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Diffstat (limited to 'src/livarot/PathCutting.cpp')
| -rw-r--r-- | src/livarot/PathCutting.cpp | 1539 |
1 files changed, 1539 insertions, 0 deletions
diff --git a/src/livarot/PathCutting.cpp b/src/livarot/PathCutting.cpp new file mode 100644 index 0000000..0b170bd --- /dev/null +++ b/src/livarot/PathCutting.cpp @@ -0,0 +1,1539 @@ +// SPDX-License-Identifier: GPL-2.0-or-later +/* + * PathCutting.cpp + * nlivarot + * + * Created by fred on someday in 2004. + * public domain + * + * Additional Code by Authors: + * Richard Hughes <cyreve@users.sf.net> + * + * Copyright (C) 2005 Richard Hughes + * + * Released under GNU GPL v2+, read the file 'COPYING' for more information. + */ + +#include <cstring> +#include <string> +#include <cstdio> +#include <typeinfo> +#include "Path.h" +#include "style.h" +#include "livarot/path-description.h" +#include <2geom/pathvector.h> +#include <2geom/point.h> +#include <2geom/affine.h> +#include <2geom/sbasis-to-bezier.h> +#include <2geom/curves.h> +#include "helper/geom-curves.h" +#include "helper/geom.h" + +#include "svg/svg.h" + +void Path::DashPolyline(float head,float tail,float body,int nbD,float *dashs,bool stPlain,float stOffset) +{ + if ( nbD <= 0 || body <= 0.0001 ) return; // pas de tirets, en fait + + std::vector<path_lineto> orig_pts = pts; + pts.clear(); + + int lastMI=-1; + int curP = 0; + int lastMP = -1; + + for (int i = 0; i < int(orig_pts.size()); i++) { + if ( orig_pts[curP].isMoveTo == polyline_moveto ) { + if ( lastMI >= 0 && lastMI < i-1 ) { // au moins 2 points + DashSubPath(i-lastMI,lastMP, orig_pts, head,tail,body,nbD,dashs,stPlain,stOffset); + } + lastMI=i; + lastMP=curP; + } + curP++; + } + if ( lastMI >= 0 && lastMI < int(orig_pts.size()) - 1 ) { + DashSubPath(orig_pts.size() - lastMI, lastMP, orig_pts, head, tail, body, nbD, dashs, stPlain, stOffset); + } +} + +void Path::DashPolylineFromStyle(SPStyle *style, float scale, float min_len) +{ + if (!style->stroke_dasharray.values.empty()) { + + double dlen = 0.0; + // Find total length + for (auto & value : style->stroke_dasharray.values) { + dlen += value.value * scale; + } + if (dlen >= min_len) { + // Extract out dash pattern (relative positions) + double dash_offset = style->stroke_dashoffset.value * scale; + size_t n_dash = style->stroke_dasharray.values.size(); + double *dash = g_new(double, n_dash); + for (unsigned i = 0; i < n_dash; i++) { + dash[i] = style->stroke_dasharray.values[i].value * scale; + } + + // Convert relative positions to absolute positions + int nbD = n_dash; + float *dashs=(float*)malloc((nbD+1)*sizeof(float)); + while ( dash_offset >= dlen ) dash_offset-=dlen; + dashs[0]=dash[0]; + for (int i=1; i<nbD; i++) { + dashs[i]=dashs[i-1]+dash[i]; + } + + // modulo dlen + this->DashPolyline(0.0, 0.0, dlen, nbD, dashs, true, dash_offset); + + free(dashs); + g_free(dash); + } + } +} + + +void Path::DashSubPath(int spL, int spP, std::vector<path_lineto> const &orig_pts, float head,float tail,float body,int nbD,float *dashs,bool stPlain,float stOffset) +{ + if ( spL <= 0 || spP == -1 ) return; + + double totLength=0; + Geom::Point lastP; + lastP = orig_pts[spP].p; + for (int i=1;i<spL;i++) { + Geom::Point const n = orig_pts[spP + i].p; + Geom::Point d=n-lastP; + double nl=Geom::L2(d); + if ( nl > 0.0001 ) { + totLength+=nl; + lastP=n; + } + } + + if ( totLength <= head+tail ) return; // tout mange par la tete et la queue + + double curLength=0; + double dashPos=0; + int dashInd=0; + bool dashPlain=false; + double lastT=0; + int lastPiece=-1; + lastP = orig_pts[spP].p; + for (int i=1;i<spL;i++) { + Geom::Point n; + int nPiece=-1; + double nT=0; + if ( back ) { + n = orig_pts[spP + i].p; + nPiece = orig_pts[spP + i].piece; + nT = orig_pts[spP + i].t; + } else { + n = orig_pts[spP + i].p; + } + Geom::Point d=n-lastP; + double nl=Geom::L2(d); + if ( nl > 0.0001 ) { + double stLength=curLength; + double enLength=curLength+nl; + // couper les bouts en trop + if ( curLength <= head && curLength+nl > head ) { + nl-=head-curLength; + curLength=head; + dashInd=0; + dashPos=stOffset; + bool nPlain=stPlain; + while ( dashs[dashInd] < stOffset ) { + dashInd++; + nPlain=!