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-rw-r--r--src/livarot/ShapeSweep.cpp3319
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diff --git a/src/livarot/ShapeSweep.cpp b/src/livarot/ShapeSweep.cpp
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+++ b/src/livarot/ShapeSweep.cpp
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+// SPDX-License-Identifier: GPL-2.0-or-later
+/** @file
+ * TODO: insert short description here
+ *//*
+ * Authors:
+ * see git history
+ * Fred
+ *
+ * Copyright (C) 2018 Authors
+ * Released under GNU GPL v2+, read the file 'COPYING' for more information.
+ */
+
+#include <cstdio>
+#include <cstdlib>
+#include <cstring>
+#include <glib.h>
+#include <2geom/affine.h>
+#include "Shape.h"
+#include "livarot/sweep-event-queue.h"
+#include "livarot/sweep-tree-list.h"
+#include "livarot/sweep-tree.h"
+
+//int doDebug=0;
+
+/*
+ * El Intersector.
+ * algorithm: 1) benley ottman to get intersections of all the polygon's edges
+ * 2) rounding of the points of the polygon, Hooby's algorithm
+ * 3) DFS with clockwise choice of the edge to compute the windings
+ * 4) choose edges according to winding numbers and fill rule
+ * some additional nastyness: step 2 needs a seed winding number for the upper-left point of each
+ * connex subgraph of the graph. computing these brutally is O(n^3): baaaad. so during the sweeping in 1)
+ * we keep for each point the edge of the resulting graph (not the original) that lies just on its left;
+ * when the time comes for the point to get its winding number computed, that edge must have been treated,
+ * because its upper end lies above the aforementioned point, meaning we know the winding number of the point.
+ * only, there is a catch: since we're sweeping the polygon, the edge we want to link the point to has not yet been
+ * added (that would be too easy...). so the points are put on a linked list on the original shape's edge, and the list
+ * is flushed when the edge is added.
+ * rounding: to do the rounding, we need to find which edges cross the surrounding of the rounded points (at
+ * each sweepline position). grunt method tries all combination of "rounded points in the sweepline"x"edges crossing
+ * the sweepline". That's bad (and that's what polyboolean does, if i am not mistaken). so for each point
+ * rounded in a given sweepline, keep immediate left and right edges at the time the point is treated.
+ * when edges/points crossing are searched, walk the edge list (in the sweepline at the end of the batch) starting
+ * from the rounded points' left and right from that time. may sound strange, but it works because edges that
+ * end or start in the batch have at least one end in the batch.
+ * all these are the cause of the numerous linked lists of points and edges maintained in the sweeping
+ */
+
+void
+Shape::ResetSweep ()
+{
+ MakePointData (true);
+ MakeEdgeData (true);
+ MakeSweepSrcData (true);
+}
+
+void
+Shape::CleanupSweep ()
+{
+ MakePointData (false);
+ MakeEdgeData (false);
+ MakeSweepSrcData (false);
+}
+
+void
+Shape::ForceToPolygon ()
+{
+ type = shape_polygon;
+}
+
+int
+Shape::Reoriente (Shape * a)
+{
+ Reset (0, 0);
+ if (a->numberOfPoints() <= 1 || a->numberOfEdges() <= 1)
+ return 0;
+ if (directedEulerian(a) == false)
+ return shape_input_err;
+
+ _pts = a->_pts;
+ if (numberOfPoints() > maxPt)
+ {
+ maxPt = numberOfPoints();
+ if (_has_points_data) {
+ pData.resize(maxPt);
+ _point_data_initialised = false;
+ _bbox_up_to_date = false;
+ }
+ }
+
+ _aretes = a->_aretes;
+ if (numberOfEdges() > maxAr)
+ {
+ maxAr = numberOfEdges();
+ if (_has_edges_data)
+ eData.resize(maxAr);
+ if (_has_sweep_src_data)
+ swsData.resize(maxAr);
+ if (_has_sweep_dest_data)
+ swdData.resize(maxAr);
+ if (_has_raster_data)
+ swrData.resize(maxAr);
+ }
+
+ MakePointData (true);
+ MakeEdgeData (true);
+ MakeSweepDestData (true);
+
+ initialisePointData();
+
+ for (int i = 0; i < numberOfPoints(); i++) {
+ _pts[i].x = pData[i].rx;
+ _pts[i].oldDegree = getPoint(i).totalDegree();
+ }
+
+ for (int i = 0; i < a->numberOfEdges(); i++)
+ {
+ eData[i].rdx = pData[getEdge(i).en].rx - pData[getEdge(i).st].rx;
+ eData[i].weight = 1;
+ _aretes[i].dx = eData[i].rdx;
+ }
+
+ SortPointsRounded ();
+
+ _need_edges_sorting = true;
+ GetWindings (this, nullptr, bool_op_union, true);
+
+// Plot(341,56,8,400,400,true,true,false,true);
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ swdData[i].leW %= 2;
+ swdData[i].riW %= 2;
+ if (swdData[i].leW < 0)
+ swdData[i].leW = -swdData[i].leW;
+ if (swdData[i].riW < 0)
+ swdData[i].riW = -swdData[i].riW;
+ if (swdData[i].leW > 0 && swdData[i].riW <= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+
+ MakePointData (false);
+ MakeEdgeData (false);
+ MakeSweepDestData (false);
+
+ if (directedEulerian(this) == false)
+ {
+// printf( "pas euclidian2");
+ _pts.clear();
+ _aretes.clear();
+ return shape_euler_err;
+ }
+
+ type = shape_polygon;
+ return 0;
+}
+
+int
+Shape::ConvertToShape (Shape * a, FillRule directed, bool invert)
+{
+ Reset (0, 0);
+
+ if (a->numberOfPoints() <= 1 || a->numberOfEdges() <= 1) {
+ return 0;
+ }
+
+ if ( directed != fill_justDont && directedEulerian(a) == false ) {
+ g_warning ("Shape error in ConvertToShape: directedEulerian(a) == false\n");
+ return shape_input_err;
+ }
+
+ a->ResetSweep();
+
+ if (sTree == nullptr) {
+ sTree = new SweepTreeList(a->numberOfEdges());
+ }
+ if (sEvts == nullptr) {
+ sEvts = new SweepEventQueue(a->numberOfEdges());
+ }
+
+ MakePointData(true);
+ MakeEdgeData(true);
+ MakeSweepSrcData(true);
+ MakeSweepDestData(true);
+ MakeBackData(a->_has_back_data);
+
+ a->initialisePointData();
+ a->initialiseEdgeData();
+
+ a->SortPointsRounded();
+
+ chgts.clear();
+
+ double lastChange = a->pData[0].rx[1] - 1.0;
+ int lastChgtPt = 0;
+ int edgeHead = -1;
+ Shape *shapeHead = nullptr;
+
+ clearIncidenceData();
+
+ int curAPt = 0;
+
+ while (curAPt < a->numberOfPoints() || sEvts->size() > 0) {
+ Geom::Point ptX;
+ double ptL, ptR;
+ SweepTree *intersL = nullptr;
+ SweepTree *intersR = nullptr;
+ int nPt = -1;
+ Shape *ptSh = nullptr;
+ bool isIntersection = false;
+ if (sEvts->peek(intersL, intersR, ptX, ptL, ptR))
+ {
+ if (a->pData[curAPt].pending > 0
+ || (a->pData[curAPt].rx[1] > ptX[1]
+ || (a->pData[curAPt].rx[1] == ptX[1]
+ && a->pData[curAPt].rx[0] > ptX[0])))
+ {
+ /* FIXME: could just be pop? */
+ sEvts->extract(intersL, intersR, ptX, ptL, ptR);
+ isIntersection = true;
+ }
+ else
+ {
+ nPt = curAPt++;
+ ptSh = a;
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+ }
+ else
+ {
+ nPt = curAPt++;
+ ptSh = a;
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+
+ if (isIntersection == false)
+ {
+ if (ptSh->getPoint(nPt).dI == 0 && ptSh->getPoint(nPt).dO == 0)
+ continue;
+ }
+
+ Geom::Point rPtX;
+ rPtX[0]= Round (ptX[0]);
+ rPtX[1]= Round (ptX[1]);
+ int lastPointNo = AddPoint (rPtX);
+ pData[lastPointNo].rx = rPtX;
+
+ if (rPtX[1] > lastChange)
+ {
+ int lastI = AssemblePoints (lastChgtPt, lastPointNo);
+
+ Shape *curSh = shapeHead;
+ int curBo = edgeHead;
+ while (curSh)
+ {
+ curSh->swsData[curBo].leftRnd =
+ pData[curSh->swsData[curBo].leftRnd].newInd;
+ curSh->swsData[curBo].rightRnd =
+ pData[curSh->swsData[curBo].rightRnd].newInd;
+
+ Shape *neSh = curSh->swsData[curBo].nextSh;
+ curBo = curSh->swsData[curBo].nextBo;
+ curSh = neSh;
+ }
+
+ for (auto & chgt : chgts)
+ {
+ chgt.ptNo = pData[chgt.ptNo].newInd;
+ if (chgt.type == 0)
+ {
+ if (chgt.src->getEdge(chgt.bord).st <
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt =
+ chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt =
+ chgt.ptNo;
+ }
+ }
+ else if (chgt.type == 1)
+ {
+ if (chgt.src->getEdge(chgt.bord).st >
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt =
+ chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt =
+ chgt.ptNo;
+ }
+ }
+ }
+
+ CheckAdjacencies (lastI, lastChgtPt, shapeHead, edgeHead);
+
+ CheckEdges (lastI, lastChgtPt, a, nullptr, bool_op_union);
+
+ for (int i = lastChgtPt; i < lastI; i++) {
+ if (pData[i].askForWindingS) {
+ Shape *windS = pData[i].askForWindingS;
+ int windB = pData[i].askForWindingB;
+ pData[i].nextLinkedPoint = windS->swsData[windB].firstLinkedPoint;
+ windS->swsData[windB].firstLinkedPoint = i;
+ }
+ }
+
+ if (lastI < lastPointNo) {
+ _pts[lastI] = getPoint(lastPointNo);
+ pData[lastI] = pData[lastPointNo];
+ }
+ lastPointNo = lastI;
+ _pts.resize(lastI + 1);
+
+ lastChgtPt = lastPointNo;
+ lastChange = rPtX[1];
+ chgts.clear();
+ edgeHead = -1;
+ shapeHead = nullptr;
+ }
+
+
+ if (isIntersection)
+ {
+// printf("(%i %i [%i %i]) ",intersL->bord,intersR->bord,intersL->startPoint,intersR->startPoint);
+ intersL->RemoveEvent (*sEvts, LEFT);
+ intersR->RemoveEvent (*sEvts, RIGHT);
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, INTERSECTION,
+ intersL->src, intersL->bord, intersR->src, intersR->bord);
+
+ intersL->SwapWithRight (*sTree, *sEvts);
+
+ TesteIntersection (intersL, LEFT, false);
+ TesteIntersection (intersR, RIGHT, false);
+ }
+ else
+ {
+ int cb;
+
+ int nbUp = 0, nbDn = 0;
+ int upNo = -1, dnNo = -1;
+ cb = ptSh->getPoint(nPt).incidentEdge[FIRST];
+ while (cb >= 0 && cb < ptSh->numberOfEdges())
+ {
+ if ((ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ upNo = cb;
+ nbUp++;
+ }
+ if ((ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ dnNo = cb;
+ nbDn++;
+ }
+ cb = ptSh->NextAt (nPt, cb);
+ }
+
+ if (nbDn <= 0)
+ {
+ upNo = -1;
+ }
+ if (upNo >= 0 && (SweepTree *) ptSh->swsData[upNo].misc == nullptr)
+ {
+ upNo = -1;
+ }
+
+ bool doWinding = true;
+
+ if (nbUp > 0)
+ {
+ cb = ptSh->getPoint(nPt).incidentEdge[FIRST];
+ while (cb >= 0 && cb < ptSh->numberOfEdges())
+ {
+ if ((ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ if (cb != upNo)
+ {
+ SweepTree *node =
+ (SweepTree *) ptSh->swsData[cb].misc;
+ if (node == nullptr)
+ {
+ }
+ else
+ {
+ AddChgt (lastPointNo, lastChgtPt, shapeHead,
+ edgeHead, EDGE_REMOVED, node->src, node->bord,
+ nullptr, -1);
+ ptSh->swsData[cb].misc = nullptr;
+
+ int onLeftB = -1, onRightB = -1;
+ Shape *onLeftS = nullptr;
+ Shape *onRightS = nullptr;
+ if (node->elem[LEFT])
+ {
+ onLeftB =
+ (static_cast <
+ SweepTree * >(node->elem[LEFT]))->bord;
+ onLeftS =
+ (static_cast <
+ SweepTree * >(node->elem[LEFT]))->src;
+ }
+ if (node->elem[RIGHT])
+ {
+ onRightB =
+ (static_cast <
+ SweepTree * >(node->elem[RIGHT]))->bord;
+ onRightS =
+ (static_cast <
+ SweepTree * >(node->elem[RIGHT]))->src;
+ }
+
+ node->Remove (*sTree, *sEvts, true);
+ if (onLeftS && onRightS)
+ {
+ SweepTree *onLeft =
+ (SweepTree *) onLeftS->swsData[onLeftB].
