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SoSphere
Langue: en
Version: 320006 (ubuntu - 07/07/09)
Section: 3 (Bibliothèques de fonctions)
Sommaire
- NAME
- SYNOPSIS
- Detailed Description
- Constructor & Destructor Documentation
- Member Function Documentation
- SoType SoSphere::getClassTypeId (void) [static]
- SoType SoSphere::getTypeId (void) const [virtual]
- const SoFieldData ** SoSphere::getFieldDataPtr (void) [static, protected]
- const SoFieldData * SoSphere::getFieldData (void) const [protected, virtual]
- void SoSphere::initClass (void) [static]
- void SoSphere::GLRender (SoGLRenderAction * action) [virtual]
- void SoSphere::rayPick (SoRayPickAction * action) [virtual]
- void SoSphere::getPrimitiveCount (SoGetPrimitiveCountAction * action) [virtual]
- void SoSphere::generatePrimitives (SoAction * action) [protected, virtual]
- void SoSphere::computeBBox (SoAction * action, SbBox3f & box, SbVec3f & center) [protected, virtual]
- Member Data Documentation
- Author
NAME
SoSphere -SYNOPSIS
#include <Inventor/nodes/SoSphere.h>
Inherits SoShape.
Detailed Description
The SoSphere class is for rendering sphere shapes.
Renders a sphere with the size given by the SoSphere::radius field. The sphere is rendered with the current material, texture and drawstyle settings (if any, otherwise the default settings are used).
The SoSphere node class is provided as a convenient abstraction for the application programmer to use 'complex' shapes of this type without having to do the tessellation to polygons and other low-level programming herself.
A good trick for rendering ellipsoidal 3D shapes is to use an SoSphere prefixed with an SoScale transformation to 'flatten' it along one or more of the principal axes. (Ie use for instance an SoScale node with SoScale::scaleFactor equal to [1, 1, 0.1] to flatten it along the Z direction.)
A sphere is visualized by the underlying rendering system by first tessellating the conceptual sphere into a set of polygons. To control the trade-off between an as much as possible correct visual appearance of the sphere versus fast rendering, use an SoComplexity node to influence the number of polygons generated from the tessellation process. (The higher the complexity value, the more polygons will be generated, the more rounded the sphere will look.) Set the SoComplexity::value field to what you believe would be a good trade-off between correctness and speed for your particular application.
FILE FORMAT/DEFAULTS:
Sphere { radius 1 }
See also:
- SoCone, SoCylinder, SoCube
Public Member Functions
virtual SoType getTypeId (void) const
SoSphere (void)
virtual void GLRender (SoGLRenderAction *action)
virtual void rayPick (SoRayPickAction *action)
virtual void getPrimitiveCount (SoGetPrimitiveCountAction *action)
Static Public Member Functions
static SoType getClassTypeId (void)
static void initClass (void)
Public Attributes
SoSFFloat radius
Protected Member Functions
virtual const SoFieldData * getFieldData (void) const
virtual ~SoSphere ()
virtual void generatePrimitives (SoAction *action)
virtual void computeBBox (SoAction *action, SbBox3f &box, SbVec3f ¢er)
Static Protected Member Functions
static const SoFieldData ** getFieldDataPtr (void)
Constructor & Destructor Documentation
SoSphere::SoSphere (void)
Constructor.
SoSphere::~SoSphere () [protected, virtual]
Destructor.
References SoNode::VRML1.
Member Function Documentation
SoType SoSphere::getClassTypeId (void) [static]
This static method returns the SoType object associated with objects of this class.
Reimplemented from SoShape.
SoType SoSphere::getTypeId (void) const [virtual]
Returns the type identification of an object derived from a class inheriting SoBase. This is used for run-time type checking and 'downward' casting.
Usage example:
void foo(SoNode * node) { if (node->getTypeId() == SoFile::getClassTypeId()) { SoFile * filenode = (SoFile *)node; // safe downward cast, knows the type } else if (node->getTypeId().isOfType(SoGroup::getClassTypeId())) { SoGroup * group = (SoGroup *)node; // safe downward cast, knows the type } }
For application programmers wanting to extend the library with new nodes, engines, nodekits, draggers or others: this method needs to be overridden in all subclasses. This is typically done as part of setting up the full type system for extension classes, which is usually accomplished by using the pre-defined macros available through for instance Inventor/nodes/SoSubNode.h (SO_NODE_INIT_CLASS and SO_NODE_CONSTRUCTOR for node classes), Inventor/engines/SoSubEngine.h (for engine classes) and so on.
For more information on writing Coin extensions, see the class documentation of the toplevel superclasses for the various class groups.
Reimplemented from SoShape.
const SoFieldData ** SoSphere::getFieldDataPtr (void) [static, protected]
This API member is considered internal to the library, as it is not likely to be of interest to the application programmer.
Reimplemented from SoShape.
const SoFieldData * SoSphere::getFieldData (void) const [protected, virtual]
Returns a pointer to the class-wide field data storage object for this instance. If no fields are present, returns NULL.
Reimplemented from SoShape.
void SoSphere::initClass (void) [static]
Sets up initialization for data common to all instances of this class, like submitting necessary information to the Coin type system.
Reimplemented from SoShape.
References SoAction::getState(), and SoShape::shouldGLRender().
Referenced by SoNode::initClasses().
void SoSphere::GLRender (SoGLRenderAction * action) [virtual]
Action method for the SoGLRenderAction.
This is called during rendering traversals. Nodes influencing the rendering state in any way or who wants to throw geometry primitives at OpenGL overrides this method.
Reimplemented from SoShape.
void SoSphere::rayPick (SoRayPickAction * action) [virtual]
Calculates picked point based on primitives generated by subclasses.
Reimplemented from SoShape.
void SoSphere::getPrimitiveCount (SoGetPrimitiveCountAction * action) [virtual]
Action method for the SoGetPrimitiveCountAction.
Calculates the number of triangle, line segment and point primitives for the node and adds these to the counters of the action.
Nodes influencing how geometry nodes calculates their primitive count also overrides this method to change the relevant state variables.
Reimplemented from SoShape.
void SoSphere::generatePrimitives (SoAction * action) [protected, virtual]
The method implements action behavior for shape nodes for SoCallbackAction. It is invoked from SoShape::callback(). (Subclasses should not override SoNode::callback().)
The subclass implementations uses the convenience methods SoShape::beginShape(), SoShape::shapeVertex(), and SoShape::endShape(), with SoDetail instances, to pass the primitives making up the shape back to the caller.
Implements SoShape.
void SoSphere::computeBBox (SoAction * action, SbBox3f & box, SbVec3f & center) [protected, virtual]
Implemented by SoShape subclasses to let the SoShape superclass know the exact size and weighted center point of the shape's bounding box.
The bounding box and center point should be calculated and returned in the local coordinate system.
The method implements action behavior for shape nodes for SoGetBoundingBoxAction. It is invoked from SoShape::getBoundingBox(). (Subclasses should not override SoNode::getBoundingBox().)
The box parameter sent in is guaranteed to be an empty box, while center is undefined upon function entry.
Implements SoShape.
Member Data Documentation
SoSFFloat SoSphere::radius
Radius of sphere. Default value is 1.0.
Author
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Contenus ©2006-2024 Benjamin Poulain
Design ©2006-2024 Maxime Vantorre