Ejemplo n.º 1
0
    // Generates a new polygon by dragging a polygon through an angle, and taking all the points it
    // touched (and a few extras for overestimation)
    // Only valid for convex polygons, and small rotations (20 degrees or less)
    // stroke from theta1 to theta2
    public static Polygon strokeRot(double theta1, double theta2, Polygon poly) {
      Polygon poly1 = mul(Mat.rotation(theta1), poly);
      Polygon poly2 = mul(Mat.rotation(theta2), poly);
      Polygon stroked = combine(poly1, poly2);
      ArrayList<Mat> cornerVerts;
      Polygon corner;
      int thisVertex, prevVertex, nextVertex;
      Mat origin = Mat.encodePoint(0, 0);
      Mat cornerVert1a, cornerVert1b;
      Mat cornerVert2a, cornerVert2b;
      double actualDist, desiredDist;
      Mat cornerTransform;
      for (thisVertex = 0; thisVertex < poly.vertices.size(); thisVertex++) {
        if (thisVertex == 0) {
          prevVertex = poly.vertices.size() - 1;
        } else {
          prevVertex = thisVertex - 1;
        }

        if (thisVertex == poly.vertices.size() - 1) {
          nextVertex = 0;
        } else {
          nextVertex = thisVertex + 1;
        }

        cornerVerts = new ArrayList<Mat>();
        cornerVerts.add(poly2.vertices.get(nextVertex));
        cornerVerts.add(origin);
        cornerVerts.add(poly1.vertices.get(prevVertex));

        cornerVert1a = poly1.vertices.get(thisVertex);
        cornerVert2a = poly2.vertices.get(thisVertex);

        actualDist = ptSegDistance(cornerVert1a, cornerVert2a, origin);
        desiredDist = Mat.dist(cornerVert1a, Mat.encodePoint(0, 0));

        cornerTransform = Mat.mul(desiredDist / actualDist, Mat.eye(4));
        cornerVert1b = Mat.mul(cornerTransform, cornerVert1a);
        cornerVert2b = Mat.mul(cornerTransform, cornerVert2a);

        cornerVert1b =
            lineSegIntersection(
                cornerVert1b, cornerVert2b, poly1.vertices.get(prevVertex), cornerVert1a);
        cornerVert2b =
            lineSegIntersection(
                cornerVert1b, cornerVert2b, poly2.vertices.get(nextVertex), cornerVert2a);

        cornerVerts.add(cornerVert1b);
        cornerVerts.add(cornerVert2b);

        corner = new Polygon(cornerVerts);
        stroked = combine(stroked, corner);
      }

      return stroked;
    }
Ejemplo n.º 2
0
    public static Mat lineSegIntersection(Mat e00, Mat e01, Mat e10, Mat e11) {
      double x0 = e00.data[0][0];
      double y0 = e00.data[1][0];
      double x1 = e10.data[0][0];
      double y1 = e10.data[1][0];

      double x, y;
      double m0, m1;
      if (x0 == e01.data[0][0]) {
        m1 = (y1 - e11.data[1][0]) / (x1 - e11.data[0][0]);

        x = x0;
        y = m1 * (x - x1) + y1;
      } else if (x1 == e11.data[0][0]) {
        m0 = (y0 - e01.data[1][0]) / (x0 - e01.data[0][0]);

        x = x1;
        y = m0 * (x - x0) + y0;
      } else {
        m0 = (y0 - e01.data[1][0]) / (x0 - e01.data[0][0]);
        m1 = (y1 - e11.data[1][0]) / (x1 - e11.data[0][0]);

        // System.err.println("m0 = " + m0);
        // System.err.println("m1 = " + m1);

        x = (m0 * x0 - m1 * x1 - y0 + y1) / (m0 - m1);
        y = m1 * (x - x1) + y1;