+ misc;
+ if (onLeftS == ptSh
+ && (onLeftS->getEdge(onLeftB).en == nPt
+ || onLeftS->getEdge(onLeftB).st ==
+ nPt))
+ {
+ }
+ else
+ {
+ if (onRightS == ptSh
+ && (onRightS->getEdge(onRightB).en ==
+ nPt
+ || onRightS->getEdge(onRightB).
+ st == nPt))
+ {
+ }
+ else
+ {
+ TesteIntersection (onLeft, RIGHT, false);
+ }
+ }
+ }
+ }
+ }
+ }
+ cb = ptSh->NextAt (nPt, cb);
+ }
+ }
+
+ // traitement du "upNo devient dnNo"
+ SweepTree *insertionNode = nullptr;
+ if (dnNo >= 0)
+ {
+ if (upNo >= 0)
+ {
+ SweepTree *node = (SweepTree *) ptSh->swsData[upNo].misc;
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, EDGE_REMOVED,
+ node->src, node->bord, nullptr, -1);
+
+ ptSh->swsData[upNo].misc = nullptr;
+
+ node->RemoveEvents (*sEvts);
+ node->ConvertTo (ptSh, dnNo, 1, lastPointNo);
+ ptSh->swsData[dnNo].misc = node;
+ TesteIntersection (node, RIGHT, false);
+ TesteIntersection (node, LEFT, false);
+ insertionNode = node;
+
+ ptSh->swsData[dnNo].curPoint = lastPointNo;
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, EDGE_INSERTED,
+ node->src, node->bord, nullptr, -1);
+ }
+ else
+ {
+ SweepTree *node = sTree->add(ptSh, dnNo, 1, lastPointNo, this);
+ ptSh->swsData[dnNo].misc = node;
+ node->Insert (*sTree, *sEvts, this, lastPointNo, true);
+ if (doWinding)
+ {
+ SweepTree *myLeft =
+ static_cast < SweepTree * >(node->elem[LEFT]);
+ if (myLeft)
+ {
+ pData[lastPointNo].askForWindingS = myLeft->src;
+ pData[lastPointNo].askForWindingB = myLeft->bord;
+ }
+ else
+ {
+ pData[lastPointNo].askForWindingB = -1;
+ }
+ doWinding = false;
+ }
+ TesteIntersection (node, RIGHT, false);
+ TesteIntersection (node, LEFT, false);
+ insertionNode = node;
+
+ ptSh->swsData[dnNo].curPoint = lastPointNo;
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, EDGE_INSERTED,
+ node->src, node->bord, nullptr, -1);
+ }
+ }
+
+ if (nbDn > 1)
+ { // si nbDn == 1 , alors dnNo a deja ete traite
+ cb = ptSh->getPoint(nPt).incidentEdge[FIRST];
+ while (cb >= 0 && cb < ptSh->numberOfEdges())
+ {
+ if ((ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ if (cb != dnNo)
+ {
+ SweepTree *node = sTree->add(ptSh, cb, 1, lastPointNo, this);
+ ptSh->swsData[cb].misc = node;
+ node->InsertAt (*sTree, *sEvts, this, insertionNode,
+ nPt, true);
+ if (doWinding)
+ {
+ SweepTree *myLeft =
+ static_cast < SweepTree * >(node->elem[LEFT]);
+ if (myLeft)
+ {
+ pData[lastPointNo].askForWindingS =
+ myLeft->src;
+ pData[lastPointNo].askForWindingB =
+ myLeft->bord;
+ }
+ else
+ {
+ pData[lastPointNo].askForWindingB = -1;
+ }
+ doWinding = false;
+ }
+ TesteIntersection (node, RIGHT, false);
+ TesteIntersection (node, LEFT, false);
+
+ ptSh->swsData[cb].curPoint = lastPointNo;
+ AddChgt (lastPointNo, lastChgtPt, shapeHead,
+ edgeHead, EDGE_INSERTED, node->src, node->bord, nullptr,
+ -1);
+ }
+ }
+ cb = ptSh->NextAt (nPt, cb);
+ }
+ }
+ }
+ }
+ {
+ int lastI = AssemblePoints (lastChgtPt, numberOfPoints());
+
+
+ Shape *curSh = shapeHead;
+ int curBo = edgeHead;
+ while (curSh)
+ {
+ curSh->swsData[curBo].leftRnd =
+ pData[curSh->swsData[curBo].leftRnd].newInd;
+ curSh->swsData[curBo].rightRnd =
+ pData[curSh->swsData[curBo].rightRnd].newInd;
+
+ Shape *neSh = curSh->swsData[curBo].nextSh;
+ curBo = curSh->swsData[curBo].nextBo;
+ curSh = neSh;
+ }
+
+ for (auto & chgt : chgts)
+ {
+ chgt.ptNo = pData[chgt.ptNo].newInd;
+ if (chgt.type == 0)
+ {
+ if (chgt.src->getEdge(chgt.bord).st <
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt = chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt = chgt.ptNo;
+ }
+ }
+ else if (chgt.type == 1)
+ {
+ if (chgt.src->getEdge(chgt.bord).st >
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt = chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt = chgt.ptNo;
+ }
+ }
+ }
+
+ CheckAdjacencies (lastI, lastChgtPt, shapeHead, edgeHead);
+
+ CheckEdges (lastI, lastChgtPt, a, nullptr, bool_op_union);
+
+ for (int i = lastChgtPt; i < lastI; i++)
+ {
+ if (pData[i].askForWindingS)
+ {
+ Shape *windS = pData[i].askForWindingS;
+ int windB = pData[i].askForWindingB;
+ pData[i].nextLinkedPoint = windS->swsData[windB].firstLinkedPoint;
+ windS->swsData[windB].firstLinkedPoint = i;
+ }
+ }
+
+ _pts.resize(lastI);
+
+ edgeHead = -1;
+ shapeHead = nullptr;
+ }
+
+ chgts.clear();
+
+// Plot (98.0, 112.0, 8.0, 400.0, 400.0, true, true, true, true);
+// Plot(200.0,200.0,2.0,400.0,400.0,true,true,true,true);
+
+ // AssemblePoints(a);
+
+// GetAdjacencies(a);
+
+// MakeAretes(a);
+ clearIncidenceData();
+
+ AssembleAretes (directed);
+
+// Plot (98.0, 112.0, 8.0, 400.0, 400.0, true, true, true, true);
+
+ for (int i = 0; i < numberOfPoints(); i++)
+ {
+ _pts[i].oldDegree = getPoint(i).totalDegree();
+ }
+// Validate();
+
+ _need_edges_sorting = true;
+ if ( directed == fill_justDont ) {
+ SortEdges();
+ } else {
+ GetWindings (a);
+ }
+// Plot (98.0, 112.0, 8.0, 400.0, 400.0, true, true, true, true);
+// if ( doDebug ) {
+// a->CalcBBox();
+// a->Plot(a->leftX,a->topY,32.0,0.0,0.0,true,true,true,true,"orig.svg");
+// Plot(a->leftX,a->topY,32.0,0.0,0.0,true,true,true,true,"winded.svg");
+// }
+ if (directed == fill_positive)
+ {
+ if (invert)
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW < 0 && swdData[i].riW >= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW >= 0 && swdData[i].riW < 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+ else
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW > 0 && swdData[i].riW <= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+ }
+ else if (directed == fill_nonZero)
+ {
+ if (invert)
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW < 0 && swdData[i].riW == 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW > 0 && swdData[i].riW == 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW == 0 && swdData[i].riW < 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW == 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+ else
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW > 0 && swdData[i].riW == 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW < 0 && swdData[i].riW == 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW == 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW == 0 && swdData[i].riW < 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+ }
+ else if (directed == fill_oddEven)
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ swdData[i].leW %= 2;
+ swdData[i].riW %= 2;
+ if (swdData[i].leW < 0)
+ swdData[i].leW = -swdData[i].leW;
+ if (swdData[i].riW < 0)
+ swdData[i].riW = -swdData[i].riW;
+ if (swdData[i].leW > 0 && swdData[i].riW <= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ } else if ( directed == fill_justDont ) {
+ for (int i=0;i<numberOfEdges();i++) {
+ if ( getEdge(i).st < 0 || getEdge(i).en < 0 ) {
+ SubEdge(i);
+ i--;
+ } else {
+ eData[i].weight = 0;
+ }
+ }
+ }
+
+// Plot(200.0,200.0,2.0,400.0,400.0,true,true,true,true);
+
+ delete sTree;
+ sTree = nullptr;
+ delete sEvts;
+ sEvts = nullptr;
+
+ MakePointData (false);
+ MakeEdgeData (false);
+ MakeSweepSrcData (false);
+ MakeSweepDestData (false);
+ a->CleanupSweep ();
+ type = shape_polygon;
+ return 0;
+}
+
+// technically it's just a ConvertToShape() on 2 polygons at the same time, and different rules
+// for choosing the edges according to their winding numbers.
+// probably one of the biggest function i ever wrote.
