
	while (pos--)
		p = p->next();
	return p;
}

template <class T>
int VIList<T>::getPosOf(T *elem)
{
	int count = 0;
	T *p = m_begin;

	while (p && p != elem) {
		count++;
		p = p->next();
	}
	assert(p == elem);
	return count;
}

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

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

#ifdef LEVO

void print(list<Intersection> &intersectionList, char *str)
{
	ofstream of(str);

	of << "***************************" << endl;

	list<Intersection>::const_iterator it;
	list<IntersectedStroke>::const_iterator it1;
	int i, j;
	for (i = 0, it = intersectionList.begin(); it != intersectionList.end(); it++, i++) {
		of << "***************************" << endl;
		of << "Intersection#" << i << ": " << it->m_intersection << "numBranches: " << it->m_numInter << endl;
		of << endl;

		for (j = 0, it1 = it->m_strokeList.begin(); it1 != it->m_strokeList.end(); it1++, j++) {
			of << "----Branch #" << j;
			if (it1->m_edge.m_index < 0)
				of << "(AUTOCLOSE)";
			of << "Intersection at " << it1->m_edge.m_w0 << ": "
			   << ": " << endl;
			of << "ColorId: " << it1->m_edge.m_styleId << endl;
			/*
    TColorStyle* fs = it1->m_edge.m_fillStyle;
    if (fs==0)
      of<<"NO color: "<< endl;
    else 
      {
      TFillStyleP fp = fs->getFillStyle();
      if (fp)
        {
        fp->
      assert(false) ;
    else
      of<<"Color: ("<< colorStyle->getColor().r<<", "<< colorStyle->getColor().g<<", "<< colorStyle->getColor().b<<")"<<endl;
   */

			of << "----Stroke " << (it1->m_gettingOut ? "OUT" : "IN") << " #" << it1->m_edge.m_index << ": " << endl;
			//if (it1->m_dead)
			//of<<"---- DEAD Intersection.";
			//else
			{
				of << "---- NEXT Intersection:";
				if (it1->m_nextIntersection != intersectionList.end()) {
					int dist = std::distance(intersectionList.begin(), it1->m_nextIntersection);
					of << dist;
					list<Intersection>::iterator iit = intersectionList.begin();
					std::advance(iit, dist);
					of << " " << std::distance(iit->m_strokeList.begin(), it1->m_nextStroke);
				}

				else
					of << "NULL!!";
				of << "---- NEXT Stroke:";
				if (it1->m_nextIntersection != intersectionList.end())
					of << it1->m_nextStroke->m_edge.m_index;
				else
					of << "NULL!!";
			}
			of << endl
			   << endl;
		}
	}
}

#endif

void findNearestIntersection(list<Intersection> &interList,
							 const list<Intersection>::iterator &i1,
							 const list<IntersectedStroke>::iterator &i2);

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

#ifdef _TOLGO
void checkInterList(list<Intersection> &intersectionList)
{
	list<Intersection>::iterator it;
	list<IntersectedStroke>::iterator it1;

	for (it = intersectionList.begin(); it != intersectionList.end(); it++) {
		int count = 0;
		for (it1 = it->m_strokeList.begin(); it1 != it->m_strokeList.end(); it1++) {
			int val;
			if (it1->m_nextIntersection != intersectionList.end()) {
				count++;
				//assert (it1->m_nextIntersection!=intersectionList.end());
				assert(it1->m_nextStroke->m_nextIntersection == it);
				assert(it1->m_nextStroke->m_nextStroke == it1);

				//int k = it1->m_edge.m_index;
				val = std::distance(intersectionList.begin(), it1->m_nextIntersection);
			}
			//else
			// assert(it1->m_nextIntersection==intersectionList.end());
		}
		assert(count == it->m_numInter);
	}
}
#else
#define checkInterList
#endif

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

//void addFakeIntersection(list<Intersection>& intersectionList,TStroke* s, UINT ii, double w);

void addIntersections(IntersectionData &intersectionData,
					  const vector<VIStroke *> &s, int ii, int jj, const vector<DoublePair> &intersections, int numStrokes, bool isVectorized);

void addIntersection(IntersectionData &intData,
					 const vector<VIStroke *> &s, int ii, int jj,
					 DoublePair intersections, int strokeSize, bool isVectorized);

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

bool sortBBox(const TStroke *s1, const TStroke *s2)
{
	return s1->getBBox().x0 < s2->getBBox().x0;
}

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

void cleanIntersectionMarks(const VIList<Intersection> &interList)
{
	Intersection *p;
	IntersectedStroke *q;
	for (p = interList.first(); p; p = p->next())
		for (q = p->m_strokeList.first(); q; q = q->next()) {
			q->m_visited = false; // Ogni ramo della lista viene messo nella condizione
								  // di poter essere visitato

			if (q->m_nextIntersection) {
				q->m_nextIntersection = 0;
				p->m_numInter--;
			}
		}
}

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

void cleanNextIntersection(const VIList<Intersection> &interList, TStroke *s)
{
	Intersection *p;
	IntersectedStroke *q;

	for (p = interList.first(); p; p = p->next())
		for (q = p->m_strokeList.first(); q; q = q->next())
			if (q->m_edge.m_s == s) {
				//if (it2->m_nextIntersection==NULL)
				//  return; //gia' ripulita prima
				if (q->m_nextIntersection) {
					q->m_nextIntersection = 0;
					p->m_numInter--;
				}
				q->m_nextStroke = 0;
			}
}

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

void TVectorImage::Imp::eraseEdgeFromStroke(IntersectedStroke *is)
{
	if (is->m_edge.m_index >= 0) //elimino il puntatore all'edge nella lista della VIStroke
	{
		VIStroke *s;
		s = m_strokes[is->m_edge.m_index];
		assert(s->m_s == is->m_edge.m_s);
		list<TEdge *>::iterator iit = s->m_edgeList.begin(), it_e = s->m_edgeList.end();

		for (; iit != it_e; ++iit)
			if ((*iit)->m_w0 == is->m_edge.m_w0 && (*iit)->m_w1 == is->m_edge.m_w1) {
				assert((*iit)->m_toBeDeleted == false);
				s->m_edgeList.erase(iit);
				return;
			}
	}
}

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

IntersectedStroke *TVectorImage::Imp::eraseBranch(Intersection *in,
												  IntersectedStroke *is)
{
	if (is->m_nextIntersection) {
		Intersection *nextInt = is->m_nextIntersection;
		IntersectedStroke *nextStroke = is->m_nextStroke;
		assert(nextStroke->m_nextIntersection == in);
		assert(nextStroke->m_nextStroke == is);
		assert(nextStroke != is);

		//nextStroke->m_nextIntersection = intList.end();
		//nextStroke->m_nextStroke = nextInt->m_strokeList.end();

		if (nextStroke->m_nextIntersection) {
			nextStroke->m_nextIntersection = 0;
			nextInt->m_numInter--;
		}
		//nextInt->m_strokeList.erase(nextStroke);//non posso cancellarla, puo' servire in futuro!
	}
	if (is->m_nextIntersection)
		in->m_numInter--;

	eraseEdgeFromStroke(is);

	is->m_edge.m_w0 = is->m_edge.m_w1 = -3;
	is->m_edge.m_index = -3;
	is->m_edge.m_s = 0;
	is->m_edge.m_styleId = -3;

	return in->m_strokeList.erase(is);
}

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

void TVectorImage::Imp::eraseDeadIntersections()
{
	Intersection *p = m_intersectionData->m_intList.first();

	while (p) //la faccio qui, e non nella eraseIntersection. vedi commento li'.
	{
		//Intersection* &intList = m_intersectionData->m_intList;

		if (p->m_strokeList.size() == 1) {
			eraseBranch(p, p->m_strokeList.first());
			assert(p->m_strokeList.size() == 0);
			p = m_intersectionData->m_intList.erase(p);
		} else if (p->m_strokeList.size() == 2 &&
				   (p->m_strokeList.first()->m_edge.m_s == p->m_strokeList.last()->m_edge.m_s &&
					p->m_strokeList.first()->m_edge.m_w0 == p->m_strokeList.last()->m_edge.m_w0)) //intersezione finta
		{
			IntersectedStroke *it1 = p->m_strokeList.first(), *iit1, *iit2;
			IntersectedStroke *it2 = it1->next();

			eraseEdgeFromStroke(p->m_strokeList.first());
			eraseEdgeFromStroke(p->m_strokeList.first()->next());

			iit1 = (it1->m_nextIntersection) ? it1->m_nextStroke : 0;
			iit2 = (it2->m_nextIntersection) ? it2->m_nextStroke : 0;

			if (iit1 && iit2) {
				iit1->m_edge.m_w1 = iit2->m_edge.m_w0;
				iit2->m_edge.m_w1 = iit1->m_edge.m_w0;
			}
			if (iit1) {
				iit1->m_nextStroke = iit2;
				iit1->m_nextIntersection = it2->m_nextIntersection;
				if (!iit1->m_nextIntersection)
					it1->m_nextIntersection->m_numInter--;
			}

			if (iit2) {
				iit2->m_nextStroke = iit1;
				iit2->m_nextIntersection = it1->m_nextIntersection;
				if (!iit2->m_nextIntersection)
					it2->m_nextIntersection->m_numInter--;
			}

			p->m_strokeList.clear();
			p->m_numInter = 0;
			p = m_intersectionData->m_intList.erase(p);
		} else
			p = p->next();
	}
}

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

void TVectorImage::Imp::doEraseIntersection(int index, vector<int> *toBeDeleted)
{
	Intersection *p1 = m_intersectionData->m_intList.first();
	TStroke *deleteIt = 0;

	while (p1) {
		bool removeAutocloses = false;

		IntersectedStroke *p2 = p1->m_strokeList.first();

		while (p2) {
			IntersectedStroke &is = *p2;

			if (is.m_edge.m_index == index) {
				if (is.m_edge.m_index >= 0)
					//if (!is.m_autoclose && (is.m_edge.m_w0==1 || is.m_edge.m_w0==0))
					removeAutocloses = true;
				else
					deleteIt = is.m_edge.m_s;
				p2 = eraseBranch(p1, p2);
			} else
				p2 = p2->next();
			//checkInterList(interList);
		}
		if (removeAutocloses) //se ho tolto una stroke dall'inter corrente, tolgo tutti le stroke di autclose che partono da qui
		{
			assert(toBeDeleted);
			for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next())
				if (p2->m_edge.m_index < 0 && (p2->m_edge.m_w0 == 1 || p2->m_edge.m_w0 == 0))
					toBeDeleted->push_back(p2->m_edge.m_index);
		}

		if (p1->m_strokeList.empty())
			p1 = m_intersectionData->m_intList.erase(p1);
		else
			p1 = p1->next();
	}

	if (deleteIt)
		delete deleteIt;
}

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

UINT TVectorImage::Imp::getFillData(std::unique_ptr<IntersectionBranch[]>& v)
{
	//print(m_intersectionData->m_intList, "C:\\temp\\intersectionPrimaSave.txt");

	//Intersection* intList = m_intersectionData->m_intList;
	if (m_intersectionData->m_intList.empty())
		return 0;

	Intersection *p1;
	IntersectedStroke *p2;
	UINT currInt = 0;
	vector<UINT> branchesBefore(m_intersectionData->m_intList.size() + 1);

	branchesBefore[0] = 0;
	UINT count = 0, size = 0;

	p1 = m_intersectionData->m_intList.first();

	for (; p1; p1 = p1->next(), currInt++) {
		UINT strokeListSize = p1->m_strokeList.size();
		size += strokeListSize;
		branchesBefore[currInt + 1] = branchesBefore[currInt] + strokeListSize;
	}

	v.reset(new IntersectionBranch[size]);
	currInt = 0;
	p1 = m_intersectionData->m_intList.first();
	for (; p1; p1 = p1->next(), currInt++) {
		UINT currBranch = 0;
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next(), currBranch++) {
			IntersectionBranch &b = v[count];
			b.m_currInter = currInt;
			b.m_strokeIndex = p2->m_edge.m_index;
			b.m_w = p2->m_edge.m_w0;
			b.m_style = p2->m_edge.m_styleId;
			//assert(b.m_style<100);
			b.m_gettingOut = p2->m_gettingOut;
			if (!p2->m_nextIntersection)
				b.m_nextBranch = count;
			else {
				UINT distInt = m_intersectionData->m_intList.getPosOf(p2->m_nextIntersection);
				UINT distBranch = p2->m_nextIntersection->m_strokeList.getPosOf(p2->m_nextStroke);

				if ((distInt < currInt) ||
					(distInt == currInt && distBranch < currBranch)) {
					UINT posNext = branchesBefore[distInt] + distBranch;
					assert(posNext < count);
					b.m_nextBranch = posNext;
					assert(v[posNext].m_nextBranch == (std::numeric_limits<UINT>::max)());
					v[posNext].m_nextBranch = count;
				} else
					b.m_nextBranch = (std::numeric_limits<UINT>::max)();
			}
			count++;
		}
	}

//for (UINT i=0; i<count; i++)
//  assert(v[i].m_nextBranch != std::numeric_limits<UINT>::max());

#ifdef _DEBUG
/*ofstream of("C:\\temp\\fillDataOut.txt");

for (UINT ii=0; ii<size; ii++)
  {
  of<<ii<<"----------------------"<<endl;
  of<<"index:"<<v[ii].m_strokeIndex<<endl;
  of<<"w:"<<v[ii].m_w<<endl;
  of<<"curr inter:"<<v[ii].m_currInter<<endl;
  of<<"next inter:"<<v[ii].m_nextBranch<<endl;
  of<<"gettingOut:"<<((v[ii].m_gettingOut)?"TRUE":"FALSE")<<endl;
  of<<"colorId:"<<v[ii].m_style<<endl;
  }*/
#endif

	return size;
}

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

//-----------------------------------------------------------------------------
namespace
{
TStroke *reconstructAutocloseStroke(Intersection *p1,
									IntersectedStroke *p2)

{
	bool found = false;
	Intersection *pp1 = p1->next();
	IntersectedStroke *pp2;

