private Wire[] createWireList() { int[] ids = provider.getDomainIDs(); LOGGER.finest("computing wires for " + ids.length + " domain."); int numberOfWire = 0; for (int i = 0; i < ids.length; i++) { FDDomain domain = (FDDomain) provider.getDomain(ids[i]); numberOfWire += domain.getNumberOfXWire(); numberOfWire += domain.getNumberOfYWire(); numberOfWire += domain.getNumberOfZWire(); } LOGGER.finest("found " + numberOfWire + " wires."); Wire[] wires = new Wire[numberOfWire]; int iw = 0; for (int i = 0; i < ids.length; i++) { FDDomain domain = (FDDomain) provider.getDomain(ids[i]); Iterator<int[]> it = domain.getXWireIterator(); while (it.hasNext()) { int[] indices = it.next(); Wire w = new WireX(); w.position1 = indices[1]; w.position2 = indices[2]; w.min = indices[0]; w.max = indices[3]; wires[iw] = w; iw++; } domain = (FDDomain) provider.getDomain(ids[i]); it = domain.getYWireIterator(); while (it.hasNext()) { int[] indices = it.next(); Wire w = new WireY(); w.position1 = indices[0]; w.position2 = indices[2]; w.min = indices[1]; w.max = indices[3]; wires[iw] = w; iw++; } domain = (FDDomain) provider.getDomain(ids[i]); it = domain.getZWireIterator(); while (it.hasNext()) { int[] indices = it.next(); Wire w = new WireZ(); w.position1 = indices[0]; w.position2 = indices[1]; w.min = indices[2]; w.max = indices[3]; wires[iw] = w; iw++; } } return wires; }
public void update() { removeAllChildren(); setPickable(true); // currentSelection = new HashSet(); allEdgeShapes = new ArrayList<Shape3D>(); grid = new float[3][]; grid[0] = new float[provider.getXGridCount()]; grid[1] = new float[provider.getYGridCount()]; grid[2] = new float[provider.getZGridCount()]; for (int i = 0; i < grid[0].length; i++) { grid[0][i] = (float) provider.getXGrid(i); } for (int i = 0; i < grid[1].length; i++) { grid[1][i] = (float) provider.getYGrid(i); } for (int i = 0; i < grid[2].length; i++) { grid[2][i] = (float) provider.getZGrid(i); } makeGroups(); makeWires(); }
protected void makeGroups() { int totalQuads = 0; int totalInternalEdges = 0; int totalExternalEdges = 0; // loop over each group // loop over each group int[] groupID = provider.getDomainIDs(); for (int g = 0; g < groupID.length; ++g) { LOGGER.finest("generating java3d tree for group number " + groupID[g]); // Set of EdgeLine objects. Overlapping edges on the same line are // merged together HashMap<EdgeLine, EdgeLine> externalEdges = new HashMap<EdgeLine, EdgeLine>(); // Same trick for internal edges. HashMap<EdgeLine, EdgeLine> internalEdges = new HashMap<EdgeLine, EdgeLine>(); FDDomain fdDomain = (FDDomain) provider.getDomain(groupID[g]); baseColor.put(new Integer(g), fdDomain.getColor()); Plate[] plates = domainToPlates(fdDomain); if (plates.length == 0) continue; // Create plates for this group FloatBuffer nioCoords = ByteBuffer.allocateDirect(plates.length * 4 * 3 * 4) .order(ByteOrder.nativeOrder()) .asFloatBuffer(); FloatBuffer nioColors = ByteBuffer.allocateDirect(plates.length * 4 * 3 * 4) .order(ByteOrder.nativeOrder()) .asFloatBuffer(); float[] baseColor = getColorForOrder(g, 0); // System.out.println(baseColor[0]+" "+baseColor[1]+" "+baseColor[2]); for (int np = 0; np < plates.length; ++np) { Plate p = plates[np]; // put coordinates nioCoords.put(p.getCoordinates(grid)); // put colors for the 4 vertices nioColors.put(baseColor); nioColors.put(baseColor); nioColors.put(baseColor); nioColors.put(baseColor); // Merge external edges addEdge(externalEdges, getLine(p, 2, p.min1), p.min2, p.max2); addEdge(externalEdges, getLine(p, 2, p.max1), p.min2, p.max2); addEdge(externalEdges, getLine(p, 1, p.min2), p.min1, p.max1); addEdge(externalEdges, getLine(p, 1, p.max2), p.min1, p.max1); // Merge internal edges for (int i = p.min1 + 1; i < p.max1; ++i) addEdge(internalEdges, getLine(p, 2, i), p.min2, p.max2); for (int j = p.min2 + 1; j < p.max2; ++j) addEdge(internalEdges, getLine(p, 1, j), p.min1, p.max1); } // use by reference array of colors => fast to change! QuadArray qa = new NioQuadArray(plates.length * 4, GeometryArray.COORDINATES | GeometryArray.COLOR_3); qa.setCoordRefBuffer(new J3DBuffer(nioCoords)); qa.setColorRefBuffer(new J3DBuffer(nioColors)); qa.setCapability(GeometryArray.ALLOW_COLOR_WRITE); qa.setCapabilityIsFrequent(GeometryArray.ALLOW_COLOR_WRITE); Appearance a = new Appearance(); PolygonAttributes pa = new PolygonAttributes(PolygonAttributes.POLYGON_FILL, PolygonAttributes.CULL_NONE, 