        // System.err.println("x = " + x);
        // System.err.println("y = " + y);
      }
      return Mat.encodePoint(x, y);
    }
Ejemplo n.º 3
0
    // Generates a new polygon by dragging a polygon by a vector and taking all the points it
    // touched.
    public static Polygon stroke(double x, double y, Polygon poly) {
      Polygon polyTrans = mul(Mat.translation(x, y), poly);
      ArrayList<Mat> vertices = new ArrayList<Mat>();
      ArrayList<TreeSet<Integer>> edgesTo = new ArrayList<TreeSet<Integer>>();
      int size = poly.vertices.size();

      // The list of possible vertices of the extrusion
      vertices.addAll(poly.vertices);
      vertices.addAll(polyTrans.vertices);

      // pre-compute some information that will make it easy to find the actual perimeter of the
      // extrusion
      for (int i = 0; i < 2 * size; i++) {
        edgesTo.add(new TreeSet<Integer>());
      }

      for (int i = 0; i < size; i++) {
        edgesTo.get(i).add(new Integer((i + 1) % size));
        edgesTo.get((i + 1) % size).add(new Integer(i));

        edgesTo.get(i + size).add(new Integer(((i + 1) % size) + size));
        edgesTo.get(((i + 1) % size) + size).add(new Integer(i + size));

        edgesTo.get(i).add(new Integer(i + size));
        edgesTo.get(i + size).add(new Integer(i));
      }

      return perimeter(vertices, edgesTo);
    }
Ejemplo n.º 4
0
 // Transform a polygon by a matrix
 public static Polygon mul(Mat matrix, Polygon poly) {
   ArrayList<Mat> newVertices = new ArrayList<Mat>();
   for (Mat vertex : poly.vertices) {
     newVertices.add(Mat.mul(matrix, vertex));
   }
   return new Polygon(newVertices);
 }
Ejemplo n.º 5
0
 public void addObstacle(PolygonObstacle obstacle) {
   ArrayList<Mat> vertices = new ArrayList<Mat>();
   for (Point2D.Double vert : obstacle.getVertices()) {
     vertices.add(Mat.encodePoint(vert.x, vert.y));
   }
   addObstacle(new Polygon(vertices));
 }
Ejemplo n.º 6
0
 // assumes that there will be no enclosed empty spaces in the result, and that the result will
 // be contiguous, and that everything is convex
 public static Polygon minkowskiSumSimple(Polygon poly1, Polygon poly2) {
   ArrayList<Mat> verts = new ArrayList<Mat>();
   for (Mat v1 : poly1.vertices) {
     for (Mat v2 : poly2.vertices) {
       verts.add(Mat.add(v1, v2));
     }
   }
   ArrayList<Point2D.Double> points = new ArrayList<Point2D.Double>();
   for (Mat v : verts) {
     points.add(new Point2D.Double(v.data[0][0], v.data[1][0]));
   }
   PolygonObstacle po = GeomUtils.convexHull(points);
   verts = new ArrayList<Mat>();
   for (Point2D.Double vert : po.getVertices()) {
     verts.add(Mat.encodePoint(vert.x, vert.y));
   }
   return new Polygon(verts);
 }
Ejemplo n.º 7
0
  // occupancy grid is indexed from (xMin, yMin)
  public boolean[][] getOccupancyGrid(int nCellsLinear) {
    System.err.println("GOT HERE YO!");
    int i, j;
    double xLow, xHigh, yLow, yHigh;
    double maxDimension = Math.max(xMax - xMin, yMax - yMin);
    double resolutionLinear = maxDimension / nCellsLinear;
    Polygon resolutionCellSpace;
    resolutionCellSpace =
        new Polygon(
            Arrays.asList(
                Mat.encodePoint(-1 * resolutionLinear / 2, -1 * resolutionLinear / 2),
                Mat.encodePoint(-1 * resolutionLinear / 2, resolutionLinear / 2),
                Mat.encodePoint(resolutionLinear / 2, resolutionLinear / 2),
                Mat.encodePoint(resolutionLinear / 2, -1 * resolutionLinear / 2)));
    reflectedRobot = Polygon.minkowskiSumSimple(reflectedRobot, resolutionCellSpace);
    ArrayList<Polygon> csObstacles = getCSObstacles();
    System.err.println("GOT HERE as well.");
    boolean[][] occupancyGrid = new boolean[nCellsLinear][nCellsLinear];
    for (i = 0; i < nCellsLinear; i++) {
      xLow = xMin + resolutionLinear * i;
      xHigh = xLow + resolutionLinear;
      for (j = 0; j < nCellsLinear; j++) {
        yLow = yMin + resolutionLinear * j;
        yHigh = yLow + resolutionLinear;

