/* SPDX-License-Identifier: GPL-2.0-or-later */ /** \file * \ingroup freestyle */ #include "BPy_DensityF1D.h" #include "../../../stroke/AdvancedFunctions1D.h" #include "../../BPy_Convert.h" #include "../../BPy_IntegrationType.h" #ifdef __cplusplus extern "C" { #endif using namespace Freestyle; /////////////////////////////////////////////////////////////////////////////////////////// //------------------------INSTANCE METHODS ---------------------------------- static char DensityF1D___doc__[] = "Class hierarchy: :class:`freestyle.types.UnaryFunction1D` > " ":class:`freestyle.types.UnaryFunction1DDouble` > :class:`DensityF1D`\n" "\n" ".. method:: __init__(sigma=2.0, integration_type=IntegrationType.MEAN, sampling=2.0)\n" "\n" " Builds a DensityF1D object.\n" "\n" " :arg sigma: The sigma used in DensityF0D and determining the window size\n" " used in each density query.\n" " :type sigma: float\n" " :arg integration_type: The integration method used to compute a single value\n" " from a set of values.\n" " :type integration_type: :class:`freestyle.types.IntegrationType`\n" " :arg sampling: The resolution used to sample the chain: the\n" " corresponding 0D function is evaluated at each sample point and\n" " the result is obtained by combining the resulting values into a\n" " single one, following the method specified by integration_type.\n" " :type sampling: float\n" "\n" ".. method:: __call__(inter)\n" "\n" " Returns the density evaluated for an Interface1D. The density is\n" " evaluated for a set of points along the Interface1D (using the\n" " :class:`freestyle.functions.DensityF0D` functor) with a user-defined\n" " sampling and then integrated into a single value using a user-defined\n" " integration method.\n" "\n" " :arg inter: An Interface1D object.\n" " :type inter: :class:`freestyle.types.Interface1D`\n" " :return: The density evaluated for an Interface1D.\n" " :rtype: float\n"; static int DensityF1D___init__(BPy_DensityF1D *self, PyObject *args, PyObject *kwds) { static const char *kwlist[] = {"sigma", "integration_type", "sampling", nullptr}; PyObject *obj = nullptr; double d = 2.0; float f = 2.0; if (!PyArg_ParseTupleAndKeywords( args, kwds, "|dO!f", (char **)kwlist, &d, &IntegrationType_Type, &obj, &f)) { return -1; } IntegrationType t = (obj) ? IntegrationType_from_BPy_IntegrationType(obj) : MEAN; self->py_uf1D_double.uf1D_double = new Functions1D::DensityF1D(d, t, f); return 0; } /*-----------------------BPy_DensityF1D type definition ------------------------------*/ PyTypeObject DensityF1D_Type = { PyVarObject_HEAD_INIT(nullptr, 0) /*tp_name*/ "DensityF1D", /*tp_basicsize*/ sizeof(BPy_DensityF1D), /*tp_itemsize*/ 0, /*tp_dealloc*/ nullptr, /*tp_vectorcall_offset*/ 0, /*tp_getattr*/ nullptr, /*tp_setattr*/ nullptr, /*tp_as_async*/ nullptr, /*tp_repr*/ nullptr, /*tp_as_number*/ nullptr, /*tp_as_sequence*/ nullptr, /*tp_as_mapping*/ nullptr, /*tp_hash*/ nullptr, /*tp_call*/ nullptr, /*tp_str*/ nullptr, /*tp_getattro*/ nullptr, /*tp_setattro*/ nullptr, /*tp_as_buffer*/ nullptr, /*tp_flags*/ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, /*tp_doc*/ DensityF1D___doc__, /*tp_traverse*/ nullptr, /*tp_clear*/ nullptr, /*tp_richcompare*/ nullptr, /*tp_weaklistoffset*/ 0, /*tp_iter*/ nullptr, /*tp_iternext*/ nullptr, /*tp_methods*/ nullptr, /*tp_members*/ nullptr, /*tp_getset*/ nullptr, /*tp_base*/ &UnaryFunction1DDouble_Type, /*tp_dict*/ nullptr, /*tp_descr_get*/ nullptr, /*tp_descr_set*/ nullptr, /*tp_dictoffset*/ 0, /*tp_init*/ (initproc)DensityF1D___init__, /*tp_alloc*/ nullptr, /*tp_new*/ nullptr, }; /////////////////////////////////////////////////////////////////////////////////////////// #ifdef __cplusplus } #endif