protected Vec4[] calculateNormals(int width, int height, Vec4[] verts, int padding) {
    int padding2 = padding * 2;

    if (verts.length != (width + padding2) * (height + padding2))
      throw new IllegalStateException("Illegal vertices length");

    Vec4[] norms = new Vec4[width * height];
    for (int y = 0; y < height; y++) {
      for (int x = 0; x < width; x++) {
        //   v2
        //   |
        // v1-v0-v3
        //   |
        //   v4

        Vec4 v0 =
            verts[getArrayIndex(width + padding2, height + padding2, x + padding, y + padding)];
        if (v0 != null) {
          Vec4 v1 =
              verts[
                  getArrayIndex(width + padding2, height + padding2, x + padding - 1, y + padding)];
          Vec4 v2 =
              verts[
                  getArrayIndex(width + padding2, height + padding2, x + padding, y + padding - 1)];
          Vec4 v3 =
              verts[
                  getArrayIndex(width + padding2, height + padding2, x + padding + 1, y + padding)];
          Vec4 v4 =
              verts[
                  getArrayIndex(width + padding2, height + padding2, x + padding, y + padding + 1)];

          Vec4[] normals = new Vec4[4];
          normals[0] =
              v1 != null && v2 != null
                  ? v1.subtract3(v0).cross3(v0.subtract3(v2)).normalize3()
                  : null;
          normals[1] =
              v2 != null && v3 != null
                  ? v2.subtract3(v0).cross3(v0.subtract3(v3)).normalize3()
                  : null;
          normals[2] =
              v3 != null && v4 != null
                  ? v3.subtract3(v0).cross3(v0.subtract3(v4)).normalize3()
                  : null;
          normals[3] =
              v4 != null && v1 != null
                  ? v4.subtract3(v0).cross3(v0.subtract3(v1)).normalize3()
                  : null;
          Vec4 normal = Vec4.ZERO;
          for (Vec4 n : normals) {
            if (n != null) normal = normal.add3(n);
          }
          if (normal != Vec4.ZERO) {
            norms[getArrayIndex(width, height, x, y)] = normal.normalize3();
          }
        }
      }
    }
    return norms;
  }
示例#2
0
  /**
   * Compute the positions of the arrow head of the graphic's legs.
   *
   * @param dc Current draw context
   * @param base Position of the arrow's starting point.
   * @param tip Position of the arrow head tip.
   * @param arrowLength Length of the arrowhead as a fraction of the total line length.
   * @param arrowAngle Angle of the arrow head.
   * @return Positions required to draw the arrow head.
   */
  protected List<Position> computeArrowheadPositions(
      DrawContext dc, Position base, Position tip, double arrowLength, Angle arrowAngle) {
    // Build a triangle to represent the arrowhead. The triangle is built from two vectors, one
    // parallel to the
    // segment, and one perpendicular to it.

    Globe globe = dc.getGlobe();

    Vec4 ptA = globe.computePointFromPosition(base);
    Vec4 ptB = globe.computePointFromPosition(tip);

    // Compute parallel component
    Vec4 parallel = ptA.subtract3(ptB);

    Vec4 surfaceNormal = globe.computeSurfaceNormalAtPoint(ptB);

    // Compute perpendicular component
    Vec4 perpendicular = surfaceNormal.cross3(parallel);

    double finalArrowLength = arrowLength * parallel.getLength3();
    double arrowHalfWidth = finalArrowLength * arrowAngle.tanHalfAngle();

    perpendicular = perpendicular.normalize3().multiply3(arrowHalfWidth);
    parallel = parallel.normalize3().multiply3(finalArrowLength);

    // Compute geometry of direction arrow
    Vec4 vertex1 = ptB.add3(parallel).add3(perpendicular);
    Vec4 vertex2 = ptB.add3(parallel).subtract3(perpendicular);

    return TacticalGraphicUtil.asPositionList(globe, vertex1, vertex2, ptB);
  }
示例#3
0
  /**
   * Determine the positions that make up the arrowhead.
   *
   * @param dc Current draw context.
   * @param startPosition Position of the arrow's base.
   * @param endPosition Position of the arrow head tip.
   * @return Positions that define the arrowhead.
   */
  protected List<Position> computeArrowheadPositions(
      DrawContext dc, Position startPosition, Position endPosition) {
    Globe globe = dc.getGlobe();

    // Arrowhead looks like this:
    //                  _
    //        A\         | 1/2 width
    // ________B\       _|
    // Pt. 1    /
    //        C/
    //         | |
    //      Length