        if (i == 9 && j == 6) {
          System.err.print("(" + i + ", " + j + ")     ");
          System.err.println("(" + ((xLow + xHigh) / 2) + ", " + ((yLow + yHigh) / 2) + ")");
        }

        occupancyGrid[i][j] = true;
        for (Polygon obstacle : csObstacles) {
          if (Polygon.pointInPolygon(
              obstacle, Mat.encodePoint((xLow + xHigh) / 2, (yLow + yHigh) / 2))) {
            occupancyGrid[i][j] = false;
            break;
          }
        }
      }
    }

    System.err.println("GOT HERE TOO!");
    return occupancyGrid;
  }
Ejemplo n.º 8
0
  // occupancy grid is indexed from (xMin, yMin, 0)
  public boolean[][][] getOccupancyGrid(int nCellsLinear, int nCellsAngular) {
    int i, j, k;
    double xLow, xHigh, yLow, yHigh, thetaLow, thetaHigh;
    double maxDimension = Math.max(xMax - xMin, yMax - yMin);
    double resolutionLinear = maxDimension / nCellsLinear;
    double resolutionAngular = 2 * Math.PI / nCellsAngular;
    Polygon strokedRobot;
    ArrayList<Polygon> thetaObstacles;
    Polygon resolutionCellSpace;
    boolean[][][] occupancyGrid = new boolean[nCellsLinear][nCellsLinear][nCellsAngular];
    for (i = 0; i < nCellsLinear; i++) {
      xLow = xMin + resolutionLinear * i;
      xHigh = xLow + resolutionLinear;
      for (j = 0; j < nCellsLinear; j++) {
        yLow = yMin + resolutionLinear * j;
        yHigh = yLow + resolutionLinear;
        for (k = 0; k < nCellsAngular; k++) {
          thetaLow = resolutionAngular * k;
          thetaHigh = thetaLow + resolutionAngular;

          resolutionCellSpace =
              new Polygon(
                  Arrays.asList(
                      Mat.encodePoint(xLow, yLow),
                      Mat.encodePoint(xLow, yHigh),
                      Mat.encodePoint(xHigh, yHigh),
                      Mat.encodePoint(xHigh, yLow)));

          strokedRobot = Polygon.strokeRot(thetaLow, thetaHigh, reflectedRobot);
          occupancyGrid[i][j][k] = true;
          for (Polygon obstacle : obstacles) {
            if (Polygon.polygonsIntersect(
                resolutionCellSpace, Polygon.minkowskiSum(obstacle, strokedRobot))) {
              occupancyGrid[i][j][k] = false;
              break;
            }
          }
        }
      }
    }