+int
+Shape::Booleen (Shape * a, Shape * b, BooleanOp mod,int cutPathID)
+{
+ if (a == b || a == nullptr || b == nullptr)
+ return shape_input_err;
+ Reset (0, 0);
+ if (a->numberOfPoints() <= 1 || a->numberOfEdges() <= 1)
+ return 0;
+ if (b->numberOfPoints() <= 1 || b->numberOfEdges() <= 1)
+ return 0;
+ if ( mod == bool_op_cut ) {
+ } else if ( mod == bool_op_slice ) {
+ } else {
+ if (a->type != shape_polygon)
+ return shape_input_err;
+ if (b->type != shape_polygon)
+ return shape_input_err;
+ }
+
+ a->ResetSweep ();
+ b->ResetSweep ();
+
+ if (sTree == nullptr) {
+ sTree = new SweepTreeList(a->numberOfEdges() + b->numberOfEdges());
+ }
+ if (sEvts == nullptr) {
+ sEvts = new SweepEventQueue(a->numberOfEdges() + b->numberOfEdges());
+ }
+
+ MakePointData (true);
+ MakeEdgeData (true);
+ MakeSweepSrcData (true);
+ MakeSweepDestData (true);
+ if (a->hasBackData () && b->hasBackData ())
+ {
+ MakeBackData (true);
+ }
+ else
+ {
+ MakeBackData (false);
+ }
+
+ a->initialisePointData();
+ b->initialisePointData();
+
+ a->initialiseEdgeData();
+ b->initialiseEdgeData();
+
+ a->SortPointsRounded ();
+ b->SortPointsRounded ();
+
+ chgts.clear();
+
+ double lastChange =
+ (a->pData[0].rx[1] <
+ b->pData[0].rx[1]) ? a->pData[0].rx[1] - 1.0 : b->pData[0].rx[1] - 1.0;
+ int lastChgtPt = 0;
+ int edgeHead = -1;
+ Shape *shapeHead = nullptr;
+
+ clearIncidenceData();
+
+ int curAPt = 0;
+ int curBPt = 0;
+
+ while (curAPt < a->numberOfPoints() || curBPt < b->numberOfPoints() || sEvts->size() > 0)
+ {
+/* for (int i=0;i<sEvts.nbEvt;i++) {
+ printf("%f %f %i %i\n",sEvts.events[i].posx,sEvts.events[i].posy,sEvts.events[i].leftSweep->bord,sEvts.events[i].rightSweep->bord); // localizing ok
+ }
+ // cout << endl;
+ if ( sTree.racine ) {
+ SweepTree* ct=static_cast <SweepTree*> (sTree.racine->Leftmost());
+ while ( ct ) {
+ printf("%i %i [%i\n",ct->bord,ct->startPoint,(ct->src==a)?1:0);
+ ct=static_cast <SweepTree*> (ct->elem[RIGHT]);
+ }
+ }
+ printf("\n");*/
+
+ Geom::Point ptX;
+ double ptL, ptR;
+ SweepTree *intersL = nullptr;
+ SweepTree *intersR = nullptr;
+ int nPt = -1;
+ Shape *ptSh = nullptr;
+ bool isIntersection = false;
+
+ if (sEvts->peek(intersL, intersR, ptX, ptL, ptR))
+ {
+ if (curAPt < a->numberOfPoints())
+ {
+ if (curBPt < b->numberOfPoints())
+ {
+ if (a->pData[curAPt].rx[1] < b->pData[curBPt].rx[1]
+ || (a->pData[curAPt].rx[1] == b->pData[curBPt].rx[1]
+ && a->pData[curAPt].rx[0] < b->pData[curBPt].rx[0]))
+ {
+ if (a->pData[curAPt].pending > 0
+ || (a->pData[curAPt].rx[1] > ptX[1]
+ || (a->pData[curAPt].rx[1] == ptX[1]
+ && a->pData[curAPt].rx[0] > ptX[0])))
+ {
+ /* FIXME: could be pop? */
+ sEvts->extract(intersL, intersR, ptX, ptL, ptR);
+ isIntersection = true;
+ }
+ else
+ {
+ nPt = curAPt++;
+ ptSh = a;
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+ }
+ else
+ {
+ if (b->pData[curBPt].pending > 0
+ || (b->pData[curBPt].rx[1] > ptX[1]
+ || (b->pData[curBPt].rx[1] == ptX[1]
+ && b->pData[curBPt].rx[0] > ptX[0])))
+ {
+ /* FIXME: could be pop? */
+ sEvts->extract(intersL, intersR, ptX, ptL, ptR);
+ isIntersection = true;
+ }
+ else
+ {
+ nPt = curBPt++;
+ ptSh = b;
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+ }
+ }
+ else
+ {
+ if (a->pData[curAPt].pending > 0
+ || (a->pData[curAPt].rx[1] > ptX[1]
+ || (a->pData[curAPt].rx[1] == ptX[1]
+ && a->pData[curAPt].rx[0] > ptX[0])))
+ {
+ /* FIXME: could be pop? */
+ sEvts->extract(intersL, intersR, ptX, ptL, ptR);
+ isIntersection = true;
+ }
+ else
+ {
+ nPt = curAPt++;
+ ptSh = a;
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+ }
+ }
+ else
+ {
+ if (b->pData[curBPt].pending > 0
+ || (b->pData[curBPt].rx[1] > ptX[1]
+ || (b->pData[curBPt].rx[1] == ptX[1]
+ && b->pData[curBPt].rx[0] > ptX[0])))
+ {
+ /* FIXME: could be pop? */
+ sEvts->extract(intersL, intersR, ptX, ptL, ptR);
+ isIntersection = true;
+ }
+ else
+ {
+ nPt = curBPt++;
+ ptSh = b;
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+ }
+ }
+ else
+ {
+ if (curAPt < a->numberOfPoints())
+ {
+ if (curBPt < b->numberOfPoints())
+ {
+ if (a->pData[curAPt].rx[1] < b->pData[curBPt].rx[1]
+ || (a->pData[curAPt].rx[1] == b->pData[curBPt].rx[1]
+ && a->pData[curAPt].rx[0] < b->pData[curBPt].rx[0]))
+ {
+ nPt = curAPt++;
+ ptSh = a;
+ }
+ else
+ {
+ nPt = curBPt++;
+ ptSh = b;
+ }
+ }
+ else
+ {
+ nPt = curAPt++;
+ ptSh = a;
+ }
+ }
+ else
+ {
+ nPt = curBPt++;
+ ptSh = b;
+ }
+ ptX = ptSh->pData[nPt].rx;
+ isIntersection = false;
+ }
+
+ if (isIntersection == false)
+ {
+ if (ptSh->getPoint(nPt).dI == 0 && ptSh->getPoint(nPt).dO == 0)
+ continue;
+ }
+
+ Geom::Point rPtX;
+ rPtX[0]= Round (ptX[0]);
+ rPtX[1]= Round (ptX[1]);
+ int lastPointNo = AddPoint (rPtX);
+ pData[lastPointNo].rx = rPtX;
+
+ if (rPtX[1] > lastChange)
+ {
+ int lastI = AssemblePoints (lastChgtPt, lastPointNo);
+
+
+ Shape *curSh = shapeHead;
+ int curBo = edgeHead;
+ while (curSh)
+ {
+ curSh->swsData[curBo].leftRnd =
+ pData[curSh->swsData[curBo].leftRnd].newInd;
+ curSh->swsData[curBo].rightRnd =
+ pData[curSh->swsData[curBo].rightRnd].newInd;
+
+ Shape *neSh = curSh->swsData[curBo].nextSh;
+ curBo = curSh->swsData[curBo].nextBo;
+ curSh = neSh;
+ }
+
+ for (auto & chgt : chgts)
+ {
+ chgt.ptNo = pData[chgt.ptNo].newInd;
+ if (chgt.type == 0)
+ {
+ if (chgt.src->getEdge(chgt.bord).st <
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt =
+ chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt =
+ chgt.ptNo;
+ }
+ }
+ else if (chgt.type == 1)
+ {
+ if (chgt.src->getEdge(chgt.bord).st >
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt =
+ chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt =
+ chgt.ptNo;
+ }
+ }
+ }
+
+ CheckAdjacencies (lastI, lastChgtPt, shapeHead, edgeHead);
+
+ CheckEdges (lastI, lastChgtPt, a, b, mod);
+
+ for (int i = lastChgtPt; i < lastI; i++)
+ {
+ if (pData[i].askForWindingS)
+ {
+ Shape *windS = pData[i].askForWindingS;
+ int windB = pData[i].askForWindingB;
+ pData[i].nextLinkedPoint =
+ windS->swsData[windB].firstLinkedPoint;
+ windS->swsData[windB].firstLinkedPoint = i;
+ }
+ }
+
+ if (lastI < lastPointNo)
+ {
+ _pts[lastI] = getPoint(lastPointNo);
+ pData[lastI] = pData[lastPointNo];
+ }
+ lastPointNo = lastI;
+ _pts.resize(lastI + 1);
+
+ lastChgtPt = lastPointNo;
+ lastChange = rPtX[1];
+ chgts.clear();
+ edgeHead = -1;
+ shapeHead = nullptr;
+ }
+
+
+ if (isIntersection)
+ {
+ // les 2 events de part et d'autre de l'intersection
+ // (celui de l'intersection a deja ete depile)
+ intersL->RemoveEvent (*sEvts, LEFT);
+ intersR->RemoveEvent (*sEvts, RIGHT);
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, INTERSECTION,
+ intersL->src, intersL->bord, intersR->src, intersR->bord);
+
+ intersL->SwapWithRight (*sTree, *sEvts);
+
+ TesteIntersection (intersL, LEFT, true);
+ TesteIntersection (intersR, RIGHT, true);
+ }
+ else
+ {
+ int cb;
+
+ int nbUp = 0, nbDn = 0;
+ int upNo = -1, dnNo = -1;
+ cb = ptSh->getPoint(nPt).incidentEdge[FIRST];
+ while (cb >= 0 && cb < ptSh->numberOfEdges())
+ {
+ if ((ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ upNo = cb;
+ nbUp++;
+ }
+ if ((ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ dnNo = cb;
+ nbDn++;
+ }
+ cb = ptSh->NextAt (nPt, cb);
+ }
+
+ if (nbDn <= 0)
+ {
+ upNo = -1;
+ }
+ if (upNo >= 0 && (SweepTree *) ptSh->swsData[upNo].misc == nullptr)
+ {
+ upNo = -1;
+ }
+
+// upNo=-1;
+
+ bool doWinding = true;
+
+ if (nbUp > 0)
+ {
+ cb = ptSh->getPoint(nPt).incidentEdge[FIRST];
+ while (cb >= 0 && cb < ptSh->numberOfEdges())
+ {
+ if ((ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ if (cb != upNo)
+ {
+ SweepTree *node =
+ (SweepTree *) ptSh->swsData[cb].misc;
+ if (node == nullptr)
+ {
+ }
+ else
+ {
+ AddChgt (lastPointNo, lastChgtPt, shapeHead,
+ edgeHead, EDGE_REMOVED, node->src, node->bord,
+ nullptr, -1);
+ ptSh->swsData[cb].misc = nullptr;
+
+ int onLeftB = -1, onRightB = -1;
+ Shape *onLeftS = nullptr;
+ Shape *onRightS = nullptr;
+ if (node->elem[LEFT])
+ {
+ onLeftB =
+ (static_cast <
+ SweepTree * >(node->elem[LEFT]))->bord;
+ onLeftS =
+ (static_cast <
+ SweepTree * >(node->elem[LEFT]))->src;
+ }
+ if (node->elem[RIGHT])
+ {
+ onRightB =
+ (static_cast <
+ SweepTree * >(node->elem[RIGHT]))->bord;
+ onRightS =
+ (static_cast <
+ SweepTree * >(node->elem[RIGHT]))->src;
+ }
+
+ node->Remove (*sTree, *sEvts, true);
+ if (onLeftS && onRightS)
+ {
+ SweepTree *onLeft =
+ (SweepTree *) onLeftS->swsData[onLeftB].
+ misc;
+// SweepTree* onRight=(SweepTree*)onRightS->swsData[onRightB].misc;
+ if (onLeftS == ptSh
+ && (onLeftS->getEdge(onLeftB).en == nPt
+ || onLeftS->getEdge(onLeftB).st ==
+ nPt))
+ {
+ }
+ else
+ {
+ if (onRightS == ptSh
+ && (onRightS->getEdge(onRightB).en ==
+ nPt
+ || onRightS->getEdge(onRightB).