    Vec4 p1 = globe.computePointFromPosition(startPosition);
    Vec4 pB = globe.computePointFromPosition(endPosition);

    // Find vector in the direction of the arrow
    Vec4 vB1 = p1.subtract3(pB);

    double arrowLengthFraction = this.getArrowLength();

    // Find the point at the base of the arrowhead
    Vec4 arrowBase = pB.add3(vB1.multiply3(arrowLengthFraction));

    Vec4 normal = globe.computeSurfaceNormalAtPoint(arrowBase);

    // Compute the length of the arrowhead
    double arrowLength = vB1.getLength3() * arrowLengthFraction;
    double arrowHalfWidth = arrowLength * this.getArrowAngle().tanHalfAngle();

    // Compute a vector perpendicular to the segment and the normal vector
    Vec4 perpendicular = vB1.cross3(normal);
    perpendicular = perpendicular.normalize3().multiply3(arrowHalfWidth);

    // Find points A and C
    Vec4 pA = arrowBase.add3(perpendicular);
    Vec4 pC = arrowBase.subtract3(perpendicular);

    return TacticalGraphicUtil.asPositionList(globe, pA, pB, pC);
  }
  public void lookAt(Position lookAtPos, long timeToMove) {
    BasicFlyView view = (BasicFlyView) this.getView();
    Vec4 lookDirection;
    double distanceToSurface;
    Vec4 currentLookAtPt = view.getCenterPoint();
    Position newPosition;
    if (currentLookAtPt == null) {
      view.getGlobe().computePointFromPosition(lookAtPos);
      double elevAtLookAtPos =
          view.getGlobe().getElevation(lookAtPos.getLatitude(), lookAtPos.getLongitude());
      newPosition = new Position(lookAtPos, elevAtLookAtPos + 10000);
    } else {
      Vec4 currentEyePt = view.getEyePoint();
      distanceToSurface = currentEyePt.distanceTo3(currentLookAtPt);
      lookDirection = currentLookAtPt.subtract3(currentEyePt).normalize3();
      Vec4 newLookAtPt = view.getGlobe().computePointFromPosition(lookAtPos);
      Vec4 flyToPoint = newLookAtPt.add3(lookDirection.multiply3(-distanceToSurface));
      newPosition = view.getGlobe().computePositionFromPoint(flyToPoint);
    }

    ViewUtil.ViewState viewCoords = view.getViewState(newPosition, lookAtPos);

    FlyToFlyViewAnimator panAnimator =
        FlyToFlyViewAnimator.createFlyToFlyViewAnimator(
            view,
            view.getEyePosition(),
            newPosition,
            view.getHeading(),
            viewCoords.getHeading(),
            view.getPitch(),
            viewCoords.getPitch(),
            view.getEyePosition().getElevation(),
            viewCoords.getPosition().getElevation(),
            timeToMove,
            WorldWind.ABSOLUTE);

    this.gotoAnimControl.put(VIEW_ANIM_PAN, panAnimator);
    this.getView().firePropertyChange(AVKey.VIEW, null, this.getView());

    view.firePropertyChange(AVKey.VIEW, null, view);
  }
  /**
   * Compute points on either side of a line segment. This method requires a point on the line, and
   * either a next point, previous point, or both.
   *
   * @param point Center point about which to compute side points.
   * @param prev Previous point on the line. May be null if {@code next} is non-null.
   * @param next Next point on the line. May be null if {@code prev} is non-null.
   * @param leftPositions Left position will be added to this list.
   * @param rightPositions Right position will be added to this list.
   * @param halfWidth Distance from the center line to the left or right lines.
   * @param globe Current globe.
   */
  protected void generateParallelPoints(
      Vec4 point,
      Vec4 prev,
      Vec4 next,
      List<Position> leftPositions,
      List<Position> rightPositions,
      double halfWidth,
      Globe globe) {
    if ((point == null) || (prev == null && next == null)) {
      String message = Logging.getMessage("nullValue.PointIsNull");
      Logging.logger().severe(message);
      throw new IllegalArgumentException(message);
    }
    if (leftPositions == null || rightPositions == null) {
      String message = Logging.getMessage("nullValue.PositionListIsNull");
      Logging.logger().severe(message);
      throw new IllegalArgumentException(message);
    }
    if (globe == null) {
      String message = Logging.getMessage("nullValue.GlobeIsNull");
      Logging.logger().severe(message);
      throw new IllegalArgumentException(message);
    }

    Vec4 offset;
    Vec4 normal = globe.computeSurfaceNormalAtPoint(point);

