mirror of
https://github.com/jkriege2/JKQtPlotter.git
synced 2024-11-16 10:35:49 +08:00
404 lines
15 KiB
C++
404 lines
15 KiB
C++
/*
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Copyright (c) 2008-2022 Jan W. Krieger (<jan@jkrieger.de>)
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This software is free software: you can redistribute it and/or modify
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it under the terms of the GNU Lesser General Public License (LGPL) as published by
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the Free Software Foundation, either version 2.1 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU Lesser General Public License (LGPL) for more details.
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You should have received a copy of the GNU Lesser General Public License (LGPL)
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "jkqtcommon/jkqtpgeometrytools.h"
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#include <QDebug>
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#include <algorithm>
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#include <QTransform>
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QPolygonF jkqtpRotateRect(QRectF r, double angle) {
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QPolygonF p;
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QTransform m;
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m.rotate(angle);
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p.append(m.map(r.bottomLeft()));
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p.append(m.map(r.bottomRight()));
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p.append(m.map(r.topRight()));
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p.append(m.map(r.topLeft()));
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return p;
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}
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QVector<QPointF> JKQTPSplitEllipseIntoPoints(double x, double y, double a, double b, double angle_start, double angle_end, double alpha, int controlPoints, QPointF* x_start, QPointF* x_end) {
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QVector<QPointF> result;
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const double start=angle_start*JKQTPSTATISTICS_PI/180.0;
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const double stop=angle_end*JKQTPSTATISTICS_PI/180.0;
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double step=(stop-start)/static_cast<double>(controlPoints);
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while (fabs(stop-start)/step<10) step=step/2.0;
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const double sina=sin(1.0*alpha/180.0*JKQTPSTATISTICS_PI);
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const double cosa=cos(1.0*alpha/180.0*JKQTPSTATISTICS_PI);
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QPointF xp(x+a*cos(start)*cosa-b*sin(start)*sina, y+a*cos(start)*sina+b*sin(start)*cosa);
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result.append(xp);
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if (x_start) *x_start = xp;
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double t=start+step;
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for (int i=1; i<controlPoints; i++) {
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double cost=cos(t);
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double sint=sin(t);
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xp=QPointF( x+a*cost*cosa-b*sint*sina, y+a*cost*sina+b*sint*cosa);
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result.append(xp);
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//std::cout<<"t="<<t/JKQTPSTATISTICS_PI*180.0<<": sin(al)="<<sina<<" cos(al)="<<cosa<<" sin(t)="<<sint<<" cos(t)="<<cost<<" a="<<a<<" b="<<b<<": ("<<x+a*cost*cosa-b*sint*sina<<", "<<y+a*cost*sina+b*sint*cosa<<") = ("<<xp.x()<<", "<<xp.y()<<") \n";
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t=t+step;
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}
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if (x_end) *x_end=xp;
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return result;
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}
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QVector<QPointF> JKQTPSplitEllipseIntoPoints(std::function<QPointF (QPointF)> fTransform, double x, double y, double a, double b, double angle_start, double angle_end, double alpha, QPointF *x_start, QPointF *x_end, QPointF *x_start_notrafo, QPointF *x_end_notrafo)
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{
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const double sina=sin(1.0*alpha/180.0*JKQTPSTATISTICS_PI);
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const double cosa=cos(1.0*alpha/180.0*JKQTPSTATISTICS_PI);
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std::function<QPointF(double)> fell=[&](double t)->QPointF {
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return QPointF(x+a*cos(t)*cosa-b*sin(t)*sina, y+a*cos(t)*sina+b*sin(t)*cosa);
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};
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std::function<QPointF(double)> fxy = [&](double t) ->QPointF {
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return fTransform(fell(t));
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};
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JKQTPAdaptiveFunctionGraphEvaluator eval(fxy);
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const QVector<QPointF> points=eval.evaluate(angle_start*JKQTPSTATISTICS_PI/180.0, angle_end*JKQTPSTATISTICS_PI/180.0);
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if (points.size()>0) {
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if (x_start) *x_start=points.first();
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if (x_end) *x_end=points.last();
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if (x_start_notrafo) *x_start_notrafo=fell(angle_start*JKQTPSTATISTICS_PI/180.0);
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if (x_end_notrafo) *x_end_notrafo=fell(angle_end*JKQTPSTATISTICS_PI/180.0);
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}
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return points;
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}
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QVector<QPolygonF> JKQTPUnifyLinesToPolygons(const QVector<QLineF> &lines, double distanceThreshold, int searchMaxSurroundingElements)
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{
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#ifdef JKQTBP_AUTOTIMER
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JKQTPAutoOutputTimer jkaat(QString("JKQTPUnifyLinesToPolygons(%1, %2, %3)").arg(lines.size()).arg(distanceThreshold).arg(searchMaxSurroundingElements));
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#endif
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QList<QPolygonF> res;
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res.reserve(lines.size());
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// first simply convert all lines to polygons
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for (const QLineF& l: lines) {
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QPolygonF p;
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p<<l.p1()<<l.p2();
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res<<p;
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}
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//return res.toVector();
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// clean the resulting polygon
