#include "aubio-types.h" static char Py_filterbank_doc[] = "" "filterbank(n_filters=40, win_s=1024)\n" "\n" "Create a bank of spectral filters. Each instance is a callable\n" "that holds a matrix of coefficients.\n" "\n" "See also :meth:`set_mel_coeffs`, :meth:`set_mel_coeffs_htk`,\n" ":meth:`set_mel_coeffs_slaney`, :meth:`set_triangle_bands`, and\n" ":meth:`set_coeffs`.\n" "\n" "Parameters\n" "----------\n" "n_filters : int\n" " Number of filters to create.\n" "win_s : int\n" " Size of the input spectrum to process.\n" "\n" "Examples\n" "--------\n" ">>> f = aubio.filterbank(128, 1024)\n" ">>> f.set_mel_coeffs(44100, 0, 10000)\n" ">>> c = aubio.cvec(1024)\n" ">>> f(c).shape\n" "(128, )\n" ""; static char Py_filterbank_set_triangle_bands_doc[] ="" "set_triangle_bands(freqs, samplerate)\n" "\n" "Set triangular bands. The coefficients will be set to triangular\n" "overlapping windows using the boundaries specified by `freqs`.\n" "\n" "`freqs` should contain `n_filters + 2` frequencies in Hz, ordered\n" "by value, from smallest to largest. The first element should be greater\n" "or equal to zero; the last element should be smaller or equal to\n" "`samplerate / 2`.\n" "\n" "Parameters\n" "----------\n" "freqs: fvec\n" " List of frequencies, in Hz.\n" "samplerate : float\n" " Sampling-rate of the expected input.\n" "\n" "Example\n" "-------\n" ">>> fb = aubio.filterbank(n_filters=100, win_s=2048)\n" ">>> samplerate = 44100; freqs = np.linspace(0, 20200, 102)\n" ">>> fb.set_triangle_bands(aubio.fvec(freqs), samplerate)\n" ""; static char Py_filterbank_set_mel_coeffs_slaney_doc[] = "" "set_mel_coeffs_slaney(samplerate)\n" "\n" "Set coefficients of filterbank to match Slaney's Auditory Toolbox.\n" "\n" "The filter coefficients will be set as in Malcolm Slaney's\n" "implementation. The filterbank should have been created with\n" "`n_filters = 40`.\n" "\n" "This is approximately equivalent to using :meth:`set_mel_coeffs` with\n" "`fmin = 400./3., fmax = 6853.84`.\n" "\n" "Parameters\n" "----------\n" "samplerate : float\n" " Sampling-rate of the expected input.\n" "\n" "References\n" "----------\n" "\n" "Malcolm Slaney, `Auditory Toolbox Version 2, Technical Report #1998-010\n" "`_\n" ""; static char Py_filterbank_set_mel_coeffs_doc[] = "" "set_mel_coeffs(samplerate, fmin, fmax)\n" "\n" "Set coefficients of filterbank to linearly spaced mel scale.\n" "\n" "Parameters\n" "----------\n" "samplerate : float\n" " Sampling-rate of the expected input.\n" "fmin : float\n" " Lower frequency boundary of the first filter.\n" "fmax : float\n" " Upper frequency boundary of the last filter.\n" "\n" "See also\n" "--------\n" "hztomel\n" ""; static char Py_filterbank_set_mel_coeffs_htk_doc[] = "" "set_mel_coeffs_htk(samplerate, fmin, fmax)\n" "\n" "Set coefficients of the filters to be linearly spaced in the HTK mel scale.\n" "\n" "Parameters\n" "----------\n" "samplerate : float\n" " Sampling-rate of the expected input.\n" "fmin : float\n" " Lower frequency boundary of the first filter.\n" "fmax : float\n" " Upper frequency boundary of the last filter.\n" "\n" "See also\n" "--------\n" "hztomel with `htk=True`\n" ""; static char Py_filterbank_get_coeffs_doc[] = "" "get_coeffs()\n" "\n" "Get coefficients matrix of filterbank.\n" "\n" "Returns\n" "-------\n" "array_like\n" " Array of shape (n_filters, win_s/2+1) containing the coefficients.