	//vector<TEdge*> vapp;
	for (; !found && pp1; pp1 = pp1->next()) {
		for (pp2 = pp1->m_strokeList.first(); !found && pp2; pp2 = pp2->next()) {
			if (p2->m_edge.m_index == pp2->m_edge.m_index) {
				if ((pp2->m_edge.m_w0 == 1 && p2->m_edge.m_w0 == 0) ||
					(pp2->m_edge.m_w0 == 0 && p2->m_edge.m_w0 == 1)) {
					found = true;
					vector<TPointD> v;
					if (p2->m_edge.m_w0 == 0) {
						v.push_back(p1->m_intersection);
						v.push_back(pp1->m_intersection);
					} else {
						v.push_back(pp1->m_intersection);
						v.push_back(p1->m_intersection);
					}
					p2->m_edge.m_s = pp2->m_edge.m_s = new TStroke(v);
					//for (UINT ii=0; ii<vapp.size(); ii++)
					// vapp[ii]->m_s = it2->m_edge.m_s;
				}
				//else if (iit2->m_edge.m_w0!=0 && iit2->m_edge.m_w0!=1)
				//  vapp.push_back(&(iit2->m_edge));
			}
		}
	}
	assert(found);
	if (!found)
		p2->m_edge.m_s = 0;

	return p2->m_edge.m_s;
}

} //namespace
//-----------------------------------------------------------------------------

void TVectorImage::Imp::setFillData(std::unique_ptr<IntersectionBranch[]> const& v, UINT branchCount, bool doComputeRegions)
{
#ifdef _DEBUG
/*ofstream of("C:\\temp\\fillDataIn.txt");

for (UINT ii=0; ii<branchCount; ii++)
  {
  of<<ii<<"----------------------"<<endl;
  of<<"index:"<<v[ii].m_strokeIndex<<endl;
  of<<"w:"<<v[ii].m_w<<endl;
  of<<"curr inter:"<<v[ii].m_currInter<<endl;
  of<<"next inter:"<<v[ii].m_nextBranch<<endl;
  of<<"gettingOut:"<<((v[ii].m_gettingOut)?"TRUE":"FALSE")<<endl;
  of<<"colorId:"<<v[ii].m_style<<endl;
  }*/
#endif

	if (branchCount == 0)
		return;

	//{
	//QMutexLocker sl(m_mutex);

	VIList<Intersection> &intList = m_intersectionData->m_intList;

	clearPointerContainer(m_regions);
	m_regions.clear();
	intList.clear();
	Intersection *currInt;
	IntersectedStroke *currBranch;

	UINT size = v[branchCount - 1].m_currInter + 1;
	vector<UINT> branchesBefore(size);

	UINT i = 0;
	for (; i < branchCount; i++) {
		const IntersectionBranch &b = v[i];
		if (i == 0 || v[i].m_currInter != v[i - 1].m_currInter) {

			if (v[i].m_currInter >= size) //pezza per immagine corrotte...evito crash
			{
				intList.clear();
				return;
			}

			branchesBefore[v[i].m_currInter] = i;

			currInt = new Intersection();
			intList.pushBack(currInt);
		}

		currBranch = new IntersectedStroke();
		currInt->m_strokeList.pushBack(currBranch);

		currBranch->m_edge.m_styleId = b.m_style;
		//assert(b.m_style<100);
		currBranch->m_edge.m_index = b.m_strokeIndex;
		if (b.m_strokeIndex >= 0)
			currBranch->m_edge.m_s = m_strokes[b.m_strokeIndex]->m_s;
		else
			currBranch->m_edge.m_s = 0;
		currBranch->m_gettingOut = b.m_gettingOut;
		currBranch->m_edge.m_w0 = b.m_w;
		if (b.m_nextBranch < branchCount)
			currBranch->m_edge.m_w1 = v[b.m_nextBranch].m_w;
		else
			currBranch->m_edge.m_w1 = 1.0;
		assert(currBranch->m_edge.m_w0 >= -1e-8 && currBranch->m_edge.m_w0 <= 1 + 1e-8);
		assert(currBranch->m_edge.m_w1 >= -1e-8 && currBranch->m_edge.m_w1 <= 1 + 1e-8);

		if (b.m_nextBranch < i) {
			Intersection *p1;
			IntersectedStroke *p2;
			p1 = intList.getElemAt(v[b.m_nextBranch].m_currInter);

			assert(b.m_nextBranch - branchesBefore[v[b.m_nextBranch].m_currInter] >= 0);
			p2 = p1->m_strokeList.getElemAt(b.m_nextBranch - branchesBefore[v[b.m_nextBranch].m_currInter]);

			currBranch->m_nextIntersection = p1;
			currBranch->m_nextStroke = p2;
			p2->m_nextIntersection = currInt;
			p2->m_nextStroke = currBranch;

			//if (currBranch == currInt->m_strokeList.begin())
			//  currInt->m_intersection = currBranch->m_edge.m_s->getPoint(currBranch->m_edge.m_w0);

			currInt->m_numInter++;
			p1->m_numInter++;
		} else if (b.m_nextBranch == i)
			currBranch->m_nextIntersection = 0;
		else if (b.m_nextBranch == (std::numeric_limits<UINT>::max)()) {
			currBranch->m_nextIntersection = 0;
			currBranch->m_nextStroke = 0;
		}

		/* {
    assert(b.m_nextBranch<branchCount);
    assert(v[b.m_nextBranch].m_nextBranch==i);
    }*/

		if (i == branchCount - 1 || v[i].m_currInter != v[i + 1].m_currInter) {
			int j = i;
			while (v[j].m_strokeIndex < 0 && ((j > 0 && v[j].m_currInter == v[j - 1].m_currInter) || j == 0))
				j--;
			if (v[j].m_strokeIndex >= 0)
				currInt->m_intersection = m_strokes[v[j].m_strokeIndex]->m_s->getPoint(v[j].m_w);
		}
	}

	for (i = 0; i < m_strokes.size(); i++)
		m_strokes[i]->m_isNewForFill = false;

	//computeRegions();

	Intersection *p1;
	IntersectedStroke *p2;

	vector<UINT> toBeDeleted;

	for (p1 = intList.first(); p1; p1 = p1->next())
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next()) {
			if (p2->m_edge.m_index < 0 && !p2->m_edge.m_s &&
				(p2->m_edge.m_w0 == 0 || p2->m_edge.m_w0 == 1)) {
				p2->m_edge.m_s = reconstructAutocloseStroke(p1, p2);
				if (p2->m_edge.m_s)
					m_intersectionData->m_autocloseMap[p2->m_edge.m_index] = new VIStroke(p2->m_edge.m_s, TGroupId());
				else
					toBeDeleted.push_back(p2->m_edge.m_index);
			}
		}

	for (p1 = intList.first(); p1; p1 = p1->next())
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next()) {
			if (!p2->m_edge.m_s && p2->m_edge.m_index < 0) {
				VIStroke *vs = m_intersectionData->m_autocloseMap[p2->m_edge.m_index];
				if (vs) {
					p2->m_edge.m_s = m_intersectionData->m_autocloseMap[p2->m_edge.m_index]->m_s;

					//TEdge& e = it2->m_edge;
					if (!p2->m_edge.m_s)
						toBeDeleted.push_back(p2->m_edge.m_index);
				}
			}
		}

	for (i = 0; i < toBeDeleted.size(); i++)
		eraseIntersection(toBeDeleted[i]);

	m_areValidRegions = false;
	//}

	if (doComputeRegions)
		computeRegions();
	//print(m_intersectionData->m_intList, "C:\\temp\\intersectionDopoLoad.txt");
}

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

void TVectorImage::Imp::eraseIntersection(int index)
{
	vector<int> autocloseStrokes;
	doEraseIntersection(index, &autocloseStrokes);

	for (UINT i = 0; i < autocloseStrokes.size(); i++) {
		doEraseIntersection(autocloseStrokes[i]);
		assert(autocloseStrokes[i] < 0);
		m_intersectionData->m_autocloseMap.erase(autocloseStrokes[i]);
	}
}
//-----------------------------------------------------------------------------

void findNearestIntersection(VIList<Intersection> &interList)
{
	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = interList.first(); p1; p1 = p1->next()) {
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next()) {
			if (p2->m_nextIntersection) //already set
				continue;

			int versus = (p2->m_gettingOut) ? 1 : -1;
			double minDelta = (std::numeric_limits<double>::max)();
			Intersection *pp1, *p1Res;
			IntersectedStroke *pp2, *p2Res;

			for (pp1 = p1; pp1; pp1 = pp1->next()) {
				if (pp1 == p1)
					pp2 = p2, pp2 = pp2->next();
				else
					pp2 = pp1->m_strokeList.first();

				for (; pp2; pp2 = pp2->next()) {
					if (pp2->m_edge.m_index == p2->m_edge.m_index &&
						pp2->m_gettingOut == !p2->m_gettingOut) {
						double delta = versus * (pp2->m_edge.m_w0 - p2->m_edge.m_w0);

						if (delta > 0 && delta < minDelta) {
							p1Res = pp1;
							p2Res = pp2;
							minDelta = delta;
						}
					}
				}
			}

			if (minDelta != (std::numeric_limits<double>::max)()) {
				p2Res->m_nextIntersection = p1;
				p2Res->m_nextStroke = p2;
				p2Res->m_edge.m_w1 = p2->m_edge.m_w0;
				p2->m_nextIntersection = p1Res;
				p2->m_nextStroke = p2Res;
				p2->m_edge.m_w1 = p2Res->m_edge.m_w0;
				p1->m_numInter++;
				p1Res->m_numInter++;
			}
		}
	}
}

//-----------------------------------------------------------------------------
void markDeadIntersections(VIList<Intersection> &intList, Intersection *p);

//questa funzione "cuscinetto" serve perche crashava il compilatore in release!!!
void inline markDeadIntersectionsRic(VIList<Intersection> &intList, Intersection *p)
{
	markDeadIntersections(intList, p);
}

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

void markDeadIntersections(VIList<Intersection> &intList, Intersection *p)
{
	IntersectedStroke *p1 = p->m_strokeList.first();
	if (!p1)
		return;

	if (p->m_numInter == 1) {
		while (p1 && !!p1->m_nextIntersection)
			p1 = p1->next();
		assert(p1);
		if (!p1)
			return;

		Intersection *nextInt = p1->m_nextIntersection;
		IntersectedStroke *nextStroke = p1->m_nextStroke;

		p->m_numInter = 0;
		p1->m_nextIntersection = 0;

		if (nextInt /*&& !nextStroke->m_dead*/) {
			nextInt->m_numInter--;
			nextStroke->m_nextIntersection = 0;
			markDeadIntersectionsRic(intList, nextInt);
		}
	} else if (p->m_numInter == 2) //intersezione finta (forse)
	{
		while (p1 && !p1->m_nextIntersection)
			p1 = p1->next();
		assert(p1);
		if (!p1)
			return;
		IntersectedStroke *p2 = p1->next();

		while (p2 && !p2->m_nextIntersection)
			p2 = p2->next();

		assert(p2);
		if (!p2)
			return;

		if (p1->m_edge.m_s == p2->m_edge.m_s && p1->m_edge.m_w0 == p2->m_edge.m_w0) //intersezione finta
		{
			IntersectedStroke *pp1, *pp2;
			assert(p1->m_nextIntersection && p2->m_nextIntersection);

			pp1 = p1->m_nextStroke;
			pp2 = p2->m_nextStroke;

			pp2->m_edge.m_w1 = pp1->m_edge.m_w0;
			pp1->m_edge.m_w1 = pp2->m_edge.m_w0;

			//if (iit1!=0)
			pp1->m_nextStroke = pp2;
			//if (iit2!=0)
			pp2->m_nextStroke = pp1;
			//if (iit1!=0)
			pp1->m_nextIntersection = p2->m_nextIntersection;
			//if (iit2!=0)
			pp2->m_nextIntersection = p1->m_nextIntersection;

			p->m_numInter = 0;
			p1->m_nextIntersection = p2->m_nextIntersection = 0;
		}
	}
}

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

//se cross val era 0, cerco di spostarmi un po' su w per vedere come sono orientate le tangenti agli stroke...
double nearCrossVal(TStroke *s0, double w0, TStroke *s1, double w1)
{
	double ltot0 = s0->getLength();
	double ltot1 = s1->getLength();
	double dl = tmin(ltot1, ltot0) / 1000;

	double crossVal, dl0 = dl, dl1 = dl;

	TPointD p0, p1;
	int count = 0;

	if (w0 == 1.0)
		dl0 = -dl0;
	if (w1 == 1.0)
		dl1 = -dl1;

	double l0 = s0->getLength(w0) + dl0;
	double l1 = s1->getLength(w1) + dl1;

	do {
		p0 = s0->getSpeed(s0->getParameterAtLength(l0));
		p1 = s1->getSpeed(s1->getParameterAtLength(l1));
		crossVal = cross(p0, p1);
		l0 += dl0, l1 += dl1;
		count++;
	} while (areAlmostEqual(crossVal, 0.0) &&
			 ((dl0 > 0 && l0 < ltot0) || (dl0 < 0 && l0 > 0)) &&
			 ((dl1 > 0 && l1 < ltot1) || (dl1 < 0 && l1 > 0)));
	return crossVal;
}

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

inline void insertBranch(Intersection &in, IntersectedStroke &item, bool gettingOut)
{
	if (item.m_edge.m_w0 != (gettingOut ? 1.0 : 0.0)) {
		item.m_gettingOut = gettingOut;
		in.m_strokeList.pushBack(new IntersectedStroke(item));
	}
}

