'\"! tbl | mmdoc '\"macro stdmacro .ie n \{\ . ds Cr \fB . ds Cb \fB .\} .el \{\ . ds Cr \f7 . ds Cb \f8 .\} .TH SbCylinderSheetProjector(3IV) .SH NAME SbCylinderSheetProjector \(em cylinder-sheet projector .SH INHERITS FROM SbProjector > SbCylinderProjector > SbCylinderSheetProjector .SH SYNOPSIS .ps -1 \*(Cr#include .sp .in 1i \f1Methods from class SbCylinderSheetProjector: .in 0.5i .sp .ta 20m .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Cr .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbSbCylinderSheetProjector\*(Cr(SbBool orientToEye = TRUE) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Cr .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbSbCylinderSheetProjector\*(Cr(const SbCylinder &cyl, SbBool orientToEye = TRUE) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Cr .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(Cb~SbCylinderSheetProjector\*(Cr() .sp .in 1i \f1Methods from class SbCylinderProjector: .in 0.5i .sp .ta 20m .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(CrSbVec3f .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbprojectAndGetRotation\*(Cr(const SbVec2f &point, SbRotation &rot) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Crvirtual SbRotation .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbgetRotation\*(Cr(const SbVec3f &point1, const SbVec3f &point2) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Crvoid .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbsetCylinder\*(Cr(const SbCylinder &cyl) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Crconst SbCylinder & .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbgetCylinder\*(Cr() const .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Crvoid .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbsetOrientToEye\*(Cr(SbBool orientToEye) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(CrSbBool .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbisOrientToEye\*(Cr() const .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Crvoid .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbsetFront\*(Cr(SbBool isFront) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(CrSbBool .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbisFront\*(Cr() const .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(CrSbBool .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbisPointInFront\*(Cr(const SbVec3f &point) const .sp .in 1i \f1Methods from class SbProjector: .in 0.5i .sp .ta 23m .in 1i+23n .ti 0.5i .ta 23m .ds Pt \*(Crvirtual SbVec3f .ie \w'\*(Pt'>=23n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(Cbproject\*(Cr(const SbVec2f &point) .br .in 1i+23n .ti 0.5i .ta 23m .ds Pt \*(Crvirtual void .ie \w'\*(Pt'>=23n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbsetViewVolume\*(Cr(const SbViewVolume &vol) .br .in 1i+23n .ti 0.5i .ta 23m .ds Pt \*(Crconst SbViewVolume & .ie \w'\*(Pt'>=23n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbgetViewVolume\*(Cr() const .br .in 1i+23n .ti 0.5i .ta 23m .ds Pt \*(Crvirtual void .ie \w'\*(Pt'>=23n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbsetWorkingSpace\*(Cr(const SbMatrix &space) .br .in 1i+23n .ti 0.5i .ta 23m .ds Pt \*(Crconst SbMatrix & .ie \w'\*(Pt'>=23n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbgetWorkingSpace\*(Cr() const .br .in 1i+23n .ti 0.5i .ta 23m .ds Pt \*(Crvirtual SbProjector * .ie \w'\*(Pt'>=23n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(Cbcopy\*(Cr() const .sp .SH DESCRIPTION \*(CbSbCylinderSheetProjector\f1 projects a window space point (usually based on the mouse location) onto the surface of a cylinder with a hyperbolic sheet draped over it. This allows smooth transitions onto and off of the cylinder. \&Two projected points can produce a rotation along the cylinder's axis. When the mouse position projects on to the sheet, the rotations will be as if the sheet is being dragged, causing the cylinder to \&roll beneath it. .sp Incremental changes (delta rotation) can be computed during interactive sessions. Cylinder projectors are typically used to write interactive 3D manipulators and viewers. .SH METHODS .ta 20m .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Cr .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbSbCylinderSheetProjector\*(Cr(SbBool orientToEye = TRUE) .br .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Cr .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(CbSbCylinderSheetProjector\*(Cr(const SbCylinder &cyl, SbBool orientToEye = TRUE) .br .in 1i \f1Constructors. The first uses a default cylinder aligned with the Y axis with radius 1.0; the cylinder is supplied in the second. The \*(CborientToEye\f1 parameter determines whether the sheet is perpendicular to the eye, \&or perpendicular to the cylinder's Z axis. Setting that parameter to TRUE (the default) specifies that the plane be perpendicular to the eye, which is most often the desired behavior. .sp The default view \&volume is undefined, and the working space is identity. .sp .in 0.5i .in 1i+20n .ti 0.5i .ta 20m .ds Pt \*(Cr .ie \w'\*(Pt'>=20n \{\ .ne 3 \*(Pt .ti 0.5i \c\ \} .el\{\ .ne 2 \*(Pt \c\ \} \*(Cb~SbCylinderSheetProjector\*(Cr() .br .in 1i \f1Destructor. .sp .in 0.5i .SH SEE ALSO \*(CbSbCylinderSectionProjector, SbCylinderPlaneProjector, SbLineProjector, SbPlaneProjector, SbSpherePlaneProjector, SbSphereProjector, SbSphereSectionProjector, SbSphereSheetProjector