\n" ""; static char Py_filterbank_set_coeffs_doc[] = "" "set_coeffs(coeffs)\n" "\n" "Set coefficients of filterbank.\n" "\n" "Parameters\n" "----------\n" "coeffs : fmat\n" " Array of shape (n_filters, win_s/2+1) containing the coefficients.\n" ""; static char Py_filterbank_set_power_doc[] = "" "set_power(power)\n" "\n" "Set power applied to input spectrum of filterbank.\n" "\n" "Parameters\n" "----------\n" "power : float\n" " Power to raise input spectrum to before computing the filters.\n" ""; static char Py_filterbank_get_power_doc[] = "" "get_power()\n" "\n" "Get power applied to filterbank.\n" "\n" "Returns\n" "-------\n" "float\n" " Power parameter.\n" ""; static char Py_filterbank_set_norm_doc[] = "" "set_norm(norm)\n" "\n" "Set norm parameter. If set to `0`, the filters will not be normalized.\n" "If set to `1`, the filters will be normalized to one. Default to `1`.\n" "\n" "This function should be called *before* :meth:`set_triangle_bands`,\n" ":meth:`set_mel_coeffs`, :meth:`set_mel_coeffs_htk`, or\n" ":meth:`set_mel_coeffs_slaney`.\n" "\n" "Parameters\n" "----------\n" "norm : int\n" " `0` to disable, `1` to enable\n" ""; static char Py_filterbank_get_norm_doc[] = "" "get_norm()\n" "\n" "Get norm parameter of filterbank.\n" "\n" "Returns\n" "-------\n" "float\n" " Norm parameter.\n" ""; typedef struct { PyObject_HEAD aubio_filterbank_t * o; uint_t n_filters; uint_t win_s; cvec_t vec; fvec_t freqs; fmat_t coeffs; PyObject *out; fvec_t c_out; } Py_filterbank; static PyObject * Py_filterbank_new (PyTypeObject * type, PyObject * args, PyObject * kwds) { int win_s = 0, n_filters = 0; Py_filterbank *self; static char *kwlist[] = { "n_filters", "win_s", NULL }; if (!PyArg_ParseTupleAndKeywords (args, kwds, "|II", kwlist, &n_filters, &win_s)) { return NULL; } self = (Py_filterbank *) type->tp_alloc (type, 0); if (self == NULL) { return NULL; } self->win_s = Py_default_vector_length; if (win_s > 0) { self->win_s = win_s; } else if (win_s < 0) { PyErr_SetString (PyExc_ValueError, "can not use negative window size"); return NULL; } self->n_filters = 40; if (n_filters > 0) { self->n_filters = n_filters; } else if (n_filters < 0) { PyErr_SetString (PyExc_ValueError, "can not use negative number of filters"); return NULL; } return (PyObject *) self; } static int Py_filterbank_init (Py_filterbank * self, PyObject * args, PyObject * kwds) { self->o = new_aubio_filterbank (self->n_filters, self->win_s); if (self->o == NULL) { PyErr_Format(PyExc_RuntimeError, "error creating filterbank with" " n_filters=%d, win_s=%d", self->n_filters, self->win_s); return -1; } self->out = new_py_fvec(self->n_filters); return 0; } static void Py_filterbank_del (Py_filterbank *self, PyObject *unused) { if (self->o) { free(self->coeffs.data); del_aubio_filterbank(self->o); } Py_XDECREF(self->out); Py_TYPE(self)->tp_free((PyObject *) self); } static PyObject * Py_filterbank_do(Py_filterbank * self, PyObject * args) { PyObject *input; if (!PyArg_ParseTuple (args, "O", &input)) { return NULL; } if (!PyAubio_PyCvecToCCvec(input, &(self->vec) )) { return NULL; } if (self->vec.length != self->win_s / 2 + 1) { PyErr_Format(PyExc_ValueError, "input cvec has length %d, but filterbank expects length %d", self->vec.length, self->win_s / 2 + 1); return