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

double getAngle(const TPointD &p0, const TPointD &p1)
{
	double angle1 = 180 * atan2(p0.x, p0.y) / TConsts::pi;
	double angle2 = 180 * atan2(p1.x, p1.y) / TConsts::pi;

	if (angle1 < 0)
		angle1 = 360 + angle1;
	if (angle2 < 0)
		angle2 = 360 + angle2;

	return (angle2 - angle1) < 0 ? 360 + angle2 - angle1 : angle2 - angle1;
}

//-----------------------------------------------------------------------------
//nel caso l'angolo tra due stroke in un certo w sia nullo,
// si va un po' avanti per vedere come sono orientate....
double getNearAngle(const TStroke *s1, double w1, bool out1, const TStroke *s2, double w2, bool out2)
{
	bool verse1 = (out1 && w1 < 1) || (!out1 && w1 == 0);
	bool verse2 = (out2 && w2 < 1) || (!out2 && w2 == 0);
	double ltot1 = s1->getLength();
	double ltot2 = s2->getLength();
	double l1 = s1->getLength(w1);
	double l2 = s2->getLength(w2);
	double dl = min(ltot1, ltot2) / 1000;
	double dl1 = verse1 ? dl : -dl;
	double dl2 = verse2 ? dl : -dl;

	while (((verse1 && l1 < ltot1) || (!verse1 && l1 > 0)) && ((verse2 && l2 < ltot2) || (!verse2 && l2 > 0))) {
		l1 += dl1;
		l2 += dl2;
		TPointD p1 = (out1 ? 1 : -1) * s1->getSpeed(s1->getParameterAtLength(l1));
		TPointD p2 = (out2 ? 1 : -1) * s2->getSpeed(s2->getParameterAtLength(l2));
		double angle = getAngle(p1, p2);
		if (!areAlmostEqual(angle, 0, 1e-9))
			return angle;
	}
	return 0;
}

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

bool makeEdgeIntersection(Intersection &interList, IntersectedStroke &item1, IntersectedStroke &item2,
						  const TPointD &p1a, const TPointD &p1b, const TPointD &p2a, const TPointD &p2b)
{
	double angle1 = getAngle(p1a, p1b);
	double angle2 = getAngle(p1a, p2a);
	double angle3 = getAngle(p1a, p2b);
	double angle;

	bool eraseP1b = false, eraseP2a = false, eraseP2b = false;

	if (areAlmostEqual(angle1, 0, 1e-9)) {
		angle1 = getNearAngle(item1.m_edge.m_s, item1.m_edge.m_w0, true, item1.m_edge.m_s, item1.m_edge.m_w0, false);
		if (areAlmostEqual(angle1, 1e-9))
			eraseP1b = true;
	}
	if (areAlmostEqual(angle2, 0, 1e-9)) {
		angle2 = getNearAngle(item1.m_edge.m_s, item1.m_edge.m_w0, true, item2.m_edge.m_s, item2.m_edge.m_w0, true);
		if (areAlmostEqual(angle2, 1e-9))
			eraseP2a = true;
	}
	if (areAlmostEqual(angle3, 0, 1e-9)) {
		angle3 = getNearAngle(item1.m_edge.m_s, item1.m_edge.m_w0, true, item2.m_edge.m_s, item2.m_edge.m_w0, false);
		if (areAlmostEqual(angle3, 1e-9))
			eraseP2b = true;
	}

	if (areAlmostEqual(angle1, angle2, 1e-9)) {
		angle = getNearAngle(item1.m_edge.m_s, item1.m_edge.m_w0, false, item2.m_edge.m_s, item2.m_edge.m_w0, true);
		if (angle != 0) {
			angle2 += angle;
			if (angle2 > 360)
				angle2 -= 360;
		} else
			eraseP2a = true;
	}
	if (areAlmostEqual(angle1, angle3, 1e-9)) {
		angle = getNearAngle(item1.m_edge.m_s, item1.m_edge.m_w0, false, item2.m_edge.m_s, item2.m_edge.m_w0, false);
		if (angle != 0) {
			angle3 += angle;
			if (angle3 > 360)
				angle3 -= 360;
		} else
			eraseP2b = true;
	}
	if (areAlmostEqual(angle2, angle3, 1e-9)) {
		angle = getNearAngle(item1.m_edge.m_s, item1.m_edge.m_w0, false, item2.m_edge.m_s, item2.m_edge.m_w0, true);
		if (angle != 0) {
			angle3 += angle;
			if (angle3 > 360)
				angle3 -= 360;
		} else
			eraseP2b = true;
	}

	int fac = (angle1 < angle2) | ((angle1 < angle3) << 1) | ((angle2 < angle3) << 2);

	switch (fac) {
		CASE 0 : //p1a p2b p2a p1b
				 insertBranch(interList, item1, true);
		if (!eraseP2b)
			insertBranch(interList, item2, false);
		if (!eraseP2a)
			insertBranch(interList, item2, true);
		if (!eraseP1b)
			insertBranch(interList, item1, false);
		CASE 1 : //p1a p2b p1b p2a
				 insertBranch(interList, item1, true);
		if (!eraseP2b)
			insertBranch(interList, item2, false);
		if (!eraseP1b)
			insertBranch(interList, item1, false);
		if (!eraseP2a)
			insertBranch(interList, item2, true);
		CASE 2 : assert(false);
		CASE 3 : //p1a p1b p2b p2a
				 insertBranch(interList, item1, true);
		if (!eraseP1b)
			insertBranch(interList, item1, false);
		if (!eraseP2b)
			insertBranch(interList, item2, false);
		if (!eraseP2a)
			insertBranch(interList, item2, true);
		CASE 4 : //p1a p2a p2b p1b
				 insertBranch(interList, item1, true);
		if (!eraseP2a)
			insertBranch(interList, item2, true);
		if (!eraseP2b)
			insertBranch(interList, item2, false);
		if (!eraseP1b)
			insertBranch(interList, item1, false);
		CASE 5 : assert(false);
		CASE 6 : //p1a p2a p1b p2b
				 insertBranch(interList, item1, true);
		if (!eraseP2a)
			insertBranch(interList, item2, true);
		if (!eraseP1b)
			insertBranch(interList, item1, false);
		if (!eraseP2b)
			insertBranch(interList, item2, false);
		CASE 7 : //p1a p1b p2a p2b
				 insertBranch(interList, item1, true);
		if (!eraseP1b)
			insertBranch(interList, item1, false);
		if (!eraseP2a)
			insertBranch(interList, item2, true);
		if (!eraseP2b)
			insertBranch(interList, item2, false);
	DEFAULT:
		assert(false);
	}

	return true;
}

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

bool makeIntersection(IntersectionData &intData, const vector<VIStroke *> &s, int ii, int jj,
					  DoublePair inter, int strokeSize, Intersection &interList)
{
	IntersectedStroke item1, item2;

	interList.m_intersection = s[ii]->m_s->getPoint(inter.first);

	item1.m_edge.m_w0 = inter.first;
	item2.m_edge.m_w0 = inter.second;

	if (ii >= 0 && ii < strokeSize) {
		item1.m_edge.m_s = s[ii]->m_s;
		item1.m_edge.m_index = ii;
	} else {
		if (ii < 0) {
			item1.m_edge.m_s = intData.m_autocloseMap[ii]->m_s;
			item1.m_edge.m_index = ii;
		} else {
			item1.m_edge.m_s = s[ii]->m_s;
			item1.m_edge.m_index = -(ii + intData.maxAutocloseId * 100000);
			intData.m_autocloseMap[item1.m_edge.m_index] = s[ii];
		}
	}

	if (jj >= 0 && jj < strokeSize) {
		item2.m_edge.m_s = s[jj]->m_s;
		item2.m_edge.m_index = jj;
	} else {
		if (jj < 0) {
			item2.m_edge.m_s = intData.m_autocloseMap[jj]->m_s;
			item2.m_edge.m_index = jj;
		} else {
			item2.m_edge.m_s = s[jj]->m_s;
			item2.m_edge.m_index = -(jj + intData.maxAutocloseId * 100000);
			intData.m_autocloseMap[item2.m_edge.m_index] = s[jj];
		}
	}

	bool reversed = false;

	TPointD p0, p0b, p1, p1b;

	bool ret1 = item1.m_edge.m_s->getSpeedTwoValues(item1.m_edge.m_w0, p0, p0b);
	bool ret2 = item2.m_edge.m_s->getSpeedTwoValues(item2.m_edge.m_w0, p1, p1b);

	if (ret1 || ret2) //punto angoloso!!!!
		return makeEdgeIntersection(interList, item1, item2, p0, p0b, p1, p1b);

	double crossVal = cross(p0, p1);

	//crossVal = cross(p0, p1);

	if (areAlmostEqual(crossVal, 0.0)) {
		bool endpoint1 = (item1.m_edge.m_w0 == 0.0 || item1.m_edge.m_w0 == 1.0);
		bool endpoint2 = (item2.m_edge.m_w0 == 0.0 || item2.m_edge.m_w0 == 1.0);
		if (endpoint1 &&
			endpoint2 &&
			((p0.x * p1.x >= 0 && p0.y * p1.y >= 0 && item1.m_edge.m_w0 != item2.m_edge.m_w0) ||
			 (p0.x * p1.x <= 0 && p0.y * p1.y <= 0 && item1.m_edge.m_w0 == item2.m_edge.m_w0)))
		//due endpoint a 180 gradi;metto
		{
			item1.m_gettingOut = (item1.m_edge.m_w0 == 0.0);
			interList.m_strokeList.pushBack(new IntersectedStroke(item1));
			item2.m_gettingOut = (item2.m_edge.m_w0 == 0.0);
			interList.m_strokeList.pushBack(new IntersectedStroke(item2));
			return true;
		}
		//crossVal = nearCrossVal(item1.m_edge.m_s, item1.m_edge.m_w0, item2.m_edge.m_s, item2.m_edge.m_w0);
		//if (areAlmostEqual(crossVal, 0.0))
		// return false;
		return makeEdgeIntersection(interList, item1, item2, p0, p0b, p1, p1b);
	}

	if (crossVal > 0)
		reversed = true; //std::reverse(interList.m_strokeList.begin(), interList.m_strokeList.end());

	if (item1.m_edge.m_w0 != 1.0) {
		item1.m_gettingOut = true;
		interList.m_strokeList.pushBack(new IntersectedStroke(item1));
	}
	if (item2.m_edge.m_w0 != (reversed ? 0.0 : 1.0)) {
		item2.m_gettingOut = !reversed;
		interList.m_strokeList.pushBack(new IntersectedStroke(item2));
	}
	if (item1.m_edge.m_w0 != 0.0) {
		item1.m_gettingOut = false;
		interList.m_strokeList.pushBack(new IntersectedStroke(item1));
	}
	if (item2.m_edge.m_w0 != (reversed ? 1.0 : 0.0)) {
		item2.m_gettingOut = reversed;
		interList.m_strokeList.pushBack(new IntersectedStroke(item2));
	}

	return true;
}

//-----------------------------------------------------------------------------
/*
void checkAuto(const vector<VIStroke*>& s)
{
for (int i=0; i<(int)s.size(); i++)
for (int j=i+1; j<(int)s.size(); j++)
  if (s[i]->m_s->getChunkCount()==1 && s[j]->m_s->getChunkCount()==1) //se ha una sola quadratica, probabilmente e' un autoclose.
	  {
		const TThickQuadratic*q = s[i]->m_s->getChunk(0);
		const TThickQuadratic*p = s[j]->m_s->getChunk(0);

		if (areAlmostEqual(q->getP0(), p->getP0(), 1e-2) && areAlmostEqual(q->getP2(), p->getP2(), 1e-2))
		  assert(!"eccolo!");
		if (areAlmostEqual(q->getP0(), p->getP2(), 1e-2) && areAlmostEqual(q->getP2(), p->getP0(), 1e-2))
		  assert(!"eccolo!");
    }
}
*/
//-----------------------------------------------------------------------------

bool addAutocloseIntersection(IntersectionData &intData, vector<VIStroke *> &s,
							  int ii, int jj, double w0, double w1, int strokeSize, bool isVectorized)
{

	assert(s[ii]->m_groupId == s[jj]->m_groupId);

	Intersection *rp = intData.m_intList.last();

	assert(w0 >= 0.0 && w0 <= 1.0);
	assert(w1 >= 0.0 && w1 <= 1.0);

	for (; rp; rp = rp->prev()) // evito di fare la connessione, se gia' ce
								// ne e' una simile tra le stesse due stroke
	{
		if (rp->m_strokeList.size() < 2)
			continue;
		IntersectedStroke *ps = rp->m_strokeList.first();
		int s0 = ps->m_edge.m_index;
		if (s0 < 0)
			continue;
		double ww0 = ps->m_edge.m_w0;
		ps = ps->next();
		if (ps->m_edge.m_index == s0 && ps->m_edge.m_w0 == ww0) {
			ps = ps->next();
			if (!ps)
				continue;
		}
		int s1 = ps->m_edge.m_index;
		if (s1 < 0)
			continue;
		double ww1 = ps->m_edge.m_w0;

		if (!((s0 == ii && s1 == jj) || (s0 == jj && s1 == ii)))
			continue;

		if (s0 == ii && areAlmostEqual(w0, ww0, 0.1) && areAlmostEqual(w1, ww1, 0.1))
			return false;
		else if (s1 == ii && areAlmostEqual(w0, ww1, 0.1) && areAlmostEqual(w1, ww0, 0.1))
			return false;
	}

	vector<TPointD> v;
	v.push_back(s[ii]->m_s->getPoint(w0));
	v.push_back(s[jj]->m_s->getPoint(w1));
	if (v[0] == v[1]) //le stroke si intersecano , ma la fottuta funzione intersect non ha trovato l'intersezione(tipicamente, questo accade agli estremi)!!!
	{
		addIntersection(intData, s, ii, jj, DoublePair(w0, w1), strokeSize, isVectorized);
		return true;
	}

	//se gia e' stato messo questo autoclose, evito
	for (int i = 0; i < (int)s.size(); i++)
		if (s[i]->m_s->getChunkCount() == 1) //se ha una sola quadratica, probabilmente e' un autoclose.
		{
			const TThickQuadratic *q = s[i]->m_s->getChunk(0);

			if (areAlmostEqual(q->getP0(), v[0], 1e-2) && areAlmostEqual(q->getP2(), v[1], 1e-2) ||
				areAlmostEqual(q->getP0(), v[1], 1e-2) && areAlmostEqual(q->getP2(), v[0], 1e-2)) {
				return true;
				addIntersection(intData, s, i, ii, DoublePair(0.0, w0), strokeSize, isVectorized);
				addIntersection(intData, s, i, jj, DoublePair(1.0, w1), strokeSize, isVectorized);
				return true;
			}
		}
	assert(s[ii]->m_groupId == s[jj]->m_groupId);

	s.push_back(new VIStroke(new TStroke(v), s[ii]->m_groupId));
	addIntersection(intData, s, s.size() - 1, ii, DoublePair(0.0, w0), strokeSize, isVectorized);
	addIntersection(intData, s, s.size() - 1, jj, DoublePair(1.0, w1), strokeSize, isVectorized);
	return true;
}