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std::transform(res.begin(), res.end(), res.begin(), std::bind(&JKQTPCleanPolygon, std::placeholders::_1, distanceThreshold));
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int maxIterations=100;
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int iter=0;
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bool found=true;
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//qDebug()<<" iter "<<-1<<" -> polygons start "<<res.size();
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while (found && iter<maxIterations) {
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found=false;
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int i=0;
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while (i<res.size()-1) {
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int j=i+1;
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while (j<res.size() && j<i+searchMaxSurroundingElements) {
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if (jkqtp_distance(res[i].first(),res[j].first())<=distanceThreshold) {
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found=true;
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for (int k=1; k<res[j].size(); k++) {
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res[i].prepend(res[j].at(k));
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}
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res.removeAt(j);
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} else if (jkqtp_distance(res[i].first(),res[j].last())<=distanceThreshold) {
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found=true;
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for (int k=res[j].size()-2; k>=0; k--) {
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res[i].prepend(res[j].at(k));
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}
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res.removeAt(j);
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} else if (jkqtp_distance(res[i].last(),res[j].first())<=distanceThreshold) {
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found=true;
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for (int k=1; k<res[j].size(); k++) {
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res[i].append(res[j].at(k));
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}
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res.removeAt(j);
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} else if (jkqtp_distance(res[i].last(),res[j].last())<=distanceThreshold) {
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found=true;
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for (int k=res[j].size()-2; k>=0; k--) {
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res[i].append(res[j].at(k));
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}
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res.removeAt(j);
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} else {
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j++;
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}
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}
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res[i]=JKQTPCleanPolygon(res[i], distanceThreshold);
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i++;
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}
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//qDebug()<<" iter "<<iter<<" -> polygons left "<<res.size();
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iter++;
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}
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return res.toVector();
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}
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QPolygonF JKQTPCleanPolygon(const QPolygonF &poly, double distanceThreshold)
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{
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if (poly.size()<=2) return poly;
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QPolygonF p;
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QPointF p0=poly[0];
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p<<p0;
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QVector<QPointF> inbetween;
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int i=1;
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while (i<poly.size()) {
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if ((jkqtp_distance(poly[i], p0)<=distanceThreshold)) {
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inbetween<<poly[i];
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} else {
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QPointF pmean(0,0);
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if (inbetween.size()>0) {
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for (const QPointF& pi: inbetween) {
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pmean=QPointF(pmean.x()+pi.x()/static_cast<double>(inbetween.size()), pmean.y()+pi.y()/static_cast<double>(inbetween.size()));
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}
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} else {
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pmean=poly[i];
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}
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p<<pmean;
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p0=pmean;
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inbetween.clear();
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}
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i++;
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}
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// maybe we have something left to add
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QPointF pmean(0,0);
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if (inbetween.size()>0) {
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for (const QPointF& pi: inbetween) {
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pmean=QPointF(pmean.x()+pi.x()/static_cast<double>(inbetween.size()), pmean.y()+pi.y()/static_cast<double>(inbetween.size()));
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}
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} else {
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pmean=p0;
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}
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if (jkqtp_distance(pmean, poly.last())>distanceThreshold) {
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p<<pmean<<poly.last();
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} else {
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if (p.last()!=poly.last()) p<<poly.last();
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}
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return p;
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}
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QVector<QPointF> JKQTPSplitLineIntoPoints(const QLineF &line, int controlPoints)
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{
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QVector<QPointF> result;
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result.reserve(controlPoints);
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result.push_back(line.p1());
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for (int i=1; i<controlPoints; i++) {
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result.push_back(line.p1()+static_cast<double>(i)/static_cast<double>(controlPoints)*(line.p2()-line.p1()));