0); pa.setPolygonOffset(1); pa.setPolygonOffsetFactor(1); a.setPolygonAttributes(pa); Shape3D s3d = new Shape3D(qa, a); PickTool.setCapabilities(s3d, PickTool.INTERSECT_FULL); s3d.setCapability(Shape3D.ALLOW_APPEARANCE_READ); s3d.setCapability(Shape3D.ALLOW_APPEARANCE_WRITE); s3d.setCapability(Node.ALLOW_PICKABLE_READ); s3d.setCapability(Node.ALLOW_PICKABLE_WRITE); s3d.setPickable(true); s3d.setUserData(new BehindShape(s3d, plates, g)); this.addChild(s3d); // Create edge shapes directly, don't make them appear in graph int nInternalEdges = 0; for (Iterator<EdgeLine> it = internalEdges.keySet().iterator(); it.hasNext(); ) { EdgeLine el = it.next(); nInternalEdges += el.getNumberOfEdges(); } if (nInternalEdges > 0) { DoubleBuffer nioInternalEdges = ByteBuffer.allocateDirect(nInternalEdges * 2 * 3 * 8) .order(ByteOrder.nativeOrder()) .asDoubleBuffer(); // create edge coords for (Iterator<EdgeLine> it = internalEdges.keySet().iterator(); it.hasNext(); ) { EdgeLine el = it.next(); nioInternalEdges.put(el.getCoords(grid)); } LineArray la = new NioLineArray(nInternalEdges * 2, GeometryArray.COORDINATES | GeometryArray.COLOR_3); la.setCoordRefBuffer(new J3DBuffer(nioInternalEdges)); int colSize = nInternalEdges * 2 * 3; FloatBuffer nioInternalColors = ByteBuffer.allocateDirect(colSize * 4).order(ByteOrder.nativeOrder()).asFloatBuffer(); float[] colors = getColorForOrder(g, 2); for (int i = 0; i < colSize; i += 3) nioInternalColors.put(colors); la.setColorRefBuffer(new J3DBuffer(nioInternalColors)); la.setUserData(new int[] {g, 2}); a = new Appearance(); // pa = new PolygonAttributes(PolygonAttributes.POLYGON_LINE, // PolygonAttributes.CULL_NONE, 0); // pa.setPolygonOffset(4); // pa.setPolygonOffsetFactor(4); // a.setPolygonAttributes(pa); // LineAttributes lat = new LineAttributes(); // lat.setLineAntialiasingEnable(true); // a.setLineAttributes(lat); // RenderingAttributes ra = new RenderingAttributes(); // ra.setAlphaTestFunction(RenderingAttributes.GREATER); // ra.setAlphaTestValue(0.5f); // a.setRenderingAttributes(ra); s3d = new Shape3D(la, a); PickTool.setCapabilities(s3d, PickTool.INTERSECT_FULL); s3d.setCapability(Shape3D.ALLOW_APPEARANCE_READ); s3d.setCapability(Shape3D.ALLOW_APPEARANCE_WRITE); s3d.setCapability(Node.ALLOW_PICKABLE_READ); s3d.setCapability(Node.ALLOW_PICKABLE_WRITE); s3d.setPickable(false); // by default, see actions s3d.setUserData(this); // this object will handle edges this.addChild(s3d); allEdgeShapes.add(s3d); } // Now, create external edge int nExternalEdges = 0; for (Iterator<EdgeLine> it = externalEdges.keySet().iterator(); it.hasNext(); ) { EdgeLine el = it.next(); nExternalEdges += el.getNumberOfEdges(); } if (nExternalEdges > 0) { DoubleBuffer nioExternalEdges = ByteBuffer.allocateDirect(nExternalEdges * 2 * 3 * 8) .order(ByteOrder.nativeOrder()) .asDoubleBuffer(); // create edge coords for (Iterator<EdgeLine> it = externalEdges.keySet().iterator(); it.hasNext(); ) { EdgeLine el = it.next(); nioExternalEdges.put(el.getCoords(grid)); } LineArray la = new NioLineArray(nExternalEdges * 2, GeometryArray.COORDINATES | GeometryArray.COLOR_3); la.setCoordRefBuffer(new J3DBuffer(nioExternalEdges)); int colSize = nExternalEdges * 2 * 3; FloatBuffer nioExternalColors = ByteBuffer.allocateDirect(colSize * 4).order(ByteOrder.nativeOrder()).asFloatBuffer(); float[] colors = getColorForOrder(g, 4); for (int i = 0; i < colSize; i += 3) nioExternalColors.put(colors); la.setColorRefBuffer(new J3DBuffer(nioExternalColors)); la.setUserData(new int[] {g, 4}); a = new Appearance(); // pa = new PolygonAttributes(PolygonAttributes.POLYGON_LINE, // PolygonAttributes.CULL_NONE, 0); // pa.setPolygonOffset(3); // pa.setPolygonOffsetFactor(3); // a.setPolygonAttributes(pa); s3d = new Shape3D(la, a); PickTool.setCapabilities(s3d, PickTool.INTERSECT_FULL); s3d.setCapability(Shape3D.ALLOW_APPEARANCE_READ); s3d.setCapability(Shape3D.ALLOW_APPEARANCE_WRITE); s3d.setCapability(Node.ALLOW_PICKABLE_READ); s3d.setCapability(Node.ALLOW_PICKABLE_WRITE); s3d.setPickable(false); // by default, see actions s3d.setUserData(this); // this object will handle edges this.addChild(s3d); allEdgeShapes.add(s3d); } totalQuads += plates.length; totalInternalEdges += nInternalEdges; totalExternalEdges += nExternalEdges; } System.out.println("Total quads: " + totalQuads); System.out.println("Total Internal Plate edges: " + totalInternalEdges); System.out.println("Total External Plate edges: " + totalExternalEdges); }