(nPlain); + if ( dashInd >= nbD ) { + dashPos=0; + dashInd=0; + break; + } + } + if ( nPlain == true && dashPlain == false ) { + Geom::Point p=(enLength-curLength)*lastP+(curLength-stLength)*n; + p/=(enLength-stLength); + if ( back ) { + double pT=0; + if ( nPiece == lastPiece ) { + pT=(lastT*(enLength-curLength)+nT*(curLength-stLength))/(enLength-stLength); + } else { + pT=(nPiece*(curLength-stLength))/(enLength-stLength); + } + AddPoint(p,nPiece,pT,true); + } else { + AddPoint(p,true); + } + } else if ( nPlain == false && dashPlain == true ) { + } + dashPlain=nPlain; + } + // faire les tirets + if ( curLength >= head /*&& curLength+nl <= totLength-tail*/ ) { + while ( curLength <= totLength-tail && nl > 0 ) { + if ( enLength <= totLength-tail ) nl=enLength-curLength; else nl=totLength-tail-curLength; + double leftInDash=body-dashPos; + if ( dashInd < nbD ) { + leftInDash=dashs[dashInd]-dashPos; + } + if ( leftInDash <= nl ) { + bool nPlain=false; + if ( dashInd < nbD ) { + dashPos=dashs[dashInd]; + dashInd++; + if ( dashPlain ) nPlain=false; else nPlain=true; + } else { + dashInd=0; + dashPos=0; + //nPlain=stPlain; + nPlain=dashPlain; + } + if ( nPlain == true && dashPlain == false ) { + Geom::Point p=(enLength-curLength-leftInDash)*lastP+(curLength+leftInDash-stLength)*n; + p/=(enLength-stLength); + if ( back ) { + double pT=0; + if ( nPiece == lastPiece ) { + pT=(lastT*(enLength-curLength-leftInDash)+nT*(curLength+leftInDash-stLength))/(enLength-stLength); + } else { + pT=(nPiece*(curLength+leftInDash-stLength))/(enLength-stLength); + } + AddPoint(p,nPiece,pT,true); + } else { + AddPoint(p,true); + } + } else if ( nPlain == false && dashPlain == true ) { + Geom::Point p=(enLength-curLength-leftInDash)*lastP+(curLength+leftInDash-stLength)*n; + p/=(enLength-stLength); + if ( back ) { + double pT=0; + if ( nPiece == lastPiece ) { + pT=(lastT*(enLength-curLength-leftInDash)+nT*(curLength+leftInDash-stLength))/(enLength-stLength); + } else { + pT=(nPiece*(curLength+leftInDash-stLength))/(enLength-stLength); + } + AddPoint(p,nPiece,pT,false); + } else { + AddPoint(p,false); + } + } + dashPlain=nPlain; + + curLength+=leftInDash; + nl-=leftInDash; + } else { + dashPos+=nl; + curLength+=nl; + nl=0; + } + } + if ( dashPlain ) { + if ( back ) { + AddPoint(n,nPiece,nT,false); + } else { + AddPoint(n,false); + } + } + nl=enLength-curLength; + } + if ( curLength <= totLength-tail && curLength+nl > totLength-tail ) { + nl=totLength-tail-curLength; + dashInd=0; + dashPos=0; + bool nPlain=false; + if ( nPlain == true && dashPlain == false ) { + } else if ( nPlain == false && dashPlain == true ) { + Geom::Point p=(enLength-curLength)*lastP+(curLength-stLength)*n; + p/=(enLength-stLength); + if ( back ) { + double pT=0; + if ( nPiece == lastPiece ) { + pT=(lastT*(enLength-curLength)+nT*(curLength-stLength))/(enLength-stLength); + } else { + pT=(nPiece*(curLength-stLength))/(enLength-stLength); + } + AddPoint(p,nPiece,pT,false); + } else { + AddPoint(p,false); + } + } + dashPlain=nPlain; + } + // continuer + curLength=enLength; + lastP=n; + lastPiece=nPiece; + lastT=nT; + } + } +} + +/** + * Make a Geom::PathVector version of the path description. + * + * \return A PathVector copy of the path description + */ +Geom::PathVector +Path::MakePathVector() +{ + Geom::PathVector pv; + Geom::Path * currentpath = nullptr; + + Geom::Point lastP,bezSt,bezEn; + int bezNb=0; + for (int i=0;i<int(descr_cmd.size());i++) { + int const typ = descr_cmd[i]->getType(); + switch ( typ ) { + case descr_close: + { + currentpath->close(true); + } + break; + + case descr_lineto: + { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[i]); + currentpath->appendNew<Geom::LineSegment>(Geom::Point(nData->p[0], nData->p[1])); + lastP = nData->p; + } + break; + + case descr_moveto: + { + PathDescrMoveTo *nData = dynamic_cast<PathDescrMoveTo *>(descr_cmd[i]); + pv.push_back(Geom::Path()); + currentpath = &pv.back(); + currentpath->start(Geom::Point(nData->p[0], nData->p[1])); + lastP = nData->p; + } + break; + + case descr_arcto: + { + /* TODO: add testcase for this descr_arcto case */ + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[i]); + currentpath->appendNew<Geom::EllipticalArc>( nData->rx, nData->ry, nData->angle*M_PI/180.0, nData->large, !nData->clockwise, nData->p ); + lastP = nData->p; + } + break; + + case descr_cubicto: + { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[i]); + gdouble x1=lastP[0]+0.333333*nData->start[0]; + gdouble y1=lastP[1]+0.333333*nData->start[1]; + gdouble x2=nData->p[0]-0.333333*nData->end[0]; + gdouble y2=nData->p[1]-0.333333*nData->end[1]; + gdouble x3=nData->p[0]; + gdouble y3=nData->p[1]; + currentpath->appendNew<Geom::CubicBezier>( Geom::Point(x1,y1) , Geom::Point(x2,y2) , Geom::Point(x3,y3) ); + lastP = nData->p; + } + break; + + case descr_bezierto: + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[i]); + if ( nData->nb <= 0 ) { + currentpath->appendNew<Geom::LineSegment>( Geom::Point(nData->p[0], nData->p[1]) ); + bezNb=0; + } else if ( nData->nb == 1 ){ + PathDescrIntermBezierTo *iData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i+1]); + gdouble x1=0.333333*(lastP[0]+2*iData->p[0]); + gdouble y1=0.333333*(lastP[1]+2*iData->p[1]); + gdouble x2=0.333333*(nData->p[0]+2*iData->p[0]); + gdouble y2=0.333333*(nData->p[1]+2*iData->p[1]); + gdouble x3=nData->p[0]; + gdouble y3=nData->p[1]; + currentpath->appendNew<Geom::CubicBezier>( Geom::Point(x1,y1) , Geom::Point(x2,y2) , Geom::Point(x3,y3) ); + bezNb=0; + } else { + bezSt = 2*lastP-nData->p; + bezEn = nData->p; + bezNb = nData->nb; + } + lastP = nData->p; + } + break; + + case