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}
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result.push_back(line.p2());
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return result;
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}
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QVector<QPointF> JKQTPSimplyfyLineSegemnts(const QVector<QPointF> &points, double maxConsecutiveAngleDegree)
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{
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QVector<QPointF> result;
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if (points.size()>2) {
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result.push_back(points[0]);
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for (int i=1; i<points.size()-1; i++) {
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const QLineF l1(result.last(), points[i]);
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const QLineF l2(points[i], points[i+1]);
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if (fabs(l1.angle()-l2.angle())>maxConsecutiveAngleDegree && l1.length()>0 ) {
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result.push_back(points[i]);
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}
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}
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if (result.last()!=points.last()) result.push_back(points.last());
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return result;
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} else {
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return points;
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}
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}
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JKQTPAdaptiveFunctionGraphEvaluator::JKQTPAdaptiveFunctionGraphEvaluator(const std::function<double (double)> &fx_, const std::function<double (double)> &fy_, unsigned int minSamples_, unsigned int maxRefinementDegree_, double slopeTolerance_, double minPixelPerSample_):
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fx(fx_),
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fy(fy_),
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fxy([&](double t)->QPointF { return QPointF(fx(t), fy(t)); }),
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minSamples(minSamples_),
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maxRefinementDegree(maxRefinementDegree_),
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slopeTolerance(slopeTolerance_),
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minPixelPerSample(minPixelPerSample_)
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{
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}
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JKQTPAdaptiveFunctionGraphEvaluator::JKQTPAdaptiveFunctionGraphEvaluator(const std::function<QPointF (double)> &fxy_, unsigned int minSamples_, unsigned int maxRefinementDegree_, double slopeTolerance_, double minPixelPerSample_):
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fxy(fxy_),
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minSamples(minSamples_),
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maxRefinementDegree(maxRefinementDegree_),
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slopeTolerance(slopeTolerance_),
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minPixelPerSample(minPixelPerSample_)
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{
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}
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QVector<QPointF> JKQTPAdaptiveFunctionGraphEvaluator::evaluate(double tmin, double tmax) const
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{
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InternalList intData;
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double delta_t0=(tmax-tmin)/static_cast<double>(minSamples);
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intData.push_front(std::pair<double, QPointF>(tmin, fxy(tmin)));
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InternalList::iterator a=intData.begin();
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//qDebug()<<"**************************************************";
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for (double t=tmin+delta_t0; t<tmax; t=t+delta_t0) {
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const double treal=t;
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intData.insert_after(a, std::pair<double, QPointF>(treal, fxy(treal)));
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InternalList::iterator b=a; ++b;
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//qDebug()<<"t="<<t<<", dist(a,b)="<<std::distance(a,b);
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refine(intData, a, b, 0);
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//qDebug()<<" after refine: dist(a,b)="<<std::distance(a,b);
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a=b;
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}
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intData.insert_after(a, std::pair<double, QPointF>(tmax, fxy(tmax)));
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auto b=a; b++;
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refine(intData, a, b, 0);
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// copy data to output data structure
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QVector<QPointF> result;
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result.reserve(std::distance(intData.begin(), intData.end()));
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for (const auto& d: intData) {
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result.push_back(d.second);
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}
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return result;
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}
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void JKQTPAdaptiveFunctionGraphEvaluator::refine(JKQTPAdaptiveFunctionGraphEvaluator::InternalList &intData, JKQTPAdaptiveFunctionGraphEvaluator::InternalList::iterator a, JKQTPAdaptiveFunctionGraphEvaluator::InternalList::iterator b, unsigned int degree) const
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{
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if (degree>=maxRefinementDegree) return;
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const double ta=a->first;
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const double tb=b->first;
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const double tmid=ta+(tb-ta)*(0.5 +(static_cast<double>(rand())/static_cast<double>(RAND_MAX)-0.5)/5.0);
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const QPointF pa=a->second;
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const QPointF pb=b->second;
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const QPointF pmid(fxy(tmid));
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const double delta=QLineF(pa, pb).length();
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const double slope_a_mid=(pmid.y()-pa.y())/(pmid.x()-pa.x());
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const double slope_mid_b=(pb.y()-pmid.y())/(pb.x()-pmid.x());
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if (fabs(slope_mid_b-slope_a_mid)>slopeTolerance || delta>minPixelPerSample) {
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intData.insert_after(a, std::pair<double, QPointF>(tmid, pmid));
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InternalList::iterator abmid=a; ++abmid;
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refine(intData, a, abmid, degree+1);
