void register_Quat_class(){
{ //::osg::Quat
typedef bp::class_< osg::Quat > Quat_exposer_t;
Quat_exposer_t Quat_exposer = Quat_exposer_t( "Quat", "\n A quaternion class. It can be used to represent an orientation in 3D space.\n", bp::init< >() );
bp::scope Quat_scope( Quat_exposer );
Quat_exposer.def( bp::init< double, double, double, double >(( bp::arg("x"), bp::arg("y"), bp::arg("z"), bp::arg("w") )) );
Quat_exposer.def( bp::init< osg::Vec4f const & >(( bp::arg("v") )) );
bp::implicitly_convertible< osg::Vec4f const &, osg::Quat >();
Quat_exposer.def( bp::init< osg::Vec4d const & >(( bp::arg("v") )) );
bp::implicitly_convertible< osg::Vec4d const &, osg::Quat >();
Quat_exposer.def( bp::init< double, osg::Vec3f const & >(( bp::arg("angle"), bp::arg("axis") )) );
Quat_exposer.def( bp::init< double, osg::Vec3d const & >(( bp::arg("angle"), bp::arg("axis") )) );
Quat_exposer.def( bp::init< double, osg::Vec3f const &, double, osg::Vec3f const &, double, osg::Vec3f const & >(( bp::arg("angle1"), bp::arg("axis1"), bp::arg("angle2"), bp::arg("axis2"), bp::arg("angle3"), bp::arg("axis3") )) );
Quat_exposer.def( bp::init< double, osg::Vec3d const &, double, osg::Vec3d const &, double, osg::Vec3d const & >(( bp::arg("angle1"), bp::arg("axis1"), bp::arg("angle2"), bp::arg("axis2"), bp::arg("angle3"), bp::arg("axis3") )) );
{ //::osg::Quat::asVec3
typedef ::osg::Vec3d ( ::osg::Quat::*asVec3_function_type )( ) const;
Quat_exposer.def(
"asVec3"
, asVec3_function_type( &::osg::Quat::asVec3 ) );
}
{ //::osg::Quat::asVec4
typedef ::osg::Vec4d ( ::osg::Quat::*asVec4_function_type )( ) const;
Quat_exposer.def(
"asVec4"
, asVec4_function_type( &::osg::Quat::asVec4 ) );
}
{ //::osg::Quat::conj
typedef ::osg::Quat ( ::osg::Quat::*conj_function_type )( ) const;
Quat_exposer.def(
"conj"
, conj_function_type( &::osg::Quat::conj )
, "\n Conjugate\n" );
}
{ //::osg::Quat::get
typedef void ( ::osg::Quat::*get_function_type )( ::osg::Matrixf & ) const;
Quat_exposer.def(
"get"
, get_function_type( &::osg::Quat::get )
, ( bp::arg("matrix") ) );
}
{ //::osg::Quat::get
typedef void ( ::osg::Quat::*get_function_type )( ::osg::Matrixd & ) const;
Quat_exposer.def(
"get"
, get_function_type( &::osg::Quat::get )
, ( bp::arg("matrix") ) );
}
{ //::osg::Quat::getRotate
typedef boost::python::tuple ( *getRotate_function_type )( ::osg::Quat const & );
Quat_exposer.def(
"getRotate"
, getRotate_function_type( &getRotate_7cd433cce0eabe855a9b774688d2845e )
, ( bp::arg("inst") )
, " Return the angle and vector represented by the quaternion." );
}
{ //::osg::Quat::inverse
typedef ::osg::Quat const ( ::osg::Quat::*inverse_function_type )( ) const;
Quat_exposer.def(
"inverse"
, inverse_function_type( &::osg::Quat::inverse )
, "\n Multiplicative inverse method: q^(-1) = q^*/(q.q^*)\n" );
}
{ //::osg::Quat::length
typedef double ( ::osg::Quat::*length_function_type )( ) const;
Quat_exposer.def(
"length"
, length_function_type( &::osg::Quat::length )
, "\n Length of the quaternion = sqrt( vec . vec )\n" );
}
{ //::osg::Quat::length2
typedef double ( ::osg::Quat::*length2_function_type )( ) const;
Quat_exposer.def(
"length2"
, length2_function_type( &::osg::Quat::length2 )