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

//double g_autocloseTolerance = c_newAutocloseTolerance;

bool isCloseEnoughP2P(double facMin, double facMax, TStroke *s1, double w0, TStroke *s2, double w1)
{
	double autoDistMin, autoDistMax;

	TThickPoint p0 = s1->getThickPoint(w0);
	TThickPoint p1 = s2->getThickPoint(w1);
	double dist2;

	dist2 = tdistance2(p0, p1);

	/*!when closing beetween a normal stroke and a 0-thickness stroke (very typical) the thin  one is assumed to have same thickness of the other*/
	if (p0.thick == 0)
		p0.thick = p1.thick;
	else if (p1.thick == 0)
		p1.thick = p0.thick;
	if (facMin == 0) {
		autoDistMin = 0;
		autoDistMax = tmax(-2.0, facMax * (p0.thick + p1.thick) * (p0.thick + p1.thick));
		if (autoDistMax < 0.0000001) //! for strokes without thickness, I connect for distances less than min between 2.5 and half of the length of the stroke)
		{
			double len1 = s1->getLength();
			double len2 = s2->getLength();
			autoDistMax = facMax * tmin(2.5, len1 * len1 / (2 * 2), len2 * len2 / (2 * 2), 100.0 /*dummyVal*/);
		}
	} else {
		autoDistMin = tmax(-2.0, facMin * (p0.thick + p1.thick) * (p0.thick + p1.thick));
		if (autoDistMin < 0.0000001) //! for strokes without thickness, I connect for distances less than min between 2.5 and half of the length of the stroke)
		{
			double len1 = s1->getLength();
			double len2 = s2->getLength();
			autoDistMin = facMax * tmin(2.5, len1 * len1 / (2 * 2), len2 * len2 / (2 * 2), 100.0 /*dummyVal*/);
		}

		autoDistMax = autoDistMin + (facMax - facMin) * (facMax - facMin);
	}

	if (dist2 < autoDistMin || dist2 > autoDistMax)
		return false;

	//if (dist2<=tmax(2.0, g_autocloseTolerance*(p0.thick+p1.thick)*(p0.thick+p1.thick))) //0.01 tiene conto di quando thick==0
	if (s1 == s2) {
		TRectD r = s1->getBBox(); //se e' un autoclose su una stroke piccolissima, creerebbe uan area trascurabile, ignoro
		if (fabs(r.x1 - r.x0) < 2 && fabs(r.y1 - r.y0) < 2)
			return false;
	}
	return true;
}

//---------------------------------------------------------------------------------------------------------------------
/*
bool makePoint2PointConnections(double factor, vector<VIStroke*>& s, 
                             int ii, bool isIStartPoint, 
                             int jj, bool isJStartPoint, IntersectionData& intData,
                              int strokeSize)
{
double w0 = (isIStartPoint?0.0:1.0);
double w1 = (isJStartPoint?0.0:1.0);
if (isCloseEnoughP2P(factor, s[ii]->m_s, w0,  s[jj]->m_s, w1))
  return addAutocloseIntersection(intData, s, ii, jj, w0, w1, strokeSize);
return false;
}
*/
//-----------------------------------------------------------------------------

double getCurlW(TStroke *s, bool isBegin) //trova il punto di split su una stroke, in prossimita di un ricciolo;
										  // un ricciolo c'e' se la curva ha un  min o max relativo su x seguito da uno su y, o viceversa.
{
	int numChunks = s->getChunkCount();
	double dx2, dx1 = 0, dy2, dy1 = 0;
	int i = 0;
	for (i = 0; i < numChunks; i++) {
		const TQuadratic *q = s->getChunk(isBegin ? i : numChunks - 1 - i);
		dy2 = q->getP1().y - q->getP0().y;
		if (dy1 * dy2 < 0)
			break;
		dy1 = dy2;
		dy2 = q->getP2().y - q->getP1().y;
		if (dy1 * dy2 < 0)
			break;
		dy1 = dy2;
	}
	if (i == numChunks)
		return -1;

	int maxMin0 = isBegin ? i : numChunks - 1 - i;
	int j = 0;
	for (j = 0; j < numChunks; j++) {
		const TQuadratic *q = s->getChunk(isBegin ? j : numChunks - 1 - j);
		dx2 = q->getP1().x - q->getP0().x;
		if (dx1 * dx2 < 0)
			break;
		dx1 = dx2;
		dx2 = q->getP2().x - q->getP1().x;
		if (dx1 * dx2 < 0)
			break;
		dx1 = dx2;
	}
	if (j == numChunks)
		return -1;

	int maxMin1 = isBegin ? j : numChunks - 1 - j;

	return getWfromChunkAndT(s, isBegin ? tmax(maxMin0, maxMin1) : tmin(maxMin0, maxMin1), isBegin ? 1.0 : 0.0);
}

#ifdef Levo
bool lastIsX = false, lastIsY = false;
for (int i = 0; i < numChunks; i++) {
	const TThickQuadratic *q = s->getChunk(isBegin ? i : numChunks - 1 - i);
	if ((q->getP0().y < q->getP1().y && q->getP2().y < q->getP1().y) || //la quadratica ha un minimo o massimo relativo
		(q->getP0().y > q->getP1().y && q->getP2().y > q->getP1().y)) {
		double w = getWfromChunkAndT(s, isBegin ? i : numChunks - 1 - i, isBegin ? 1.0 : 0.0);
		if (lastIsX) //e' il secondo min o max relativo
			return w;
		lastIsX = false;
		lastIsY = true;

	} else if ((q->getP0().x < q->getP1().x && q->getP2().x < q->getP1().x) || //la quadratica ha un minimo o massimo relativo
			   (q->getP0().x > q->getP1().x && q->getP2().x > q->getP1().x)) {
		double w = getWfromChunkAndT(s, isBegin ? i : numChunks - 1 - i, isBegin ? 1.0 : 0.0);
		if (lastIsY) //e' il secondo min o max relativo
			return w;
		lastIsX = true;
		lastIsY = false;
	}
}

return -1;
}

#endif
//-----------------------------------------------------------------------------

bool isCloseEnoughP2L(double facMin, double facMax, TStroke *s1, double w1, TStroke *s2, double &w)
{
	if (s1->isSelfLoop())
		return false;

	TThickPoint p0 = s1->getThickPoint(w1);
	double t, dist2;
	int index;
	TStroke sAux, *sComp;

	if (s1 == s2) //per trovare le intersezioni con una stroke e se stessa, si toglie il
				  //pezzo di stroke di cui si cercano vicinanze fino alla prima curva
	{
		double w = getCurlW(s1, w1 == 0.0);
		if (w == -1)
			return false;

		split<TStroke>(*s1, tmin(1 - w1, w), tmax(1 - w1, w), sAux);
		sComp = &sAux;
	} else
		sComp = s2;

	if (sComp->getNearestChunk(p0, t, index, dist2) && dist2 > 0) {
		if (s1 == s2) {
			double dummy;
			s2->getNearestChunk(sComp->getChunk(index)->getPoint(t), t, index, dummy);
		}

		//if (areAlmostEqual(w, 0.0, 0.05) || areAlmostEqual(w, 1.0, 0.05))
		//  return; //se w e' vicino ad un estremo, rientra nell'autoclose point to point

		//if (s[jj]->m_s->getLength(w)<=s[jj]->m_s->getThickPoint(0).thick ||
		//    s[jj]->m_s->getLength(w, 1)<=s[jj]->m_s->getThickPoint(1).thick)
		//  return;

		TThickPoint p1 = s2->getChunk(index)->getThickPoint(t);

		/*!when closing beetween a normal stroke and a 0-thickness stroke (very typical) the thin  one is assumed to have same thickness of the other*/
		if (p0.thick == 0)
			p0.thick = p1.thick;
		else if (p1.thick == 0)
			p1.thick = p0.thick;
		double autoDistMin, autoDistMax;
		if (facMin == 0) {
			autoDistMin = 0;
			autoDistMax = tmax(-2.0, (facMax + 0.7) * (p0.thick + p1.thick) * (p0.thick + p1.thick));
			if (autoDistMax < 0.0000001) //! for strokes without thickness, I connect for distances less than min between 2.5 and half of the length of the pointing stroke)
			{
				double len1 = s1->getLength();
				autoDistMax = facMax * tmin(2.5, len1 * len1 / (2 * 2));
			}
		} else {
			autoDistMin = tmax(-2.0, (facMin + 0.7) * (p0.thick + p1.thick) * (p0.thick + p1.thick));
			if (autoDistMin < 0.0000001) //! for strokes without thickness, I connect for distances less than min between 2.5 and half of the length of the pointing stroke)
			{
				double len1 = s1->getLength();
				autoDistMin = facMax * tmin(2.5, len1 * len1 / (2 * 2));
			}

			autoDistMax = autoDistMin + (facMax - facMin + 0.7) * (facMax - facMin + 0.7);
		}

		//double autoDistMin = tmax(-2.0, facMin==0?0:(facMin+0.7)*(p0.thick+p1.thick)*(p0.thick+p1.thick));
		//double autoDistMax = tmax(-2.0, (facMax+0.7)*(p0.thick+p1.thick)*(p0.thick+p1.thick));

		if (dist2 < autoDistMin || dist2 > autoDistMax)
			return false;

		//if (dist2<=(tmax(2.0, (g_autocloseTolerance+0.7)*(p0.thick+p1.thick)*(p0.thick+p1.thick)))) //0.01 tiene conto di quando thick==0

		w = getWfromChunkAndT(s2, index, t);
		return true;
	}
	return false;
}

//-------------------------------------------------------------
/*
void makePoint2LineConnection(double factor, vector<VIStroke*>& s, int ii, int jj, bool isBegin, IntersectionData& intData, 
                    int strokeSize)
{
double w1 = isBegin?0.0: 1.0;

TStroke* s1 = s[ii]->m_s;
TStroke* s2 = s[jj]->m_s;
double w;
if (isCloseEnoughP2L(factor, s1, w1,  s2, w))
  addAutocloseIntersection(intData, s, ii, jj, w1, w, strokeSize);
}
*/
//-----------------------------------------------------------------------------

namespace
{

inline bool isSegment(const TStroke &s)
{
	vector<TThickPoint> v;
	s.getControlPoints(v);
	UINT n = v.size();
	if (areAlmostEqual(v[n - 1].x, v[0].x, 1e-4)) {
		for (UINT i = 1; i < n - 1; i++)
			if (!areAlmostEqual(v[i].x, v[0].x, 1e-4))
				return false;
	} else if (areAlmostEqual(v[n - 1].y, v[0].y, 1e-4)) {
		for (UINT i = 1; i < n - 1; i++)
			if (!areAlmostEqual(v[i].y, v[0].y, 1e-4))
				return false;
	} else {
		double fac = (v[n - 1].y - v[0].y) / (v[n - 1].x - v[0].x);
		for (UINT i = 1; i < n - 1; i++)
			if (!areAlmostEqual((v[i].y - v[0].y) / (v[i].x - v[0].x), fac, 1e-4))
				return false;
	}
	return true;
}

//---------------------------------------------------------------------------------
/*
bool segmentAlreadyExist(const TVectorImageP& vi, const TPointD& p1, const TPointD& p2)
{
for (UINT i=0; i<vi->getStrokeCount(); i++)
  {
  TStroke*s = vi->getStroke(i);
  if (!s->getBBox().contains(p1) || !s->getBBox().contains(p2))
    continue;
  if (((areAlmostEqual(s->getPoint(0.0), p1, 1e-4) && areAlmostEqual(s->getPoint(1.0), p2, 1e-4)) ||
      (areAlmostEqual(s->getPoint(0.0), p2, 1e-4) && areAlmostEqual(s->getPoint(1.0), p1, 1e-4))) &&
       isSegment(*s))
    return true;
  
  }
return false;
}
*/
//----------------------------------------------------------------------------------

bool segmentAlreadyPresent(const TVectorImageP &vi, const TPointD &p1, const TPointD &p2)
{
	for (UINT i = 0; i < vi->getStrokeCount(); i++) {
		TStroke *s = vi->getStroke(i);
		if (((areAlmostEqual(s->getPoint(0.0), p1, 1e-4) && areAlmostEqual(s->getPoint(1.0), p2, 1e-4)) ||
			 (areAlmostEqual(s->getPoint(0.0), p2, 1e-4) && areAlmostEqual(s->getPoint(1.0), p1, 1e-4))) &&
			isSegment(*s))
			return true;
	}
	return false;
	/*
for (UINT i=0; i<vi->getStrokeCount(); i++)
  {
  TStroke* s = vi->getStroke(i);
  
  if (s->getChunkCount()!=1)
    continue;
  if (areAlmostEqual((TPointD)s->getControlPoint(0),                           p1, 1e-2) && 
      areAlmostEqual((TPointD)s->getControlPoint(s->getControlPointCount()-1), p2, 1e-2))
    return true;
  }
  
return false;
*/
}

void getClosingSegments(TL2LAutocloser &l2lautocloser, double facMin, double facMax, TStroke *s1, TStroke *s2,
						vector<DoublePair> *intersections, vector<std::pair<double, double>> &segments)
{
	bool ret1 = false, ret2 = false, ret3 = false, ret4 = false;
#define L2LAUTOCLOSE
#ifdef L2LAUTOCLOSE
	double thickmax2 = s1->getMaxThickness() + s2->getMaxThickness();
	thickmax2 *= thickmax2;
	if (facMin == 0)
		l2lautocloser.setMaxDistance2((facMax + 0.7) * thickmax2);
	else
		l2lautocloser.setMaxDistance2((facMax + 0.7) * thickmax2 + (facMax - facMin + 0.7) * (facMax - facMin + 0.7));

	std::vector<TL2LAutocloser::Segment> l2lSegments;
	if (intersections)
		l2lautocloser.search(l2lSegments, s1, s2, *intersections);
	else
		l2lautocloser.search(l2lSegments, s1, s2);

