The sbspheresheetprojector class projects 2d points to 3d points on a sheet covering a spherical shape. the following stand-alone example shows how screen space coordinates projects into 3d when mapped with an sbspheresheetprojector. it outputs the resulting projections as an sopointset in a inventor-file on stdout:
#include <Inventor/projectors/SbSphereSheetProjector.h>
Inherits SbSphereProjector.
SbSphereSheetProjector (const SbBool orienttoeye=TRUE)
SbSphereSheetProjector (const SbSphere &sph, const SbBool orienttoeye=TRUE)
virtual SbProjector * copy (void) const
virtual SbVec3f project (const SbVec2f &point)
virtual SbRotation getRotation (const SbVec3f &point1, const SbVec3f &point2)
void setupPlane (void)
SbVec3f workingProjPoint
SbVec3f planePoint
SbVec3f planeDir
float planeDist
SbPlane tolPlane
The SbSphereSheetProjector class projects 2D points to 3D points on a sheet covering a spherical shape.
The following stand-alone example shows how screen space coordinates projects into 3D when mapped with an SbSphereSheetProjector. It outputs the resulting projections as an SoPointSet in a Inventor-file on stdout:
#include <stdio.h>
#include <Inventor/SbLinear.h>
#include <Inventor/projectors/SbSphereSheetProjector.h>
#include <Inventor/SoDB.h>
int
main(void)
{
SoDB::init();
const float START = 0.0f;
const float END = 1.0f;
const float STEPS = 50.0f;
const float STEPSIZE = ((END - START) / STEPS);
SbSphere s(SbVec3f(0, 0, 0), 0.8);
SbSphereSheetProjector ssp(s, TRUE); // last argument is orientToEye
SbViewVolume volume;
volume.ortho(-1, 1, -1, 1, -1, 1);
ssp.setViewVolume(volume);
(void)fprintf(stdout, "#Inventor V2.1 ascii\n\n"
"Separator {\n"
" Coordinate3 {\n"
" point [\n");
for (float i=START; i <= END; i += STEPSIZE) {
for (float j=START; j <= END; j += STEPSIZE) {
SbVec3f v = ssp.project(SbVec2f(j, i));
(void)fprintf(stdout, "\t%f %f %f,\n", v[0], v[1], v[2]);
}
}
(void)fprintf(stdout, " ]\n"
" }\n"
" DrawStyle { pointSize 2 }\n"
" PointSet { }\n"
"}\n");
return 0;
}
The projections to 3D points in the resulting Inventor-file looks like this:
Constructor. Uses default sphere defintion, see SbSphereProjector::SbSphereProjector().
orienttoeye decides whether or not the sheet should always be oriented towards the viewer.
Constructor with explicit definition of projection sphere.
Construct and return a copy of this projector. The caller is responsible for destructing the new instance.
Note that if the Coin library has been built as a DLL under Microsoft Windows and you use this method from application code, you must make sure that both the Coin DLL and the application executable is using the same instance of a C Run-Time (CRT) library. Otherwise, you will get memory heap corruption upon deallocating the returned instances, eventually leading to mysterious crashes.
Implements SbProjector.
Project the 2D point from normalized viewport coordinates to a 3D point. The mapping will be done in accordance with the type of the projector.
Implements SbProjector.
Returns rotation on the projection surface which re-orients point1 to point2.
Implements SbSphereProjector.
Recalculates projection surface settings after changes to the parameters.
Last projected point, in the working space coordinate system.
Position of the center of the sphere in the plane of the hyberbolic sheet.
Normal vector of the plane defining the orientation of the sheet.
This API member is considered internal to the library, as it is not likely to be of interest to the application programmer.
The tolerance value specifying how much of the sphere is 'above' the sheet.
Generated automatically by Doxygen for Coin from the source code.