descr_interm_bezier: + { + if ( bezNb > 0 ) { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i]); + Geom::Point p_m=nData->p,p_s=0.5*(bezSt+p_m),p_e; + if ( bezNb > 1 ) { + PathDescrIntermBezierTo *iData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i+1]); + p_e=0.5*(p_m+iData->p); + } else { + p_e=bezEn; + } + + Geom::Point cp1=0.333333*(p_s+2*p_m),cp2=0.333333*(2*p_m+p_e); + gdouble x1=cp1[0]; + gdouble y1=cp1[1]; + gdouble x2=cp2[0]; + gdouble y2=cp2[1]; + gdouble x3=p_e[0]; + gdouble y3=p_e[1]; + currentpath->appendNew<Geom::CubicBezier>( Geom::Point(x1,y1) , Geom::Point(x2,y2) , Geom::Point(x3,y3) ); + + bezNb--; + } + } + break; + } + } + + return pv; +} + +void Path::AddCurve(Geom::Curve const &c) +{ + if( is_straight_curve(c) ) + { + LineTo( c.finalPoint() ); + } + /* + else if(Geom::QuadraticBezier const *quadratic_bezier = dynamic_cast<Geom::QuadraticBezier const *>(c)) { + ... + } + */ + else if(Geom::CubicBezier const *cubic_bezier = dynamic_cast<Geom::CubicBezier const *>(&c)) { + Geom::Point tmp = (*cubic_bezier)[3]; + Geom::Point tms = 3 * ((*cubic_bezier)[1] - (*cubic_bezier)[0]); + Geom::Point tme = 3 * ((*cubic_bezier)[3] - (*cubic_bezier)[2]); + CubicTo (tmp, tms, tme); + } + else if(Geom::EllipticalArc const *elliptical_arc = dynamic_cast<Geom::EllipticalArc const *>(&c)) { + ArcTo( elliptical_arc->finalPoint(), + elliptical_arc->ray(Geom::X), elliptical_arc->ray(Geom::Y), + elliptical_arc->rotationAngle()*180.0/M_PI, // convert from radians to degrees + elliptical_arc->largeArc(), !elliptical_arc->sweep() ); + } else { + //this case handles sbasis as well as all other curve types + Geom::Path sbasis_path = Geom::cubicbezierpath_from_sbasis(c.toSBasis(), 0.1); + + //recurse to convert the new path resulting from the sbasis to svgd + for(const auto & iter : sbasis_path) { + AddCurve(iter); + } + } +} + +/** append is false by default: it means that the path should be resetted. If it is true, the path is not resetted and Geom::Path will be appended as a new path + */ +void Path::LoadPath(Geom::Path const &path, Geom::Affine const &tr, bool doTransformation, bool append) +{ + if (!append) { + SetBackData (false); + Reset(); + } + if (path.empty()) + return; + + // TODO: this can be optimized by not generating a new path here, but doing the transform in AddCurve + // directly on the curve parameters + + Geom::Path const pathtr = doTransformation ? path * tr : path; + + MoveTo( pathtr.initialPoint() ); + + for(const auto & cit : pathtr) { + AddCurve(cit); + } + + if (pathtr.closed()) { + Close(); + } +} + +void Path::LoadPathVector(Geom::PathVector const &pv) +{ + LoadPathVector(pv, Geom::Affine(), false); +} + +void Path::LoadPathVector(Geom::PathVector const &pv, Geom::Affine const &tr, bool doTransformation) +{ + SetBackData (false); + Reset(); + + // FIXME: 2geom is currently unable to maintain SVGElliptical arcs through transformation, and + // sometimes it crashes on a continuity error during conversions, therefore convert to beziers here. + // (the fix is of course to fix 2geom and then remove this if-statement, and just execute the 'else'-clause) + if (doTransformation) { + Geom::PathVector pvbezier = pathv_to_linear_and_cubic_beziers(pv); + for(const auto & it : pvbezier) { + LoadPath(it, tr, doTransformation, true); + } + } else { + for(const auto & it : pv) { + LoadPath(it, tr, doTransformation, true); + } + } +} + +/** + * \return Length of the lines in the pts vector. + */ + +double Path::Length() +{ + if ( pts.empty() ) { + return 0; + } + + Geom::Point lastP = pts[0].p; + + double len = 0; + for (const auto & pt : pts) { + + if ( pt.isMoveTo != polyline_moveto ) { + len += Geom::L2(pt.p - lastP); + } + + lastP = pt.p; + } + + return len; +} + + +double Path::Surface() +{ + if ( pts.empty() ) { + return 0; + } + + Geom::Point lastM = pts[0].p; + Geom::Point lastP = lastM; + + double surf = 0; + for (const auto & pt : pts) { + + if ( pt.isMoveTo == polyline_moveto ) { + surf += Geom::cross(lastM, lastM - lastP); + lastP = lastM = pt.p; + } else { + surf += Geom::cross(pt.p, pt.p - lastP); + lastP = pt.p; + } + + } + + return surf; +} + + +Path** Path::SubPaths(int &outNb,bool killNoSurf) +{ + int nbRes=0; + Path** res=nullptr; + Path* curAdd=nullptr; + + for (auto & i : descr_cmd) { + int const typ = i->getType(); + switch ( typ ) { + case descr_moveto: + if ( curAdd ) { + if ( curAdd->descr_cmd.size() > 1 ) { + curAdd->Convert(1.0); + double addSurf=curAdd->Surface(); + if ( fabs(addSurf) > 0.0001 || killNoSurf == false ) { + res=(Path**)g_realloc(res,(nbRes+1)*sizeof(Path*)); + res[nbRes++]=curAdd; + } else { + delete curAdd; + } + } else { + delete curAdd; + } + curAdd=nullptr; + } + curAdd=new Path; + curAdd->SetBackData(false); + { + PathDescrMoveTo *nData = dynamic_cast<PathDescrMoveTo *>(i); + curAdd->MoveTo(nData->p); + } + break; + case descr_close: + { + curAdd->Close(); + } + break; + case