	for (UINT i = 0; i < l2lSegments.size(); i++) {
		TL2LAutocloser::Segment &seg = l2lSegments[i];
		double autoDistMin, autoDistMax;
		if (facMin == 0) {
			autoDistMin = 0;
			autoDistMax = (facMax + 0.7) * (seg.p0.thick + seg.p1.thick) * (seg.p0.thick + seg.p1.thick);
		} else {
			autoDistMin = (facMin + 0.7) * (seg.p0.thick + seg.p1.thick) * (seg.p0.thick + seg.p1.thick);
			autoDistMax = autoDistMin + (facMax - facMin + 0.7) * (facMax - facMin + 0.7);
		}

		if (seg.dist2 > autoDistMin && seg.dist2 < autoDistMax)
			segments.push_back(std::pair<double, double>(seg.w0, seg.w1));
	}
#endif

	if (s1->isSelfLoop() && s2->isSelfLoop())
		return;

	if (!s1->isSelfLoop() && !s2->isSelfLoop()) {
		if (ret1 = isCloseEnoughP2P(facMin, facMax, s1, 0.0, s2, 1.0))
			segments.push_back(std::pair<double, double>(0.0, 1.0));

		if (s1 != s2) {
			if (ret2 = isCloseEnoughP2P(facMin, facMax, s1, 0.0, s2, 0.0))
				segments.push_back(std::pair<double, double>(0.0, 0.0));
			if (ret3 = isCloseEnoughP2P(facMin, facMax, s1, 1.0, s2, 0.0))
				segments.push_back(std::pair<double, double>(1.0, 0.0));
			if (ret4 = isCloseEnoughP2P(facMin, facMax, s1, 1.0, s2, 1.0))
				segments.push_back(std::pair<double, double>(1.0, 1.0));
		}
	}

	double w;
	if (!ret1 && !ret2 && isCloseEnoughP2L(facMin, facMax, s1, 0.0, s2, w))
		segments.push_back(std::pair<double, double>(0.0, w));
	if (!ret1 && !ret4 && isCloseEnoughP2L(facMin, facMax, s2, 1.0, s1, w))
		segments.push_back(std::pair<double, double>(w, 1.0));

	if (s1 != s2) {
		if (!ret2 && !ret3 && isCloseEnoughP2L(facMin, facMax, s2, 0.0, s1, w))
			segments.push_back(std::pair<double, double>(w, 0.0));
		if (!ret3 && !ret4 && isCloseEnoughP2L(facMin, facMax, s1, 1.0, s2, w))
			segments.push_back(std::pair<double, double>(1.0, w));
	}
}

} //namaspace

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

void getClosingPoints(const TRectD &rect, double fac, const TVectorImageP &vi,
					  vector<pair<int, double>> &startPoints, vector<pair<int, double>> &endPoints)
{
	UINT strokeCount = vi->getStrokeCount();
	TL2LAutocloser l2lautocloser;

	for (UINT i = 0; i < strokeCount; i++) {
		TStroke *s1 = vi->getStroke(i);
		if (!rect.overlaps(s1->getBBox()))
			continue;
		if (s1->getChunkCount() == 1)
			continue;

		for (UINT j = i; j < strokeCount; j++) {
			TStroke *s2 = vi->getStroke(j);

			if (!rect.overlaps(s1->getBBox()))
				continue;
			if (s2->getChunkCount() == 1)
				continue;

#ifdef NEW_REGION_FILL
			double autoTol = 0;
#else
			double autoTol = vi->getAutocloseTolerance();
#endif

			double enlarge1 = (autoTol + 0.7) * (s1->getMaxThickness() > 0 ? s1->getMaxThickness() : 2.5) + fac;
			double enlarge2 = (autoTol + 0.7) * (s2->getMaxThickness() > 0 ? s2->getMaxThickness() : 2.5) + fac;

			if (i != j && !s1->getBBox().enlarge(enlarge1).overlaps(s2->getBBox().enlarge(enlarge2)))
				continue;

			vector<std::pair<double, double>> segments;
			getClosingSegments(l2lautocloser, autoTol, autoTol + fac, s1, s2, 0, segments);
			for (UINT k = 0; k < segments.size(); k++) {
				TPointD p1 = s1->getPoint(segments[k].first);
				TPointD p2 = s2->getPoint(segments[k].second);
				if (rect.contains(p1) && rect.contains(p2)) {
					if (segmentAlreadyPresent(vi, p1, p2))
						continue;
					startPoints.push_back(pair<int, double>(i, segments[k].first));
					endPoints.push_back(pair<int, double>(j, segments[k].second));
				}
			}
		}
	}
}

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

void autoclose(double factor, vector<VIStroke *> &s, int ii, int jj, IntersectionData &IntData,
			   int strokeSize, TL2LAutocloser &l2lautocloser, vector<DoublePair> *intersections, bool isVectorized)
{
	vector<std::pair<double, double>> segments;
	getClosingSegments(l2lautocloser, 0, factor, s[ii]->m_s, s[jj]->m_s, intersections, segments);

	for (UINT i = 0; i < segments.size(); i++)
		addAutocloseIntersection(IntData, s, ii, jj, segments[i].first, segments[i].second, strokeSize, isVectorized);
}

//------------------------------------------------------------------------------------------------------
#ifdef LEVO
void autoclose(double factor, vector<VIStroke *> &s, int ii, int jj, IntersectionData &IntData,
			   int strokeSize)
{
	bool ret1 = false, ret2 = false, ret3 = false, ret4 = false;

	if (s[ii]->m_s->isSelfLoop() && s[jj]->m_s->isSelfLoop())
		return;

	if (!s[ii]->m_s->isSelfLoop() && !s[jj]->m_s->isSelfLoop()) {
		ret1 = makePoint2PointConnections(factor, s, ii, true, jj, false, IntData, strokeSize);

		if (ii != jj) {
			ret2 = makePoint2PointConnections(factor, s, ii, true, jj, true, IntData, strokeSize);
			ret3 = makePoint2PointConnections(factor, s, ii, false, jj, true, IntData, strokeSize);
			ret4 = makePoint2PointConnections(factor, s, ii, false, jj, false, IntData, strokeSize);
		}
	}

	if (!ret1 && !ret2)
		makePoint2LineConnection(factor, s, ii, jj, true, IntData, strokeSize);
	if (!ret1 && !ret4)
		makePoint2LineConnection(factor, s, jj, ii, false, IntData, strokeSize);
	if (ii != jj) {
		if (!ret2 && !ret3)
			makePoint2LineConnection(factor, s, jj, ii, true, IntData, strokeSize);
		if (!ret3 && !ret4)
			makePoint2LineConnection(factor, s, ii, jj, false, IntData, strokeSize);
	}
}

#endif

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

TPointD inline getTangent(const IntersectedStroke &item)
{
	return (item.m_gettingOut ? 1 : -1) * item.m_edge.m_s->getSpeed(item.m_edge.m_w0, item.m_gettingOut);
}

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

void addBranch(IntersectionData &intData, VIList<IntersectedStroke> &strokeList,
			   const vector<VIStroke *> &s, int ii, double w, int strokeSize, bool gettingOut)
{
	IntersectedStroke *p1, *p2;
	TPointD tanRef, lastTan;

	IntersectedStroke *item = new IntersectedStroke();

	if (ii < 0) {
		item->m_edge.m_s = intData.m_autocloseMap[ii]->m_s;
		item->m_edge.m_index = ii;
	} else {
		item->m_edge.m_s = s[ii]->m_s;
		if (ii < strokeSize)
			item->m_edge.m_index = ii;
		else {
			item->m_edge.m_index = -(ii + intData.maxAutocloseId * 100000);
			intData.m_autocloseMap[item->m_edge.m_index] = s[ii];
		}
	}

	item->m_edge.m_w0 = w;
	item->m_gettingOut = gettingOut;

	/*
if (strokeList.size()==2) //potrebbero essere orientati male; due branch possono stare come vogliono, ma col terzo no.
  {
  TPointD tan2 = getTangent(strokeList.back());
  TPointD aux= getTangent(*(strokeList.begin()));
  double crossVal = cross(aux, tan2);
  if (areAlmostEqual(aux, tan2, 1e-3))
	  return;

	if (crossVal>0)
    {
		std::reverse(strokeList.begin(), strokeList.end());
    //tan2 = getTangent(strokeList.back());
		}
  }
*/
	/*
if (areAlmostEqual(lastCross, 0.0) && tan1.x*tan2.x>=0 && tan1.y*tan2.y>=0) //significa angolo tra tangenti nullo
	  {
		crossVal =  nearCrossVal(item.m_edge.m_s, item.m_edge.m_w0, strokeList.back().m_edge.m_s, strokeList.back().m_edge.m_w0);
    if (areAlmostEqual(crossVal, 0.0))
		  return;
		if (!strokeList.back().m_gettingOut)
		  crossVal = -crossVal;
    }
*/

	tanRef = getTangent(*item);
	lastTan = getTangent(*strokeList.last());
	/*
for (it=strokeList.begin(); it!=strokeList.end(); ++it)
  {
	TPointD curTan = getTangent(*it);
  double angle0 = getAngle(lastTan, curTan);
  double angle1 = getAngle(lastTan, tanRef);
 
  if (areAlmostEqual(angle0, angle1, 1e-8))
	  {
		double angle = getNearAngle( it->m_edge.m_s,  it->m_edge.m_w0,  it->m_gettingOut, 
		                            item.m_edge.m_s, item.m_edge.m_w0, item.m_gettingOut);
    angle1 += angle; if (angle1>360) angle1-=360;
    }

  if (angle1<angle0)
    {
    strokeList.insert(it, item);
    return;
    }
	lastTan=curTan;
  }*/

	p2 = strokeList.last();

	for (p1 = strokeList.first(); p1; p1 = p1->next()) {
		TPointD curTan = getTangent(*p1);
		double angle0 = getAngle(lastTan, curTan);
		double angle1 = getAngle(lastTan, tanRef);

		if (areAlmostEqual(angle1, 0, 1e-8)) {
			double angle = getNearAngle(p2->m_edge.m_s, p2->m_edge.m_w0, p2->m_gettingOut,
										item->m_edge.m_s, item->m_edge.m_w0, item->m_gettingOut);
			angle1 += angle;
			if (angle1 > 360)
				angle1 -= 360;
		}

		if (areAlmostEqual(angle0, angle1, 1e-8)) {
			double angle = getNearAngle(p1->m_edge.m_s, p1->m_edge.m_w0, p1->m_gettingOut,
										item->m_edge.m_s, item->m_edge.m_w0, item->m_gettingOut);
			angle1 += angle;
			if (angle1 > 360)
				angle1 -= 360;
		}

		if (angle1 < angle0) {
			strokeList.insert(p1, item);
			return;
		}
		lastTan = curTan;
		p2 = p1;
	}

	//assert(!"add branch: can't find where to insert!");
	strokeList.pushBack(item);
}

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

void addBranches(IntersectionData &intData, Intersection &intersection, const vector<VIStroke *> &s, int ii, int jj,
				 DoublePair intersectionPair, int strokeSize)
{
	bool foundS1 = false, foundS2 = false;
	IntersectedStroke *p;

	assert(!intersection.m_strokeList.empty());

	for (p = intersection.m_strokeList.first(); p; p = p->next()) {

		if ((ii >= 0 && p->m_edge.m_s == s[ii]->m_s && p->m_edge.m_w0 == intersectionPair.first) ||
			(ii < 0 && p->m_edge.m_index == ii && p->m_edge.m_w0 == intersectionPair.first))
			foundS1 = true;
		if ((jj >= 0 && p->m_edge.m_s == s[jj]->m_s && p->m_edge.m_w0 == intersectionPair.second) ||
			(jj < 0 && p->m_edge.m_index == jj && p->m_edge.m_w0 == intersectionPair.second))
			foundS2 = true;
	}

	if (foundS1 && foundS2) {
		/*
  //errore!(vedi commento sotto) possono essere un sacco di intersezioni coincidenti se passano per l'estremo di una quad
	//significa che ci sono due intersezioni coincidenti. cioe' due stroke tangenti. quindi devo invertire l'ordine di due branch enlla rosa dei branch.
  list<IntersectedStroke>::iterator it1, it2;
	it1=intersection.m_strokeList.begin();
	it2 = it1; it2++;
	for (; it2!=intersection.m_strokeList.end(); ++it1, ++it2)
    {
    if ((*it1).m_gettingOut!=(*it2).m_gettingOut &&((*it1).m_edge.m_index==jj && (*it2).m_edge.m_index==ii) || 
		    ((*it1).m_edge.m_index==ii && (*it2).m_edge.m_index==jj))
      {
			IntersectedStroke& el1 = (*it1);
			IntersectedStroke& el2 = (*it2);
      IntersectedStroke app;
			app = el1;
			el1=el2;
			el2=app;
			break;
      }
		}
  */
		return;
	}

	if (!foundS1) {
		if (intersectionPair.first != 1)
			addBranch(intData, intersection.m_strokeList, s, ii, intersectionPair.first, strokeSize, true);
		if (intersectionPair.first != 0)
			addBranch(intData, intersection.m_strokeList, s, ii, intersectionPair.first, strokeSize, false);
		//assert(intersection.m_strokeList.size()-size>0);
	}
	if (!foundS2) {
		if (intersectionPair.second != 1)
			addBranch(intData, intersection.m_strokeList, s, jj, intersectionPair.second, strokeSize, true);
		if (intersectionPair.second != 0)
			addBranch(intData, intersection.m_strokeList, s, jj, intersectionPair.second, strokeSize, false);
		//intersection.m_numInter+=intersection.m_strokeList.size()-size;
		//assert(intersection.m_strokeList.size()-size>0);
	}
}

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

void addIntersections(IntersectionData &intData,
					  const vector<VIStroke *> &s, int ii, int jj,
					  vector<DoublePair> &intersections, int strokeSize, bool isVectorized)
{
	for (int k = 0; k < (int)intersections.size(); k++) {
		if (ii >= strokeSize &&
			(areAlmostEqual(intersections[k].first, 0.0) || areAlmostEqual(intersections[k].first, 1.0)))
			continue;
		if (jj >= strokeSize &&
			(areAlmostEqual(intersections[k].second, 0.0) || areAlmostEqual(intersections[k].second, 1.0)))
			continue;

		addIntersection(intData, s, ii, jj, intersections[k], strokeSize, isVectorized);
	}
}