, "\n Length of the quaternion = vec . vec\n" );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( double,double,double,double ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("angle"), bp::arg("x"), bp::arg("y"), bp::arg("z") ) );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( double,::osg::Vec3f const & ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("angle"), bp::arg("vec") ) );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( double,::osg::Vec3d const & ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("angle"), bp::arg("vec") ) );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( double,::osg::Vec3f const &,double,::osg::Vec3f const &,double,::osg::Vec3f const & ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("angle1"), bp::arg("axis1"), bp::arg("angle2"), bp::arg("axis2"), bp::arg("angle3"), bp::arg("axis3") ) );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( double,::osg::Vec3d const &,double,::osg::Vec3d const &,double,::osg::Vec3d const & ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("angle1"), bp::arg("axis1"), bp::arg("angle2"), bp::arg("axis2"), bp::arg("angle3"), bp::arg("axis3") ) );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( ::osg::Vec3f const &,::osg::Vec3f const & ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("vec1"), bp::arg("vec2") )
, "\n Make a rotation Quat which will rotate vec1 to vec2.\n Generally take a dot product to get the angle between these\n and then use a cross product to get the rotation axis\n Watch out for the two special cases when the vectors\n are co-incident or opposite in direction.\n" );
}
{ //::osg::Quat::makeRotate
typedef void ( ::osg::Quat::*makeRotate_function_type )( ::osg::Vec3d const &,::osg::Vec3d const & ) ;
Quat_exposer.def(
"makeRotate"
, makeRotate_function_type( &::osg::Quat::makeRotate )
, ( bp::arg("vec1"), bp::arg("vec2") )
, "\n Make a rotation Quat which will rotate vec1 to vec2.\n Generally take a dot product to get the angle between these\n and then use a cross product to get the rotation axis\n Watch out for the two special cases of when the vectors\n are co-incident or opposite in direction.\n" );
}
{ //::osg::Quat::makeRotate_original
typedef void ( ::osg::Quat::*makeRotate_original_function_type )( ::osg::Vec3d const &,::osg::Vec3d const & ) ;
Quat_exposer.def(
"makeRotate_original"
, makeRotate_original_function_type( &::osg::Quat::makeRotate_original )
, ( bp::arg("vec1"), bp::arg("vec2") ) );
}
Quat_exposer.def( bp::self != bp::self );
Quat_exposer.def( bp::self * bp::other< double >() );
Quat_exposer.def( bp::self * bp::self );
Quat_exposer.def( bp::self * bp::other< osg::Vec3f >() );
Quat_exposer.def( bp::self * bp::other< osg::Vec3d >() );
Quat_exposer.def( bp::self *= bp::other< double >() );
Quat_exposer.def( bp::self *= bp::self );
Quat_exposer.def( bp::self + bp::self );
Quat_exposer.def( bp::self += bp::self );
Quat_exposer.def( bp::self - bp::self );
Quat_exposer.def( -bp::self );
Quat_exposer.def( bp::self -= bp::self );
Quat_exposer.def( bp::self / bp::other< double >() );
Quat_exposer.def( bp::self / bp::self );
Quat_exposer.def( bp::self /= bp::other< double >() );
Quat_exposer.def( bp::self /= bp::self );
Quat_exposer.def( bp::self < bp::self );
{ //::osg::Quat::operator=
typedef ::osg::Quat & ( ::osg::Quat::*assign_function_type )( ::osg::Quat const & ) ;
Quat_exposer.def(
"assign"
, assign_function_type( &::osg::Quat::operator= )
, ( bp::arg("v") )
, bp::return_self< >() );
}
Quat_exposer.def( bp::self == bp::self );
{ //::osg::Quat::operator[]
typedef double & ( ::osg::Quat::*__getitem___function_type )( int ) ;
Quat_exposer.def(
"__getitem__"
, __getitem___function_type( &::osg::Quat::operator[] )
, ( bp::arg("i") )
, bp::return_value_policy< bp::copy_non_const_reference >() );
}
{ //::osg::Quat::operator[]
typedef double ( ::osg::Quat::*__getitem___function_type )( int ) const;
Quat_exposer.def(
"__getitem__"
, __getitem___function_type( &::osg::Quat::operator[] )
, ( bp::arg("i") ) );
}
{ //::osg::Quat::set
typedef void ( ::osg::Quat::*set_function_type )( double,double,double,double ) ;
Quat_exposer.def(
"set"
