@Override
  protected List<Vec4> computeMinimalGeometry(Globe globe, double verticalExaggeration) {
    double[] angles = this.computeAngles();
    // Angles are equal, fall back to building a closed cylinder.
    if (angles == null) return super.computeMinimalGeometry(globe, verticalExaggeration);

    double[] radii = this.getRadii();
    Matrix transform = this.computeTransform(globe, verticalExaggeration);

    GeometryBuilder gb = this.getGeometryBuilder();
    int count = gb.getPartialDiskVertexCount(MINIMAL_GEOMETRY_SLICES, MINIMAL_GEOMETRY_LOOPS);
    int numCoords = 3 * count;
    float[] verts = new float[numCoords];
    gb.makePartialDiskVertices(
        (float) radii[0],
        (float) radii[1], // Inner radius, outer radius.
        MINIMAL_GEOMETRY_SLICES,
        MINIMAL_GEOMETRY_LOOPS, // Slices, loops,
        (float) angles[0],
        (float) angles[2], // Start angle, sweep angle.
        verts);

    List<LatLon> locations = new ArrayList<LatLon>();
    for (int i = 0; i < numCoords; i += 3) {
      Vec4 v = new Vec4(verts[i], verts[i + 1], verts[i + 2]);
      v = v.transformBy4(transform);
      locations.add(globe.computePositionFromPoint(v));
    }

    ArrayList<Vec4> points = new ArrayList<Vec4>();
    this.makeExtremePoints(globe, verticalExaggeration, locations, points);

    return points;
  }
  private void makeRadialWall(
      DrawContext dc,
      double[] radii,
      double angle,
      double[] altitudes,
      boolean[] terrainConformant,
      int pillars,
      int stacks,
      int orientation,
      Vec4 referenceCenter,
      Geometry dest) {
    GeometryBuilder gb = this.getGeometryBuilder();
    gb.setOrientation(orientation);
    float height = (float) (altitudes[1] - altitudes[0]);

    int count = gb.getRadialWallVertexCount(pillars, stacks);
    int numCoords = 3 * count;
    float[] verts = new float[numCoords];
    float[] norms = new float[numCoords];
    gb.makeRadialWallVertices(
        (float) radii[0], (float) radii[1], height, (float) angle, pillars, stacks, verts);
    this.makeRadialWallTerrainConformant(
        dc, pillars, stacks, verts, altitudes, terrainConformant, referenceCenter);
    gb.makeRadialWallNormals(
        (float) radii[0], (float) radii[1], height, (float) angle, pillars, stacks, norms);

    dest.setVertexData(count, verts);
    dest.setNormalData(count, norms);
  }
Пример #3
0
  private void makeSectionOutlineIndices(
      int subdivisions,
      int vertexPos,
      int indexPos,
      int[] indices,
      boolean beginEdgeFlag,
      boolean endEdgeFlag) {
    GeometryBuilder gb = this.getGeometryBuilder();
    int count = gb.getSubdivisionPointsVertexCount(subdivisions);

    int index = indexPos;
    int pos, nextPos;

    if (beginEdgeFlag) {
      pos = vertexPos;
      indices[index++] = pos;
      indices[index++] = pos + 1;
    }

    for (int i = 0; i < count - 1; i++) {
      pos = vertexPos + 2 * i;
      nextPos = vertexPos + 2 * (i + 1);
      indices[index++] = pos;
      indices[index++] = nextPos;
      indices[index++] = pos + 1;
      indices[index++] = nextPos + 1;
    }

    if (endEdgeFlag) {
      pos = vertexPos + 2 * (count - 1);
      indices[index++] = pos;
      indices[index] = pos + 1;
    }
  }
  private void makePartialCylinder(
      DrawContext dc,
      double radius,
      double[] altitudes,
      boolean[] terrainConformant,
      int slices,
      int stacks,
      int orientation,
      double start,
      double sweep,
      Vec4 referenceCenter,
      Geometry dest) {
    GeometryBuilder gb = this.getGeometryBuilder();
    gb.setOrientation(orientation);
    float height = (float) (altitudes[1] - altitudes[0]);