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

inline double truncate(double x)
{
	x += 1.0;
	TUINT32 *l = (TUINT32 *)&x;

#if TNZ_LITTLE_ENDIAN
	l[0] &= 0xFFE00000;
#else
	l[1] &= 0xFFE00000;
#endif

	return x - 1.0;
}

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

void addIntersection(IntersectionData &intData,
					 const vector<VIStroke *> &s, int ii, int jj,
					 DoublePair intersection, int strokeSize, bool isVectorized)
{
	Intersection *p;
	TPointD point;

	assert(ii < 0 || jj < 0 || s[ii]->m_groupId == s[jj]->m_groupId);

	//UINT iw;
	//iw = ((UINT)(intersection.first*0x3fffffff));
	//intersection.first = truncate(intersection.first);
	//iw = (UINT)(intersection.second*0x3fffffff);

	//intersection.second = truncate(intersection.second);

	if (areAlmostEqual(intersection.first, 0.0, 1e-5))
		intersection.first = 0.0;
	else if (areAlmostEqual(intersection.first, 1.0, 1e-5))
		intersection.first = 1.0;

	if (areAlmostEqual(intersection.second, 0.0, 1e-5))
		intersection.second = 0.0;
	else if (areAlmostEqual(intersection.second, 1.0, 1e-5))
		intersection.second = 1.0;

	point = s[ii]->m_s->getPoint(intersection.first);

	for (p = intData.m_intList.first(); p; p = p->next())
		if (p->m_intersection == point ||
			(isVectorized && areAlmostEqual(p->m_intersection, point, 1e-2))) //devono essere rigorosamente uguali, altrimenti
																			  // il calcolo dell'ordine dei rami con le tangenti sballa
		{
			addBranches(intData, *p, s, ii, jj, intersection, strokeSize);
			return;
		}

	intData.m_intList.pushBack(new Intersection);

	if (!makeIntersection(intData, s, ii, jj, intersection, strokeSize, *intData.m_intList.last()))
		intData.m_intList.erase(intData.m_intList.last());
}

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

void TVectorImage::Imp::findIntersections()
{
	vector<VIStroke *> &strokeArray = m_strokes;
	IntersectionData &intData = *m_intersectionData;
	int strokeSize = (int)strokeArray.size();
	int i, j;
	bool isVectorized = (m_autocloseTolerance < 0);

	assert(intData.m_intersectedStrokeArray.empty());
#define AUTOCLOSE_ATTIVO
#ifdef AUTOCLOSE_ATTIVO
	intData.maxAutocloseId++;

	map<int, VIStroke *>::iterator it, it_b = intData.m_autocloseMap.begin();
	map<int, VIStroke *>::iterator it_e = intData.m_autocloseMap.end();

	//prima cerco le intersezioni tra nuove strokes e vecchi autoclose
	for (i = 0; i < strokeSize; i++) {
		TStroke *s1 = strokeArray[i]->m_s;
		if (!strokeArray[i]->m_isNewForFill || strokeArray[i]->m_isPoint)
			continue;

		TRectD bBox = s1->getBBox();
		double thick2 = s1->getThickPoint(0).thick * 2.1; //2.1 instead of 2.0, for usual problems of approx...
		if (bBox.getLx() <= thick2 && bBox.getLy() <= thick2) {
			strokeArray[i]->m_isPoint = true;
			continue;
		}

		roundStroke(s1);

		for (it = it_b; it != it_e; ++it) {
			if (!it->second || it->second->m_groupId != strokeArray[i]->m_groupId)
				continue;

			TStroke *s2 = it->second->m_s;
			vector<DoublePair> parIntersections;
			if (intersect(s1, s2, parIntersections, true))
				addIntersections(intData, strokeArray, i, it->first, parIntersections, strokeSize, isVectorized);
		}
	}
#endif

	//poi,  intersezioni tra stroke, in cui almeno uno dei due deve essere nuovo

	map<pair<int, int>, vector<DoublePair>> intersectionMap;

	for (i = 0; i < strokeSize; i++) {
		TStroke *s1 = strokeArray[i]->m_s;
		if (strokeArray[i]->m_isPoint)
			continue;
		for (j = i; j < strokeSize /*&& (strokeArray[i]->getBBox().x1>= strokeArray[j]->getBBox().x0)*/; j++) {
			TStroke *s2 = strokeArray[j]->m_s;

			if (strokeArray[j]->m_isPoint || !(strokeArray[i]->m_isNewForFill || strokeArray[j]->m_isNewForFill))
				continue;
			if (strokeArray[i]->m_groupId != strokeArray[j]->m_groupId)
				continue;

			vector<DoublePair> parIntersections;
			if (s1->getBBox().overlaps(s2->getBBox())) {
				UINT size = intData.m_intList.size();

				if (intersect(s1, s2, parIntersections, false)) {
					//if (i==0 && j==1) parIntersections.erase(parIntersections.begin());
					intersectionMap[pair<int, int>(i, j)] = parIntersections;
					addIntersections(intData, strokeArray, i, j, parIntersections, strokeSize, isVectorized);
				} else
					intersectionMap[pair<int, int>(i, j)] = vector<DoublePair>();

				if (!strokeArray[i]->m_isNewForFill && size != intData.m_intList.size() && !strokeArray[i]->m_edgeList.empty()) //aggiunte nuove intersezioni
				{
					intData.m_intersectedStrokeArray.push_back(IntersectedStrokeEdges(i));
					list<TEdge *> &_list = intData.m_intersectedStrokeArray.back().m_edgeList;
					list<TEdge *>::const_iterator it;
					for (it = strokeArray[i]->m_edgeList.begin(); it != strokeArray[i]->m_edgeList.end(); ++it)
						_list.push_back(new TEdge(**it, false));
				}
			}
		}
	}

#ifdef AUTOCLOSE_ATTIVO
	TL2LAutocloser l2lautocloser;

	for (i = 0; i < strokeSize; i++) {
		TStroke *s1 = strokeArray[i]->m_s;
		if (strokeArray[i]->m_isPoint)
			continue;
		for (j = i; j < strokeSize; j++) {
			if (strokeArray[i]->m_groupId != strokeArray[j]->m_groupId)
				continue;

			TStroke *s2 = strokeArray[j]->m_s;
			if (strokeArray[j]->m_isPoint)
				continue;
			if (!(strokeArray[i]->m_isNewForFill || strokeArray[j]->m_isNewForFill))
				continue;

			double enlarge1 = (m_autocloseTolerance + 0.7) * (s1->getMaxThickness() > 0 ? s1->getMaxThickness() : 2.5);
			double enlarge2 = (m_autocloseTolerance + 0.7) * (s2->getMaxThickness() > 0 ? s2->getMaxThickness() : 2.5);

			if (s1->getBBox().enlarge(enlarge1).overlaps(s2->getBBox().enlarge(enlarge2))) {
				map<pair<int, int>, vector<DoublePair>>::iterator it = intersectionMap.find(pair<int, int>(i, j));
				if (it == intersectionMap.end())
					autoclose(m_autocloseTolerance, strokeArray, i, j, intData, strokeSize, l2lautocloser, 0, isVectorized);
				else
					autoclose(m_autocloseTolerance, strokeArray, i, j, intData, strokeSize, l2lautocloser, &(it->second), isVectorized);
			}
		}
		strokeArray[i]->m_isNewForFill = false;
	}
#endif

	for (i = 0; i < strokeSize; i++) {
		list<TEdge *>::iterator it, it_b = strokeArray[i]->m_edgeList.begin(), it_e = strokeArray[i]->m_edgeList.end();
		for (it = it_b; it != it_e; ++it)
			if ((*it)->m_toBeDeleted == 1)
				delete *it;

		strokeArray[i]->m_edgeList.clear();
	}

	//si devono cercare le intersezioni con i segmenti aggiunti per l'autoclose

	for (i = strokeSize; i < (int)strokeArray.size(); ++i) {
		TStroke *s1 = strokeArray[i]->m_s;

		for (j = i + 1; j < (int)strokeArray.size(); ++j) //intersezione segmento-segmento
		{
			if (strokeArray[i]->m_groupId != strokeArray[j]->m_groupId)
				continue;

			TStroke *s2 = strokeArray[j]->m_s;
			vector<DoublePair> parIntersections;
			if (intersect(s1, s2, parIntersections, true))
				addIntersections(intData, strokeArray, i, j, parIntersections, strokeSize, isVectorized);
		}
		for (j = 0; j < strokeSize; ++j) //intersezione segmento-curva
		{
			if (strokeArray[j]->m_isPoint)
				continue;
			if (strokeArray[i]->m_groupId != strokeArray[j]->m_groupId)
				continue;

			TStroke *s2 = strokeArray[j]->m_s;
			vector<DoublePair> parIntersections;
			if (intersect(s1, s2, parIntersections, true))
				addIntersections(intData, strokeArray, i, j, parIntersections, strokeSize, isVectorized);
		}
	}
}

//la struttura delle intersezioni viene poi visitata per trovare
// i link tra un'intersezione e la successiva

//-----------------------------------------------------------------------------
void TVectorImage::Imp::deleteRegionsData()
{
	clearPointerContainer(m_strokes);
	clearPointerContainer(m_regions);

	Intersection *p1;
	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		p1->m_strokeList.clear();
	m_intersectionData->m_intList.clear();
	delete m_intersectionData;
	m_intersectionData = 0;
}

void TVectorImage::Imp::initRegionsData()
{
	m_intersectionData = new IntersectionData();
}

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

int TVectorImage::Imp::computeIntersections()
{
	Intersection *p1;
	IntersectionData &intData = *m_intersectionData;
	int strokeSize = (int)m_strokes.size();

	findIntersections();

	findNearestIntersection(intData.m_intList);

	//for (it1=intData.m_intList.begin(); it1!=intData.m_intList.end();) //la faccio qui, e non nella eraseIntersection. vedi commento li'.
	eraseDeadIntersections();

	for (p1 = intData.m_intList.first(); p1; p1 = p1->next())
		markDeadIntersections(intData.m_intList, p1);

	//checkInterList(intData.m_intList);
	return strokeSize;
}

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

/*
void endPointIntersect(const TStroke* s0, const TStroke* s1, vector<DoublePair>& parIntersections)
{
TPointD p00 = s0->getPoint(0);
TPointD p11 = s1->getPoint(1);
if (tdistance2(p00, p11)< 2*0.06*0.06)
  parIntersections.push_back(DoublePair(0, 1));

if (s0==s1)
  return;

TPointD p01 = s0->getPoint(1);
TPointD p10 = s1->getPoint(0);

if (tdistance2(p00, p10)< 2*0.06*0.06)
  parIntersections.push_back(DoublePair(0, 0));
if (tdistance2(p01, p10)< 2*0.06*0.06)
  parIntersections.push_back(DoublePair(1, 0));
if (tdistance2(p01, p11)< 2*0.06*0.06)
  parIntersections.push_back(DoublePair(1, 1));

}
*/
//-----------------------------------------------------------------------------

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

// Trova una possibile regione data una lista di punti di intersezione
TRegion *findRegion(
	VIList<Intersection> &intList,
	Intersection *p1,
	IntersectedStroke *p2,
	bool minimizeEdges)
{
	TRegion *r = new TRegion();
	int currStyle = 0;

	IntersectedStroke *pStart = p2;
	Intersection *nextp1;
	IntersectedStroke *nextp2;

	//Cicla finche' t2 non punta ad uno stroke gia' visitato
	while (!p2->m_visited) {

		p2->m_visited = true;

		// Ciclo finche' lo stroke puntato da it2 non ha un successivo punto di intersezione
		do {
			p2 = p2->next();
			if (!p2) // uso la lista come se fosse circolare
				p2 = p1->m_strokeList.first();
			if (!p2) {
				delete r;
				return 0;
			}

		} while (!p2->m_nextIntersection);

		nextp1 = p2->m_nextIntersection;
		nextp2 = p2->m_nextStroke;

		// Viene controllato e sistemato lo stile degli stroke
		if (p2->m_edge.m_styleId != 0) {
			if (currStyle == 0)
				currStyle = p2->m_edge.m_styleId;
			else if (p2->m_edge.m_styleId != currStyle) {
				currStyle = p2->m_edge.m_styleId;
				for (UINT i = 0; i < r->getEdgeCount(); i++)
					r->getEdge(i)->m_styleId = currStyle;
			}
		} else
			p2->m_edge.m_styleId = currStyle;

		//Aggiunge lo stroke puntato da p2 alla regione
		r->addEdge(&p2->m_edge, minimizeEdges);

		if (nextp2 == pStart)
			return r;

		p1 = nextp1;
		p2 = nextp2;
	}

	delete r;
	return 0;
}

//-----------------------------------------------------------------------------
/*
bool areEqualRegions(const TRegion& r1, const TRegion& r2)
{
if (r1.getBBox()!=r2.getBBox())
  return false;
if (r1.getEdgeCount()!=r2.getEdgeCount())
  return false;

for (UINT i=0; i<r1.getEdgeCount(); i++)
  {
  TEdge *e1 = r1.getEdge(i);
  for (j=0; j<r2.getEdgeCount(); j++)
    {
    TEdge *e2 = r2.getEdge(j);
    if (e1->m_s==e2->m_s &&
        tmin(e1->m_w0, e1->m_w1)==tmin(e2->m_w0, e2->m_w1) &&
        tmax(e1->m_w0, e1->m_w1)==tmax(e2->m_w0, e2->m_w1))
      {
      if (e1->m_styleId && !e2->m_styleId)
        e2->m_styleId=e1->m_styleId;
      else if (e2->m_styleId && !e1->m_styleId)
        e1->m_styleId=e2->m_styleId;
      break;
      }
    }
  if (j==r2.getEdgeCount())  //e1 non e' uguale a nessun edge di r2
    return false;
  }


return true;
}
*/
//-----------------------------------------------------------------------------
/*
bool isMetaRegion(const TRegion& r1, const TRegion& r2)
{
if (areEqualRegions(r1, r2))
    return true;

for (UINT i=0; i<r1.getRegionCount(); i++)
  {
  if (isMetaRegion(*r1.getRegion(i), r2))
    return true;
  }
return false;
}