, set_function_type( &::osg::Quat::set )
, ( bp::arg("x"), bp::arg("y"), bp::arg("z"), bp::arg("w") ) );
}
{ //::osg::Quat::set
typedef void ( ::osg::Quat::*set_function_type )( ::osg::Vec4f const & ) ;
Quat_exposer.def(
"set"
, set_function_type( &::osg::Quat::set )
, ( bp::arg("v") ) );
}
{ //::osg::Quat::set
typedef void ( ::osg::Quat::*set_function_type )( ::osg::Vec4d const & ) ;
Quat_exposer.def(
"set"
, set_function_type( &::osg::Quat::set )
, ( bp::arg("v") ) );
}
{ //::osg::Quat::set
typedef void ( ::osg::Quat::*set_function_type )( ::osg::Matrixf const & ) ;
Quat_exposer.def(
"set"
, set_function_type( &::osg::Quat::set )
, ( bp::arg("matrix") ) );
}
{ //::osg::Quat::set
typedef void ( ::osg::Quat::*set_function_type )( ::osg::Matrixd const & ) ;
Quat_exposer.def(
"set"
, set_function_type( &::osg::Quat::set )
, ( bp::arg("matrix") ) );
}
{ //::osg::Quat::slerp
typedef void ( ::osg::Quat::*slerp_function_type )( double,::osg::Quat const &,::osg::Quat const & ) ;
Quat_exposer.def(
"slerp"
, slerp_function_type( &::osg::Quat::slerp )
, ( bp::arg("t"), bp::arg("from"), bp::arg("to") )
, "\n Spherical Linear Interpolation.\n As t goes from 0 to 1, the Quat object goes from from to to.\n" );
}
{ //::osg::Quat::w
typedef double & ( ::osg::Quat::*w_function_type )( ) ;
Quat_exposer.def(
"w"
, w_function_type( &::osg::Quat::w )
, bp::return_value_policy< bp::copy_non_const_reference >() );
}
{ //::osg::Quat::w
typedef double ( ::osg::Quat::*w_function_type )( ) const;
Quat_exposer.def(
"w"
, w_function_type( &::osg::Quat::w ) );
}
{ //::osg::Quat::x
typedef double & ( ::osg::Quat::*x_function_type )( ) ;
Quat_exposer.def(
"x"
, x_function_type( &::osg::Quat::x )
, bp::return_value_policy< bp::copy_non_const_reference >() );
}
{ //::osg::Quat::x
typedef double ( ::osg::Quat::*x_function_type )( ) const;
Quat_exposer.def(
"x"
, x_function_type( &::osg::Quat::x ) );
}
{ //::osg::Quat::y
typedef double & ( ::osg::Quat::*y_function_type )( ) ;
Quat_exposer.def(
"y"
, y_function_type( &::osg::Quat::y )
, bp::return_value_policy< bp::copy_non_const_reference >() );
}
{ //::osg::Quat::y
typedef double ( ::osg::Quat::*y_function_type )( ) const;
Quat_exposer.def(
"y"
, y_function_type( &::osg::Quat::y ) );
}
{ //::osg::Quat::z
typedef double & ( ::osg::Quat::*z_function_type )( ) ;
Quat_exposer.def(
"z"
, z_function_type( &::osg::Quat::z )
, bp::return_value_policy< bp::copy_non_const_reference >() );
}
{ //::osg::Quat::z
typedef double ( ::osg::Quat::*z_function_type )( ) const;
Quat_exposer.def(
"z"
, z_function_type( &::osg::Quat::z ) );
}
{ //::osg::Quat::zeroRotation
typedef bool ( ::osg::Quat::*zeroRotation_function_type )( ) const;
Quat_exposer.def(
"zeroRotation"
, zeroRotation_function_type( &::osg::Quat::zeroRotation )
, "\n return true if the Quat represents a zero rotation, and therefore can be ignored in computations.\n" );
}
Quat_exposer.def( bp::self_ns::str( bp::self ) );
Quat_exposer.def( bp::self_ns::str(bp::self) );
Quat_exposer.def(bp::indexing::container_suite<
osg::Quat,
bp::indexing::all_methods,
OsgVec_algorithms<osg::Quat, osg::Quat::value_type, 4> >());
}
}
void register_Plane_class(){
{ //::osg::Plane
typedef bp::class_< osg::Plane > Plane_exposer_t;
Plane_exposer_t Plane_exposer = Plane_exposer_t( "Plane", "\n A plane class. It can be used to represent an infinite plane.\n\n The infinite plane is described by an implicit plane equation a*x+b*y+c*z+d = 0. Though it is not mandatory that\n a^2+b^2+c^2 = 1 is fulfilled in general some methods require it (aee osg::Plane::distance).\n", bp::init< >("\n Default constructor\n The default constructor initializes all values to zero.\n Warning: Although the method osg::Plane::valid() will return true after the default constructors call the plane\n is mathematically invalid! Default data do not describe a valid plane.\n") );