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refine(intData, abmid, b, degree+1);
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}
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}
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QVector<QPointF> JKQTPSplitLineIntoPoints(const QLineF &line, std::function<QPointF (QPointF)> fTransform)
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{
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std::function<QPointF(double)> fxy = [&line, &fTransform] (double t) ->QPointF {
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return fTransform(line.p1()+t*(line.p2()-line.p1()));
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};
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JKQTPAdaptiveFunctionGraphEvaluator eval(fxy);
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return eval.evaluate(0.0,1.0);
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}
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QVector<QPointF> JKQTPSplitPolylineIntoPoints(const QVector<QPointF> &line, std::function<QPointF (QPointF)> fTransform)
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{
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QVector<QPointF> result;
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if (line.size()==2) return JKQTPSplitLineIntoPoints(QLineF(line[0], line[1]), fTransform);
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if (line.size()>2) {
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for (int i=1; i<line.size(); i++) {
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const QVector<QPointF> ps=JKQTPSplitLineIntoPoints(QLineF(line[i-1], line[i]), fTransform);
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result.reserve(result.size()+ps.size());
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std::copy_if(ps.begin(), ps.end(), std::back_inserter(result), [&](const QPointF&p) { return result.size()==0 || result.last()!=p; });
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//qDebug()<<"line: "<<QLineF(line[i-1], line[i])<<" --> ps.size()="<<ps.size()<<", result.size()="<<result.size();
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}
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}
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return result;
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}
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bool JKQTPClipLine(QLineF &line, const QRectF &clippingRect)
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{
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//qDebug()<<"line="<<line<<", clippingRect="<<clippingRect;
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const qreal p1 = -(line.x2() - line.x1());
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const qreal p2 = -p1;
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const qreal p3 = -(line.y2() - line.y1());
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const qreal p4 = -p3;
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const qreal q1 = line.x1() - std::min(clippingRect.left(),clippingRect.right());
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const qreal q2 = std::max(clippingRect.left(),clippingRect.right()) - line.x1();
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const qreal q3 = line.y1() - std::min(clippingRect.bottom(),clippingRect.top());
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const qreal q4 = std::max(clippingRect.bottom(),clippingRect.top()) - line.y1();
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//qDebug()<<" p1="<<p1<<", p2="<<p2<<", p3="<<p3<<", p4="<<p4;
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//qDebug()<<" q1="<<q1<<", q2="<<q2<<", q3="<<p3<<", q4="<<p4;
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std::vector<qreal> posarr, negarr;
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posarr.reserve(5); negarr.reserve(5);
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posarr.push_back(1);
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negarr.push_back(0);
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if ((p1 == 0 && q1 < 0) || (p2 == 0 && q2 < 0) || (p3 == 0 && q3 < 0) || (p4 == 0 && q4 < 0)) {
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//qDebug()<<" --> parallel line";
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line=QLineF();
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return false;
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}
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if (p1 != 0) {
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const qreal r1 = q1 / p1;
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const qreal r2 = q2 / p2;
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if (p1 < 0) {
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negarr.push_back(r1); // for negative p1, add it to negative array
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posarr.push_back(r2); // and add p2 to positive array
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} else {
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negarr.push_back(r2);
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posarr.push_back(r1);
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}
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}
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if (p3 != 0) {
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const qreal r3 = q3 / p3;
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const qreal r4 = q4 / p4;
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if (p3 < 0) {
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negarr.push_back(r3);
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posarr.push_back(r4);
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} else {
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negarr.push_back(r4);
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posarr.push_back(r3);
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}
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}
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const qreal rn1 = *std::max_element(negarr.begin(), negarr.end()); // maximum of negative array
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const qreal rn2 = *std::min_element(posarr.begin(), posarr.end()); // minimum of positive array
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//qDebug()<<" rn1="<<rn1<<", rn2="<<rn2<<" negarr="<<negarr<<", posarr="<<posarr;
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if (rn1 > rn2) { // reject
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//qDebug()<<" --> rejected line";
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line=QLineF();
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return false;
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}
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const qreal xn1 = line.x1() + p2 * rn1;
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const qreal yn1 = line.y1() + p4 * rn1; // computing new points
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const qreal xn2 = line.x1() + p2 * rn2;
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const qreal yn2 = line.y1() + p4 * rn2;
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line=QLineF(xn1, yn1, xn2, yn2); // the drawing the new line
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//qDebug()<<" --> clipped line: "<<line;
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return true;
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}
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