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

bool isMetaRegion(const vector<TRegion*>& m_regions, const TRegion& r)
{
for (UINT i=0; i<m_regions.size(); i++)
  if (isMetaRegion(*(m_regions[i]), r))
    return true;

return false;
}

//-----------------------------------------------------------------------------
*/

class TRegionClockWiseFormula : public TRegionFeatureFormula
{
private:
	double m_quasiArea;

public:
	TRegionClockWiseFormula() : m_quasiArea(0) {}

	void inline update(const TPointD &p1, const TPointD &p2)
	{
		m_quasiArea += (p2.y + p1.y) * (p1.x - p2.x);
	}

	bool inline isClockwise() { return m_quasiArea > 0.5; }
};

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

void computeRegionFeature(const TRegion &r, TRegionFeatureFormula &formula)
{
	TPointD p, pOld /*, pAux*/;
	int pointAdded = 0;

	int size = r.getEdgeCount();

	if (size == 0)
		return;

	//if (size<2)
	//  return !isMetaRegion(regions, r);

	int firstControlPoint;
	int lastControlPoint;

	TEdge *e = r.getEdge(size - 1);
	pOld = e->m_s->getPoint(e->m_w1);

	for (int i = 0; i < size; i++) {
		TEdge *e = r.getEdge(i);
		TStroke *s = e->m_s;
		firstControlPoint = s->getControlPointIndexAfterParameter(e->m_w0);
		lastControlPoint = s->getControlPointIndexAfterParameter(e->m_w1);

		p = s->getPoint(e->m_w0);
		formula.update(pOld, p);

		pOld = p;
		pointAdded++;
		if (firstControlPoint <= lastControlPoint) {
			if (firstControlPoint & 0x1)
				firstControlPoint++;
			if (lastControlPoint - firstControlPoint <= 2) ///per evitare di avere troppi pochi punti....
			{
				p = s->getPoint(0.333333 * e->m_w0 + 0.666666 * e->m_w1);
				formula.update(pOld, p);

				pOld = p;
				pointAdded++;
				p = s->getPoint(0.666666 * e->m_w0 + 0.333333 * e->m_w1);
				formula.update(pOld, p);

				pOld = p;
				pointAdded++;
			} else
				for (int j = firstControlPoint; j < lastControlPoint; j += 2) {
					p = s->getControlPoint(j);
					formula.update(pOld, p);
					pOld = p;
					pointAdded++;
				}
		} else {
			firstControlPoint--; //this case, getControlPointIndexBEFOREParameter
			lastControlPoint--;
			if (firstControlPoint & 0x1)
				firstControlPoint--;
			if (firstControlPoint - lastControlPoint <= 2) ///per evitare di avere troppi pochi punti....
			{
				p = s->getPoint(0.333333 * e->m_w0 + 0.666666 * e->m_w1);
				formula.update(pOld, p);
				pOld = p;
				pointAdded++;
				p = s->getPoint(0.666666 * e->m_w0 + 0.333333 * e->m_w1);
				formula.update(pOld, p);
				pOld = p;
				pointAdded++;
			} else
				for (int j = firstControlPoint; j > lastControlPoint; j -= 2) {
					p = s->getControlPoint(j);
					formula.update(pOld, p);
					pOld = p;
					pointAdded++;
				}
		}
		p = s->getPoint(e->m_w1);
		formula.update(pOld, p);
		pOld = p;
		pointAdded++;
	}
	assert(pointAdded >= 4);
}

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

bool isValidArea(const TRegion &r)
{
	TRegionClockWiseFormula formula;
	computeRegionFeature(r, formula);
	return formula.isClockwise();
}

#ifdef LEVO

bool isValidArea(const vector<TRegion *> &regions, const TRegion &r)
{
	double area = 0.0;
	TPointD p, pOld /*, pAux*/;
	int pointAdded = 0;

	int size = r.getEdgeCount();

	if (size == 0)
		return false;

	//if (size<2)
	//  return !isMetaRegion(regions, r);

	int firstControlPoint;
	int lastControlPoint;

	TEdge *e = r.getEdge(size - 1);
	pOld = e->m_s->getPoint(e->m_w1);

	for (int i = 0; i < size; i++) {
		TEdge *e = r.getEdge(i);
		TStroke *s = e->m_s;
		firstControlPoint = s->getControlPointIndexAfterParameter(e->m_w0);
		lastControlPoint = s->getControlPointIndexAfterParameter(e->m_w1);

		p = s->getPoint(e->m_w0);
		area += (p.y + pOld.y) * (pOld.x - p.x);
		pOld = p;
		pointAdded++;
		if (firstControlPoint <= lastControlPoint) {
			if (firstControlPoint & 0x1)
				firstControlPoint++;
			if (lastControlPoint - firstControlPoint <= 2) ///per evitare di avere troppi pochi punti....
			{
				p = s->getPoint(0.333333 * e->m_w0 + 0.666666 * e->m_w1);
				area += (p.y + pOld.y) * (pOld.x - p.x);
				pOld = p;
				pointAdded++;
				p = s->getPoint(0.666666 * e->m_w0 + 0.333333 * e->m_w1);
				area += (p.y + pOld.y) * (pOld.x - p.x);
				pOld = p;
				pointAdded++;
			} else
				for (int j = firstControlPoint; j < lastControlPoint; j += 2) {
					p = s->getControlPoint(j);
					area += (p.y + pOld.y) * (pOld.x - p.x);
					pOld = p;
					pointAdded++;
				}
		} else {
			firstControlPoint--; //this case, getControlPointIndexBEFOREParameter
			lastControlPoint--;
			if (firstControlPoint & 0x1)
				firstControlPoint--;
			if (firstControlPoint - lastControlPoint <= 2) ///per evitare di avere troppi pochi punti....
			{
				p = s->getPoint(0.333333 * e->m_w0 + 0.666666 * e->m_w1);
				area += (p.y + pOld.y) * (pOld.x - p.x);
				pOld = p;
				pointAdded++;
				p = s->getPoint(0.666666 * e->m_w0 + 0.333333 * e->m_w1);
				area += (p.y + pOld.y) * (pOld.x - p.x);
				pOld = p;
				pointAdded++;
			} else
				for (int j = firstControlPoint; j > lastControlPoint; j -= 2) {
					p = s->getControlPoint(j);
					area += (p.y + pOld.y) * (pOld.x - p.x);
					pOld = p;
					pointAdded++;
				}
		}
		p = s->getPoint(e->m_w1);
		area += (p.y + pOld.y) * (pOld.x - p.x);
		pOld = p;
		pointAdded++;
	}
	assert(pointAdded >= 4);

	return area > 0.5;
}

#endif

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

void transferColors(const list<TEdge *> &oldList, const list<TEdge *> &newList, bool isStrokeChanged, bool isFlipped, bool overwriteColor);

//-----------------------------------------------------------------------------
void printStrokes1(vector<VIStroke *> &v, int size)
{
	UINT i = 0;
	ofstream of("C:\\temp\\strokes.txt");

	for (i = 0; i < (UINT)size; i++) {
		TStroke *s = v[i]->m_s;
		of << "***stroke " << i << endl;
		for (UINT j = 0; j < (UINT)s->getChunkCount(); j++) {
			const TThickQuadratic *q = s->getChunk(j);

			of << "   s0 " << q->getP0() << endl;
			of << "   s1 " << q->getP1() << endl;
			of << "   s2 " << q->getP2() << endl;
			of << "****** " << endl;
		}
		of << endl;
	}
	for (i = size; i < v.size(); i++) {
		TStroke *s = v[i]->m_s;
		of << "***Autostroke " << i << endl;
		of << "s0 " << s->getPoint(0.0) << endl;
		of << "s1 " << s->getPoint(1.0) << endl;
		of << endl;
	}
}

//-----------------------------------------------------------------------------
#ifdef _DEBUG
static void printTime(TStopWatch &sw, string name)
{
	ostrstream ss;
	ss << name << " : ";
	sw.print(ss);
	ss << '\n' << '\0';
	string s = ss.str();
	ss.freeze(false);
	//TSystem::outputDebug(s);
}
#endif
//-----------------------------------------------------------------------------
void printStrokes1(vector<VIStroke *> &v, int size);

//void testHistory();

// Trova le regioni in una TVectorImage
int TVectorImage::Imp::computeRegions()
{
#ifdef NEW_REGION_FILL
	return 0;
#endif

#if defined(_DEBUG) && !defined(MACOSX)
	TStopWatch stopWatch;
	stopWatch.start(true);
#endif

	//testHistory();

	if (!m_computeRegions)
		return 0;

	QMutexLocker sl(m_mutex);

	/*if (m_intersectionData->m_computedAlmostOnce)
  {
  UINT i,n=m_strokes.size();
	vector<int> vv(n);
  for( i=0; i<n;++i) vv[i] = i;
  m_intersectionData->m_computedAlmostOnce = true;
  notifyChangedStrokes(vv,vector<TStroke*>(), false);
  
  return true;
  }*/

	//g_autocloseTolerance = m_autocloseTolerance;

	//Cancella le regioni gia' esistenti per ricalcolarle
	clearPointerContainer(m_regions);
	m_regions.clear();

	// Controlla che ci siano degli stroke
	if (m_strokes.empty()) {
#if defined(_DEBUG) && !defined(MACOSX)
		stopWatch.stop();
#endif
		return 0;
	}

	//Inizializza la lista di intersezioni intList
	m_computedAlmostOnce = true;
	VIList<Intersection> &intList = m_intersectionData->m_intList;
	cleanIntersectionMarks(intList);

	//calcolo struttura delle intersezioni
	int added = 0, notAdded = 0;
	int strokeSize;
	strokeSize = computeIntersections();

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = intList.first(); p1; p1 = p1->next())
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next())
			p2->m_edge.m_r = 0;

	for (p1 = intList.first(); p1; p1 = p1->next()) {
		// Controlla che il punto in questione non sia isolato
		if (p1->m_numInter == 0)
			continue;

		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next()) {
			TRegion *region;

			// se lo stroke non unisce due punti di intersezione
			// non lo considero e vado avanti con un altro stroke
			if (!p2->m_nextIntersection)
				continue;

			//Se lo stroke puntato da t2 non e' stato ancora visitato, trova una regione
			if (!p2->m_visited && (region = ::findRegion(intList, p1, p2, m_minimizeEdges))) {

				// Se la regione e' valida la aggiunge al vettore delle regioni
				if (isValidArea(*region)) {
					added++;

					addRegion(region);

					//Lega ogni ramo della regione alla regione di appartenenza
					for (UINT i = 0; i < region->getEdgeCount(); i++) {
						TEdge *e = region->getEdge(i);
						e->m_r = region;
						if (e->m_index >= 0)
							m_strokes[e->m_index]->addEdge(e);
					}
				} else // Se la regione non e' valida viene scartata
				{
					notAdded++;
					delete region;
				}
			}
		}
	}

	if (!m_notIntersectingStrokes) {
		UINT i;
		for (i = 0; i < m_intersectionData->m_intersectedStrokeArray.size(); i++) {
			if (!m_strokes[m_intersectionData->m_intersectedStrokeArray[i].m_index]->m_edgeList.empty())
				transferColors(m_intersectionData->m_intersectedStrokeArray[i].m_edgeList,
							   m_strokes[m_intersectionData->m_intersectedStrokeArray[i].m_index]->m_edgeList, false, false, true);
			clearPointerContainer(m_intersectionData->m_intersectedStrokeArray[i].m_edgeList);
			m_intersectionData->m_intersectedStrokeArray[i].m_edgeList.clear();
		}
		m_intersectionData->m_intersectedStrokeArray.clear();
	}

	assert(m_intersectionData->m_intersectedStrokeArray.empty());

	//tolgo i segmenti aggiunti con l'autoclose
	vector<VIStroke *>::iterator it = m_strokes.begin();
	advance(it, strokeSize);
	m_strokes.erase(it, m_strokes.end());

	m_areValidRegions = true;

#if defined(_DEBUG)
	checkRegions(m_regions);
#endif

	return 0;
}

//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
/*
class Branch
  {
	TEdge m_edge;
  bool m_out, m_visited;
	Branch *m_next;
	Branch *m_nextBranch;
	Intersection* m_intersection;

	public:
	  Branch* next()
		  {
			assert(m_intersection);
			return m_next?m_next:m_intersection->m_branchList;
			}
	}
	
	 
class Intersection
  {
	private: 
	TPointD m_intersectionPoint;
  int m_intersectionCount;
  Branch *m_branchList;
	Intersection* m_next;
  list<IntersectedStroke> m_strokeList;
	public:
  AddIntersection(int index0, int index1, DoublePair intersectionValues);

	}

*/

#ifdef _DEBUG

void TVectorImage::Imp::checkRegions(const vector<TRegion *> &regions)
{
	for (UINT i = 0; i < regions.size(); i++) {
		TRegion *r = regions[i];
		UINT j = 0;
		for (j = 0; j < r->getEdgeCount(); j++) {
			TEdge *e = r->getEdge(j);
			//assert(areSameGroup(e->m_index, false, ==m_strokes[r->getEdge(0)->m_index]->m_groupId);
			assert(e->m_r == r);
			//if (e->m_s->isSelfLoop())
			//  {
			//  assert(r->getEdgeCount()==1);
			//assert(r->getSubregionCount()==0);
			//  }
			//if (j>0)
			//  assert(!e->m_s->isSelfLoop());
		}
		if (r->getSubregionCount() > 0) {
			vector<TRegion *> aux(r->getSubregionCount());
			for (j = 0; j < r->getSubregionCount(); j++)
				aux[j] = r->getSubregion(j);
			checkRegions(aux);
		}
	}
}

#endif

namespace
{

inline TGroupId getGroupId(TRegion *r, const vector<VIStroke *> &strokes)
{
	for (UINT i = 0; i < r->getEdgeCount(); i++)
		if (r->getEdge(i)->m_index >= 0)
			return strokes[r->getEdge(i)->m_index]->m_groupId;
	return TGroupId();
}
}