bp::scope Plane_scope( Plane_exposer );
bp::scope().attr("num_components") = (int)osg::Plane::num_components;
Plane_exposer.def( bp::init< osg::Plane const & >(( bp::arg("pl") )) );
Plane_exposer.def( bp::init< double, double, double, double >(( bp::arg("a"), bp::arg("b"), bp::arg("c"), bp::arg("d") ), "\n Constructor\n The plane is described as a*x+b*y+c*z+d = 0.\n @remark You may call osg::Plane::MakeUnitLength afterwards if the passed values are not normalized.\n") );
Plane_exposer.def( bp::init< osg::Vec4f const & >(( bp::arg("vec") ), "\n Constructor\n The plane can also be described as vec*[x,y,z,1].\n @remark You may call osg::Plane::MakeUnitLength afterwards if the passed values are not normalized.\n") );
bp::implicitly_convertible< osg::Vec4f const &, osg::Plane >();
Plane_exposer.def( bp::init< osg::Vec4d const & >(( bp::arg("vec") ), "\n Constructor\n The plane can also be described as vec*[x,y,z,1].\n @remark You may call osg::Plane::MakeUnitLength afterwards if the passed values are not normalized.\n") );
bp::implicitly_convertible< osg::Vec4d const &, osg::Plane >();
Plane_exposer.def( bp::init< osg::Vec3d const &, double >(( bp::arg("norm"), bp::arg("d") ), "\n Constructor\n This constructor initializes the internal values directly without any checking or manipulation.\n @param norm: The normal of the plane.\n @param d: The negative distance from the point of origin to the plane.\n @remark You may call osg::Plane::MakeUnitLength afterwards if the passed normal was not normalized.\n") );
Plane_exposer.def( bp::init< osg::Vec3d const &, osg::Vec3d const &, osg::Vec3d const & >(( bp::arg("v1"), bp::arg("v2"), bp::arg("v3") ), "\n Constructor\n This constructor calculates from the three points describing an infinite plane the internal values.\n @param v1: Point in the plane.\n @param v2: Point in the plane.\n @param v3: Point in the plane.\n @remark After this constructor call the planes normal is normalized in case the three points described a mathematically\n valid plane.\n @remark The normal is determined by building the cross product of (v2-v1) ^ (v3-v2).\n") );
Plane_exposer.def( bp::init< osg::Vec3d const &, osg::Vec3d const & >(( bp::arg("norm"), bp::arg("point") ), "\n Constructor\n This constructor initializes the internal values directly without any checking or manipulation.\n @param norm: The normal of the plane.\n @param point: A point of the plane.\n @remark You may call osg::Plane::MakeUnitLength afterwards if the passed normal was not normalized.\n") );
{ //::osg::Plane::asVec4
typedef ::osg::Vec4d ( ::osg::Plane::*asVec4_function_type)( ) const;
Plane_exposer.def(
"asVec4"
, asVec4_function_type( &::osg::Plane::asVec4 ) );
}
{ //::osg::Plane::calculateUpperLowerBBCorners
typedef void ( ::osg::Plane::*calculateUpperLowerBBCorners_function_type)( ) ;
Plane_exposer.def(
"calculateUpperLowerBBCorners"
, calculateUpperLowerBBCorners_function_type( &::osg::Plane::calculateUpperLowerBBCorners )
, "\n calculate the upper and lower bounding box corners to be used\n in the intersect(BoundingBox&) method for speeding calculations.\n" );
}
{ //::osg::Plane::distance
typedef float ( ::osg::Plane::*distance_function_type)( ::osg::Vec3f const & ) const;
Plane_exposer.def(
"distance"
, distance_function_type( &::osg::Plane::distance )
, ( bp::arg("v") )
, "\n Calculate the distance between a point and the plane.\n @remark This method only leads to real distance values if the planes norm is 1.\n aa osg::Plane::makeUnitLength\n" );
}
