示例#1
0
int OctreeElement::getMyChildContaining(const AACube& cube) const {
    float ourScale = getScale();
    float cubeScale = cube.getScale();

    // TODO: consider changing this to assert()
    if (cubeScale > ourScale) {
        qCDebug(octree) << "UNEXPECTED -- OctreeElement::getMyChildContaining() -- (cubeScale > ourScale)";
        qCDebug(octree) << "    cube=" << cube;
        qCDebug(octree) << "    elements AACube=" << _cube;
        qCDebug(octree) << "    cubeScale=" << cubeScale;
        qCDebug(octree) << "    ourScale=" << ourScale;
        assert(false);
    }

    // Determine which of our children the minimum and maximum corners of the cube live in...
    glm::vec3 cubeCornerMinimum = glm::clamp(cube.getCorner(), (float)-HALF_TREE_SCALE, (float)HALF_TREE_SCALE);
    glm::vec3 cubeCornerMaximum = glm::clamp(cube.calcTopFarLeft(), (float)-HALF_TREE_SCALE, (float)HALF_TREE_SCALE);

    if (_cube.contains(cubeCornerMinimum) && _cube.contains(cubeCornerMaximum)) {
        int childIndexCubeMinimum = getMyChildContainingPoint(cubeCornerMinimum);
        int childIndexCubeMaximum = getMyChildContainingPoint(cubeCornerMaximum);

        // If the minimum and maximum corners of the cube are in two different children's cubes, then we are the containing element
        if (childIndexCubeMinimum != childIndexCubeMaximum) {
            return CHILD_UNKNOWN;
        }

        return childIndexCubeMinimum; // either would do, they are the same
    }
    return CHILD_UNKNOWN; // since cube is not contained in our element, it can't be in one of our children
}
示例#2
0
OctreeProjectedPolygon ViewFrustum::getProjectedPolygon(const AACube& box) const {
    const glm::vec3& bottomNearRight = box.getCorner();
    glm::vec3 topFarLeft = box.calcTopFarLeft();

    int lookUp = ((_position.x < bottomNearRight.x)     )   //  1 = right      |   compute 6-bit
               + ((_position.x > topFarLeft.x     ) << 1)   //  2 = left       |         code to
               + ((_position.y < bottomNearRight.y) << 2)   //  4 = bottom     | classify camera
               + ((_position.y > topFarLeft.y     ) << 3)   //  8 = top        | with respect to
               + ((_position.z < bottomNearRight.z) << 4)   // 16 = front/near |  the 6 defining
               + ((_position.z > topFarLeft.z     ) << 5);  // 32 = back/far   |          planes

    int vertexCount = hullVertexLookup[lookUp][0];  //look up number of vertices

    OctreeProjectedPolygon projectedPolygon(vertexCount);

    bool pointInView = true;
    bool allPointsInView = false; // assume the best, but wait till we know we have a vertex
    bool anyPointsInView = false; // assume the worst!
    if (vertexCount) {
        allPointsInView = true; // assume the best!
        for(int i = 0; i < vertexCount; i++) {
            int vertexNum = hullVertexLookup[lookUp][i+1];
            glm::vec3 point = box.getVertex((BoxVertex)vertexNum);
            glm::vec2 projectedPoint = projectPoint(point, pointInView);
            allPointsInView = allPointsInView && pointInView;
            anyPointsInView = anyPointsInView || pointInView;
            projectedPolygon.setVertex(i, projectedPoint);
        }

        /***
        // Now that we've got the polygon, if it extends beyond the clipping window, then let's clip it
        // NOTE: This clipping does not improve our overall performance. It basically causes more polygons to
        // end up in the same quad/half and so the polygon lists get longer, and that's more calls to polygon.occludes()
        if ( (projectedPolygon.getMaxX() > PolygonClip::RIGHT_OF_CLIPPING_WINDOW ) ||
             (projectedPolygon.getMaxY() > PolygonClip::TOP_OF_CLIPPING_WINDOW   ) ||
             (projectedPolygon.getMaxX() < PolygonClip::LEFT_OF_CLIPPING_WINDOW  ) ||
             (projectedPolygon.getMaxY() < PolygonClip::BOTTOM_OF_CLIPPING_WINDOW) ) {

            CoverageRegion::_clippedPolygons++;

            glm::vec2* clippedVertices;
            int        clippedVertexCount;
            PolygonClip::clipToScreen(projectedPolygon.getVertices(), vertexCount, clippedVertices, clippedVertexCount);

            // Now reset the vertices of our projectedPolygon object
            projectedPolygon.setVertexCount(clippedVertexCount);
            for(int i = 0; i < clippedVertexCount; i++) {
                projectedPolygon.setVertex(i, clippedVertices[i]);
            }
            delete[] clippedVertices;

            lookUp += PROJECTION_CLIPPED;
        }
        ***/
    }
    // set the distance from our camera position, to the closest vertex
    float distance = glm::distance(getPosition(), box.calcCenter());
    projectedPolygon.setDistance(distance);
    projectedPolygon.setAnyInView(anyPointsInView);
    projectedPolygon.setAllInView(allPointsInView);
    projectedPolygon.setProjectionType(lookUp); // remember the projection type
    return projectedPolygon;
}