    return occupancyGrid;
  }
Ejemplo n.º 9
0
 public static void tests() {
   System.err.println("HEY!");
   Mat p0 = Mat.encodePoint(0, 0);
   Mat p1 = Mat.encodePoint(1, .1);
   Mat p2 = Mat.encodePoint(.1, 1);
   Mat p3 = Mat.encodePoint(-1, -.1);
   Mat p4 = Mat.encodePoint(-.1, -1);
   Mat p5 = Mat.encodePoint(0.0001, 0);
   Mat p6 = Mat.encodePoint(-0.0001, 0);
   if (!lineSegIntersect(p1, p3, p2, p4)) {
     try {
       throw new Exception();
     } catch (Exception e) {
       e.printStackTrace();
       System.err.println("hey there");
       System.exit(1);
     }
   }
   if (lineSegIntersect(p1, p4, p2, p3)) {
     try {
       throw new Exception();
     } catch (Exception e) {
       e.printStackTrace();
       System.err.println("hey there");
       System.exit(1);
     }
   }
   if (lineSegIntersect(p1, p5, p2, p4)) {
     try {
       throw new Exception();
     } catch (Exception e) {
       e.printStackTrace();
       System.err.println("hey there");
       System.exit(1);
     }
   }
   if (!lineSegIntersect(p1, p6, p2, p4)) {
     try {
       throw new Exception();
     } catch (Exception e) {
       e.printStackTrace();
       System.err.println("hey there");
       System.exit(1);
     }
   }
   Mat inter = lineSegIntersection(p1, p3, p2, p4);
   if (inter.data[0][0] != 0 || inter.data[1][0] != 0) {
     try {
       throw new Exception();
     } catch (Exception e) {
       e.printStackTrace();
       System.err.println("hey there");
       System.exit(1);
     }
   }
 }
Ejemplo n.º 10
0
 // assumes that there will be no enclosed empty spaces in the result, and that the result will
 // be contiguous.
 public static Polygon minkowskiSum(Polygon poly1, Polygon poly2) {
   Mat prevVertex = poly1.vertices.get(poly1.vertices.size() - 1);
   Polygon sum = poly1;
   for (Mat vertex : poly1.vertices) {
     sum =
         combine(
             sum,
             mul(
                 Mat.translation(vertex.data[0][0], vertex.data[1][0]),
                 stroke(
                     prevVertex.data[0][0] - vertex.data[0][0],
                     prevVertex.data[1][0] - vertex.data[1][0],
                     poly2)));
     prevVertex = vertex;
   }
   return sum;
 }
Ejemplo n.º 11
0
    public static double ptSegDistance(Mat e0, Mat e1, Mat p) {
      double x0 = e0.data[0][0];
      double y0 = e0.data[1][0];
      double x1 = e1.data[0][0];
      double y1 = e1.data[1][0];
      double xp = p.data[0][0];
      double yp = p.data[1][0];

      e0 = new Mat(2, 1);
      e0.data[0][0] = x0;
      e0.data[1][0] = y0;
      e1 = new Mat(2, 1);
      e1.data[0][0] = x1;
      e1.data[1][0] = y1;
      p = new Mat(2, 1);
      p.data[0][0] = xp;
      p.data[1][0] = yp;

      e1 = Mat.sub(e1, e0);
      p = Mat.sub(p, e0);
      e0.data[0][0] = 0;
      e0.data[1][0] = 0;

      Mat e0b = Mat.sub(e0, e1);
      Mat pb = Mat.sub(p, e1);
      Mat e1b = new Mat(2, 1);
      e1b.data[0][0] = 0;
      e1b.data[1][0] = 0;

      if (Mat.dot(e1, p) > 0) {
        if (Mat.dot(e0b, pb) > 0) {
          Mat e1u = Mat.mul(1 / Mat.l2(e1), e1);
          return Mat.dist(p, Mat.mul(Mat.dot(e1u, p), e1u));
        } else {
          return Mat.dist(p, e1);
        }
      } else {
        return Mat.dist(p, e0);
      }
    }
Ejemplo n.º 12
0
 public static boolean ptsEqual(Mat p0, Mat p1, double tolerance) {
   return tolerance > Mat.dist(p0, p1);
 }
Ejemplo n.º 13
0
  private void constructor(
      Polygon robot,
      double boundaryXMin,
      double boundaryYMin,
      double boundaryXMax,
      double boundaryYMax) {
    Polygon.tests();
    cSpaceObstacles.setWrap(-1 * Math.PI, Math.PI);

    xMin = boundaryXMin;
    yMin = boundaryYMin;
    xMax = boundaryXMax;
    yMax = boundaryYMax;

    reflectedRobot = Polygon.mul(Mat.mul(-1, Mat.eye(4)), robot);
    ArrayList<List<Mat>> boundaries = new ArrayList<List<Mat>>();

    boundaries.add(
        Arrays.asList(
            Mat.encodePoint(xMin - 0, yMin - 1),
            Mat.encodePoint(xMin - 0, yMax + 1),
            Mat.encodePoint(xMin - 1, yMax + 1),
            Mat.encodePoint(xMin - 1, yMin - 1)));