+ st == nPt))
+ {
+ }
+ else
+ {
+ TesteIntersection (onLeft, RIGHT, true);
+ }
+ }
+ }
+ }
+ }
+ }
+ cb = ptSh->NextAt (nPt, cb);
+ }
+ }
+
+ // traitement du "upNo devient dnNo"
+ SweepTree *insertionNode = nullptr;
+ if (dnNo >= 0)
+ {
+ if (upNo >= 0)
+ {
+ SweepTree *node = (SweepTree *) ptSh->swsData[upNo].misc;
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, EDGE_REMOVED,
+ node->src, node->bord, nullptr, -1);
+
+ ptSh->swsData[upNo].misc = nullptr;
+
+ node->RemoveEvents (*sEvts);
+ node->ConvertTo (ptSh, dnNo, 1, lastPointNo);
+ ptSh->swsData[dnNo].misc = node;
+ TesteIntersection (node, RIGHT, true);
+ TesteIntersection (node, LEFT, true);
+ insertionNode = node;
+
+ ptSh->swsData[dnNo].curPoint = lastPointNo;
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, EDGE_INSERTED,
+ node->src, node->bord, nullptr, -1);
+ }
+ else
+ {
+ SweepTree *node = sTree->add(ptSh, dnNo, 1, lastPointNo, this);
+ ptSh->swsData[dnNo].misc = node;
+ node->Insert (*sTree, *sEvts, this, lastPointNo, true);
+
+ if (doWinding)
+ {
+ SweepTree *myLeft =
+ static_cast < SweepTree * >(node->elem[LEFT]);
+ if (myLeft)
+ {
+ pData[lastPointNo].askForWindingS = myLeft->src;
+ pData[lastPointNo].askForWindingB = myLeft->bord;
+ }
+ else
+ {
+ pData[lastPointNo].askForWindingB = -1;
+ }
+ doWinding = false;
+ }
+
+ TesteIntersection (node, RIGHT, true);
+ TesteIntersection (node, LEFT, true);
+ insertionNode = node;
+
+ ptSh->swsData[dnNo].curPoint = lastPointNo;
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead, edgeHead, EDGE_INSERTED,
+ node->src, node->bord, nullptr, -1);
+ }
+ }
+
+ if (nbDn > 1)
+ { // si nbDn == 1 , alors dnNo a deja ete traite
+ cb = ptSh->getPoint(nPt).incidentEdge[FIRST];
+ while (cb >= 0 && cb < ptSh->numberOfEdges())
+ {
+ if ((ptSh->getEdge(cb).st > ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).en)
+ || (ptSh->getEdge(cb).st < ptSh->getEdge(cb).en
+ && nPt == ptSh->getEdge(cb).st))
+ {
+ if (cb != dnNo)
+ {
+ SweepTree *node = sTree->add(ptSh, cb, 1, lastPointNo, this);
+ ptSh->swsData[cb].misc = node;
+// node->Insert(sTree,*sEvts,this,lastPointNo,true);
+ node->InsertAt (*sTree, *sEvts, this, insertionNode,
+ nPt, true);
+
+ if (doWinding)
+ {
+ SweepTree *myLeft =
+ static_cast < SweepTree * >(node->elem[LEFT]);
+ if (myLeft)
+ {
+ pData[lastPointNo].askForWindingS =
+ myLeft->src;
+ pData[lastPointNo].askForWindingB =
+ myLeft->bord;
+ }
+ else
+ {
+ pData[lastPointNo].askForWindingB = -1;
+ }
+ doWinding = false;
+ }
+
+ TesteIntersection (node, RIGHT, true);
+ TesteIntersection (node, LEFT, true);
+
+ ptSh->swsData[cb].curPoint = lastPointNo;
+
+ AddChgt (lastPointNo, lastChgtPt, shapeHead,
+ edgeHead, EDGE_INSERTED, node->src, node->bord, nullptr,
+ -1);
+ }
+ }
+ cb = ptSh->NextAt (nPt, cb);
+ }
+ }
+ }
+ }
+ {
+ int lastI = AssemblePoints (lastChgtPt, numberOfPoints());
+
+
+ Shape *curSh = shapeHead;
+ int curBo = edgeHead;
+ while (curSh)
+ {
+ curSh->swsData[curBo].leftRnd =
+ pData[curSh->swsData[curBo].leftRnd].newInd;
+ curSh->swsData[curBo].rightRnd =
+ pData[curSh->swsData[curBo].rightRnd].newInd;
+
+ Shape *neSh = curSh->swsData[curBo].nextSh;
+ curBo = curSh->swsData[curBo].nextBo;
+ curSh = neSh;
+ }
+
+ /* FIXME: this kind of code seems to appear frequently */
+ for (auto & chgt : chgts)
+ {
+ chgt.ptNo = pData[chgt.ptNo].newInd;
+ if (chgt.type == 0)
+ {
+ if (chgt.src->getEdge(chgt.bord).st <
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt = chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt = chgt.ptNo;
+ }
+ }
+ else if (chgt.type == 1)
+ {
+ if (chgt.src->getEdge(chgt.bord).st >
+ chgt.src->getEdge(chgt.bord).en)
+ {
+ chgt.src->swsData[chgt.bord].stPt = chgt.ptNo;
+ }
+ else
+ {
+ chgt.src->swsData[chgt.bord].enPt = chgt.ptNo;
+ }
+ }
+ }
+
+ CheckAdjacencies (lastI, lastChgtPt, shapeHead, edgeHead);
+
+ CheckEdges (lastI, lastChgtPt, a, b, mod);
+
+ for (int i = lastChgtPt; i < lastI; i++)
+ {
+ if (pData[i].askForWindingS)
+ {
+ Shape *windS = pData[i].askForWindingS;
+ int windB = pData[i].askForWindingB;
+ pData[i].nextLinkedPoint = windS->swsData[windB].firstLinkedPoint;
+ windS->swsData[windB].firstLinkedPoint = i;
+ }
+ }
+
+ _pts.resize(lastI);
+
+ edgeHead = -1;
+ shapeHead = nullptr;
+ }
+
+ chgts.clear();
+ clearIncidenceData();
+
+// Plot(190,70,6,400,400,true,false,true,true);
+
+ if ( mod == bool_op_cut ) {
+ AssembleAretes (fill_justDont);
+ // dupliquer les aretes de la coupure
+ int i=numberOfEdges()-1;
+ for (;i>=0;i--) {
+ if ( ebData[i].pathID == cutPathID ) {
+ // on duplique
+ int nEd=AddEdge(getEdge(i).en,getEdge(i).st);
+ ebData[nEd].pathID=cutPathID;
+ ebData[nEd].pieceID=ebData[i].pieceID;
+ ebData[nEd].tSt=ebData[i].tEn;
+ ebData[nEd].tEn=ebData[i].tSt;
+ eData[nEd].weight=eData[i].weight;
+ // lui donner les firstlinkedpoitn si besoin
+ if ( getEdge(i).en >= getEdge(i).st ) {
+ int cp = swsData[i].firstLinkedPoint;
+ while (cp >= 0) {
+ pData[cp].askForWindingB = nEd;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ swsData[nEd].firstLinkedPoint = swsData[i].firstLinkedPoint;
+ swsData[i].firstLinkedPoint=-1;
+ }
+ }
+ }
+ } else if ( mod == bool_op_slice ) {
+ } else {
+ AssembleAretes ();
+ }
+
+ for (int i = 0; i < numberOfPoints(); i++)
+ {
+ _pts[i].oldDegree = getPoint(i).totalDegree();
+ }
+
+ _need_edges_sorting = true;
+ if ( mod == bool_op_slice ) {
+ } else {
+ GetWindings (a, b, mod, false);
+ }
+// Plot(190,70,6,400,400,true,true,true,true);
+
+ if (mod == bool_op_symdiff)
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ swdData[i].leW = swdData[i].leW % 2;
+ if (swdData[i].leW < 0)
+ swdData[i].leW = -swdData[i].leW;
+ swdData[i].riW = swdData[i].riW;
+ if (swdData[i].riW < 0)
+ swdData[i].riW = -swdData[i].riW;
+
+ if (swdData[i].leW > 0 && swdData[i].riW <= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+ else if (mod == bool_op_union || mod == bool_op_diff)
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW > 0 && swdData[i].riW <= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+ else if (mod == bool_op_inters)
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW > 1 && swdData[i].riW <= 1)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 1 && swdData[i].riW > 1)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ } else if ( mod == bool_op_cut ) {
+ // inverser les aretes de la coupe au besoin
+ for (int i=0;i<numberOfEdges();i++) {
+ if ( getEdge(i).st < 0 || getEdge(i).en < 0 ) {
+ if ( i < numberOfEdges()-1 ) {
+ // decaler les askForWinding
+ int cp = swsData[numberOfEdges()-1].firstLinkedPoint;
+ while (cp >= 0) {
+ pData[cp].askForWindingB = i;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ }
+ SwapEdges(i,numberOfEdges()-1);
+ SubEdge(numberOfEdges()-1);
+// SubEdge(i);
+ i--;
+ } else if ( ebData[i].pathID == cutPathID ) {
+ swdData[i].leW=swdData[i].leW%2;
+ swdData[i].riW=swdData[i].riW%2;
+ if ( swdData[i].leW < swdData[i].riW ) {
+ Inverse(i);
+ }
+ }
+ }
+ } else if ( mod == bool_op_slice ) {
+ // supprimer les aretes de la coupe
+ int i=numberOfEdges()-1;
+ for (;i>=0;i--) {
+ if ( ebData[i].pathID == cutPathID || getEdge(i).st < 0 || getEdge(i).en < 0 ) {
+ SubEdge(i);
+ }
+ }
+ }
+ else
+ {
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ if (swdData[i].leW > 0 && swdData[i].riW <= 0)
+ {
+ eData[i].weight = 1;
+ }
+ else if (swdData[i].leW <= 0 && swdData[i].riW > 0)
+ {
+ Inverse (i);
+ eData[i].weight = 1;
+ }
+ else
+ {
+ eData[i].weight = 0;
+ SubEdge (i);
+ i--;
+ }
+ }
+ }
+
+ delete sTree;
+ sTree = nullptr;
+ delete sEvts;
+ sEvts = nullptr;
+
+ if ( mod == bool_op_cut ) {
+ // on garde le askForWinding
+ } else {
+ MakePointData (false);
+ }
+ MakeEdgeData (false);
+ MakeSweepSrcData (false);
+ MakeSweepDestData (false);
+ a->CleanupSweep ();
+ b->CleanupSweep ();
+
+ if (directedEulerian(this) == false)
+ {
+// printf( "pas euclidian2");
+ _pts.clear();
+ _aretes.clear();
+ return shape_euler_err;
+ }
+ type = shape_polygon;
+ return 0;
+}
+
+// frontend to the TesteIntersection() below
+void Shape::TesteIntersection(SweepTree *t, Side s, bool onlyDiff)
+{
+ SweepTree *tt = static_cast<SweepTree*>(t->elem[s]);
+ if (tt == nullptr) {
+ return;
+ }
+
+ SweepTree *a = (s == LEFT) ? tt : t;
+ SweepTree *b = (s == LEFT) ? t : tt;
+
+ Geom::Point atx;
+ double atl;
+ double atr;
+ if (TesteIntersection(a, b, atx, atl, atr, onlyDiff)) {
+ sEvts->add(a, b, atx, atl, atr);
+ }
+}
+
+// a crucial piece of code: computing intersections between segments
+bool
+Shape::TesteIntersection (SweepTree * iL, SweepTree * iR, Geom::Point &atx, double &atL, double &atR, bool onlyDiff)
+{
+ int lSt = iL->src->getEdge(iL->bord).st, lEn = iL->src->getEdge(iL->bord).en;
+ int rSt = iR->src->getEdge(iR->bord).st, rEn = iR->src->getEdge(iR->bord).en;
+ Geom::Point ldir, rdir;
+ ldir = iL->src->eData[iL->bord].rdx;
+ rdir = iR->src->eData[iR->bord].rdx;
+ // first, a round of checks to quickly dismiss edge which obviously dont intersect,
+ // such as having disjoint bounding boxes
+ if (lSt < lEn)
+ {
+ }
+ else
+ {
+ int swap = lSt;
+ lSt = lEn;
+ lEn = swap;
+ ldir = -ldir;
+ }
+ if (rSt < rEn)
+ {
+ }
+ else
+ {
+ int swap = rSt;
+ rSt = rEn;
+ rEn = swap;
+ rdir = -rdir;
+ }
+
+ if (iL->src->pData[lSt].rx[0] < iL->src->pData[lEn].rx[0])
+ {
+ if (iR->src->pData[rSt].rx[0] < iR->src->pData[rEn].rx[0])
+ {
+ if (iL->src->pData[lSt].rx[0] > iR->src->pData[rEn].rx[0])
+ return false;
+ if (iL->src->pData[lEn].rx[0] < iR->src->pData[rSt].rx[0])
+ return false;
+ }
+ else
+ {
+ if (iL->src->pData[lSt].rx[0] > iR->src->pData[rSt].rx[0])
+ return false;
+ if (iL->src->pData[lEn].rx[0] < iR->src->pData[rEn].rx[0])
+ return false;
+ }
+ }
+ else
+ {
+ if (iR->src->pData[rSt].rx[0] < iR->src->pData[rEn].rx[0])
+ {
+ if (iL->src->pData[lEn].rx[0] > iR->src->pData[rEn].rx[0])
+ return false;
+ if (iL->src->pData[lSt].rx[0] < iR->src->pData[rSt].rx[0])
+ return false;
+ }
+ else
+ {
+ if (iL->src->pData[lEn].rx[0] > iR->src->pData[rSt].rx[0])
+ return false;
+ if (iL->src->pData[lSt].rx[0] < iR->src->pData[rEn].rx[0])
+ return false;
+ }
+ }
+
+ double ang = cross (ldir, rdir);
+// ang*=iL->src->eData[iL->bord].isqlength;
+// ang*=iR->src->eData[iR->bord].isqlength;
+ if (ang <= 0) return false; // edges in opposite directions: <-left ... right ->
+ // they can't intersect
+
+ // d'abord tester les bords qui partent d'un meme point
+ if (iL->src == iR->src && lSt == rSt)
+ {
+ if (iL->src == iR->src && lEn == rEn)
+ return false; // c'est juste un doublon
+ atx = iL->src->pData[lSt].rx;
+ atR = atL = -1;
+ return true; // l'ordre est mauvais
+ }
+ if (iL->src == iR->src && lEn == rEn)
+ return false; // rien a faire=ils vont terminer au meme endroit
+
+ // tester si on est dans une intersection multiple
+
+ if (onlyDiff && iL->src == iR->src)
+ return false;
+
+ // on reprend les vrais points
+ lSt = iL->src->getEdge(iL->bord).st;
+ lEn = iL->src->getEdge(iL->bord).en;
+ rSt = iR->src->getEdge(iR->bord).st;
+ rEn = iR->src->getEdge(iR->bord).en;
+
+ // compute intersection (if there is one)
+ // Boissonat anr Preparata said in one paper that double precision floats were sufficient for get single precision
+ // coordinates for the intersection, if the endpoints are single precision. i hope they're right...
