Class SoVolumeBufferedShape

  • All Implemented Interfaces:
    SafeDisposable

    public class SoVolumeBufferedShape
    extends SoBufferedShape
    Buffered shape node for volume data. This node defines a shape which is the intersection of the volume data defined by an SoVolumeData node and the 3D shape defined by an SoBufferedShape node. The shape defined by this intersection is colored using the data values from the current SoVolumeData node and color map from the current SoTransferFunction node.

    The shape defined by this intersection is textured using the data from the current SoVolumeData node and SoTransferFunction node. The interpolation field controls how the texture is interpolated. Texture coordinates are automatically computed for each vertex based on its position relative to the 3D extent of the volume. If texture coordinates are specified, they are ignored.

    This node can be used to create custom "slices" through the volume, for example a cylinder slice. It can be considered a generalization of the SoOrthoSlice, SoObliqueSlice, SoFenceSlice, etc features. But note:

    • Compared to an equivalent standard slice (e.g. SoOrthoSlice), the rendering may be slightly different due to positioning and interpolation.
    • The standard slices (e.g. SoOrthoSlice) have "two-sided lighting" enabled by default as a convenience. This is not true for volume geometry nodes (which have the same default as their corresponding standard geometry node), so the "back" side of the geometry will not be lighted unless you enable two-sided lighting using an SoShapeHints node.

    When set to false, the clipGeometry field allows rendering of the portion of the geometry that does not intersect the volume data. This portion is not textured and is rendered as a regular SoBufferedShape.

    This node uses 3D texturing and is not available if the hardware does not support this feature.

    SoBufferedShape provides fields for:

    • Vertices
    • Indices (optional)
    • Colors (optional)
    • Normals (optional)
    • Texture coordinates (optional)

    SoVolumeBufferedShape is useful to manage the rendering of large geometry, provide application control over where the data is stored (CPU or GPU) and to integrate rendering with the Open Inventor computing framework (through the SoBufferObject classes).

    SoVolumeBufferedShape can render many types of geometric primitives including points, lines, quads and triangles. (A single type must be specified per instance of SoVolumeBufferedShape.) You specify the type of primitive in the SoSFEnum field shapeType.

    SoVolumeBufferedShape can render multiple primitives of the same type. You can specify the number of vertices (or indices if provided) to use for each primitive in the SoMFInt32 field numVertices (similar to SoFaceSet).

    You can also use the primitive restart feature to define multiple indexed strip shapes, for example TRIANGLE_STRIP or LINE_STRIP. The end of each primitive is marked by a special index value in the index buffer and this value can be specified in the primitiveRestartValue field. The behavior is similar to the "-1" value that can be used in Open Inventor indexed shape nodes like SoIndexedFaceSet, but is implemented on the GPU.

    NOTE:

    The geometry and its attributes must be stored in buffer objects (see SoBufferObject). The buffer objects can be SoGLBufferObjects stored directly on the graphics board or SoCpuBufferObjects stored in system memory. This allows the application to control what data is stored where.

    If lighting is enabled (there is no SoLightModel node or the model field of the SoLightModel is set to PHONG) and the normalBuffer field is not set, then normal vectors are automatically generated, similar to other geometry nodes. Normal generation is affected by the creaseAngle field of the SoShapeHints node if the vertices are NOT indexed. If the vertices are indexed the creaseAngle is forced to PI in order to have smooth surface rendering. It is not possible to display sharp edges by using indexed vertices if the normals are not set by the application. It is possible to disable normal generation (if for example the normals are generated by a geometry shader) by setting the useNormalsGenerator field to false. Note that normal generation is disabled in some cases. See the limitations section. If no normal vectors are specified or generated, and lighting is enabled, the primitive may not be rendered correctly.

    SoVolumeBufferedShape provides fields to describe the content of each buffer, e.g. the data type and number of components in each buffer, as well as how to access the buffers, e.g. the offset into the buffer and "stride" separating data values in the buffer. The default values for offset and stride assume that the vertices, normals, etc are each in a separate buffer. However setting appropriate offset and stride allows, for example, vertices and normals to be interleaved in a single buffer. In this case the same buffer would be set into both the vertexBuffer and normalBuffer fields.

    To disable computing the bounding box, which can take a long time with very large geometry, use the SoBBox node to specify a pre-computed bounding box.