    boundaries.add(
        Arrays.asList(
            Mat.encodePoint(xMax + 0, yMin - 1),
            Mat.encodePoint(xMax + 0, yMax + 1),
            Mat.encodePoint(xMax + 1, yMax + 1),
            Mat.encodePoint(xMax + 1, yMin - 1)));

    boundaries.add(
        Arrays.asList(
            Mat.encodePoint(xMin - 1, yMin - 0),
            Mat.encodePoint(xMax + 1, yMin - 0),
            Mat.encodePoint(xMax + 1, yMin - 1),
            Mat.encodePoint(xMin - 1, yMin - 1)));

    boundaries.add(
        Arrays.asList(
            Mat.encodePoint(xMin - 1, yMax + 0),
            Mat.encodePoint(xMax + 1, yMax + 0),
            Mat.encodePoint(xMax + 1, yMax + 1),
            Mat.encodePoint(xMin - 1, yMax + 1)));

    for (List<Mat> boundary : boundaries) {
      addObstacle(new Polygon(boundary));
    }
  }
Ejemplo n.º 14
0
    // take the union of two polygons, assuming no enclosed empty spaces, and that the result will
    // be contiguous.
    public static Polygon combine(Polygon poly1, Polygon poly2) {
      ArrayList<Mat> vertices = new ArrayList<Mat>();
      ArrayList<TreeSet<Integer>> edgesTo = new ArrayList<TreeSet<Integer>>();
      int sizePoly1 = poly1.vertices.size();
      int sizePoly2 = poly2.vertices.size();
      int size = sizePoly1 + sizePoly2;
      boolean done;

      Publisher<GUISegmentMsg> segmentPub =
          node.newPublisher("/gui/Segment", "lab5_msgs/GUISegmentMsg");
      Publisher<GUIEraseMsg> erasePub = node.newPublisher("/gui/Erase", "lab5_msgs/GUIEraseMsg");
      // erasePub.publish(new GUIEraseMsg());
      GUISegmentMsg segmentPlot = new GUISegmentMsg();
      ColorMsg segmentPlotColor = new ColorMsg();

      // add all the vertices in both polygons
      vertices.addAll(poly1.vertices);
      vertices.addAll(poly2.vertices);

      for (int i = 0; i < size; i++) {
        edgesTo.add(new TreeSet<Integer>());
      }

      // add all the edges in both polygons
      for (int i = 0; i < sizePoly1; i++) {
        edgesTo.get(i).add(new Integer((i + 1) % sizePoly1));
        edgesTo.get((i + 1) % sizePoly1).add(new Integer(i));
      }
      for (int i = 0; i < sizePoly2; i++) {
        edgesTo.get(i + sizePoly1).add(new Integer(((i + 1) % sizePoly2) + sizePoly1));
        edgesTo.get(((i + 1) % sizePoly2) + sizePoly1).add(new Integer(i + sizePoly1));
      }

      System.err.println(vertices);
      System.err.println(edgesTo);

      segmentPlotColor.r = 255;
      segmentPlotColor.g = 0;
      segmentPlotColor.b = 0;
      segmentPlot.color = segmentPlotColor;
      for (int e0 = 0; e0 < size; e0++) {
        for (int e1 : edgesTo.get(e0)) {
          double[] xyStart = Mat.decodePoint(vertices.get(e0));
          double[] xyEnd = Mat.decodePoint(vertices.get(e1));
          segmentPlot.startX = xyStart[0];
          segmentPlot.startY = xyStart[1];
          segmentPlot.endX = xyEnd[0];
          segmentPlot.endY = xyEnd[1];
          segmentPub.publish(segmentPlot);
        }
      }