+ {
+ Geom::Point sDiff, eDiff;
+ double slDot, elDot;
+ double srDot, erDot;
+ sDiff = iL->src->pData[lSt].rx - iR->src->pData[rSt].rx;
+ eDiff = iL->src->pData[lEn].rx - iR->src->pData[rSt].rx;
+ srDot = cross(rdir, sDiff);
+ erDot = cross(rdir, eDiff);
+ sDiff = iR->src->pData[rSt].rx - iL->src->pData[lSt].rx;
+ eDiff = iR->src->pData[rEn].rx - iL->src->pData[lSt].rx;
+ slDot = cross(ldir, sDiff);
+ elDot = cross(ldir, eDiff);
+
+ if ((srDot >= 0 && erDot >= 0) || (srDot <= 0 && erDot <= 0))
+ {
+ if (srDot == 0)
+ {
+ if (lSt < lEn)
+ {
+ atx = iL->src->pData[lSt].rx;
+ atL = 0;
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+ else
+ {
+ return false;
+ }
+ }
+ else if (erDot == 0)
+ {
+ if (lSt > lEn)
+ {
+ atx = iL->src->pData[lEn].rx;
+ atL = 1;
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+ else
+ {
+ return false;
+ }
+ }
+ if (srDot > 0 && erDot > 0)
+ {
+ if (rEn < rSt)
+ {
+ if (srDot < erDot)
+ {
+ if (lSt < lEn)
+ {
+ atx = iL->src->pData[lSt].rx;
+ atL = 0;
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+ }
+ else
+ {
+ if (lEn < lSt)
+ {
+ atx = iL->src->pData[lEn].rx;
+ atL = 1;
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+ }
+ }
+ }
+ if (srDot < 0 && erDot < 0)
+ {
+ if (rEn > rSt)
+ {
+ if (srDot > erDot)
+ {
+ if (lSt < lEn)
+ {
+ atx = iL->src->pData[lSt].rx;
+ atL = 0;
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+ }
+ else
+ {
+ if (lEn < lSt)
+ {
+ atx = iL->src->pData[lEn].rx;
+ atL = 1;
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+ }
+ }
+ }
+ return false;
+ }
+ if ((slDot >= 0 && elDot >= 0) || (slDot <= 0 && elDot <= 0))
+ {
+ if (slDot == 0)
+ {
+ if (rSt < rEn)
+ {
+ atx = iR->src->pData[rSt].rx;
+ atR = 0;
+ atL = srDot / (srDot - erDot);
+ return true;
+ }
+ else
+ {
+ return false;
+ }
+ }
+ else if (elDot == 0)
+ {
+ if (rSt > rEn)
+ {
+ atx = iR->src->pData[rEn].rx;
+ atR = 1;
+ atL = srDot / (srDot - erDot);
+ return true;
+ }
+ else
+ {
+ return false;
+ }
+ }
+ if (slDot > 0 && elDot > 0)
+ {
+ if (lEn > lSt)
+ {
+ if (slDot < elDot)
+ {
+ if (rSt < rEn)
+ {
+ atx = iR->src->pData[rSt].rx;
+ atR = 0;
+ atL = srDot / (srDot - erDot);
+ return true;
+ }
+ }
+ else
+ {
+ if (rEn < rSt)
+ {
+ atx = iR->src->pData[rEn].rx;
+ atR = 1;
+ atL = srDot / (srDot - erDot);
+ return true;
+ }
+ }
+ }
+ }
+ if (slDot < 0 && elDot < 0)
+ {
+ if (lEn < lSt)
+ {
+ if (slDot > elDot)
+ {
+ if (rSt < rEn)
+ {
+ atx = iR->src->pData[rSt].rx;
+ atR = 0;
+ atL = srDot / (srDot - erDot);
+ return true;
+ }
+ }
+ else
+ {
+ if (rEn < rSt)
+ {
+ atx = iR->src->pData[rEn].rx;
+ atR = 1;
+ atL = srDot / (srDot - erDot);
+ return true;
+ }
+ }
+ }
+ }
+ return false;
+ }
+
+/* double slb=slDot-elDot,srb=srDot-erDot;
+ if ( slb < 0 ) slb=-slb;
+ if ( srb < 0 ) srb=-srb;*/
+ if (iL->src->eData[iL->bord].siEd > iR->src->eData[iR->bord].siEd)
+ {
+ atx =
+ (slDot * iR->src->pData[rEn].rx -
+ elDot * iR->src->pData[rSt].rx) / (slDot - elDot);
+ }
+ else
+ {
+ atx =
+ (srDot * iL->src->pData[lEn].rx -
+ erDot * iL->src->pData[lSt].rx) / (srDot - erDot);
+ }
+ atL = srDot / (srDot - erDot);
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+
+ return true;
+}
+
+int
+Shape::PushIncidence (Shape * a, int cb, int pt, double theta)
+{
+ if (theta < 0 || theta > 1)
+ return -1;
+
+ if (nbInc >= maxInc)
+ {
+ maxInc = 2 * nbInc + 1;
+ iData =
+ (incidenceData *) g_realloc(iData, maxInc * sizeof (incidenceData));
+ }
+ int n = nbInc++;
+ iData[n].nextInc = a->swsData[cb].firstLinkedPoint;
+ iData[n].pt = pt;
+ iData[n].theta = theta;
+ a->swsData[cb].firstLinkedPoint = n;
+ return n;
+}
+
+int
+Shape::CreateIncidence (Shape * a, int no, int nPt)
+{
+ Geom::Point adir, diff;
+ adir = a->eData[no].rdx;
+ diff = getPoint(nPt).x - a->pData[a->getEdge(no).st].rx;
+ double t = dot (diff, adir);
+ t *= a->eData[no].ilength;
+ return PushIncidence (a, no, nPt, t);
+}
+
+int
+Shape::Winding (int nPt) const
+{
+ int askTo = pData[nPt].askForWindingB;
+ if (askTo < 0 || askTo >= numberOfEdges())
+ return 0;
+ if (getEdge(askTo).st < getEdge(askTo).en)
+ {
+ return swdData[askTo].leW;
+ }
+ else
+ {
+ return swdData[askTo].riW;
+ }
+ return 0;
+}
+
+int
+Shape::Winding (const Geom::Point px) const
+{
+ int lr = 0, ll = 0, rr = 0;
+
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ Geom::Point adir, diff, ast, aen;
+ adir = eData[i].rdx;
+
+ ast = pData[getEdge(i).st].rx;
+ aen = pData[getEdge(i).en].rx;
+
+ int nWeight = eData[i].weight;
+
+ if (ast[0] < aen[0])
+ {
+ if (ast[0] > px[0])
+ continue;
+ if (aen[0] < px[0])
+ continue;
+ }
+ else
+ {
+ if (ast[0] < px[0])
+ continue;
+ if (aen[0] > px[0])
+ continue;
+ }
+ if (ast[0] == px[0])
+ {
+ if (ast[1] >= px[1])
+ continue;
+ if (aen[0] == px[0])
+ continue;
+ if (aen[0] < px[0])
+ ll += nWeight;
+ else
+ rr -= nWeight;
+ continue;
+ }
+ if (aen[0] == px[0])
+ {
+ if (aen[1] >= px[1])
+ continue;
+ if (ast[0] == px[0])
+ continue;
+ if (ast[0] < px[0])
+ ll -= nWeight;
+ else
+ rr += nWeight;
+ continue;
+ }
+
+ if (ast[1] < aen[1])
+ {
+ if (ast[1] >= px[1])
+ continue;
+ }
+ else
+ {
+ if (aen[1] >= px[1])
+ continue;
+ }
+
+ diff = px - ast;
+ double cote = cross(adir, diff);
+ if (cote == 0)
+ continue;
+ if (cote < 0)
+ {
+ if (ast[0] > px[0])
+ lr += nWeight;
+ }
+ else
+ {
+ if (ast[0] < px[0])
+ lr -= nWeight;
+ }
+ }
+ return lr + (ll + rr) / 2;
+}
+
+// merging duplicate points and edges
+int
+Shape::AssemblePoints (int st, int en)
+{
+ if (en > st) {
+ for (int i = st; i < en; i++) pData[i].oldInd = i;
+// SortPoints(st,en-1);
+ SortPointsByOldInd (st, en - 1); // SortPointsByOldInd() is required here, because of the edges we have
+ // associated with the point for later computation of winding numbers.
+ // specifically, we need the first point we treated, it's the only one with a valid
+ // associated edge (man, that was a nice bug).
+ for (int i = st; i < en; i++) pData[pData[i].oldInd].newInd = i;
+
+ int lastI = st;
+ for (int i = st; i < en; i++) {
+ pData[i].pending = lastI++;
+ if (i > st && getPoint(i - 1).x[0] == getPoint(i).x[0] && getPoint(i - 1).x[1] == getPoint(i).x[1]) {
+ pData[i].pending = pData[i - 1].pending;
+ if (pData[pData[i].pending].askForWindingS == nullptr) {
+ pData[pData[i].pending].askForWindingS = pData[i].askForWindingS;
+ pData[pData[i].pending].askForWindingB = pData[i].askForWindingB;
+ } else {
+ if (pData[pData[i].pending].askForWindingS == pData[i].askForWindingS
+ && pData[pData[i].pending].askForWindingB == pData[i].askForWindingB) {
+ // meme bord, c bon
+ } else {
+ // meme point, mais pas le meme bord: ouille!