    // Compute vector in the direction backward along the line.
    Vec4 backward = (prev != null) ? prev.subtract3(point) : point.subtract3(next);

    // Compute a vector perpendicular to segment BC, and the globe normal vector.
    Vec4 perpendicular = backward.cross3(normal);

    double length;
    // If both next and previous points are supplied then calculate the angle that bisects the angle
    // current, next, prev.
    if (next != null && prev != null && !Vec4.areColinear(prev, point, next)) {
      // Compute vector in the forward direction.
      Vec4 forward = next.subtract3(point);

      // Calculate the vector that bisects angle ABC.
      offset = forward.normalize3().add3(backward.normalize3());
      offset = offset.normalize3();

      // Compute the scalar triple product of the vector BC, the normal vector, and the offset
      // vector to
      // determine if the offset points to the left or the right of the control line.
      double tripleProduct = perpendicular.dot3(offset);
      if (tripleProduct < 0) {
        offset = offset.multiply3(-1);
      }

      // Determine the length of the offset vector that will keep the left and right lines parallel
      // to the control
      // line.
      Angle theta = backward.angleBetween3(offset);
      if (!Angle.ZERO.equals(theta)) length = halfWidth / theta.sin();
      else length = halfWidth;
    } else {
      offset = perpendicular.normalize3();
      length = halfWidth;
    }
    offset = offset.multiply3(length);

    // Determine the left and right points by applying the offset.
    Vec4 ptRight = point.add3(offset);
    Vec4 ptLeft = point.subtract3(offset);

    // Convert cartesian points to geographic.
    Position posLeft = globe.computePositionFromPoint(ptLeft);
    Position posRight = globe.computePositionFromPoint(ptRight);

    leftPositions.add(posLeft);
    rightPositions.add(posRight);
  }
  protected void onMoveTo(
      Position focalPosition,
      ViewInputAttributes.DeviceAttributes deviceAttributes,
      ViewInputAttributes.ActionAttributes actionAttribs) {
    BasicFlyView view = (BasicFlyView) this.getView();
    if (view == null) // include this test to ensure any derived implementation performs it
    {
      return;
    }

    // We're treating a speed parameter as smoothing here. A greater speed results in greater
    // smoothing and
    // slower response. Therefore the min speed used at lower altitudes ought to be *greater* than
    // the max
    // speed used at higher altitudes.
    double smoothing = this.getScaleValueElevation(deviceAttributes, actionAttribs);
    if (!actionAttribs.isEnableSmoothing()) smoothing = 0.0;

    Vec4 currentLookAtPt = view.getCenterPoint();
    if (currentLookAtPt == null) {
      currentLookAtPt = view.getGlobe().computePointFromPosition(focalPosition);
    }

    Vec4 currentEyePt = view.getEyePoint();
    double distanceToSurface = currentEyePt.distanceTo3(currentLookAtPt);
    Vec4 lookDirection = currentEyePt.subtract3(currentLookAtPt).normalize3();
    Vec4 newLookAtPt = view.getGlobe().computePointFromPosition(focalPosition);
    Vec4 flyToPoint = newLookAtPt.add3(lookDirection.multiply3(distanceToSurface));

    Position newPosition = view.getGlobe().computePositionFromPoint(flyToPoint);

    ViewUtil.ViewState viewCoords = view.getViewState(newPosition, focalPosition);

    this.stopAnimators();
    this.gotoAnimControl.put(
        VIEW_ANIM_HEADING,
        new RotateToAngleAnimator(
            view.getHeading(),
            viewCoords.getHeading(),
            smoothing,
            ViewPropertyAccessor.createHeadingAccessor(view)));
    this.gotoAnimControl.put(
        VIEW_ANIM_PITCH,
        new RotateToAngleAnimator(
            view.getPitch(),
            viewCoords.getPitch(),
            smoothing,
            ViewPropertyAccessor.createPitchAccessor(view)));

    double elevation =
        ((FlyViewLimits) view.getViewPropertyLimits())
            .limitEyeElevation(newPosition, view.getGlobe());
    if (elevation != newPosition.getElevation()) {
      newPosition = new Position(newPosition, elevation);
    }
    this.gotoAnimControl.put(
        VIEW_ANIM_POSITION,
        new MoveToPositionAnimator(
            view.getEyePosition(),
            newPosition,
            smoothing,
            ViewPropertyAccessor.createEyePositionAccessor(view)));

    view.firePropertyChange(AVKey.VIEW, null, view);
  }