NULL; } Py_INCREF(self->out); if (!PyAubio_ArrayToCFvec(self->out, &(self->c_out))) { return NULL; } // compute the function aubio_filterbank_do (self->o, &(self->vec), &(self->c_out)); return self->out; } static PyMemberDef Py_filterbank_members[] = { {"win_s", T_INT, offsetof (Py_filterbank, win_s), READONLY, "size of the window"}, {"n_filters", T_INT, offsetof (Py_filterbank, n_filters), READONLY, "number of filters"}, {NULL} /* sentinel */ }; static PyObject * Py_filterbank_set_triangle_bands (Py_filterbank * self, PyObject *args) { uint_t err = 0; PyObject *input; smpl_t samplerate; if (!PyArg_ParseTuple (args, "O" AUBIO_NPY_SMPL_CHR, &input, &samplerate)) { return NULL; } if (input == NULL) { return NULL; } if (!PyAubio_ArrayToCFvec(input, &(self->freqs) )) { return NULL; } err = aubio_filterbank_set_triangle_bands (self->o, &(self->freqs), samplerate); if (err > 0) { if (PyErr_Occurred() == NULL) { PyErr_SetString (PyExc_ValueError, "error running set_triangle_bands"); } else { // change the RuntimeError into ValueError PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_Restore(PyExc_ValueError, value, traceback); } return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_set_mel_coeffs_slaney (Py_filterbank * self, PyObject *args) { uint_t err = 0; smpl_t samplerate; if (!PyArg_ParseTuple (args, AUBIO_NPY_SMPL_CHR, &samplerate)) { return NULL; } err = aubio_filterbank_set_mel_coeffs_slaney (self->o, samplerate); if (err > 0) { if (PyErr_Occurred() == NULL) { PyErr_SetString (PyExc_ValueError, "error running set_mel_coeffs_slaney"); } else { // change the RuntimeError into ValueError PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_Restore(PyExc_ValueError, value, traceback); } return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_set_mel_coeffs (Py_filterbank * self, PyObject *args) { uint_t err = 0; smpl_t samplerate; smpl_t freq_min; smpl_t freq_max; if (!PyArg_ParseTuple (args, AUBIO_NPY_SMPL_CHR AUBIO_NPY_SMPL_CHR AUBIO_NPY_SMPL_CHR, &samplerate, &freq_min, &freq_max)) { return NULL; } err = aubio_filterbank_set_mel_coeffs (self->o, samplerate, freq_min, freq_max); if (err > 0) { if (PyErr_Occurred() == NULL) { PyErr_SetString (PyExc_ValueError, "error running set_mel_coeffs"); } else { // change the RuntimeError into ValueError PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_Restore(PyExc_ValueError, value, traceback); } return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_set_mel_coeffs_htk (Py_filterbank * self, PyObject *args) { uint_t err = 0; smpl_t samplerate; smpl_t freq_min; smpl_t freq_max; if (!PyArg_ParseTuple (args, AUBIO_NPY_SMPL_CHR AUBIO_NPY_SMPL_CHR AUBIO_NPY_SMPL_CHR, &samplerate, &freq_min, &freq_max)) { return NULL; } err = aubio_filterbank_set_mel_coeffs_htk (self->o, samplerate, freq_min, freq_max); if (err > 0) { if (PyErr_Occurred() == NULL) { PyErr_SetString (PyExc_ValueError, "error running set_mel_coeffs_htk"); } else { // change the RuntimeError into ValueError PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_Restore(PyExc_ValueError, value, traceback); } return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_set_coeffs (Py_filterbank * self, PyObject *args) { uint_t err = 0; PyObject *input; if (!PyArg_ParseTuple (args, "O", &input)) { return NULL; } if (!PyAubio_ArrayToCFmat(input, &(self->coeffs))) { return NULL; } err = aubio_filterbank_set_coeffs (self->o, &(self->coeffs)); if (err > 0) { PyErr_SetString (PyExc_ValueError, "error when setting filter coefficients"); return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_get_coeffs (Py_filterbank * self, PyObject *unused) { return (PyObject *)PyAubio_CFmatToArray( aubio_filterbank_get_coeffs (self->o) ); } static PyObject * Py_filterbank_set_power(Py_filterbank *self, PyObject *args) { smpl_t power; if (!PyArg_ParseTuple (args, AUBIO_NPY_SMPL_CHR, &power)) { return NULL; } if(aubio_filterbank_set_power (self->o, power)) { if (PyErr_Occurred() == NULL) { PyErr_SetString (PyExc_ValueError, "error running filterbank.set_power"); } else { // change the RuntimeError into ValueError PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_Restore(PyExc_ValueError, value, traceback); } return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_get_power (Py_filterbank * self, PyObject *unused) { smpl_t power = aubio_filterbank_get_power(self->o); return (PyObject *)PyFloat_FromDouble (power); } static PyObject * Py_filterbank_set_norm(Py_filterbank *self, PyObject *args) { smpl_t norm; if (!PyArg_ParseTuple (args, AUBIO_NPY_SMPL_CHR, &norm)) { return NULL; } if(aubio_filterbank_set_norm (self->o, norm)) { if (PyErr_Occurred() == NULL) { PyErr_SetString (PyExc_ValueError, "error running filterbank.set_power"); } else { // change the RuntimeError into ValueError PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_Restore(PyExc_ValueError, value, traceback); } return NULL; } Py_RETURN_NONE; } static PyObject * Py_filterbank_get_norm (Py_filterbank * self, PyObject *unused) { smpl_t norm = aubio_filterbank_get_norm(self->o); return (PyObject *)PyFloat_FromDouble (norm); } static PyMethodDef Py_filterbank_methods[] = { {"set_triangle_bands", (PyCFunction) Py_filterbank_set_triangle_bands, METH_VARARGS, Py_filterbank_set_triangle_bands_doc}, {"set_mel_coeffs_slaney", (PyCFunction) Py_filterbank_set_mel_coeffs_slaney, METH_VARARGS, Py_filterbank_set_mel_coeffs_slaney_doc}, {"set_mel_coeffs", (PyCFunction) Py_filterbank_set_mel_coeffs, METH_VARARGS, Py_filterbank_set_mel_coeffs_doc}, {"set_mel_coeffs_htk", (PyCFunction) Py_filterbank_set_mel_coeffs_htk, METH_VARARGS, Py_filterbank_set_mel_coeffs_htk_doc}, {"get_coeffs", (PyCFunction) Py_filterbank_get_coeffs, METH_NOARGS, Py_filterbank_get_coeffs_doc}, {"set_coeffs", (PyCFunction) Py_filterbank_set_coeffs, METH_VARARGS, Py_filterbank_set_coeffs_doc}, {"set_power", (PyCFunction) Py_filterbank_set_power, METH_VARARGS, Py_filterbank_set_power_doc}, {"get_power", (PyCFunction) Py_filterbank_get_power, METH_NOARGS, Py_filterbank_get_power_doc}, {"set_norm", (PyCFunction) Py_filterbank_set_norm, METH_VARARGS, Py_filterbank_set_norm_doc}, {"get_norm", (PyCFunction) Py_filterbank_get_norm, METH_NOARGS, Py_filterbank_get_norm_doc}, {NULL} }; PyTypeObject Py_filterbankType = { PyVarObject_HEAD_INIT (NULL, 0) "aubio.filterbank", sizeof (Py_filterbank), 0, (destructor) Py_filterbank_del, 0, 0, 0, 0, 0, 0, 0, 0, 0, (ternaryfunc)Py_filterbank_do, 0, 0, 0, 0, Py_TPFLAGS_DEFAULT, Py_filterbank_doc, 0, 0, 0, 0, 0, 0, Py_filterbank_methods, Py_filterbank_members, 0, 0, 0, 0, 0, 0, (initproc) Py_filterbank_init, 0, Py_filterbank_new, 0, 0, 0, 0, 0, 0, 0, 0, 0, };