+ // il faut prendre le bord le plus a gauche
+ // en pratique, n'arrive que si 2 maxima sont dans la meme case -> le mauvais choix prend une arete incidente
+ // au bon choix
+// printf("doh");
+ }
+ }
+ lastI--;
+ } else {
+ if (i > pData[i].pending) {
+ _pts[pData[i].pending].x = getPoint(i).x;
+ pData[pData[i].pending].rx = getPoint(i).x;
+ pData[pData[i].pending].askForWindingS = pData[i].askForWindingS;
+ pData[pData[i].pending].askForWindingB = pData[i].askForWindingB;
+ }
+ }
+ }
+ for (int i = st; i < en; i++) pData[i].newInd = pData[pData[i].newInd].pending;
+ return lastI;
+ }
+ return en;
+}
+
+void
+Shape::AssemblePoints (Shape * a)
+{
+ if (hasPoints())
+ {
+ int lastI = AssemblePoints (0, numberOfPoints());
+
+ for (int i = 0; i < a->numberOfEdges(); i++)
+ {
+ a->swsData[i].stPt = pData[a->swsData[i].stPt].newInd;
+ a->swsData[i].enPt = pData[a->swsData[i].enPt].newInd;
+ }
+ for (int i = 0; i < nbInc; i++)
+ iData[i].pt = pData[iData[i].pt].newInd;
+
+ _pts.resize(lastI);
+ }
+}
+void
+Shape::AssembleAretes (FillRule directed)
+{
+ if ( directed == fill_justDont && _has_back_data == false ) {
+ directed=fill_nonZero;
+ }
+
+ for (int i = 0; i < numberOfPoints(); i++) {
+ if (getPoint(i).totalDegree() == 2) {
+ int cb, cc;
+ cb = getPoint(i).incidentEdge[FIRST];
+ cc = getPoint(i).incidentEdge[LAST];
+ bool doublon=false;
+ if ((getEdge(cb).st == getEdge(cc).st && getEdge(cb).en == getEdge(cc).en)
+ || (getEdge(cb).st == getEdge(cc).en && getEdge(cb).en == getEdge(cc).en)) doublon=true;
+ if ( directed == fill_justDont ) {
+ if ( doublon ) {
+ if ( ebData[cb].pathID > ebData[cc].pathID ) {
+ cc = getPoint(i).incidentEdge[FIRST]; // on swappe pour enlever cc
+ cb = getPoint(i).incidentEdge[LAST];
+ } else if ( ebData[cb].pathID == ebData[cc].pathID ) {
+ if ( ebData[cb].pieceID > ebData[cc].pieceID ) {
+ cc = getPoint(i).incidentEdge[FIRST]; // on swappe pour enlever cc
+ cb = getPoint(i).incidentEdge[LAST];
+ } else if ( ebData[cb].pieceID == ebData[cc].pieceID ) {
+ if ( ebData[cb].tSt > ebData[cc].tSt ) {
+ cc = getPoint(i).incidentEdge[FIRST]; // on swappe pour enlever cc
+ cb = getPoint(i).incidentEdge[LAST];
+ }
+ }
+ }
+ }
+ if ( doublon ) eData[cc].weight = 0;
+ } else {
+ }
+ if ( doublon ) {
+ if (getEdge(cb).st == getEdge(cc).st) {
+ eData[cb].weight += eData[cc].weight;
+ } else {
+ eData[cb].weight -= eData[cc].weight;
+ }
+ eData[cc].weight = 0;
+
+ if (swsData[cc].firstLinkedPoint >= 0) {
+ int cp = swsData[cc].firstLinkedPoint;
+ while (cp >= 0) {
+ pData[cp].askForWindingB = cb;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ if (swsData[cb].firstLinkedPoint < 0) {
+ swsData[cb].firstLinkedPoint = swsData[cc].firstLinkedPoint;
+ } else {
+ int ncp = swsData[cb].firstLinkedPoint;
+ while (pData[ncp].nextLinkedPoint >= 0) {
+ ncp = pData[ncp].nextLinkedPoint;
+ }
+ pData[ncp].nextLinkedPoint = swsData[cc].firstLinkedPoint;
+ }
+ }
+
+ DisconnectStart (cc);
+ DisconnectEnd (cc);
+ if (numberOfEdges() > 1) {
+ int cp = swsData[numberOfEdges() - 1].firstLinkedPoint;
+ while (cp >= 0) {
+ pData[cp].askForWindingB = cc;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ }
+ SwapEdges (cc, numberOfEdges() - 1);
+ if (cb == numberOfEdges() - 1) {
+ cb = cc;
+ }
+ _aretes.pop_back();
+ }
+ } else {
+ int cb;
+ cb = getPoint(i).incidentEdge[FIRST];
+ while (cb >= 0 && cb < numberOfEdges()) {
+ int other = Other (i, cb);
+ int cc;
+ cc = getPoint(i).incidentEdge[FIRST];
+ while (cc >= 0 && cc < numberOfEdges()) {
+ int ncc = NextAt (i, cc);
+ bool doublon=false;
+ if (cc != cb && Other (i, cc) == other ) doublon=true;
+ if ( directed == fill_justDont ) {
+ if ( doublon ) {
+ if ( ebData[cb].pathID > ebData[cc].pathID ) {
+ doublon=false;
+ } else if ( ebData[cb].pathID == ebData[cc].pathID ) {
+ if ( ebData[cb].pieceID > ebData[cc].pieceID ) {
+ doublon=false;
+ } else if ( ebData[cb].pieceID == ebData[cc].pieceID ) {
+ if ( ebData[cb].tSt > ebData[cc].tSt ) {
+ doublon=false;
+ }
+ }
+ }
+ }
+ if ( doublon ) eData[cc].weight = 0;
+ } else {
+ }
+ if ( doublon ) {
+// if (cc != cb && Other (i, cc) == other) {
+ // doublon
+ if (getEdge(cb).st == getEdge(cc).st) {
+ eData[cb].weight += eData[cc].weight;
+ } else {
+ eData[cb].weight -= eData[cc].weight;
+ }
+ eData[cc].weight = 0;
+
+ if (swsData[cc].firstLinkedPoint >= 0) {
+ int cp = swsData[cc].firstLinkedPoint;
+ while (cp >= 0) {
+ pData[cp].askForWindingB = cb;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ if (swsData[cb].firstLinkedPoint < 0) {
+ swsData[cb].firstLinkedPoint = swsData[cc].firstLinkedPoint;
+ } else {
+ int ncp = swsData[cb].firstLinkedPoint;
+ while (pData[ncp].nextLinkedPoint >= 0) {
+ ncp = pData[ncp].nextLinkedPoint;
+ }
+ pData[ncp].nextLinkedPoint = swsData[cc].firstLinkedPoint;
+ }
+ }
+
+ DisconnectStart (cc);
+ DisconnectEnd (cc);
+ if (numberOfEdges() > 1) {
+ int cp = swsData[numberOfEdges() - 1].firstLinkedPoint;
+ while (cp >= 0) {
+ pData[cp].askForWindingB = cc;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ }
+ SwapEdges (cc, numberOfEdges() - 1);
+ if (cb == numberOfEdges() - 1) {
+ cb = cc;
+ }
+ if (ncc == numberOfEdges() - 1) {
+ ncc = cc;
+ }
+ _aretes.pop_back();
+ }
+ cc = ncc;
+ }
+ cb = NextAt (i, cb);
+ }
+ }
+ }
+
+ if ( directed == fill_justDont ) {
+ for (int i = 0; i < numberOfEdges(); i++) {
+ if (eData[i].weight == 0) {
+// SubEdge(i);
+ // i--;
+ } else {
+ if (eData[i].weight < 0) Inverse (i);
+ }
+ }
+ } else {
+ for (int i = 0; i < numberOfEdges(); i++) {
+ if (eData[i].weight == 0) {
+ // SubEdge(i);
+ // i--;
+ } else {
+ if (eData[i].weight < 0) Inverse (i);
+ }
+ }
+ }
+}
+void
+Shape::GetWindings (Shape * /*a*/, Shape * /*b*/, BooleanOp /*mod*/, bool brutal)
+{
+ // preparation du parcours
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ swdData[i].misc = nullptr;
+ swdData[i].precParc = swdData[i].suivParc = -1;
+ }
+
+ // chainage
+ SortEdges ();
+
+ int searchInd = 0;
+
+ int lastPtUsed = 0;
+ do
+ {
+ int startBord = -1;
+ int outsideW = 0;
+ {
+ int fi = 0;
+ for (fi = lastPtUsed; fi < numberOfPoints(); fi++)
+ {
+ if (getPoint(fi).incidentEdge[FIRST] >= 0 && swdData[getPoint(fi).incidentEdge[FIRST]].misc == nullptr)
+ break;
+ }
+ lastPtUsed = fi + 1;
+ if (fi < numberOfPoints())
+ {
+ int bestB = getPoint(fi).incidentEdge[FIRST];
+ if (bestB >= 0)
+ {
+ startBord = bestB;
+ if (fi == 0)
+ {
+ outsideW = 0;
+ }
+ else
+ {
+ if (brutal)
+ {
+ outsideW = Winding (getPoint(fi).x);
+ }
+ else
+ {
+ outsideW = Winding (fi);
+ }
+ }
+ if ( getPoint(fi).totalDegree() == 1 ) {
+ if ( fi == getEdge(startBord).en ) {
+ if ( eData[startBord].weight == 0 ) {
+ // on se contente d'inverser
+ Inverse(startBord);
+ } else {
+ // on passe le askForWinding (sinon ca va rester startBord)
+ pData[getEdge(startBord).st].askForWindingB=pData[getEdge(startBord).en].askForWindingB;
+ }
+ }
+ }
+ if (getEdge(startBord).en == fi)
+ outsideW += eData[startBord].weight;
+ }
+ }
+ }
+ if (startBord >= 0)
+ {
+ // parcours en profondeur pour mettre les leF et riF a leurs valeurs
+ swdData[startBord].misc = (void *) 1;
+ swdData[startBord].leW = outsideW;
+ swdData[startBord].riW = outsideW - eData[startBord].weight;
+// if ( doDebug ) printf("part de %d\n",startBord);
+ int curBord = startBord;
+ bool curDir = true;
+ swdData[curBord].precParc = -1;
+ swdData[curBord].suivParc = -1;
+ do
+ {
+ int cPt;
+ if (curDir)
+ cPt = getEdge(curBord).en;
+ else
+ cPt = getEdge(curBord).st;
+ int nb = curBord;
+// if ( doDebug ) printf("de curBord= %d avec leF= %d et riF= %d -> ",curBord,swdData[curBord].leW,swdData[curBord].riW);
+ do
+ {
+ int nnb = -1;
+ if (getEdge(nb).en == cPt)
+ {
+ outsideW = swdData[nb].riW;
+ nnb = CyclePrevAt (cPt, nb);
+ }
+ else
+ {
+ outsideW = swdData[nb].leW;
+ nnb = CyclePrevAt (cPt, nb);
+ }
+ if (nnb == nb)
+ {
+ // cul-de-sac
+ nb = -1;
+ break;
+ }
+ nb = nnb;
+ }
+ while (nb >= 0 && nb != curBord && swdData[nb].misc != nullptr);
+ if (nb < 0 || nb == curBord)
+ {
+ // retour en arriere
+ int oPt;
+ if (curDir)
+ oPt = getEdge(curBord).st;
+ else
+ oPt = getEdge(curBord).en;
+ curBord = swdData[curBord].precParc;
+// if ( doDebug ) printf("retour vers %d\n",curBord);
+ if (curBord < 0)
+ break;
+ if (oPt == getEdge(curBord).en)
+ curDir = true;
+ else
+ curDir = false;
+ }
+ else
+ {
+ swdData[nb].misc = (void *) 1;
+ swdData[nb].ind = searchInd++;
+ if (cPt == getEdge(nb).st)
+ {
+ swdData[nb].riW = outsideW;
+ swdData[nb].leW = outsideW + eData[nb].weight;
+ }
+ else
+ {
+ swdData[nb].leW = outsideW;
+ swdData[nb].riW = outsideW - eData[nb].weight;
+ }
+ swdData[nb].precParc = curBord;
+ swdData[curBord].suivParc = nb;
+ curBord = nb;
+// if ( doDebug ) printf("suite %d\n",curBord);
+ if (cPt == getEdge(nb).en)
+ curDir = false;
+ else
+ curDir = true;
+ }
+ }
+ while (true /*swdData[curBord].precParc >= 0 */ );
+ // fin du cas non-oriente
+ }
+ }
+ while (lastPtUsed < numberOfPoints());
+// fflush(stdout);
+}
+
+bool
+Shape::TesteIntersection (Shape * ils, Shape * irs, int ilb, int irb,
+ Geom::Point &atx, double &atL, double &atR,
+ bool /*onlyDiff*/)
+{
+ int lSt = ils->getEdge(ilb).st, lEn = ils->getEdge(ilb).en;
+ int rSt = irs->getEdge(irb).st, rEn = irs->getEdge(irb).en;
+ if (lSt == rSt || lSt == rEn)
+ {
+ return false;
+ }
+ if (lEn == rSt || lEn == rEn)
+ {
+ return false;
+ }
+
+ Geom::Point ldir, rdir;
+ ldir = ils->eData[ilb].rdx;
+ rdir = irs->eData[irb].rdx;
+
+ double il = ils->pData[lSt].rx[0], it = ils->pData[lSt].rx[1], ir =
+ ils->pData[lEn].rx[0], ib = ils->pData[lEn].rx[1];
+ if (il > ir)
+ {
+ double swf = il;
+ il = ir;
+ ir = swf;
+ }
+ if (it > ib)
+ {
+ double swf = it;
+ it = ib;
+ ib = swf;
+ }
+ double jl = irs->pData[rSt].rx[0], jt = irs->pData[rSt].rx[1], jr =
+ irs->pData[rEn].rx[0], jb = irs->pData[rEn].rx[1];
+ if (jl > jr)
+ {
+ double swf = jl;
+ jl = jr;
+ jr = swf;
+ }
+ if (jt > jb)
+ {
+ double swf = jt;
+ jt = jb;
+ jb = swf;
+ }
+
+ if (il > jr || it > jb || ir < jl || ib < jt)
+ return false;
+
+ // pre-test
+ {
+ Geom::Point sDiff, eDiff;
+ double slDot, elDot;
+ double srDot, erDot;
+ sDiff = ils->pData[lSt].rx - irs->pData[rSt].rx;
+ eDiff = ils->pData[lEn].rx - irs->pData[rSt].rx;
+ srDot = cross(rdir, sDiff);
+ erDot = cross(rdir, eDiff);
+ if ((srDot >= 0 && erDot >= 0) || (srDot <= 0 && erDot <= 0))