    int count = gb.getPartialCylinderVertexCount(slices, stacks);
    int numCoords = 3 * count;
    float[] verts = new float[numCoords];
    float[] norms = new float[numCoords];
    gb.makePartialCylinderVertices(
        (float) radius, height, slices, stacks, (float) start, (float) sweep, verts);
    gb.makePartialCylinderNormals(
        (float) radius, height, slices, stacks, (float) start, (float) sweep, norms);
    this.makePartialCylinderTerrainConformant(
        dc, slices, stacks, verts, altitudes, terrainConformant, referenceCenter);

    dest.setVertexData(count, verts);
    dest.setNormalData(count, norms);
  }
Пример #5
0
  protected void makeTessellatedLocations(
      Globe globe, int subdivisions, List<LatLon> locations, List<LatLon> tessellatedLocations) {
    ArrayList<Vec4> points = new ArrayList<Vec4>();
    for (LatLon ll : locations) {
      points.add(globe.computePointFromLocation(ll));
    }

    //noinspection StringEquality
    if (WWMath.computeWindingOrderOfLocations(locations) != AVKey.COUNTER_CLOCKWISE)
      Collections.reverse(locations);

    Vec4 centerPoint = Vec4.computeAveragePoint(points);
    Vec4 surfaceNormal = globe.computeSurfaceNormalAtPoint(centerPoint);

    int numPoints = points.size();
    float[] coords = new float[3 * numPoints];
    for (int i = 0; i < numPoints; i++) {
      points.get(i).toFloatArray(coords, 3 * i, 3);
    }

    GeometryBuilder gb = new GeometryBuilder();
    GeometryBuilder.IndexedTriangleArray tessellatedPoints =
        gb.tessellatePolygon(0, numPoints, coords, surfaceNormal);

    for (int i = 0; i < subdivisions; i++) {
      gb.subdivideIndexedTriangleArray(tessellatedPoints);
    }

    for (int i = 0; i < tessellatedPoints.getVertexCount(); i++) {
      Vec4 v = Vec4.fromFloatArray(tessellatedPoints.getVertices(), 3 * i, 3);
      tessellatedLocations.add(globe.computePositionFromPoint(v));
    }
  }
Пример #6
0
  private int getSectionOutlineIndexCount(
      int subdivisions, boolean beginEdgeFlag, boolean endEdgeFlag) {
    GeometryBuilder gb = this.getGeometryBuilder();
    int count = 4 * (gb.getSubdivisionPointsVertexCount(subdivisions) - 1);
    if (beginEdgeFlag) count += 2;
    if (endEdgeFlag) count += 2;

    return count;
  }
Пример #7
0
  private void makeEdge(
      DrawContext dc,
      int count,
      float[] locations,
      Boolean[] edgeFlags,
      double[] altitudes,
      boolean[] terrainConformant,
      int subdivisions,
      int orientation,
      Matrix locationTransform,
      Vec4 referenceCenter,
      int fillIndexPos,
      int[] fillIndices,
      int outlineIndexPos,
      int[] outlineIndices,
      int vertexPos,
      float[] vertices,
      float[] normals) {
    GeometryBuilder gb = this.getGeometryBuilder();
    gb.setOrientation(orientation);

    int sectionFillIndexCount = this.getSectionFillIndexCount(subdivisions);
    int sectionVertexCount = this.getSectionVertexCount(subdivisions);

    for (int i = 0; i < count - 1; i++) {
      boolean beginEdgeFlag = edgeFlags[i];
      boolean endEdgeFlag = edgeFlags[i + 1];

      this.makeSectionFillIndices(subdivisions, vertexPos, fillIndexPos, fillIndices);
      this.makeSectionOutlineIndices(
          subdivisions, vertexPos, outlineIndexPos, outlineIndices, beginEdgeFlag, endEdgeFlag);
      this.makeSectionVertices(
          dc,
          i,
          locations,
          altitudes,
          terrainConformant,
          subdivisions,
          locationTransform,
          referenceCenter,
          vertexPos,
          vertices);
      gb.makeIndexedTriangleArrayNormals(
          fillIndexPos,
          sectionFillIndexCount,
          fillIndices,
          vertexPos,
          sectionVertexCount,
          vertices,
          normals);