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

TRegion *TVectorImage::findRegion(const TRegion &region) const
{
	TRegion *ret = 0;

	for (vector<TRegion *>::iterator it = m_imp->m_regions.begin(); it != m_imp->m_regions.end(); ++it)
		if ((ret = (*it)->findRegion(region)) != 0)
			return ret;

	return 0;
}

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

void TVectorImage::Imp::addRegion(TRegion *region)
{
	for (vector<TRegion *>::iterator it = m_regions.begin(); it != m_regions.end(); ++it) {
		if (getGroupId(region, m_strokes) != getGroupId(*it, m_strokes))
			continue;

		if (region->contains(**it)) {
			//region->addSubregion(*it);
			region->addSubregion(*it);
			it = m_regions.erase(it);
			while (it != m_regions.end()) {
				if (region->contains(**it)) {
					region->addSubregion(*it);
					//region->addSubregion(*it);
					it = m_regions.erase(it);
				} else
					it++;
			}

			m_regions.push_back(region);
			return;
		} else if ((*it)->contains(*region)) {
			(*it)->addSubregion(region);
			//(*it)->addSubregion(region);
			return;
		}
	}
	m_regions.push_back(region);
}

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

void TVectorImage::replaceStroke(int index, TStroke *newStroke)
{
	if ((int)m_imp->m_strokes.size() <= index)
		return;

	delete m_imp->m_strokes[index]->m_s;
	m_imp->m_strokes[index]->m_s = newStroke;

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_imp->m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next())
			if (p2->m_edge.m_index == index)
				p2->m_edge.m_s = newStroke;
}

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

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

void TVectorImage::Imp::moveStroke(int fromIndex, int moveBefore)
{
	assert((int)m_strokes.size() > fromIndex);
	assert((int)m_strokes.size() >= moveBefore);

#ifdef _DEBUG
	checkIntersections();
#endif

	VIStroke *vi = m_strokes[fromIndex];

	m_strokes.erase(m_strokes.begin() + fromIndex);

	vector<VIStroke *>::iterator it = m_strokes.begin();
	if (fromIndex < moveBefore)
		advance(it, moveBefore - 1);
	else
		advance(it, moveBefore);

	m_strokes.insert(it, vi);

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next()) {
			if (fromIndex < moveBefore) {
				if (p2->m_edge.m_index == fromIndex)
					p2->m_edge.m_index = moveBefore - 1;
				else if (p2->m_edge.m_index > fromIndex && p2->m_edge.m_index < moveBefore)
					p2->m_edge.m_index--;
			} else //(fromIndex>moveBefore)
			{
				if (p2->m_edge.m_index == fromIndex)
					p2->m_edge.m_index = moveBefore;
				else if (p2->m_edge.m_index >= moveBefore && p2->m_edge.m_index < fromIndex)
					p2->m_edge.m_index++;
			}
		}

#ifdef _DEBUG
	checkIntersections();
#endif
}

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

void TVectorImage::Imp::reindexEdges(UINT strokeIndex)
{
	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next()) {
			assert(p2->m_edge.m_index != (int)strokeIndex || p2->m_edge.m_index < 0);
			if (p2->m_edge.m_index > (int)strokeIndex)
				p2->m_edge.m_index--;
		}
}

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

void TVectorImage::Imp::reindexEdges(const vector<int> &indexes, bool areAdded)
{
	int i;
	int size = indexes.size();

	if (size == 0)
		return;

#ifdef _DEBUG
	for (i = 0; i < size; i++)
		assert(i == 0 || indexes[i - 1] < indexes[i]);
#endif

	int min = (int)indexes[0];

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = p1->m_strokeList.first(); p2; p2 = p2->next()) {
			if (areAdded) {
				if (p2->m_edge.m_index < min)
					continue;
				else
					for (i = size - 1; i >= 0; i--)
						if (p2->m_edge.m_index >= (int)indexes[i] - i) {
							p2->m_edge.m_index += i + 1;
							break;
						}
			} else {
				if (p2->m_edge.m_index < min)
					continue;
				else
					for (i = size - 1; i >= 0; i--)
						if (p2->m_edge.m_index > (int)indexes[i]) {
							p2->m_edge.m_index -= i + 1;
							break;
						}
			}
			//assert(it2->m_edge.m_index!=1369);
		}
}

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

void TVectorImage::Imp::insertStrokeAt(VIStroke *vs, int strokeIndex, bool recomputeRegions)
{
	list<TEdge *> oldEdgeList, emptyList;

	if (m_computedAlmostOnce && recomputeRegions) {
		oldEdgeList = vs->m_edgeList;
		vs->m_edgeList.clear();
	}

	assert(strokeIndex >= 0 && strokeIndex <= (int)m_strokes.size());

	vector<VIStroke *>::iterator it = m_strokes.begin();
	advance(it, strokeIndex);

	vs->m_isNewForFill = true;
	m_strokes.insert(it, vs);

	if (!m_computedAlmostOnce)
		return;

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next())
			if (p2->m_edge.m_index >= (int)strokeIndex)
				p2->m_edge.m_index++;

	if (!recomputeRegions)
		return;

	computeRegions();
	transferColors(oldEdgeList, m_strokes[strokeIndex]->m_edgeList, true, false, true);

	/*
#ifdef _DEBUG
checkIntersections();
#endif
*/
}

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

void invalidateRegionPropAndBBox(TRegion *reg)
{
	for (UINT regId = 0; regId != reg->getSubregionCount(); regId++) {
		invalidateRegionPropAndBBox(reg->getSubregion(regId));
	}
	reg->invalidateProp();
	reg->invalidateBBox();
}

void TVectorImage::transform(const TAffine &aff, bool doChangeThickness)
{
	UINT i;
	for (i = 0; i < m_imp->m_strokes.size(); ++i)
		m_imp->m_strokes[i]->m_s->transform(aff, doChangeThickness);

	map<int, VIStroke *>::iterator it = m_imp->m_intersectionData->m_autocloseMap.begin();
	for (; it != m_imp->m_intersectionData->m_autocloseMap.end(); ++it)
		it->second->m_s->transform(aff, false);

	for (i = 0; i < m_imp->m_regions.size(); ++i)
		invalidateRegionPropAndBBox(m_imp->m_regions[i]);
}

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

#ifdef _DEBUG
#include "tvectorrenderdata.h"
#include "tgl.h"
void TVectorImage::drawAutocloses(const TVectorRenderData &rd) const
{
	float width;

	glPushMatrix();
	tglMultMatrix(rd.m_aff);

	glGetFloatv(GL_LINE_WIDTH, &width);
	tglColor(TPixel(0, 255, 0, 255));
	glLineWidth(1.5);
	glBegin(GL_LINES);

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_imp->m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next()) {
			if (p2->m_edge.m_index < 0 && p2->m_edge.m_w0 == 0.0) {
				TStroke *s = p2->m_edge.m_s;
				TPointD p0 = s->getPoint(0.0);
				TPointD p1 = s->getPoint(1.0);

				glVertex2d(p0.x, p0.y);
				glVertex2d(p1.x, p1.y);
			}
		}
	glEnd();
	glLineWidth(width);

	glPopMatrix();
}

#endif

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

void TVectorImage::reassignStyles(map<int, int> &table)
{
	UINT i;
	UINT strokeCount = getStrokeCount();
	//UINT regionCount = getRegionCount();
	for (i = 0; i < strokeCount; ++i) {
		TStroke *stroke = getStroke(i);
		int styleId = stroke->getStyle();
		if (styleId != 0) {
			map<int, int>::iterator it = table.find(styleId);
			if (it != table.end())
				stroke->setStyle(it->second);
		}
	}

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_imp->m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next())
			if (p2->m_edge.m_styleId != 0) {
				map<int, int>::iterator it = table.find(p2->m_edge.m_styleId);
				if (it != table.end())
					p2->m_edge.m_styleId = it->second;
				//assert(it->second<100);
			}
}

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

struct TDeleteMapFunctor {
	void operator()(pair<int, VIStroke *> ptr)
	{
		delete ptr.second;
	}
};

IntersectionData::~IntersectionData()
{
	std::for_each(m_autocloseMap.begin(), m_autocloseMap.end(), TDeleteMapFunctor());
}
//-----------------------------------------------------------------------------

#ifdef _DEBUG
void TVectorImage::Imp::checkIntersections()
{
	//return;
	UINT i, j;

	Intersection *p1;
	IntersectedStroke *p2;

	for (i = 0, p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next(), i++)
		for (j = 0, p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next(), j++) {
			IntersectedStroke &is = *p2;
			assert(is.m_edge.m_styleId >= 0 && is.m_edge.m_styleId <= 1000);
			assert(is.m_edge.m_w0 >= 0 && is.m_edge.m_w0 <= 1);
			assert(is.m_edge.m_index < (int)m_strokes.size());
			if (is.m_edge.m_index >= 0) {

				assert(is.m_edge.m_s->getChunkCount() >= 0 && is.m_edge.m_s->getChunkCount() <= 10000);
				assert(m_strokes[is.m_edge.m_index]->m_s == is.m_edge.m_s);
			} else
				assert(m_intersectionData->m_autocloseMap[is.m_edge.m_index]);

			if (p2->m_nextIntersection) {
				IntersectedStroke *nextStroke = p2->m_nextStroke;
				assert(nextStroke->m_nextIntersection == p1);
				assert(nextStroke->m_nextStroke == p2);
			}
		}

	for (i = 0; i < m_strokes.size(); i++) {
		VIStroke *vs = m_strokes[i];
		list<TEdge *>::const_iterator it = vs->m_edgeList.begin(), it_e = vs->m_edgeList.end();
		for (; it != it_e; ++it) {
			TEdge *e = *it;
			assert(e->getStyle() >= 0 && e->getStyle() <= 1000);
			assert(e->m_w0 >= 0 && e->m_w1 <= 1);
			assert(e->m_s == vs->m_s);
			assert(e->m_s->getChunkCount() >= 0 && e->m_s->getChunkCount() <= 10000);
			//assert(e->m_index<(int)m_strokes.size());   l'indice nella stroke potrebbe essere non valido, non importa.
			//assert(m_strokes[e->m_index]->m_s==e->m_s); deve essere buono nella intersectionData
		}
	}

	for (i = 0; i < m_regions.size(); i++) {
		m_regions[i]->checkRegion();
	}
}

#endif
//-----------------------------------------------------------------------------

TStroke *TVectorImage::Imp::removeEndpoints(int strokeIndex)
{
#ifdef _DEBUG
	checkIntersections();
#endif

	VIStroke *vs = m_strokes[strokeIndex];

	if (vs->m_s->isSelfLoop())
		return 0;
	if (vs->m_edgeList.empty())
		return 0;

	list<TEdge *>::iterator it = vs->m_edgeList.begin();

	double minW = 1.0;
	double maxW = 0.0;
	for (; it != vs->m_edgeList.end(); ++it) {
		minW = tmin(minW - 0.00002, (*it)->m_w0, (*it)->m_w1);
		maxW = tmax(maxW + 0.00002, (*it)->m_w0, (*it)->m_w1);
	}

	if (areAlmostEqual(minW, 0.0, 0.001) && areAlmostEqual(maxW, 1.0, 0.001))
		return 0;

	TStroke *oldS = vs->m_s;

	TStroke *s = new TStroke(*(vs->m_s));

	double offs = s->getLength(minW);

	TStroke s0, s1, final;

	if (!areAlmostEqual(maxW, 1.0, 0.001)) {
		s->split(maxW, s0, s1);
	} else
		s0 = *s;

	if (!areAlmostEqual(minW, 0.0, 0.001)) {
		double newW = (maxW == 1.0) ? minW : s0.getParameterAtLength(offs);
		s0.split(newW, s1, final);
	} else
		final = s0;

	vs->m_s = new TStroke(final);
	vs->m_s->setStyle(oldS->getStyle());

	for (it = vs->m_edgeList.begin(); it != vs->m_edgeList.end(); ++it) {
		(*it)->m_w0 = vs->m_s->getParameterAtLength(s->getLength((*it)->m_w0) - offs);
		(*it)->m_w1 = vs->m_s->getParameterAtLength(s->getLength((*it)->m_w1) - offs);
		(*it)->m_s = vs->m_s;
	}

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next()) {
			if (p2->m_edge.m_s == oldS) {
				p2->m_edge.m_w0 = vs->m_s->getParameterAtLength(s->getLength(p2->m_edge.m_w0) - offs);
				p2->m_edge.m_w1 = vs->m_s->getParameterAtLength(s->getLength(p2->m_edge.m_w1) - offs);
				p2->m_edge.m_s = vs->m_s;
			}
		}

#ifdef _DEBUG
	checkIntersections();
#endif

	return oldS;
}

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

void TVectorImage::Imp::restoreEndpoints(int index, TStroke *oldStroke)
{
#ifdef _DEBUG
	checkIntersections();
#endif

	VIStroke *vs = m_strokes[index];

	TStroke *s = vs->m_s;
	TPointD p = s->getPoint(0.0);

	double offs = oldStroke->getLength(oldStroke->getW(p));

	vs->m_s = oldStroke;

	list<TEdge *>::iterator it = vs->m_edgeList.begin();
	for (; it != vs->m_edgeList.end(); ++it) {
		(*it)->m_w0 = vs->m_s->getParameterAtLength(s->getLength((*it)->m_w0) + offs);
		(*it)->m_w1 = vs->m_s->getParameterAtLength(s->getLength((*it)->m_w1) + offs);
		(*it)->m_s = vs->m_s;
	}

	Intersection *p1;
	IntersectedStroke *p2;

	for (p1 = m_intersectionData->m_intList.first(); p1; p1 = p1->next())
		for (p2 = (*p1).m_strokeList.first(); p2; p2 = p2->next()) {
			if (p2->m_edge.m_s == s) {
				p2->m_edge.m_w0 = vs->m_s->getParameterAtLength(s->getLength(p2->m_edge.m_w0) + offs);
				p2->m_edge.m_w1 = vs->m_s->getParameterAtLength(s->getLength(p2->m_edge.m_w1) + offs);
				p2->m_edge.m_s = vs->m_s;
			}
		}

	delete s;

#ifdef _DEBUG
	checkIntersections();
#endif
}