descr_lineto: + { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(i); + curAdd->LineTo(nData->p); + } + break; + case descr_cubicto: + { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(i); + curAdd->CubicTo(nData->p,nData->start,nData->end); + } + break; + case descr_arcto: + { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(i); + curAdd->ArcTo(nData->p,nData->rx,nData->ry,nData->angle,nData->large,nData->clockwise); + } + break; + case descr_bezierto: + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(i); + curAdd->BezierTo(nData->p); + } + break; + case descr_interm_bezier: + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(i); + curAdd->IntermBezierTo(nData->p); + } + break; + default: + break; + } + } + if ( curAdd ) { + if ( curAdd->descr_cmd.size() > 1 ) { + curAdd->Convert(1.0); + double addSurf=curAdd->Surface(); + if ( fabs(addSurf) > 0.0001 || killNoSurf == false ) { + res=(Path**)g_realloc(res,(nbRes+1)*sizeof(Path*)); + res[nbRes++]=curAdd; + } else { + delete curAdd; + } + } else { + delete curAdd; + } + } + curAdd=nullptr; + + outNb=nbRes; + return res; +} +Path** Path::SubPathsWithNesting(int &outNb,bool killNoSurf,int nbNest,int* nesting,int* conts) +{ + int nbRes=0; + Path** res=nullptr; + Path* curAdd=nullptr; + bool increment=false; + + for (int i=0;i<int(descr_cmd.size());i++) { + int const typ = descr_cmd[i]->getType(); + switch ( typ ) { + case descr_moveto: + { + if ( curAdd && increment == false ) { + if ( curAdd->descr_cmd.size() > 1 ) { + // sauvegarder descr_cmd[0]->associated + int savA=curAdd->descr_cmd[0]->associated; + curAdd->Convert(1.0); + curAdd->descr_cmd[0]->associated=savA; // associated n'est pas utilise apres + double addSurf=curAdd->Surface(); + if ( fabs(addSurf) > 0.0001 || killNoSurf == false ) { + res=(Path**)g_realloc(res,(nbRes+1)*sizeof(Path*)); + res[nbRes++]=curAdd; + } else { + delete curAdd; + } + } else { + delete curAdd; + } + curAdd=nullptr; + } + Path* hasParent=nullptr; + for (int j=0;j<nbNest;j++) { + if ( conts[j] == i && nesting[j] >= 0 ) { + int parentMvt=conts[nesting[j]]; + for (int k=0;k<nbRes;k++) { + if ( res[k] && res[k]->descr_cmd.empty() == false && res[k]->descr_cmd[0]->associated == parentMvt ) { + hasParent=res[k]; + break; + } + } + } + if ( conts[j] > i ) break; + } + if ( hasParent ) { + curAdd=hasParent; + increment=true; + } else { + curAdd=new Path; + curAdd->SetBackData(false); + increment=false; + } + PathDescrMoveTo *nData = dynamic_cast<PathDescrMoveTo *>(descr_cmd[i]); + int mNo=curAdd->MoveTo(nData->p); + curAdd->descr_cmd[mNo]->associated=i; + } + break; + case descr_close: + { + curAdd->Close(); + } + break; + case descr_lineto: + { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[i]); + curAdd->LineTo(nData->p); + } + break; + case descr_cubicto: + { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[i]); + curAdd->CubicTo(nData->p,nData->start,nData->end); + } + break; + case descr_arcto: + { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[i]); + curAdd->ArcTo(nData->p,nData->rx,nData->ry,nData->angle,nData->large,nData->clockwise); + } + break; + case descr_bezierto: + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[i]); + curAdd->BezierTo(nData->p); + } + break; + case descr_interm_bezier: + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i]); + curAdd->IntermBezierTo(nData->p); + } + break; + default: + break; + } + } + if ( curAdd && increment == false ) { + if ( curAdd->descr_cmd.size() > 1 ) { + curAdd->Convert(1.0); + double addSurf=curAdd->Surface(); + if ( fabs(addSurf) > 0.0001 || killNoSurf == false ) { + res=(Path**)g_realloc(res,(nbRes+1)*sizeof(Path*)); + res[nbRes++]=curAdd; + } else { + delete curAdd; + } + } else { + delete curAdd; + } + } + curAdd=nullptr; + + outNb=nbRes; + return res; +} + + +void Path::ConvertForcedToVoid() +{ + for (int i=0; i < int(descr_cmd.size()); i++) { + if ( descr_cmd[i]->getType() == descr_forced) { + delete descr_cmd[i]; + descr_cmd.erase(descr_cmd.begin() + i); + } + } +} + + +void Path::ConvertForcedToMoveTo() +{ + Geom::Point lastSeen(0, 0); + Geom::Point lastMove(0, 0); + + { + Geom::Point lastPos(0, 0); + for (int i = int(descr_cmd.size()) - 1; i >= 0; i--) { + int const typ = descr_cmd[i]->getType(); + switch ( typ ) { + case descr_forced: + { + PathDescrForced *d = dynamic_cast<PathDescrForced *>(descr_cmd[i]); + d->p = lastPos; + break; + } + case descr_close: + { + PathDescrClose *d = dynamic_cast<PathDescrClose *>(descr_cmd[i]); + d->p = lastPos; + break; + } + case descr_moveto: + { + PathDescrMoveTo *d = dynamic_cast<PathDescrMoveTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_lineto: + { + PathDescrLineTo *d = dynamic_cast<PathDescrLineTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_arcto: + { + PathDescrArcTo *d = dynamic_cast<PathDescrArcTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_cubicto: + { + PathDescrCubicTo *d = dynamic_cast<PathDescrCubicTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_bezierto: + { + PathDescrBezierTo *d = dynamic_cast<PathDescrBezierTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_interm_bezier: + { + PathDescrIntermBezierTo *d = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + default: + break; + } + } + } + + bool hasMoved = false; + for (int i = 0; i < int(descr_cmd.size()); i++) { + int const typ = descr_cmd[i]->getType(); + switch ( typ ) { + case descr_forced: + if ( i < int(descr_cmd.size()) - 1 && hasMoved ) { // sinon il termine le chemin + + delete descr_cmd[i]; + descr_cmd[i] = new PathDescrMoveTo(lastSeen); + lastMove = lastSeen; + hasMoved = true; + } + break; + + case descr_moveto: + { + PathDescrMoveTo *nData = dynamic_cast<PathDescrMoveTo *>(descr_cmd[i]); + lastMove = lastSeen = nData->p; + hasMoved = true; + } + break; + case descr_close: + { + lastSeen=lastMove; + } + break; + case descr_lineto: + { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[i]); + lastSeen=nData->p; + } + break; + case descr_cubicto: + { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[i]); + lastSeen=nData->p; + } + break; + case descr_arcto: + { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[i]); + lastSeen=nData->p; + } + break; + case descr_bezierto: + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[i]); + lastSeen=nData->p; + } + break; + case descr_interm_bezier: + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i]); + lastSeen=nData->p; + } + break; + default: + break; + } + } +} +static int CmpPosition(const void * p1, const void * p2) { + Path::cut_position *cp1=(Path::cut_position*)p1; + Path::cut_position *cp2=(Path::cut_position*)p2; + if ( cp1->piece < cp2->piece ) return -1; + if ( cp1->piece > cp2->piece ) return 1; + if ( cp1->t < cp2->t ) return -1; + if ( cp1->t > cp2->t ) return 1; + return 0; +} +static int CmpCurv(const void * p1, const void * p2) { + double *cp1=(double*)p1; + double *cp2=(double*)p2; + if ( *cp1 < *cp2 ) return -1; + if ( *cp1 > *cp2 ) return 1; + return 0; +} + + +Path::cut_position* Path::CurvilignToPosition(int nbCv, double *cvAbs, int &nbCut) +{ + if ( nbCv <= 0 || pts.empty() || back == false ) { + return nullptr; + } + + qsort(cvAbs, nbCv, sizeof(double), CmpCurv); + + cut_position *res = nullptr; + nbCut = 0; + int curCv = 0; + + double len = 0; + double lastT = 0; + int lastPiece = -1; + + Geom::Point lastM = pts[0].p; + Geom::Point lastP = lastM; + + for (const auto & pt : pts) { + + if ( pt.isMoveTo == polyline_moveto ) { + + lastP = lastM = pt.p; + lastT = pt.t; + lastPiece = pt.piece; + + } else { + + double const add = Geom::L2(pt.p - lastP); + double curPos = len; + double curAdd = add; + + while ( curAdd > 0.0001 && curCv < nbCv && curPos + curAdd >= cvAbs[curCv] ) { + double const theta = (cvAbs[curCv] - len) / add; + res = (cut_position*) g_realloc(res, (nbCut + 1) * sizeof(cut_position)); + res[nbCut].piece = pt.piece; + res[nbCut].t = theta * pt.t + (1 - theta) * ( (lastPiece != pt.piece) ? 0 : lastT); + nbCut++; + curAdd -= cvAbs[curCv] - curPos; + curPos = cvAbs[curCv]; + curCv++; + } + + len += add; + lastPiece = pt.piece; + lastP = pt.p; + lastT = pt.t; + } + } + + return res; +} + +/* +Moved from Layout-TNG-OutIter.cpp +TODO: clean up uses of the original function and remove + +Original Comment: +"this function really belongs to Path. I'll probably move it there eventually, +hence the Path-esque coding style" + +*/ +template<typename T> inline static T square(T x) {return x*x;} +Path::cut_position Path::PointToCurvilignPosition(Geom::Point const &pos, unsigned seg) const +{ + // if the parameter "seg" == 0, then all segments will be considered + // In however e.g. "seg" == 6 , then only the 6th segment will be considered + + unsigned bestSeg = 0; + double bestRangeSquared = DBL_MAX; + double bestT = 0.0; // you need a sentinel, or make sure that you prime with correct values. + + for (unsigned i = 1 ; i < pts.size() ; i++) { + if (pts[i].isMoveTo == polyline_moveto || (seg > 0 && i != seg)) continue; + Geom::Point p1, p2, localPos; + double thisRangeSquared; + double t; + + if (pts[i - 1].p == pts[i].p) { + thisRangeSquared = square(pts[i].p[Geom::X] - pos[Geom::X]) + square(pts[i].p[Geom::Y] - pos[Geom::Y]); + t = 0.0; + } else { + // we rotate all our coordinates so we're always looking at a mostly vertical line. + if (fabs(pts[i - 1].p[Geom::X] - pts[i].p[Geom::X]) < fabs(pts[i - 1].p[Geom::Y] - pts[i].p[Geom::Y])) { + p1 = pts[i - 1].p; + p2 = pts[i].p; + localPos = pos; + } else { + p1 = pts[i - 1].p.cw(); + p2 = pts[i].p.cw(); + localPos = pos.cw(); + } + double gradient = (p2[Geom::X] - p1[Geom::X]) / (p2[Geom::Y] - p1[Geom::Y]); + double intersection = p1[Geom::X] - gradient * p1[Geom::Y]; + /* + orthogonalGradient = -1.0 / gradient; // you are going to have numerical problems here. + orthogonalIntersection = localPos[Geom::X] - orthogonalGradient * localPos[Geom::Y]; + nearestY = (orthogonalIntersection - intersection) / (gradient - orthogonalGradient); + + expand out nearestY fully : + nearestY = (localPos[Geom::X] - (-1.0 / gradient) * localPos[Geom::Y] - intersection) / (gradient - (-1.0 / gradient)); + + multiply top and bottom by gradient: + nearestY = (localPos[Geom::X] * gradient - (-1.0) * localPos[Geom::Y] - intersection * gradient) / (gradient * gradient - (-1.0)); + + and simplify to get: + */ + double nearestY = (localPos[Geom::X] * gradient + localPos[Geom::Y] - intersection * gradient) + / (gradient * gradient + 1.0); + t = (nearestY - p1[Geom::Y]) / (p2[Geom::Y] - p1[Geom::Y]); + if (t <= 0.0) { + thisRangeSquared = square(p1[Geom::X] - localPos[Geom::X]) + square(p1[Geom::Y] - localPos[Geom::Y]); + t = 0.0; + } else if (t >= 1.0) { + thisRangeSquared = square(p2[Geom::X] - localPos[Geom::X]) + square(p2[Geom::Y] - localPos[Geom::Y]); + t = 1.0; + } else { + thisRangeSquared = square(nearestY * gradient + intersection - localPos[Geom::X]) + square(nearestY - localPos[Geom::Y]); + } + } + + if (thisRangeSquared < bestRangeSquared) { + bestSeg = i; + bestRangeSquared = thisRangeSquared; + bestT = t; + } + } + Path::cut_position result; + if (bestSeg == 0) { + result.piece = 0; + result.t = 0.0; + } else { + result.piece = pts[bestSeg].piece; + if (result.piece == pts[bestSeg - 1].piece) { + result.t = pts[bestSeg - 1].t * (1.0 - bestT) + pts[bestSeg].t * bestT; + } else { + result.t = pts[bestSeg].t * bestT; + } + } + return result; +} +/* + this one also belongs to Path + returns the length of the path up to the position indicated by t (0..1) + + TODO: clean up uses of the original function and remove + + should this take a cut_position as a parameter? +*/ +double Path::PositionToLength(int piece, double t) +{ + double length = 0.0; + for (unsigned i = 1 ; i < pts.size() ; i++) { + if (pts[i].isMoveTo == polyline_moveto) continue; + if (pts[i].piece == piece && t < pts[i].t) { + length += Geom::L2((t - pts[i - 1].t) / (pts[i].t - pts[i - 1].t) * (pts[i].p - pts[i - 1].p)); + break; + } + length += Geom::L2(pts[i].p - pts[i - 1].p); + } + return length; +} + +void Path::ConvertPositionsToForced(int nbPos, cut_position *poss) +{ + if ( nbPos <= 0 ) { + return; + } + + { + Geom::Point lastPos(0, 0); + for (int i = int(descr_cmd.size()) - 1; i >= 0; i--) { + int const typ = descr_cmd[i]->getType(); + switch ( typ ) { + + case descr_forced: + { + PathDescrForced *d = dynamic_cast<PathDescrForced *>(descr_cmd[i]); + d->p = lastPos; + break; + } + + case descr_close: + { + delete descr_cmd[i]; + descr_cmd[i] = new PathDescrLineTo(Geom::Point(0, 0)); + + int fp = i - 1; + while ( fp >= 0 && (descr_cmd[fp]->getType()) != descr_moveto ) { + fp--; + } + + if ( fp >= 0 ) { + PathDescrMoveTo *oData = dynamic_cast<PathDescrMoveTo *>(descr_cmd[fp]); + dynamic_cast<PathDescrLineTo*>(descr_cmd[i])->p = oData->p; + } + } + break; + + case descr_bezierto: + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[i]); + Geom::Point theP = nData->p; + if ( nData->nb == 0 ) { + lastPos = theP; + } + } + break; + + case descr_moveto: + { + PathDescrMoveTo *d = dynamic_cast<PathDescrMoveTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_lineto: + { + PathDescrLineTo *d = dynamic_cast<PathDescrLineTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_arcto: + { + PathDescrArcTo *d = dynamic_cast<PathDescrArcTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_cubicto: + { + PathDescrCubicTo *d = dynamic_cast<PathDescrCubicTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + case descr_interm_bezier: + { + PathDescrIntermBezierTo *d = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i]); + lastPos = d->p; + break; + } + default: + break; + } + } + } + if (descr_cmd[0]->getType() == descr_moveto) + descr_flags |= descr_doing_subpath; // see LP Bug 166302 + + qsort(poss, nbPos, sizeof(cut_position), CmpPosition); + + for (int curP=0;curP<nbPos;curP++) { + int cp=poss[curP].piece; + if ( cp < 0 || cp >= int(descr_cmd.size()) ) break; + float ct=poss[curP].t; + if ( ct < 0 ) continue; + if ( ct > 1 ) continue; + + int const typ = descr_cmd[cp]->getType(); + if ( typ == descr_moveto || typ == descr_forced || typ == descr_close ) { + // ponctuel= rien a faire + } else if ( typ == descr_lineto || typ == descr_arcto || typ == descr_cubicto ) { + // facile: creation d'un morceau et d'un forced -> 2 commandes + Geom::Point theP; + Geom::Point theT; + Geom::Point startP; + startP=PrevPoint(cp-1); + if ( typ == descr_cubicto ) { + double len,rad; + Geom::Point stD,enD,endP; + { + PathDescrCubicTo *oData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[cp]); + stD=oData->start; + enD=oData->end; + endP=oData->p; + TangentOnCubAt (ct, startP, *oData,true, theP,theT,len,rad); + } + + theT*=len; + + InsertCubicTo(endP,(1-ct)*theT,(1-ct)*enD,cp+1); + InsertForcePoint(cp+1); + { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[cp]); + nData->start=ct*stD; + nData->end=ct*theT; + nData->p=theP; + } + // decalages dans le tableau des positions de coupe + for (int j=curP+1;j<nbPos;j++) { + if ( poss[j].piece == cp ) { + poss[j].piece+=2; + poss[j].t=(poss[j].t-ct)/(1-ct); + } else { + poss[j].piece+=2; + } + } + } else if ( typ == descr_lineto ) { + Geom::Point endP; + { + PathDescrLineTo *oData = dynamic_cast<PathDescrLineTo *>(descr_cmd[cp]); + endP=oData->p; + } + + theP=ct*endP+(1-ct)*startP; + + InsertLineTo(endP,cp+1); + InsertForcePoint(cp+1); + { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[cp]); + nData->p=theP; + } + // decalages dans le tableau des positions de coupe + for (int j=curP+1;j<nbPos;j++) { + if ( poss[j].piece == cp ) { + poss[j].piece+=2; + poss[j].t=(poss[j].t-ct)/(1-ct); + } else { + poss[j].piece+=2; + } + } + } else if ( typ == descr_arcto ) { + Geom::Point endP; + double rx,ry,angle; + bool clockw,large; + double delta=0; + { + PathDescrArcTo *oData = dynamic_cast<PathDescrArcTo *>(descr_cmd[cp]); + endP=oData->p; + rx=oData->rx; + ry=oData->ry; + angle=oData->angle; + clockw=oData->clockwise; + large=oData->large; + } + { + double sang,eang; + ArcAngles(startP,endP,rx,ry,angle*M_PI/180.0,large,clockw,sang,eang); + + if (clockw) { + if ( sang < eang ) sang += 2*M_PI; + delta=eang-sang; + } else { + if ( sang > eang ) sang -= 2*M_PI; + delta=eang-sang; + } + if ( delta < 0 ) delta=-delta; + } + + PointAt (cp,ct, theP); + + if ( delta*(1-ct) > M_PI ) { + InsertArcTo(endP,rx,ry,angle,true,clockw,cp+1); + } else { + InsertArcTo(endP,rx,ry,angle,false,clockw,cp+1); + } + InsertForcePoint(cp+1); + { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[cp]); + nData->p=theP; + if ( delta*ct > M_PI ) { + nData->large=true; + } else { + nData->large=false; + } + } + // decalages dans le tableau des positions de coupe + for (int j=curP+1;j<nbPos;j++) { + if ( poss[j].piece == cp ) { + poss[j].piece+=2; + poss[j].t=(poss[j].t-ct)/(1-ct); + } else { + poss[j].piece+=2; + } + } + } + } else if ( typ == descr_bezierto || typ == descr_interm_bezier ) { + // dur + int theBDI=cp; + while ( theBDI >= 0 && (descr_cmd[theBDI]->getType()) != descr_bezierto ) theBDI--; + if ( (descr_cmd[theBDI]->getType()) == descr_bezierto ) { + PathDescrBezierTo theBD=*(dynamic_cast<PathDescrBezierTo *>(descr_cmd[theBDI])); + if ( cp >= theBDI && cp < theBDI+theBD.nb ) { + if ( theBD.nb == 1 ) { + Geom::Point endP=theBD.p; + Geom::Point midP; + Geom::Point startP; + startP=PrevPoint(theBDI-1); + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[theBDI+1]); + midP=nData->p; + } + Geom::Point aP=ct*midP+(1-ct)*startP; + Geom::Point bP=ct*endP+(1-ct)*midP; + Geom::Point knotP=ct*bP+(1-ct)*aP; + + InsertIntermBezierTo(bP,theBDI+2); + InsertBezierTo(knotP,1,theBDI+2); + InsertForcePoint(theBDI+2); + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[theBDI+1]); + nData->p=aP; + } + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[theBDI]); + nData->p=knotP; + } + // decalages dans le tableau des positions de coupe + for (int j=curP+1;j<nbPos;j++) { + if ( poss[j].piece == cp ) { + poss[j].piece+=3; + poss[j].t=(poss[j].t-ct)/(1-ct); + } else { + poss[j].piece+=3; + } + } + + } else { + // decouper puis repasser + if ( cp > theBDI ) { + Geom::Point pcP,ncP; + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[cp]); + pcP=nData->p; + } + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[cp+1]); + ncP=nData->p; + } + Geom::Point knotP=0.5*(pcP+ncP); + + InsertBezierTo(knotP,theBD.nb-(cp-theBDI),cp+1); + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[theBDI]); + nData->nb=cp-theBDI; + } + + // decalages dans le tableau des positions de coupe + for (int j=curP;j<nbPos;j++) { + if ( poss[j].piece == cp ) { + poss[j].piece+=1; + } else { + poss[j].piece+=1; + } + } + curP--; + } else { + Geom::Point pcP,ncP; + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[cp+1]); + pcP=nData->p; + } + { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[cp+2]); + ncP=nData->p; + } + Geom::Point knotP=0.5*(pcP+ncP); + + InsertBezierTo(knotP,theBD.nb-1,cp+2); + { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[theBDI]); + nData->nb=1; + } + + // decalages dans le tableau des positions de coupe + for (int j=curP;j<nbPos;j++) { + if ( poss[j].piece == cp ) { +// poss[j].piece+=1; + } else { + poss[j].piece+=1; + } + } + curP--; + } + } + } else { + // on laisse aussi tomber + } + } else { + // on laisse tomber + } + } + } +} + +void Path::ConvertPositionsToMoveTo(int nbPos,cut_position* poss) +{ + ConvertPositionsToForced(nbPos,poss); +// ConvertForcedToMoveTo(); + // on fait une version customizee a la place + + Path* res=new Path; + + Geom::Point lastP(0,0); + for (int i=0;i<int(descr_cmd.size());i++) { + int const typ = descr_cmd[i]->getType(); + if ( typ == descr_moveto ) { + Geom::Point np; + { + PathDescrMoveTo *nData = dynamic_cast<PathDescrMoveTo *>(descr_cmd[i]); + np=nData->p; + } + Geom::Point endP; + bool hasClose=false; + int hasForced=-1; + bool doesClose=false; + int j=i+1; + for (;j<int(descr_cmd.size());j++) { + int const ntyp = descr_cmd[j]->getType(); + if ( ntyp == descr_moveto ) { + j--; + break; + } else if ( ntyp == descr_forced ) { + if ( hasForced < 0 ) hasForced=j; + } else if ( ntyp == descr_close ) { + hasClose=true; + break; + } else if ( ntyp == descr_lineto ) { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[j]); + endP=nData->p; + } else if ( ntyp == descr_arcto ) { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[j]); + endP=nData->p; + } else if ( ntyp == descr_cubicto ) { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[j]); + endP=nData->p; + } else if ( ntyp == descr_bezierto ) { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[j]); + endP=nData->p; + } else { + } + } + if ( Geom::LInfty(endP-np) < 0.00001 ) { + doesClose=true; + } + if ( ( doesClose || hasClose ) && hasForced >= 0 ) { + // printf("nasty i=%i j=%i frc=%i\n",i,j,hasForced); + // aghhh. + Geom::Point nMvtP=PrevPoint(hasForced); + res->MoveTo(nMvtP); + Geom::Point nLastP=nMvtP; + for (int k = hasForced + 1; k < j; k++) { + int ntyp=descr_cmd[k]->getType(); + if ( ntyp == descr_moveto ) { + // ne doit pas arriver + } else if ( ntyp == descr_forced ) { + res->MoveTo(nLastP); + } else if ( ntyp == descr_close ) { + // rien a faire ici; de plus il ne peut y en avoir qu'un + } else if ( ntyp == descr_lineto ) { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[k]); + res->LineTo(nData->p); + nLastP=nData->p; + } else if ( ntyp == descr_arcto ) { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[k]); + res->ArcTo(nData->p,nData->rx,nData->ry,nData->angle,nData->large,nData->clockwise); + nLastP=nData->p; + } else if ( ntyp == descr_cubicto ) { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[k]); + res->CubicTo(nData->p,nData->start,nData->end); + nLastP=nData->p; + } else if ( ntyp == descr_bezierto ) { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[k]); + res->BezierTo(nData->p); + nLastP=nData->p; + } else if ( ntyp == descr_interm_bezier ) { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[k]); + res->IntermBezierTo(nData->p); + } else { + } + } + if ( doesClose == false ) res->LineTo(np); + nLastP=np; + for (int k=i+1;k<hasForced;k++) { + int ntyp=descr_cmd[k]->getType(); + if ( ntyp == descr_moveto ) { + // ne doit pas arriver + } else if ( ntyp == descr_forced ) { + res->MoveTo(nLastP); + } else if ( ntyp == descr_close ) { + // rien a faire ici; de plus il ne peut y en avoir qu'un + } else if ( ntyp == descr_lineto ) { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[k]); + res->LineTo(nData->p); + nLastP=nData->p; + } else if ( ntyp == descr_arcto ) { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[k]); + res->ArcTo(nData->p,nData->rx,nData->ry,nData->angle,nData->large,nData->clockwise); + nLastP=nData->p; + } else if ( ntyp == descr_cubicto ) { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[k]); + res->CubicTo(nData->p,nData->start,nData->end); + nLastP=nData->p; + } else if ( ntyp == descr_bezierto ) { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[k]); + res->BezierTo(nData->p); + nLastP=nData->p; + } else if ( ntyp == descr_interm_bezier ) { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[k]); + res->IntermBezierTo(nData->p); + } else { + } + } + lastP=nMvtP; + i=j; + } else { + // regular, just move on + res->MoveTo(np); + lastP=np; + } + } else if ( typ == descr_close ) { + res->Close(); + } else if ( typ == descr_forced ) { + res->MoveTo(lastP); + } else if ( typ == descr_lineto ) { + PathDescrLineTo *nData = dynamic_cast<PathDescrLineTo *>(descr_cmd[i]); + res->LineTo(nData->p); + lastP=nData->p; + } else if ( typ == descr_arcto ) { + PathDescrArcTo *nData = dynamic_cast<PathDescrArcTo *>(descr_cmd[i]); + res->ArcTo(nData->p,nData->rx,nData->ry,nData->angle,nData->large,nData->clockwise); + lastP=nData->p; + } else if ( typ == descr_cubicto ) { + PathDescrCubicTo *nData = dynamic_cast<PathDescrCubicTo *>(descr_cmd[i]); + res->CubicTo(nData->p,nData->start,nData->end); + lastP=nData->p; + } else if ( typ == descr_bezierto ) { + PathDescrBezierTo *nData = dynamic_cast<PathDescrBezierTo *>(descr_cmd[i]); + res->BezierTo(nData->p); + lastP=nData->p; + } else if ( typ == descr_interm_bezier ) { + PathDescrIntermBezierTo *nData = dynamic_cast<PathDescrIntermBezierTo *>(descr_cmd[i]); + res->IntermBezierTo(nData->p); + } else { + } + } + + Copy(res); + delete res; + return; +} + +/* + Local Variables: + mode:c++ + c-file-style:"stroustrup" + c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +)) + indent-tabs-mode:nil + fill-column:99 + End: +*/ +// vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:fileencoding=utf-8:textwidth=99 : |