      fillIndexPos += sectionFillIndexCount;
      outlineIndexPos += this.getSectionOutlineIndexCount(subdivisions, beginEdgeFlag, endEdgeFlag);
      vertexPos += sectionVertexCount;
    }
  }
  private void makeRadialWallIndices(int pillars, int stacks, int orientation, Geometry dest) {
    GeometryBuilder gb = this.getGeometryBuilder();
    gb.setOrientation(orientation);

    int mode = gb.getRadialWallDrawMode();
    int count = gb.getRadialWallIndexCount(pillars, stacks);
    int[] indices = new int[count];
    gb.makeRadialWallIndices(pillars, stacks, indices);

    dest.setElementData(mode, count, indices);
  }
  private void makePartialDiskIndices(int slices, int loops, int orientation, Geometry dest) {
    GeometryBuilder gb = this.getGeometryBuilder();
    gb.setOrientation(orientation);

    int mode = gb.getPartialDiskDrawMode();
    int count = gb.getPartialDiskIndexCount(slices, loops);
    int[] indices = new int[count];
    gb.makePartialDiskIndices(slices, loops, indices);

    dest.setElementData(mode, count, indices);
  }
Пример #10
0
  private void makeCap(
      DrawContext dc,
      GeometryBuilder.IndexedTriangleArray ita,
      double altitude,
      boolean terrainConformant,
      int orientation,
      Matrix locationTransform,
      Vec4 referenceCenter,
      int indexPos,
      int[] indices,
      int vertexPos,
      float[] vertices,
      float[] normals) {
    GeometryBuilder gb = this.getGeometryBuilder();
    Globe globe = dc.getGlobe();

    int indexCount = ita.getIndexCount();
    int vertexCount = ita.getVertexCount();
    int[] locationIndices = ita.getIndices();
    float[] locationVerts = ita.getVertices();

    this.copyIndexArray(
        indexCount,
        (orientation == GeometryBuilder.INSIDE),
        locationIndices,
        vertexPos,
        indexPos,
        indices);

    for (int i = 0; i < vertexCount; i++) {
      int index = 3 * i;
      Vec4 vec = new Vec4(locationVerts[index], locationVerts[index + 1], locationVerts[index + 2]);
      vec = vec.transformBy4(locationTransform);

      Position pos = globe.computePositionFromPoint(vec);
      vec =
          this.computePointFromPosition(
              dc, pos.getLatitude(), pos.getLongitude(), altitude, terrainConformant);

      index = 3 * (vertexPos + i);
      vertices[index] = (float) (vec.x - referenceCenter.x);
      vertices[index + 1] = (float) (vec.y - referenceCenter.y);
      vertices[index + 2] = (float) (vec.z - referenceCenter.z);
    }

    gb.makeIndexedTriangleArrayNormals(
        indexPos, indexCount, indices, vertexPos, vertexCount, vertices, normals);
  }
Пример #11
0
  private void makeSectionVertices(
      DrawContext dc,
      int locationPos,
      float[] locations,
      double[] altitude,
      boolean[] terrainConformant,
      int subdivisions,
      Matrix locationTransform,
      Vec4 referenceCenter,
      int vertexPos,
      float[] vertices) {
    GeometryBuilder gb = this.getGeometryBuilder();
    int numPoints = gb.getSubdivisionPointsVertexCount(subdivisions);