+ return false;
+
+ sDiff = irs->pData[rSt].rx - ils->pData[lSt].rx;
+ eDiff = irs->pData[rEn].rx - ils->pData[lSt].rx;
+ slDot = cross(ldir, sDiff);
+ elDot = cross(ldir, eDiff);
+ if ((slDot >= 0 && elDot >= 0) || (slDot <= 0 && elDot <= 0))
+ return false;
+
+ double slb = slDot - elDot, srb = srDot - erDot;
+ if (slb < 0)
+ slb = -slb;
+ if (srb < 0)
+ srb = -srb;
+ if (slb > srb)
+ {
+ atx =
+ (slDot * irs->pData[rEn].rx - elDot * irs->pData[rSt].rx) / (slDot -
+ elDot);
+ }
+ else
+ {
+ atx =
+ (srDot * ils->pData[lEn].rx - erDot * ils->pData[lSt].rx) / (srDot -
+ erDot);
+ }
+ atL = srDot / (srDot - erDot);
+ atR = slDot / (slDot - elDot);
+ return true;
+ }
+
+ // a mettre en double precision pour des resultats exacts
+ Geom::Point usvs;
+ usvs = irs->pData[rSt].rx - ils->pData[lSt].rx;
+
+ // pas sur de l'ordre des coefs de m
+ Geom::Affine m(ldir[0], ldir[1],
+ rdir[0], rdir[1],
+ 0, 0);
+ double det = m.det();
+
+ double tdet = det * ils->eData[ilb].isqlength * irs->eData[irb].isqlength;
+
+ if (tdet > -0.0001 && tdet < 0.0001)
+ { // ces couillons de vecteurs sont colineaires
+ Geom::Point sDiff, eDiff;
+ double sDot, eDot;
+ sDiff = ils->pData[lSt].rx - irs->pData[rSt].rx;
+ eDiff = ils->pData[lEn].rx - irs->pData[rSt].rx;
+ sDot = cross(rdir, sDiff);
+ eDot = cross(rdir, eDiff);
+
+ atx =
+ (sDot * irs->pData[lEn].rx - eDot * irs->pData[lSt].rx) / (sDot -
+ eDot);
+ atL = sDot / (sDot - eDot);
+
+ sDiff = irs->pData[rSt].rx - ils->pData[lSt].rx;
+ eDiff = irs->pData[rEn].rx - ils->pData[lSt].rx;
+ sDot = cross(ldir, sDiff);
+ eDot = cross(ldir, eDiff);
+
+ atR = sDot / (sDot - eDot);
+
+ return true;
+ }
+
+ // plus de colinearite ni d'extremites en commun
+ m[1] = -m[1];
+ m[2] = -m[2];
+ {
+ double swap = m[0];
+ m[0] = m[3];
+ m[3] = swap;
+ }
+
+ atL = (m[0]* usvs[0] + m[1] * usvs[1]) / det;
+ atR = -(m[2] * usvs[0] + m[3] * usvs[1]) / det;
+ atx = ils->pData[lSt].rx + atL * ldir;
+
+
+ return true;
+}
+
+bool
+Shape::TesteAdjacency (Shape * a, int no, const Geom::Point atx, int nPt,
+ bool push)
+{
+ if (nPt == a->swsData[no].stPt || nPt == a->swsData[no].enPt)
+ return false;
+
+ Geom::Point adir, diff, ast, aen, diff1, diff2, diff3, diff4;
+
+ ast = a->pData[a->getEdge(no).st].rx;
+ aen = a->pData[a->getEdge(no).en].rx;
+
+ adir = a->eData[no].rdx;
+
+ double sle = a->eData[no].length;
+ double ile = a->eData[no].ilength;
+
+ diff = atx - ast;
+
+ double e = IHalfRound(cross(adir, diff) * a->eData[no].isqlength);
+ if (-3 < e && e < 3)
+ {
+ double rad = HalfRound (0.501); // when using single precision, 0.505 is better (0.5 would be the correct value,
+ // but it produces lots of bugs)
+ diff1[0] = diff[0] - rad;
+ diff1[1] = diff[1] - rad;
+ diff2[0] = diff[0] + rad;
+ diff2[1] = diff[1] - rad;
+ diff3[0] = diff[0] + rad;
+ diff3[1] = diff[1] + rad;
+ diff4[0] = diff[0] - rad;
+ diff4[1] = diff[1] + rad;
+ double di1, di2;
+ bool adjacent = false;
+ di1 = cross(adir, diff1);
+ di2 = cross(adir, diff3);
+ if ((di1 < 0 && di2 > 0) || (di1 > 0 && di2 < 0))
+ {
+ adjacent = true;
+ }
+ else
+ {
+ di1 = cross(adir, diff2);
+ di2 = cross(adir, diff4);
+ if ((di1 < 0 && di2 > 0) || (di1 > 0 && di2 < 0))
+ {
+ adjacent = true;
+ }
+ }
+ if (adjacent)
+ {
+ double t = dot (diff, adir);
+ if (t > 0 && t < sle)
+ {
+ if (push)
+ {
+ t *= ile;
+ PushIncidence (a, no, nPt, t);
+ }
+ return true;
+ }
+ }
+ }
+ return false;
+}
+
+void
+Shape::CheckAdjacencies (int lastPointNo, int lastChgtPt, Shape * /*shapeHead*/,
+ int /*edgeHead*/)
+{
+ for (auto & chgt : chgts)
+ {
+ int chLeN = chgt.ptNo;
+ int chRiN = chgt.ptNo;
+ if (chgt.src)
+ {
+ Shape *lS = chgt.src;
+ int lB = chgt.bord;
+ int lftN = lS->swsData[lB].leftRnd;
+ int rgtN = lS->swsData[lB].rightRnd;
+ if (lftN < chLeN)
+ chLeN = lftN;
+ if (rgtN > chRiN)
+ chRiN = rgtN;
+// for (int n=lftN;n<=rgtN;n++) CreateIncidence(lS,lB,n);
+ for (int n = lftN - 1; n >= lastChgtPt; n--)
+ {
+ if (TesteAdjacency (lS, lB, getPoint(n).x, n, false) ==
+ false)
+ break;
+ lS->swsData[lB].leftRnd = n;
+ }
+ for (int n = rgtN + 1; n < lastPointNo; n++)
+ {
+ if (TesteAdjacency (lS, lB, getPoint(n).x, n, false) ==
+ false)
+ break;
+ lS->swsData[lB].rightRnd = n;
+ }
+ }
+ if (chgt.osrc)
+ {
+ Shape *rS = chgt.osrc;
+ int rB = chgt.obord;
+ int lftN = rS->swsData[rB].leftRnd;
+ int rgtN = rS->swsData[rB].rightRnd;
+ if (lftN < chLeN)
+ chLeN = lftN;
+ if (rgtN > chRiN)
+ chRiN = rgtN;
+// for (int n=lftN;n<=rgtN;n++) CreateIncidence(rS,rB,n);
+ for (int n = lftN - 1; n >= lastChgtPt; n--)
+ {
+ if (TesteAdjacency (rS, rB, getPoint(n).x, n, false) ==
+ false)
+ break;
+ rS->swsData[rB].leftRnd = n;
+ }
+ for (int n = rgtN + 1; n < lastPointNo; n++)
+ {
+ if (TesteAdjacency (rS, rB, getPoint(n).x, n, false) ==
+ false)
+ break;
+ rS->swsData[rB].rightRnd = n;
+ }
+ }
+ if (chgt.lSrc)
+ {
+ if (chgt.lSrc->swsData[chgt.lBrd].leftRnd < lastChgtPt)
+ {
+ Shape *nSrc = chgt.lSrc;
+ int nBrd = chgt.lBrd /*,nNo=chgts[cCh].ptNo */ ;
+ bool hit;
+
+ do
+ {
+ hit = false;
+ for (int n = chRiN; n >= chLeN; n--)
+ {
+ if (TesteAdjacency
+ (nSrc, nBrd, getPoint(n).x, n, false))
+ {
+ if (nSrc->swsData[nBrd].leftRnd < lastChgtPt)
+ {
+ nSrc->swsData[nBrd].leftRnd = n;
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ else
+ {
+ if (n < nSrc->swsData[nBrd].leftRnd)
+ nSrc->swsData[nBrd].leftRnd = n;
+ if (n > nSrc->swsData[nBrd].rightRnd)
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ hit = true;
+ }
+ }
+ for (int n = chLeN - 1; n >= lastChgtPt; n--)
+ {
+ if (TesteAdjacency
+ (nSrc, nBrd, getPoint(n).x, n, false) == false)
+ break;
+ if (nSrc->swsData[nBrd].leftRnd < lastChgtPt)
+ {
+ nSrc->swsData[nBrd].leftRnd = n;
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ else
+ {
+ if (n < nSrc->swsData[nBrd].leftRnd)
+ nSrc->swsData[nBrd].leftRnd = n;
+ if (n > nSrc->swsData[nBrd].rightRnd)
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ hit = true;
+ }
+ if (hit)
+ {
+ SweepTree *node =
+ static_cast < SweepTree * >(nSrc->swsData[nBrd].misc);
+ if (node == nullptr)
+ break;
+ node = static_cast < SweepTree * >(node->elem[LEFT]);
+ if (node == nullptr)
+ break;
+ nSrc = node->src;
+ nBrd = node->bord;
+ if (nSrc->swsData[nBrd].leftRnd >= lastChgtPt)
+ break;
+ }
+ }
+ while (hit);
+
+ }
+ }
+ if (chgt.rSrc)
+ {
+ if (chgt.rSrc->swsData[chgt.rBrd].leftRnd < lastChgtPt)
+ {
+ Shape *nSrc = chgt.rSrc;
+ int nBrd = chgt.rBrd /*,nNo=chgts[cCh].ptNo */ ;
+ bool hit;
+ do
+ {
+ hit = false;
+ for (int n = chLeN; n <= chRiN; n++)
+ {
+ if (TesteAdjacency
+ (nSrc, nBrd, getPoint(n).x, n, false))
+ {
+ if (nSrc->swsData[nBrd].leftRnd < lastChgtPt)
+ {
+ nSrc->swsData[nBrd].leftRnd = n;
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ else
+ {
+ if (n < nSrc->swsData[nBrd].leftRnd)
+ nSrc->swsData[nBrd].leftRnd = n;
+ if (n > nSrc->swsData[nBrd].rightRnd)
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ hit = true;
+ }
+ }
+ for (int n = chRiN + 1; n < lastPointNo; n++)
+ {
+ if (TesteAdjacency
+ (nSrc, nBrd, getPoint(n).x, n, false) == false)
+ break;
+ if (nSrc->swsData[nBrd].leftRnd < lastChgtPt)
+ {
+ nSrc->swsData[nBrd].leftRnd = n;
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ else
+ {
+ if (n < nSrc->swsData[nBrd].leftRnd)
+ nSrc->swsData[nBrd].leftRnd = n;
+ if (n > nSrc->swsData[nBrd].rightRnd)
+ nSrc->swsData[nBrd].rightRnd = n;
+ }
+ hit = true;
+ }
+ if (hit)
+ {
+ SweepTree *node =
+ static_cast < SweepTree * >(nSrc->swsData[nBrd].misc);
+ if (node == nullptr)
+ break;
+ node = static_cast < SweepTree * >(node->elem[RIGHT]);
+ if (node == nullptr)
+ break;
+ nSrc = node->src;
+ nBrd = node->bord;
+ if (nSrc->swsData[nBrd].leftRnd >= lastChgtPt)
+ break;
+ }
+ }
+ while (hit);
+ }
+ }
+ }
+}
+
+
+void Shape::AddChgt(int lastPointNo, int lastChgtPt, Shape * &shapeHead,
+ int &edgeHead, sTreeChangeType type, Shape * lS, int lB, Shape * rS,
+ int rB)
+{
+ sTreeChange c;
+ c.ptNo = lastPointNo;
+ c.type = type;
+ c.src = lS;
+ c.bord = lB;
+ c.osrc = rS;
+ c.obord = rB;
+ chgts.push_back(c);
+ const int nCh = chgts.size() - 1;
+
+ /* FIXME: this looks like a cut and paste job */
+
+ if (lS) {
+ SweepTree *lE = static_cast < SweepTree * >(lS->swsData[lB].misc);
+ if (lE && lE->elem[LEFT]) {
+ SweepTree *llE = static_cast < SweepTree * >(lE->elem[LEFT]);
+ chgts[nCh].lSrc = llE->src;
+ chgts[nCh].lBrd = llE->bord;
+ } else {
+ chgts[nCh].lSrc = nullptr;
+ chgts[nCh].lBrd = -1;
+ }
+
+ if (lS->swsData[lB].leftRnd < lastChgtPt) {
+ lS->swsData[lB].leftRnd = lastPointNo;
+ lS->swsData[lB].nextSh = shapeHead;
+ lS->swsData[lB].nextBo = edgeHead;
+ edgeHead = lB;
+ shapeHead = lS;
+ } else {
+ int old = lS->swsData[lB].leftRnd;
+ if (getPoint(old).x[0] > getPoint(lastPointNo).x[0]) {
+ lS->swsData[lB].leftRnd = lastPointNo;
+ }
+ }
+ if (lS->swsData[lB].rightRnd < lastChgtPt) {
+ lS->swsData[lB].rightRnd = lastPointNo;
+ } else {
+ int old = lS->swsData[lB].rightRnd;
+ if (getPoint(old).x[0] < getPoint(lastPointNo).x[0])
+ lS->swsData[lB].rightRnd = lastPointNo;
+ }
+ }
+
+ if (rS) {
+ SweepTree *rE = static_cast < SweepTree * >(rS->swsData[rB].misc);
+ if (rE->elem[RIGHT]) {
+ SweepTree *rrE = static_cast < SweepTree * >(rE->elem[RIGHT]);
+ chgts[nCh].rSrc = rrE->src;
+ chgts[nCh].rBrd = rrE->bord;
+ } else {
+ chgts[nCh].rSrc = nullptr;
+ chgts[nCh].rBrd = -1;
+ }
+
+ if (rS->swsData[rB].leftRnd < lastChgtPt) {
+ rS->swsData[rB].leftRnd = lastPointNo;
+ rS->swsData[rB].nextSh = shapeHead;
+ rS->swsData[rB].nextBo = edgeHead;
+ edgeHead = rB;
+ shapeHead = rS;
+ } else {
+ int old = rS->swsData[rB].leftRnd;
+ if (getPoint(old).x[0] > getPoint(lastPointNo).x[0]) {
+ rS->swsData[rB].leftRnd = lastPointNo;
+ }
+ }
+ if (rS->swsData[rB].rightRnd < lastChgtPt) {
+ rS->swsData[rB].rightRnd = lastPointNo;
+ } else {
+ int old = rS->swsData[rB].rightRnd;
+ if (getPoint(old).x[0] < getPoint(lastPointNo).x[0])
+ rS->swsData[rB].rightRnd = lastPointNo;
+ }
+ } else {
+ SweepTree *lE = static_cast < SweepTree * >(lS->swsData[lB].misc);
+ if (lE && lE->elem[RIGHT]) {
+ SweepTree *rlE = static_cast < SweepTree * >(lE->elem[RIGHT]);
+ chgts[nCh].rSrc = rlE->src;
+ chgts[nCh].rBrd = rlE->bord;
+ } else {
+ chgts[nCh].rSrc = nullptr;
+ chgts[nCh].rBrd = -1;
+ }
+ }
+}
+
+// is this a debug function? It's calling localized "printf" ...
