// python wrapper for vtkSphericalDirectionEncoder // #define VTK_WRAPPING_CXX #define VTK_STREAMS_FWD_ONLY #include "vtkPythonArgs.h" #include "vtkPythonOverload.h" #include "vtkConfigure.h" #include #include #include "vtkVariant.h" #include "vtkIndent.h" #include "vtkSphericalDirectionEncoder.h" extern "C" { VTK_ABI_EXPORT void PyVTKAddFile_vtkSphericalDirectionEncoder(PyObject *); } extern "C" { VTK_ABI_EXPORT PyObject *PyvtkSphericalDirectionEncoder_ClassNew(); } #ifndef DECLARED_PyvtkDirectionEncoder_ClassNew extern "C" { PyObject *PyvtkDirectionEncoder_ClassNew(); } #define DECLARED_PyvtkDirectionEncoder_ClassNew #endif static const char *PyvtkSphericalDirectionEncoder_Doc = "vtkSphericalDirectionEncoder - A direction encoder based on spherical\ncoordinates\n\n" "Superclass: vtkDirectionEncoder\n\n" "vtkSphericalDirectionEncoder is a direction encoder which uses\n" "spherical coordinates for mapping (nx, ny, nz) into an azimuth,\n" "elevation pair.\n\n" "@sa\n" "vtkDirectionEncoder\n\n"; static PyObject * PyvtkSphericalDirectionEncoder_IsTypeOf(PyObject *, PyObject *args) { vtkPythonArgs ap(args, "IsTypeOf"); char *temp0 = nullptr; PyObject *result = nullptr; if (ap.CheckArgCount(1) && ap.GetValue(temp0)) { int tempr = vtkSphericalDirectionEncoder::IsTypeOf(temp0); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_IsA(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "IsA"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkSphericalDirectionEncoder *op = static_cast(vp); char *temp0 = nullptr; PyObject *result = nullptr; if (op && ap.CheckArgCount(1) && ap.GetValue(temp0)) { int tempr = (ap.IsBound() ? op->IsA(temp0) : op->vtkSphericalDirectionEncoder::IsA(temp0)); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_SafeDownCast(PyObject *, PyObject *args) { vtkPythonArgs ap(args, "SafeDownCast"); vtkObjectBase *temp0 = nullptr; PyObject *result = nullptr; if (ap.CheckArgCount(1) && ap.GetVTKObject(temp0, "vtkObjectBase")) { vtkSphericalDirectionEncoder *tempr = vtkSphericalDirectionEncoder::SafeDownCast(temp0); if (!ap.ErrorOccurred()) { result = ap.BuildVTKObject(tempr); } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_NewInstance(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "NewInstance"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkSphericalDirectionEncoder *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { vtkSphericalDirectionEncoder *tempr = (ap.IsBound() ? op->NewInstance() : op->vtkSphericalDirectionEncoder::NewInstance()); if (!ap.ErrorOccurred()) { result = ap.BuildVTKObject(tempr); if (result && PyVTKObject_Check(result)) { PyVTKObject_GetObject(result)->UnRegister(0); PyVTKObject_SetFlag(result, VTK_PYTHON_IGNORE_UNREGISTER, 1); } } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_GetEncodedDirection(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "GetEncodedDirection"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkSphericalDirectionEncoder *op = static_cast(vp); const int size0 = 3; float temp0[3]; float save0[3]; PyObject *result = nullptr; if (op && ap.CheckArgCount(1) && ap.GetArray(temp0, size0)) { ap.SaveArray(temp0, save0, size0); int tempr = (ap.IsBound() ? op->GetEncodedDirection(temp0) : op->vtkSphericalDirectionEncoder::GetEncodedDirection(temp0)); if (ap.ArrayHasChanged(temp0, save0, size0) && !ap.ErrorOccurred()) { ap.SetArray(0, temp0, size0); } if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_GetDecodedGradient(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "GetDecodedGradient"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkSphericalDirectionEncoder *op = static_cast(vp); int temp0; int sizer = 3; PyObject *result = nullptr; if (op && ap.CheckArgCount(1) && ap.GetValue(temp0)) { float *tempr = (ap.IsBound() ? op->GetDecodedGradient(temp0) : op->vtkSphericalDirectionEncoder::GetDecodedGradient(temp0)); if (!ap.ErrorOccurred()) { result = ap.BuildTuple(tempr, sizer); } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_GetNumberOfEncodedDirections(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "GetNumberOfEncodedDirections"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkSphericalDirectionEncoder *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { int tempr = (ap.IsBound() ? op->GetNumberOfEncodedDirections() : op->vtkSphericalDirectionEncoder::GetNumberOfEncodedDirections()); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkSphericalDirectionEncoder_GetDecodedGradientTable(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "GetDecodedGradientTable"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkSphericalDirectionEncoder *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { float *tempr = (ap.IsBound() ? op->GetDecodedGradientTable() : op->vtkSphericalDirectionEncoder::GetDecodedGradientTable()); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyMethodDef PyvtkSphericalDirectionEncoder_Methods[] = { {"IsTypeOf", PyvtkSphericalDirectionEncoder_IsTypeOf, METH_VARARGS, "V.IsTypeOf(string) -> int\nC++: static vtkTypeBool IsTypeOf(const char *type)\n\nGet the name of this class\n"}, {"IsA", PyvtkSphericalDirectionEncoder_IsA, METH_VARARGS, "V.IsA(string) -> int\nC++: vtkTypeBool IsA(const char *type) override;\n\nGet the name of this class\n"}, {"SafeDownCast", PyvtkSphericalDirectionEncoder_SafeDownCast, METH_VARARGS, "V.SafeDownCast(vtkObjectBase) -> vtkSphericalDirectionEncoder\nC++: static vtkSphericalDirectionEncoder *SafeDownCast(\n vtkObjectBase *o)\n\nGet the name of this class\n"}, {"NewInstance", PyvtkSphericalDirectionEncoder_NewInstance, METH_VARARGS, "V.NewInstance() -> vtkSphericalDirectionEncoder\nC++: vtkSphericalDirectionEncoder *NewInstance()\n\nGet the name of this class\n"}, {"GetEncodedDirection", PyvtkSphericalDirectionEncoder_GetEncodedDirection, METH_VARARGS, "V.GetEncodedDirection([float, float, float]) -> int\nC++: int GetEncodedDirection(float n[3]) override;\n\nGiven a normal vector n, return the encoded direction\n"}, {"GetDecodedGradient", PyvtkSphericalDirectionEncoder_GetDecodedGradient, METH_VARARGS, "V.GetDecodedGradient(int) -> (float, float, float)\nC++: float *GetDecodedGradient(int value) override;\n\n/ Given an encoded value, return a pointer to the normal vector\n"}, {"GetNumberOfEncodedDirections", PyvtkSphericalDirectionEncoder_GetNumberOfEncodedDirections, METH_VARARGS, "V.GetNumberOfEncodedDirections() -> int\nC++: int GetNumberOfEncodedDirections(void) override;\n\nReturn the number of encoded directions\n"}, {"GetDecodedGradientTable", PyvtkSphericalDirectionEncoder_GetDecodedGradientTable, METH_VARARGS, "V.GetDecodedGradientTable() -> (float, ...)\nC++: float *GetDecodedGradientTable(void) override;\n\nGet the decoded gradient table. There are\nthis->GetNumberOfEncodedDirections() entries in the table, each\ncontaining a normal (direction) vector. This is a flat structure\n- 3 times the number of directions floats in an array.\n"}, {nullptr, nullptr, 0, nullptr} }; static PyTypeObject PyvtkSphericalDirectionEncoder_Type = { PyVarObject_HEAD_INIT(&PyType_Type, 0) "vtkRenderingVolumePython.vtkSphericalDirectionEncoder", // tp_name sizeof(PyVTKObject), // tp_basicsize 0, // tp_itemsize PyVTKObject_Delete, // tp_dealloc 0, // tp_print nullptr, // tp_getattr nullptr, // tp_setattr nullptr, // tp_compare PyVTKObject_Repr, // tp_repr nullptr, // tp_as_number nullptr, // tp_as_sequence nullptr, // tp_as_mapping nullptr, // tp_hash nullptr, // tp_call PyVTKObject_String, // tp_str PyObject_GenericGetAttr, // tp_getattro PyObject_GenericSetAttr, // tp_setattro &PyVTKObject_AsBuffer, // tp_as_buffer Py_TPFLAGS_DEFAULT|Py_TPFLAGS_HAVE_GC|Py_TPFLAGS_BASETYPE, // tp_flags PyvtkSphericalDirectionEncoder_Doc, // tp_doc PyVTKObject_Traverse, // tp_traverse nullptr, // tp_clear nullptr, // tp_richcompare offsetof(PyVTKObject, vtk_weakreflist), // tp_weaklistoffset nullptr, // tp_iter nullptr, // tp_iternext nullptr, // tp_methods nullptr, // tp_members PyVTKObject_GetSet, // tp_getset nullptr, // tp_base nullptr, // tp_dict nullptr, // tp_descr_get nullptr, // tp_descr_set offsetof(PyVTKObject, vtk_dict), // tp_dictoffset nullptr, // tp_init nullptr, // tp_alloc PyVTKObject_New, // tp_new PyObject_GC_Del, // tp_free nullptr, // tp_is_gc nullptr, // tp_bases nullptr, // tp_mro nullptr, // tp_cache nullptr, // tp_subclasses nullptr, // tp_weaklist VTK_WRAP_PYTHON_SUPPRESS_UNINITIALIZED }; static vtkObjectBase *PyvtkSphericalDirectionEncoder_StaticNew() { return vtkSphericalDirectionEncoder::New(); } PyObject *PyvtkSphericalDirectionEncoder_ClassNew() { PyVTKClass_Add( &PyvtkSphericalDirectionEncoder_Type, PyvtkSphericalDirectionEncoder_Methods, "vtkSphericalDirectionEncoder", &PyvtkSphericalDirectionEncoder_StaticNew); PyTypeObject *pytype = &PyvtkSphericalDirectionEncoder_Type; if ((pytype->tp_flags & Py_TPFLAGS_READY) != 0) { return (PyObject *)pytype; } #if !defined(VTK_PY3K) && PY_VERSION_HEX >= 0x02060000 pytype->tp_flags |= Py_TPFLAGS_HAVE_NEWBUFFER; #endif pytype->tp_base = (PyTypeObject *)PyvtkDirectionEncoder_ClassNew(); PyType_Ready(pytype); return (PyObject *)pytype; } void PyVTKAddFile_vtkSphericalDirectionEncoder( PyObject *dict) { PyObject *o; o = PyvtkSphericalDirectionEncoder_ClassNew(); if (o && PyDict_SetItemString(dict, "vtkSphericalDirectionEncoder", o) != 0) { Py_DECREF(o); } }