    Globe globe = dc.getGlobe();
    int index1 = 3 * locationPos;
    int index2 = 3 * (locationPos + 1);

    float[] locationVerts = new float[3 * numPoints];
    gb.makeSubdivisionPoints(
        locations[index1],
        locations[index1 + 1],
        locations[index1 + 2],
        locations[index2],
        locations[index2 + 1],
        locations[index2 + 2],
        subdivisions,
        locationVerts);

    for (int i = 0; i < numPoints; i++) {
      int index = 3 * i;
      Vec4 vec = new Vec4(locationVerts[index], locationVerts[index + 1], locationVerts[index + 2]);
      vec = vec.transformBy4(locationTransform);
      Position pos = globe.computePositionFromPoint(vec);

      for (int j = 0; j < 2; j++) {
        vec =
            this.computePointFromPosition(
                dc, pos.getLatitude(), pos.getLongitude(), altitude[j], terrainConformant[j]);

        index = 2 * i + j;
        index = 3 * (vertexPos + index);
        vertices[index] = (float) (vec.x - referenceCenter.x);
        vertices[index + 1] = (float) (vec.y - referenceCenter.y);
        vertices[index + 2] = (float) (vec.z - referenceCenter.z);
      }
    }
  }
Пример #12
0
  private void makeSectionFillIndices(
      int subdivisions, int vertexPos, int indexPos, int[] indices) {
    GeometryBuilder gb = this.getGeometryBuilder();
    int count = gb.getSubdivisionPointsVertexCount(subdivisions);

    int index = indexPos;
    int pos, nextPos;
    for (int i = 0; i < count - 1; i++) {
      pos = vertexPos + 2 * i;
      nextPos = vertexPos + 2 * (i + 1);
      indices[index++] = pos + 1;
      indices[index++] = pos;
      indices[index++] = nextPos + 1;
      indices[index++] = nextPos + 1;
      indices[index++] = pos;
      indices[index++] = nextPos;
    }
  }
  private void makePartialDisk(
      DrawContext dc,
      double[] radii,
      double altitude,
      boolean terrainConformant,
      int slices,
      int loops,
      int orientation,
      double start,
      double sweep,
      Vec4 referenceCenter,
      Geometry dest) {
    GeometryBuilder gb = this.getGeometryBuilder();
    gb.setOrientation(orientation);

    int count = gb.getPartialDiskIndexCount(slices, loops);
    int numCoords = 3 * count;
    float[] verts = new float[numCoords];
    float[] norms = new float[numCoords];
    gb.makePartialDiskVertices(
        (float) radii[0], (float) radii[1], slices, loops, (float) start, (float) sweep, verts);
    this.makePartialDiskTerrainConformant(
        dc, numCoords, verts, altitude, terrainConformant, referenceCenter);
    gb.makePartialDiskVertexNormals(
        (float) radii[0],
        (float) radii[1],
        slices,
        loops,
        (float) start,
        (float) sweep,
        verts,
        norms);

    dest.setVertexData(count, verts);
    dest.setNormalData(count, norms);
  }
Пример #14
0
 private int getSectionVertexCount(int subdivisions) {
   GeometryBuilder gb = this.getGeometryBuilder();
   return 2 * gb.getSubdivisionPointsVertexCount(subdivisions);
 }
Пример #15
0
 private int getSectionFillIndexCount(int subdivisions) {
   GeometryBuilder gb = this.getGeometryBuilder();
   return 6 * (gb.getSubdivisionPointsVertexCount(subdivisions) - 1);
 }
Пример #16
0
  private void makePolygon(
      DrawContext dc,
      List<LatLon> locations,
      List<Boolean> edgeFlags,
      double[] altitudes,
      boolean[] terrainConformant,
      boolean enableCaps,
      int subdivisions,
      Vec4 referenceCenter,
      PolygonGeometry dest) {
    if (locations.size() == 0) return;

    GeometryBuilder gb = this.getGeometryBuilder();

    Vec4[] polyPoints = new Vec4[locations.size() + 1];
    Boolean[] polyEdgeFlags = new Boolean[locations.size() + 1];
    Matrix[] polyTransform = new Matrix[1];
    int polyCount =
        this.computeCartesianPolygon(
            dc.getGlobe(), locations, edgeFlags, polyPoints, polyEdgeFlags, polyTransform);