      // find and merge colocated points
      done = false;
      while (!done) {
        done = true;
        checkFMCP:
        {
          for (int p0 = 0; p0 < size; p0++) {
            for (int p1 = 0; p1 < size; p1++) {
              if (p0 != p1) {
                if (ptsEqual(vertices.get(p0), vertices.get(p1))) {
                  //						System.err.println("found two colocated: " + p0 + " " + p1);
                  // System.err.println(edgesTo);
                  edgesTo.get(p0).addAll(edgesTo.get(p1));
                  edgesTo.get(p0).remove(p0);
                  vertices.remove(p1);
                  edgesTo.remove(p1);
                  size--;

                  for (int e0 = 0; e0 < size; e0++) {
                    if (edgesTo.get(e0).contains(new Integer(p1))) {
                      edgesTo.get(e0).remove(new Integer(p1));
                      edgesTo.get(e0).add(new Integer(p0));
                    }
                    // System.err.println("e0: " + e0);
                    // System.err.println(edgesTo.get(e0));
                    TreeSet<Integer> head = new TreeSet(edgesTo.get(e0).headSet(new Integer(p1)));
                    // System.err.println(head);
                    for (Integer e1 : edgesTo.get(e0).tailSet(new Integer(p1))) {
                      head.add(e1 - 1);
                    }
                    head.remove(e0);
                    // System.err.println(head);
                    edgesTo.set(e0, head);
                    // System.err.println(edgesTo.get(e0));
                  }

                  done = false;
                  // System.err.println(edgesTo);
                  break checkFMCP;
                }
              }
            }
          }
        }
      }
      System.err.println("merged points");
      System.err.println(edgesTo);

      /*segmentPlotColor.r = 0;
      segmentPlotColor.g = 0;
      segmentPlotColor.b = 255;
      segmentPlot.color = segmentPlotColor;
      for (int e0 = 0; e0 < size; e0++){
      	for (int e1 : edgesTo.get(e0)) {
      		double[] xyStart = Mat.decodePoint(vertices.get(e0));
      		double[] xyEnd   = Mat.decodePoint(vertices.get(e1));
      		segmentPlot.startX = xyStart[0];
      		segmentPlot.startY = xyStart[1];
      		segmentPlot.endX = xyEnd[0];
      		segmentPlot.endY = xyEnd[1];
      		segmentPub.publish(segmentPlot);
      	}
      }*/

      // find and split edges bisected by points
      done = false;
      while (!done) {
        done = true;
        checkFSEBP:
        {
          for (int e0 = 0; e0 < size; e0++) {
            for (int e1 : edgesTo.get(e0)) {
              for (int p = 0; p < size; p++) {
                if (e0 != p && e1 != p) {
                  if (ptSegIntersect(vertices.get(e0), vertices.get(e1), vertices.get(p))) {
                    edgesTo.get(p).add(new Integer(e0));
                    edgesTo.get(p).add(new Integer(e1));

                    edgesTo.get(e0).remove(new Integer(e1));
                    edgesTo.get(e0).add(new Integer(p));

                    edgesTo.get(e1).remove(new Integer(e0));
                    edgesTo.get(e1).add(new Integer(p));

                    done = false;
                    break checkFSEBP;
                  }
                }
              }
            }
          }
        }
      }
      System.err.println("split edges on points");
      System.err.println(edgesTo);

      System.err.println("GOT HERE!");

      int iters = 0;
      done = false;
      while (!done) {
        // find and split intersecting edges
        System.err.println("size: " + size);
        done = true;
        checkFSIE:
        {
          for (int e00 = 0; e00 < size; e00++) {
            for (int e10 = 0; e10 < size; e10++) {
              if (e00 != e10) {
                for (int e01 : new TreeSet<Integer>(edgesTo.get(e00))) {
                  if (e01 != e10 && e01 != e00) {
                    for (int e11 : new TreeSet<Integer>(edgesTo.get(e10))) {
                      if (e11 != e00 && e11 != e01 && e11 != e10) {
                        if (lineSegIntersect(
                            vertices.get(e00),
                            vertices.get(e01),
                            vertices.get(e10),
                            vertices.get(e11))) {
                          // System.err.println("intersectors for iter " + iters);
                          // System.err.println(e00);
                          // System.err.println(edgesTo.get(e00));
                          // Mat.print(System.err, vertices.get(e00));
                          // System.err.println(e01);
                          // System.err.println(edgesTo.get(e01));
                          // Mat.print(System.err, vertices.get(e01));
                          // System.err.println(e10);
                          // System.err.println(edgesTo.get(e10));
                          // Mat.print(System.err, vertices.get(e10));
                          // System.err.println(e11);
                          // System.err.println(edgesTo.get(e11));
                          // Mat.print(System.err, vertices.get(e11));
                          if (iters > 10000) {
                            // F**K!
                            try {
                              throw new Exception();
                            } catch (Exception e) {
                              e.printStackTrace();
                              System.err.println("hey there");
                              System.exit(1);
                            }
                          }
                          iters++;