    Limitations

    • Projections:
      The projections used in the VolumeViz mechanism are not handled by SoVolumeBufferedShape.
    • Lighting:
      If there is no normalBuffer the normals are generated by Inventor. The crease angle (field of SoShapeHints) is not considered by the normal generator if the vertices are indexed (crease angle is PI). So if the application wants to render sharp edges on its shape, it must use the vertexBuffer without indices in the indexBuffer.
    • Transparency:
      If there is no color buffer, making the entire shape transparent using an SoMaterial node works as usual. However if there is a color buffer with RGBA values, note that Open Inventor does not currently check the color buffer for transparency (alpha values < 1). So in this case the SoVolumeBufferedShape will not be considered transparent geometry (even if there are alpha values < 1) and may not be rendered correctly. You can force Open Inventor to handle the shape as transparent geometry by putting an SoMaterial node with non-zero transparency before it in the scene graph.
    • Normal generation:
      Automatic generation of normal vectors is ONLY enabled when:
    • SoGetPrimitiveCountAction:
      When using the primitive restart feature, the triangle/line count returned by the SoGetPrimitiveCountAction will not be accurate.
    • Concave polygons:
      Unlike (for example) SoFaceSet, SoVolumeBufferedShape does not automatically tesselate concave or complex polygons. Such primitives may not be rendered correctly.
    • SoWriteAction:
      SoVolumeBufferedShape can be saved to and restored from a .iv file just like any other Open Inventor node. However, during the read operation any OpenGL buffer objects (SoGLBufferObject) in the file will be created as CPU buffers (SoCpuBufferObject) if there is no OpenGL context bound during the read operation.
    • Material binding (etc):
      SoVolumeBufferedShape effectively only supports per-vertex and per-vertex-indexed binding of materials, normals and texture coordinates.
    • Simplification:
      SoVolumeBufferedShape is ignored by the "simplify" actions (SoShapeSimplifyAction, SoGlobalSimplifyAction, SoReorganizeAction).

    Notes:

    • The volume size and orientation (like geometry) can be modified by transformation nodes in the scene graph and this in turn modifies the appearance of volume rendering nodes like SoVolumeBufferedShape. However the same transformation must be applied to the volume data node and all volume rendering nodes associated with that volume. So effectively any transformation nodes that affect the volume must be placed before the volume data node.
    • Composition with Multiple Data:
      It is possible to compose datasets that have different dimensions, tile sizes and transformations.
      In order to help fetch the correct data values in custom shaders, texture coordinates conversion functions are provided in the VolumeViz/vvizStructure.h shader include.
      For instance,
       vec3 VVizTextureToTextureVec(in VVizDataSetId datasetSrc, in VVizDataSetId datasetDst, in vec3 texCoord);
      can be used to convert texture coordinates related to one dataset to texture coordinates related to another dataset.
      The conversion is based solely on the transformations applied to each dataset, which are defined by their model matrix and their extent.
      Please note that the model matrix of a dataset is defined by to the SoTransformation nodes that are placed before the SoDataSet node in the order of the traversal.

    File format/default:

    VolumeBufferedShape {

      clipGeometry true
      offset 0
      interpolation LINEAR
      useNormalsGenerator true
      shapeType TRIANGLES
      numVertices 0
      vertexBuffer NULL
      vertexComponentsCount 3
      vertexComponentsType SbDataType.FLOAT
      vertexStride 0
      vertexOffset 0
      normalBuffer NULL
      normalComponentsType SbDataType.FLOAT
      normalStride 3 * sizeof(float)
      normalOffset 0
      indexBuffer NULL
      indexType SbDataType.UNSIGNED_INT32
      indexOffset 0
      colorBuffer NULL
      colorComponentsType SbDataType.FLOAT
      colorStride 0
      colorOffset 0
      colorComponentsCount 3
      texCoordsBuffer NULL
      texCoordsComponentsType SbDataType.FLOAT
      texCoordsStride 0
      texCoordsOffset 0
      texCoordsComponentsCount 2
      primitiveRestartEnabled false
      primitiveRestartValue -1
    }

    Action behavior:

    SoGLRenderAction
    Draws primitives based on the current coordinates, normals, materials, drawing style, and so on.

    SoRayPickAction
    Picks primitives based on the current coordinates and transformation. Details about the intersection are returned in an SoFaceDetail.

    SoGetBoundingBoxAction
    Computes the bounding box that encloses all vertices of the face set with the current transformation applied to them. Sets the center to the real center of the bounding box: center{ (xmax + xmin) / 2, (ymax + ymin) / 2, (zmax + zmin) / 2 }

    SoCallbackAction
    If any triangle callbacks are registered with the action, they will be invoked for each successive triangle generated from each face in the set.

    See Also:
    SoBufferedShape, SoVolumeData, SoTransferFunction, SoROI, SoVolumeIndexedFaceSet, SoVolumeIndexedTriangleStripSet, SoVolumeTriangleStripSet, SoFaceDetail
    • Field Detail

      • clipGeometry

        public final SoSFBool clipGeometry
        Specifies to clip the geometry at the volume boundaries.
        The SoROI node also affects the clipping process. Default is true.
      • offset

        public final SoSFFloat offset
        Sets an offset value used for computing the texture coordinates.
        The texture coordinate for each vertex will be taken from a point offset units away from the vertex. The offset is measured in the direction of the vertex normal. By default the offset is equal to 0 (no offset). When using this feature, a vertex normal must exist for every vertex. If vertex normals are not supplied, Open Inventor will compute vertex normals in the usual way except that the crease angle will be fixed at PI in order to assure that a vertex normal is computed at every vertex.
      • interpolation

        public final SoSFEnum<SoVolumeShape.Interpolations> interpolation
        Interpolation mode. . Default is LINEAR. NOTE: In most cases on modern graphics boards, indexed textures are used, so this refers to interpolation of volume data values.
    • Constructor Detail

      • SoVolumeBufferedShape

        public SoVolumeBufferedShape()
        Constructor.