+void
+Shape::Validate ()
+{
+ for (int i = 0; i < numberOfPoints(); i++)
+ {
+ pData[i].rx = getPoint(i).x;
+ }
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ eData[i].rdx = getEdge(i).dx;
+ }
+ for (int i = 0; i < numberOfEdges(); i++)
+ {
+ for (int j = i + 1; j < numberOfEdges(); j++)
+ {
+ Geom::Point atx;
+ double atL, atR;
+ if (TesteIntersection (this, this, i, j, atx, atL, atR, false))
+ {
+ printf ("%i %i %f %f di=%f %f dj=%f %f\n", i, j, atx[0],atx[1],getEdge(i).dx[0],getEdge(i).dx[1],getEdge(j).dx[0],getEdge(j).dx[1]);
+ }
+ }
+ }
+ fflush (stdout);
+}
+
+void
+Shape::CheckEdges (int lastPointNo, int lastChgtPt, Shape * a, Shape * b,
+ BooleanOp mod)
+{
+
+ for (auto & chgt : chgts)
+ {
+ if (chgt.type == 0)
+ {
+ Shape *lS = chgt.src;
+ int lB = chgt.bord;
+ lS->swsData[lB].curPoint = chgt.ptNo;
+ }
+ }
+ for (auto & chgt : chgts)
+ {
+// int chLeN=chgts[cCh].ptNo;
+// int chRiN=chgts[cCh].ptNo;
+ if (chgt.src)
+ {
+ Shape *lS = chgt.src;
+ int lB = chgt.bord;
+ Avance (lastPointNo, lastChgtPt, lS, lB, a, b, mod);
+ }
+ if (chgt.osrc)
+ {
+ Shape *rS = chgt.osrc;
+ int rB = chgt.obord;
+ Avance (lastPointNo, lastChgtPt, rS, rB, a, b, mod);
+ }
+ if (chgt.lSrc)
+ {
+ Shape *nSrc = chgt.lSrc;
+ int nBrd = chgt.lBrd;
+ while (nSrc->swsData[nBrd].leftRnd >=
+ lastChgtPt /*&& nSrc->swsData[nBrd].doneTo < lastChgtPt */ )
+ {
+ Avance (lastPointNo, lastChgtPt, nSrc, nBrd, a, b, mod);
+
+ SweepTree *node =
+ static_cast < SweepTree * >(nSrc->swsData[nBrd].misc);
+ if (node == nullptr)
+ break;
+ node = static_cast < SweepTree * >(node->elem[LEFT]);
+ if (node == nullptr)
+ break;
+ nSrc = node->src;
+ nBrd = node->bord;
+ }
+ }
+ if (chgt.rSrc)
+ {
+ Shape *nSrc = chgt.rSrc;
+ int nBrd = chgt.rBrd;
+ while (nSrc->swsData[nBrd].rightRnd >=
+ lastChgtPt /*&& nSrc->swsData[nBrd].doneTo < lastChgtPt */ )
+ {
+ Avance (lastPointNo, lastChgtPt, nSrc, nBrd, a, b, mod);
+
+ SweepTree *node =
+ static_cast < SweepTree * >(nSrc->swsData[nBrd].misc);
+ if (node == nullptr)
+ break;
+ node = static_cast < SweepTree * >(node->elem[RIGHT]);
+ if (node == nullptr)
+ break;
+ nSrc = node->src;
+ nBrd = node->bord;
+ }
+ }
+ }
+}
+
+void
+Shape::Avance (int lastPointNo, int lastChgtPt, Shape * lS, int lB, Shape * /*a*/,
+ Shape * b, BooleanOp mod)
+{
+ double dd = HalfRound (1);
+ bool avoidDiag = false;
+// if ( lastChgtPt > 0 && pts[lastChgtPt-1].y+dd == pts[lastChgtPt].y ) avoidDiag=true;
+
+ bool direct = true;
+ if (lS == b && (mod == bool_op_diff || mod == bool_op_symdiff))
+ direct = false;
+ int lftN = lS->swsData[lB].leftRnd;
+ int rgtN = lS->swsData[lB].rightRnd;
+ if (lS->swsData[lB].doneTo < lastChgtPt)
+ {
+ int lp = lS->swsData[lB].curPoint;
+ if (lp >= 0 && getPoint(lp).x[1] + dd == getPoint(lastChgtPt).x[1])
+ avoidDiag = true;
+ if (lS->eData[lB].rdx[1] == 0)
+ {
+ // tjs de gauche a droite et pas de diagonale
+ if (lS->eData[lB].rdx[0] >= 0)
+ {
+ for (int p = lftN; p <= rgtN; p++)
+ {
+ DoEdgeTo (lS, lB, p, direct, true);
+ lp = p;
+ }
+ }
+ else
+ {
+ for (int p = lftN; p <= rgtN; p++)
+ {
+ DoEdgeTo (lS, lB, p, direct, false);
+ lp = p;
+ }
+ }
+ }
+ else if (lS->eData[lB].rdx[1] > 0)
+ {
+ if (lS->eData[lB].rdx[0] >= 0)
+ {
+
+ for (int p = lftN; p <= rgtN; p++)
+ {
+ if (avoidDiag && p == lftN && getPoint(lftN).x[0] == getPoint(lp).x[0] + dd)
+ {
+ if (lftN > 0 && lftN - 1 >= lastChgtPt
+ && getPoint(lftN - 1).x[0] == getPoint(lp).x[0])
+ {
+ DoEdgeTo (lS, lB, lftN - 1, direct, true);
+ DoEdgeTo (lS, lB, lftN, direct, true);
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, lftN, direct, true);
+ }
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, p, direct, true);
+ }
+ lp = p;
+ }
+ }
+ else
+ {
+
+ for (int p = rgtN; p >= lftN; p--)
+ {
+ if (avoidDiag && p == rgtN && getPoint(rgtN).x[0] == getPoint(lp).x[0] - dd)
+ {
+ if (rgtN < numberOfPoints() && rgtN + 1 < lastPointNo
+ && getPoint(rgtN + 1).x[0] == getPoint(lp).x[0])
+ {
+ DoEdgeTo (lS, lB, rgtN + 1, direct, true);
+ DoEdgeTo (lS, lB, rgtN, direct, true);
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, rgtN, direct, true);
+ }
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, p, direct, true);
+ }
+ lp = p;
+ }
+ }
+ }
+ else
+ {
+ if (lS->eData[lB].rdx[0] >= 0)
+ {
+
+ for (int p = rgtN; p >= lftN; p--)
+ {
+ if (avoidDiag && p == rgtN && getPoint(rgtN).x[0] == getPoint(lp).x[0] - dd)
+ {
+ if (rgtN < numberOfPoints() && rgtN + 1 < lastPointNo
+ && getPoint(rgtN + 1).x[0] == getPoint(lp).x[0])
+ {
+ DoEdgeTo (lS, lB, rgtN + 1, direct, false);
+ DoEdgeTo (lS, lB, rgtN, direct, false);
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, rgtN, direct, false);
+ }
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, p, direct, false);
+ }
+ lp = p;
+ }
+ }
+ else
+ {
+
+ for (int p = lftN; p <= rgtN; p++)
+ {
+ if (avoidDiag && p == lftN && getPoint(lftN).x[0] == getPoint(lp).x[0] + dd)
+ {
+ if (lftN > 0 && lftN - 1 >= lastChgtPt
+ && getPoint(lftN - 1).x[0] == getPoint(lp).x[0])
+ {
+ DoEdgeTo (lS, lB, lftN - 1, direct, false);
+ DoEdgeTo (lS, lB, lftN, direct, false);
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, lftN, direct, false);
+ }
+ }
+ else
+ {
+ DoEdgeTo (lS, lB, p, direct, false);
+ }
+ lp = p;
+ }
+ }
+ }
+ lS->swsData[lB].curPoint = lp;
+ }
+ lS->swsData[lB].doneTo = lastPointNo - 1;
+}
+
+void
+Shape::DoEdgeTo (Shape * iS, int iB, int iTo, bool direct, bool sens)
+{
+ int lp = iS->swsData[iB].curPoint;
+ int ne = -1;
+ if (sens)
+ {
+ if (direct)
+ ne = AddEdge (lp, iTo);
+ else
+ ne = AddEdge (iTo, lp);
+ }
+ else
+ {
+ if (direct)
+ ne = AddEdge (iTo, lp);
+ else
+ ne = AddEdge (lp, iTo);
+ }
+ if (ne >= 0 && _has_back_data)
+ {
+ ebData[ne].pathID = iS->ebData[iB].pathID;
+ ebData[ne].pieceID = iS->ebData[iB].pieceID;
+ if (iS->eData[iB].length < 0.00001)
+ {
+ ebData[ne].tSt = ebData[ne].tEn = iS->ebData[iB].tSt;
+ }
+ else
+ {
+ double bdl = iS->eData[iB].ilength;
+ Geom::Point bpx = iS->pData[iS->getEdge(iB).st].rx;
+ Geom::Point bdx = iS->eData[iB].rdx;
+ Geom::Point psx = getPoint(getEdge(ne).st).x;
+ Geom::Point pex = getPoint(getEdge(ne).en).x;
+ Geom::Point psbx=psx-bpx;
+ Geom::Point pebx=pex-bpx;
+ double pst = dot(psbx,bdx) * bdl;
+ double pet = dot(pebx,bdx) * bdl;
+ pst = iS->ebData[iB].tSt * (1 - pst) + iS->ebData[iB].tEn * pst;
+ pet = iS->ebData[iB].tSt * (1 - pet) + iS->ebData[iB].tEn * pet;
+ ebData[ne].tEn = pet;
+ ebData[ne].tSt = pst;
+ }
+ }
+ iS->swsData[iB].curPoint = iTo;
+ if (ne >= 0)
+ {
+ int cp = iS->swsData[iB].firstLinkedPoint;
+ swsData[ne].firstLinkedPoint = iS->swsData[iB].firstLinkedPoint;
+ while (cp >= 0)
+ {
+ pData[cp].askForWindingB = ne;
+ cp = pData[cp].nextLinkedPoint;
+ }
+ iS->swsData[iB].firstLinkedPoint = -1;
+ }
+}