// python wrapper for vtkExtractTemporalFieldData // #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 "vtkExtractTemporalFieldData.h" extern "C" { VTK_ABI_EXPORT void PyVTKAddFile_vtkExtractTemporalFieldData(PyObject *); } extern "C" { VTK_ABI_EXPORT PyObject *PyvtkExtractTemporalFieldData_ClassNew(); } #ifndef DECLARED_PyvtkDataObjectAlgorithm_ClassNew extern "C" { PyObject *PyvtkDataObjectAlgorithm_ClassNew(); } #define DECLARED_PyvtkDataObjectAlgorithm_ClassNew #endif static const char *PyvtkExtractTemporalFieldData_Doc = "vtkExtractTemporalFieldData - Extract temporal arrays from input\nfield data\n\n" "Superclass: vtkDataObjectAlgorithm\n\n" "vtkExtractTemporalFieldData extracts arrays from the input\n" "vtkFieldData. These arrays are assumed to contain temporal data,\n" "where the nth tuple contains the value for the nth timestep.\n\n" "For composite datasets, the filter has two modes, it can treat each\n" "block in the dataset individually (default) or just look at the first\n" "non-empty field data (common for readers vtkExodusIIReader). For\n" "latter, set HandleCompositeDataBlocksIndividually to false.\n\n" "The output is a vtkTable (or a multiblock of vtkTables) based of\n" "whether HandleCompositeDataBlocksIndividually is true and input is a\n" "composite dataset.\n\n" "This algorithm does not produce a TIME_STEPS or TIME_RANGE\n" "information because it works across time.\n\n" "@par Caveat: This algorithm works only with source that produce\n" "TIME_STEPS(). Continuous time range is not yet supported.\n\n"; static PyObject * PyvtkExtractTemporalFieldData_IsTypeOf(PyObject *, PyObject *args) { vtkPythonArgs ap(args, "IsTypeOf"); char *temp0 = nullptr; PyObject *result = nullptr; if (ap.CheckArgCount(1) && ap.GetValue(temp0)) { int tempr = vtkExtractTemporalFieldData::IsTypeOf(temp0); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_IsA(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "IsA"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *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->vtkExtractTemporalFieldData::IsA(temp0)); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_SafeDownCast(PyObject *, PyObject *args) { vtkPythonArgs ap(args, "SafeDownCast"); vtkObjectBase *temp0 = nullptr; PyObject *result = nullptr; if (ap.CheckArgCount(1) && ap.GetVTKObject(temp0, "vtkObjectBase")) { vtkExtractTemporalFieldData *tempr = vtkExtractTemporalFieldData::SafeDownCast(temp0); if (!ap.ErrorOccurred()) { result = ap.BuildVTKObject(tempr); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_NewInstance(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "NewInstance"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { vtkExtractTemporalFieldData *tempr = (ap.IsBound() ? op->NewInstance() : op->vtkExtractTemporalFieldData::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 * PyvtkExtractTemporalFieldData_GetNumberOfTimeSteps(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "GetNumberOfTimeSteps"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { int tempr = (ap.IsBound() ? op->GetNumberOfTimeSteps() : op->vtkExtractTemporalFieldData::GetNumberOfTimeSteps()); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_SetHandleCompositeDataBlocksIndividually(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "SetHandleCompositeDataBlocksIndividually"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *op = static_cast(vp); bool temp0 = false; PyObject *result = nullptr; if (op && ap.CheckArgCount(1) && ap.GetValue(temp0)) { if (ap.IsBound()) { op->SetHandleCompositeDataBlocksIndividually(temp0); } else { op->vtkExtractTemporalFieldData::SetHandleCompositeDataBlocksIndividually(temp0); } if (!ap.ErrorOccurred()) { result = ap.BuildNone(); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_GetHandleCompositeDataBlocksIndividually(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "GetHandleCompositeDataBlocksIndividually"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { bool tempr = (ap.IsBound() ? op->GetHandleCompositeDataBlocksIndividually() : op->vtkExtractTemporalFieldData::GetHandleCompositeDataBlocksIndividually()); if (!ap.ErrorOccurred()) { result = ap.BuildValue(tempr); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_HandleCompositeDataBlocksIndividuallyOn(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "HandleCompositeDataBlocksIndividuallyOn"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { if (ap.IsBound()) { op->HandleCompositeDataBlocksIndividuallyOn(); } else { op->vtkExtractTemporalFieldData::HandleCompositeDataBlocksIndividuallyOn(); } if (!ap.ErrorOccurred()) { result = ap.BuildNone(); } } return result; } static PyObject * PyvtkExtractTemporalFieldData_HandleCompositeDataBlocksIndividuallyOff(PyObject *self, PyObject *args) { vtkPythonArgs ap(self, args, "HandleCompositeDataBlocksIndividuallyOff"); vtkObjectBase *vp = ap.GetSelfPointer(self, args); vtkExtractTemporalFieldData *op = static_cast(vp); PyObject *result = nullptr; if (op && ap.CheckArgCount(0)) { if (ap.IsBound()) { op->HandleCompositeDataBlocksIndividuallyOff(); } else { op->vtkExtractTemporalFieldData::HandleCompositeDataBlocksIndividuallyOff(); } if (!ap.ErrorOccurred()) { result = ap.BuildNone(); } } return result; } static PyMethodDef PyvtkExtractTemporalFieldData_Methods[] = { {"IsTypeOf", PyvtkExtractTemporalFieldData_IsTypeOf, METH_VARARGS, "V.IsTypeOf(string) -> int\nC++: static vtkTypeBool IsTypeOf(const char *type)\n\nReturn 1 if this class type is the same type of (or a subclass\nof) the named class. Returns 0 otherwise. This method works in\ncombination with vtkTypeMacro found in vtkSetGet.h.\n"}, {"IsA", PyvtkExtractTemporalFieldData_IsA, METH_VARARGS, "V.IsA(string) -> int\nC++: vtkTypeBool IsA(const char *type) override;\n\nReturn 1 if this class is the same type of (or a subclass of) the\nnamed class. Returns 0 otherwise. This method works in\ncombination with vtkTypeMacro found in vtkSetGet.h.\n"}, {"SafeDownCast", PyvtkExtractTemporalFieldData_SafeDownCast, METH_VARARGS, "V.SafeDownCast(vtkObjectBase) -> vtkExtractTemporalFieldData\nC++: static vtkExtractTemporalFieldData *SafeDownCast(\n vtkObjectBase *o)\n\n"}, {"NewInstance", PyvtkExtractTemporalFieldData_NewInstance, METH_VARARGS, "V.NewInstance() -> vtkExtractTemporalFieldData\nC++: vtkExtractTemporalFieldData *NewInstance()\n\n"}, {"GetNumberOfTimeSteps", PyvtkExtractTemporalFieldData_GetNumberOfTimeSteps, METH_VARARGS, "V.GetNumberOfTimeSteps() -> int\nC++: int GetNumberOfTimeSteps()\n\nGet the number of time steps\n"}, {"SetHandleCompositeDataBlocksIndividually", PyvtkExtractTemporalFieldData_SetHandleCompositeDataBlocksIndividually, METH_VARARGS, "V.SetHandleCompositeDataBlocksIndividually(bool)\nC++: virtual void SetHandleCompositeDataBlocksIndividually(\n bool _arg)\n\nWhen set to true (default), if the input is a\nvtkCompositeDataSet, then each block in the input dataset in\nprocessed separately. If false, then the first non-empty\nFieldData is considered.\n"}, {"GetHandleCompositeDataBlocksIndividually", PyvtkExtractTemporalFieldData_GetHandleCompositeDataBlocksIndividually, METH_VARARGS, "V.GetHandleCompositeDataBlocksIndividually() -> bool\nC++: virtual bool GetHandleCompositeDataBlocksIndividually()\n\nWhen set to true (default), if the input is a\nvtkCompositeDataSet, then each block in the input dataset in\nprocessed separately. If false, then the first non-empty\nFieldData is considered.\n"}, {"HandleCompositeDataBlocksIndividuallyOn", PyvtkExtractTemporalFieldData_HandleCompositeDataBlocksIndividuallyOn, METH_VARARGS, "V.HandleCompositeDataBlocksIndividuallyOn()\nC++: virtual void HandleCompositeDataBlocksIndividuallyOn()\n\nWhen set to true (default), if the input is a\nvtkCompositeDataSet, then each block in the input dataset in\nprocessed separately. If false, then the first non-empty\nFieldData is considered.\n"}, {"HandleCompositeDataBlocksIndividuallyOff", PyvtkExtractTemporalFieldData_HandleCompositeDataBlocksIndividuallyOff, METH_VARARGS, "V.HandleCompositeDataBlocksIndividuallyOff()\nC++: virtual void HandleCompositeDataBlocksIndividuallyOff()\n\nWhen set to true (default), if the input is a\nvtkCompositeDataSet, then each block in the input dataset in\nprocessed separately. If false, then the first non-empty\nFieldData is considered.\n"}, {nullptr, nullptr, 0, nullptr} }; static PyTypeObject PyvtkExtractTemporalFieldData_Type = { PyVarObject_HEAD_INIT(&PyType_Type, 0) "vtkFiltersExtractionPython.vtkExtractTemporalFieldData", // 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 PyvtkExtractTemporalFieldData_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 *PyvtkExtractTemporalFieldData_StaticNew() { return vtkExtractTemporalFieldData::New(); } PyObject *PyvtkExtractTemporalFieldData_ClassNew() { PyVTKClass_Add( &PyvtkExtractTemporalFieldData_Type, PyvtkExtractTemporalFieldData_Methods, "vtkExtractTemporalFieldData", &PyvtkExtractTemporalFieldData_StaticNew); PyTypeObject *pytype = &PyvtkExtractTemporalFieldData_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 *)PyvtkDataObjectAlgorithm_ClassNew(); PyType_Ready(pytype); return (PyObject *)pytype; } void PyVTKAddFile_vtkExtractTemporalFieldData( PyObject *dict) { PyObject *o; o = PyvtkExtractTemporalFieldData_ClassNew(); if (o && PyDict_SetItemString(dict, "vtkExtractTemporalFieldData", o) != 0) { Py_DECREF(o); } }