{ //::osg::Plane::distance
typedef double ( ::osg::Plane::*distance_function_type)( ::osg::Vec3d const & ) const;
Plane_exposer.def(
"distance"
, distance_function_type( &::osg::Plane::distance )
, ( bp::arg("v") )
, "\n Calculate the distance between a point and the plane.\n @remark This method only leads to real distance values if the planes norm is 1.\n aa osg::Plane::makeUnitLength\n" );
}
{ //::osg::Plane::dotProductNormal
typedef float ( ::osg::Plane::*dotProductNormal_function_type)( ::osg::Vec3f const & ) const;
Plane_exposer.def(
"dotProductNormal"
, dotProductNormal_function_type( &::osg::Plane::dotProductNormal )
, ( bp::arg("v") )
, "\n calculate the dot product of the plane normal and a point.\n" );
}
{ //::osg::Plane::dotProductNormal
typedef double ( ::osg::Plane::*dotProductNormal_function_type)( ::osg::Vec3d const & ) const;
Plane_exposer.def(
"dotProductNormal"
, dotProductNormal_function_type( &::osg::Plane::dotProductNormal )
, ( bp::arg("v") )
, "\n calculate the dot product of the plane normal and a point.\n" );
}
{ //::osg::Plane::flip
typedef void ( ::osg::Plane::*flip_function_type)( ) ;
Plane_exposer.def(
"flip"
, flip_function_type( &::osg::Plane::flip )
, "\n flip/reverse the orientation of the plane.\n" );
}
{ //::osg::Plane::getNormal
typedef ::osg::Vec3d ( ::osg::Plane::*getNormal_function_type)( ) const;
Plane_exposer.def(
"getNormal"
, getNormal_function_type( &::osg::Plane::getNormal ) );
}
{ //::osg::Plane::intersect
typedef int ( ::osg::Plane::*intersect_function_type)( ::std::vector< osg::Vec3f > const & ) const;
Plane_exposer.def(
"intersect"
, intersect_function_type( &::osg::Plane::intersect )
, ( bp::arg("vertices") )
, "\n intersection test between plane and vertex list\n return 1 if the bs is completely above plane,\n return 0 if the bs intersects the plane,\n return -1 if the bs is completely below the plane.\n" );
}
{ //::osg::Plane::intersect
typedef int ( ::osg::Plane::*intersect_function_type)( ::std::vector< osg::Vec3d > const & ) const;
Plane_exposer.def(
"intersect"
, intersect_function_type( &::osg::Plane::intersect )
, ( bp::arg("vertices") )
, "\n intersection test between plane and vertex list\n return 1 if the bs is completely above plane,\n return 0 if the bs intersects the plane,\n return -1 if the bs is completely below the plane.\n" );
}
{ //::osg::Plane::intersect
typedef int ( ::osg::Plane::*intersect_function_type)( ::osg::BoundingSphere const & ) const;
Plane_exposer.def(
"intersect"
, intersect_function_type( &::osg::Plane::intersect )
, ( bp::arg("bs") )
, "\n intersection test between plane and bounding sphere.\n return 1 if the bs is completely above plane,\n return 0 if the bs intersects the plane,\n return -1 if the bs is completely below the plane.\n" );
}
{ //::osg::Plane::intersect
typedef int ( ::osg::Plane::*intersect_function_type)( ::osg::BoundingBox const & ) const;
Plane_exposer.def(
"intersect"
, intersect_function_type( &::osg::Plane::intersect )
, ( bp::arg("bb") )
, "\n intersection test between plane and bounding sphere.\n return 1 if the bs is completely above plane,\n return 0 if the bs intersects the plane,\n return -1 if the bs is completely below the plane.\n" );
}
{ //::osg::Plane::isNaN
typedef bool ( ::osg::Plane::*isNaN_function_type)( ) const;
Plane_exposer.def(
"isNaN"
, isNaN_function_type( &::osg::Plane::isNaN ) );
}
{ //::osg::Plane::makeUnitLength
typedef void ( ::osg::Plane::*makeUnitLength_function_type)( ) ;
Plane_exposer.def(
"makeUnitLength"
, makeUnitLength_function_type( &::osg::Plane::makeUnitLength )
, "\n This method multiplies the coefficients of the plane equation with a constant factor so that the\n equation a^2+b^2+c^2 = 1 holds.\n" );