                          Mat newVertex =
                              lineSegIntersection(
                                  vertices.get(e00),
                                  vertices.get(e01),
                                  vertices.get(e10),
                                  vertices.get(e11));

                          if (ptsEqual(newVertex, vertices.get(e00))) {
                            edgesTo.get(e10).remove(new Integer(e11));
                            edgesTo.get(e10).add(new Integer(e00));
                            edgesTo.get(e00).add(new Integer(e10));

                            edgesTo.get(e11).remove(new Integer(e10));
                            edgesTo.get(e11).add(new Integer(e00));
                            edgesTo.get(e00).add(new Integer(e11));
                          } else if (ptsEqual(newVertex, vertices.get(e01))) {
                            edgesTo.get(e10).remove(new Integer(e11));
                            edgesTo.get(e10).add(new Integer(e01));
                            edgesTo.get(e01).add(new Integer(e10));

                            edgesTo.get(e11).remove(new Integer(e10));
                            edgesTo.get(e11).add(new Integer(e01));
                            edgesTo.get(e01).add(new Integer(e11));
                          } else if (ptsEqual(newVertex, vertices.get(e10))) {
                            edgesTo.get(e00).remove(new Integer(e01));
                            edgesTo.get(e00).add(new Integer(e10));
                            edgesTo.get(e10).add(new Integer(e00));

                            edgesTo.get(e01).remove(new Integer(e00));
                            edgesTo.get(e01).add(new Integer(e10));
                            edgesTo.get(e10).add(new Integer(e01));
                          } else if (ptsEqual(newVertex, vertices.get(e11))) {
                            edgesTo.get(e00).remove(new Integer(e01));
                            edgesTo.get(e00).add(new Integer(e11));
                            edgesTo.get(e11).add(new Integer(e00));

                            edgesTo.get(e01).remove(new Integer(e00));
                            edgesTo.get(e01).add(new Integer(e11));
                            edgesTo.get(e11).add(new Integer(e01));
                          } else {
                            vertices.add(newVertex);

                            edgesTo.add(new TreeSet<Integer>());

                            edgesTo.get(size).add(new Integer(e00));
                            edgesTo.get(size).add(new Integer(e01));
                            edgesTo.get(size).add(new Integer(e10));
                            edgesTo.get(size).add(new Integer(e11));

                            edgesTo.get(e00).remove(new Integer(e01));
                            edgesTo.get(e00).add(new Integer(size));

                            edgesTo.get(e01).remove(new Integer(e00));
                            edgesTo.get(e01).add(new Integer(size));

                            edgesTo.get(e10).remove(new Integer(e11));
                            edgesTo.get(e10).add(new Integer(size));

                            edgesTo.get(e11).remove(new Integer(e10));
                            edgesTo.get(e11).add(new Integer(size));

                            size++;
                          }
                          done = false;
                          break checkFSIE;
                        }
                      }
                    }
                  }
                }
              }
            }
          }
        }
        System.err.println("split edges on edges");
        System.err.println(edgesTo);
      }

      System.err.println("GOT HERE TOO!");

      System.err.println("begin vertices");
      for (Mat vertex : vertices) {
        Mat.print(System.err, vertex);
      }
      System.err.println("end vertices");
      System.err.println(edgesTo);

      return perimeter(vertices, edgesTo);
    }