    // Compute the winding order of the planar cartesian points. If the order is not
    // counter-clockwise, then
    // reverse the locations and points ordering.
    int winding = gb.computePolygonWindingOrder2(0, polyCount, polyPoints);
    if (winding != GeometryBuilder.COUNTER_CLOCKWISE) {
      gb.reversePoints(0, polyCount, polyPoints);
      gb.reversePoints(0, polyCount, polyEdgeFlags);
    }

    float[] polyVertices = new float[3 * polyCount];
    this.makePolygonVertices(polyCount, polyPoints, polyVertices);

    int fillDrawMode = GL.GL_TRIANGLES;
    int outlineDrawMode = GL.GL_LINES;

    int fillIndexCount = 0;
    int outlineIndexCount = 0;
    int vertexCount = 0;

    GeometryBuilder.IndexedTriangleArray ita = null;

    fillIndexCount += this.getEdgeFillIndexCount(polyCount, subdivisions);
    outlineIndexCount += this.getEdgeOutlineIndexCount(polyCount, subdivisions, polyEdgeFlags);
    vertexCount += this.getEdgeVertexCount(polyCount, subdivisions);

    if (enableCaps) {
      ita = gb.tessellatePolygon2(0, polyCount, polyVertices);
      for (int i = 0; i < subdivisions; i++) {
        gb.subdivideIndexedTriangleArray(ita);
      }

      fillIndexCount += ita.getIndexCount();
      vertexCount += ita.getVertexCount();
      // Bottom cap isn't drawn if airspace is collapsed.
      if (!this.isAirspaceCollapsed()) {
        fillIndexCount += ita.getIndexCount();
        vertexCount += ita.getVertexCount();
      }
    }

    int[] fillIndices = new int[fillIndexCount];
    int[] outlineIndices = new int[outlineIndexCount];
    float[] vertices = new float[3 * vertexCount];
    float[] normals = new float[3 * vertexCount];

    int fillIndexPos = 0;
    int outlineIndexPos = 0;
    int vertexPos = 0;

    this.makeEdge(
        dc,
        polyCount,
        polyVertices,
        polyEdgeFlags,
        altitudes,
        terrainConformant,
        subdivisions,
        GeometryBuilder.OUTSIDE,
        polyTransform[0],
        referenceCenter,
        fillIndexPos,
        fillIndices,
        outlineIndexPos,
        outlineIndices,
        vertexPos,
        vertices,
        normals);
    fillIndexPos += this.getEdgeFillIndexCount(polyCount, subdivisions);
    outlineIndexPos += this.getEdgeOutlineIndexCount(polyCount, subdivisions, polyEdgeFlags);
    vertexPos += this.getEdgeVertexCount(polyCount, subdivisions);

    if (enableCaps) {
      this.makeCap(
          dc,
          ita,
          altitudes[1],
          terrainConformant[1],
          GeometryBuilder.OUTSIDE,
          polyTransform[0],
          referenceCenter,
          fillIndexPos,
          fillIndices,
          vertexPos,
          vertices,
          normals);
      fillIndexPos += ita.getIndexCount();
      vertexPos += ita.getVertexCount();
      // Bottom cap isn't drawn if airspace is collapsed.
      if (!this.isAirspaceCollapsed()) {
        this.makeCap(
            dc,
            ita,
            altitudes[0],
            terrainConformant[0],
            GeometryBuilder.INSIDE,
            polyTransform[0],
            referenceCenter,
            fillIndexPos,
            fillIndices,
            vertexPos,
            vertices,
            normals);
        fillIndexPos += ita.getIndexCount();
        vertexPos += ita.getVertexCount();
      }
    }

    dest.getFillIndexGeometry().setElementData(fillDrawMode, fillIndexCount, fillIndices);
    dest.getOutlineIndexGeometry()
        .setElementData(outlineDrawMode, outlineIndexCount, outlineIndices);
    dest.getVertexGeometry().setVertexData(vertexCount, vertices);
    dest.getVertexGeometry().setNormalData(vertexCount, normals);
  }