}
Plane_exposer.def( bp::self != bp::self );
Plane_exposer.def( bp::self < bp::self );
{ //::osg::Plane::operator=
typedef ::osg::Plane & ( ::osg::Plane::*assign_function_type)( ::osg::Plane const & ) ;
Plane_exposer.def(
"assign"
, assign_function_type( &::osg::Plane::operator= )
, ( bp::arg("pl") )
, bp::return_self< >() );
}
Plane_exposer.def( bp::self == bp::self );
{ //::osg::Plane::operator[]
typedef double & ( ::osg::Plane::*__getitem___function_type)( unsigned int ) ;
Plane_exposer.def(
"__getitem__"
, __getitem___function_type( &::osg::Plane::operator[] )
, ( bp::arg("i") )
, bp::return_value_policy< bp::copy_non_const_reference >() );
}
{ //::osg::Plane::operator[]
typedef double ( ::osg::Plane::*__getitem___function_type)( unsigned int ) const;
Plane_exposer.def(
"__getitem__"
, __getitem___function_type( &::osg::Plane::operator[] )
, ( bp::arg("i") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( ::osg::Plane const & ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("pl") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( double,double,double,double ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("a"), bp::arg("b"), bp::arg("c"), bp::arg("d") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( ::osg::Vec4f const & ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("vec") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( ::osg::Vec4d const & ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("vec") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( ::osg::Vec3d const &,double ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("norm"), bp::arg("d") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( ::osg::Vec3d const &,::osg::Vec3d const &,::osg::Vec3d const & ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("v1"), bp::arg("v2"), bp::arg("v3") ) );
}
{ //::osg::Plane::set
typedef void ( ::osg::Plane::*set_function_type)( ::osg::Vec3d const &,::osg::Vec3d const & ) ;
Plane_exposer.def(
"set"
, set_function_type( &::osg::Plane::set )
, ( bp::arg("norm"), bp::arg("point") ) );
}
{ //::osg::Plane::transform
typedef void ( ::osg::Plane::*transform_function_type)( ::osg::Matrix const & ) ;
Plane_exposer.def(
"transform"
, transform_function_type( &::osg::Plane::transform )
, ( bp::arg("matrix") )
, "\n Transform the plane by matrix. Note, this operation carries out\n the calculation of the inverse of the matrix since a plane\n must be multiplied by the inverse transposed to transform it. This\n make this operation expensive. If the inverse has been already\n calculated elsewhere then use transformProvidingInverse() instead.\n See http://www.worldserver.com/turk/computergraphics/NormalTransformations.pdf\n" );
}
{ //::osg::Plane::transformProvidingInverse
typedef void ( ::osg::Plane::*transformProvidingInverse_function_type)( ::osg::Matrix const & ) ;
Plane_exposer.def(
"transformProvidingInverse"
, transformProvidingInverse_function_type( &::osg::Plane::transformProvidingInverse )
, ( bp::arg("matrix") )
, "\n Transform the plane by providing a pre inverted matrix.\n see transform for details.\n" );
}
{ //::osg::Plane::valid
typedef bool ( ::osg::Plane::*valid_function_type)( ) const;
Plane_exposer.def(
"valid"
, valid_function_type( &::osg::Plane::valid )
, "\n Checks if all internal values describing the plane have valid numbers\n Warning: This method does not check if the plane is mathematically correctly described!\n @remark The only case where all elements have valid numbers and the plane description is invalid occurs if the planes normal\n is zero.\n" );
}
Plane_exposer.def( bp::self_ns::str( bp::self ) );
}
}
