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396 lines
10 KiB
C++
396 lines
10 KiB
C++
/* eq.c
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This file is part of a program that implements a Software-Defined Radio.
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Copyright (C) 2013, 2016, 2017 Warren Pratt, NR0V
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Copyright (C) 2024 Edouard Griffiths, F4EXB Adapted to SDRangel
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License
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as published by the Free Software Foundation; either version 2
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of the License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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The author can be reached by email at
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warren@wpratt.com
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*/
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#include "comm.hpp"
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#include "eqp.hpp"
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#include "fircore.hpp"
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#include "fir.hpp"
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namespace WDSP {
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int EQP::fEQcompare (const void * a, const void * b)
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{
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if (*(float*)a < *(float*)b)
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return -1;
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else if (*(float*)a == *(float*)b)
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return 0;
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else
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return 1;
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}
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void EQP::eq_impulse (
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std::vector<float>& impulse,
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int N,
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int _nfreqs,
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const float* F,
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const float* G,
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double samplerate,
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double scale,
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int ctfmode,
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int wintype
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)
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{
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std::vector<float> fp(_nfreqs + 2);
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std::vector<float> gp(_nfreqs + 2);
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std::vector<float> A(N / 2 + 1);
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float* sary = new float[2 * _nfreqs];
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double gpreamp;
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double f;
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double frac;
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int i;
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int j;
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int mid;
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fp[0] = 0.0;
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fp[_nfreqs + 1] = 1.0;
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gpreamp = G[0];
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for (i = 1; i <= _nfreqs; i++)
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{
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fp[i] = (float) (2.0 * F[i] / samplerate);
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if (fp[i] < 0.0)
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fp[i] = 0.0;
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if (fp[i] > 1.0)
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fp[i] = 1.0;
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gp[i] = G[i];
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}
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for (i = 1, j = 0; i <= _nfreqs; i++, j+=2)
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{
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sary[j + 0] = fp[i];
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sary[j + 1] = gp[i];
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}
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qsort (sary, _nfreqs, 2 * sizeof (float), fEQcompare);
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for (i = 1, j = 0; i <= _nfreqs; i++, j+=2)
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{
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fp[i] = sary[j + 0];
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gp[i] = sary[j + 1];
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}
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gp[0] = gp[1];
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gp[_nfreqs + 1] = gp[_nfreqs];
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mid = N / 2;
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j = 0;
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if (N & 1)
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{
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for (i = 0; i <= mid; i++)
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{
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f = (double)i / (double)mid;
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while ((f > fp[j + 1]) && (j < _nfreqs))
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j++;
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frac = (f - fp[j]) / (fp[j + 1] - fp[j]);
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A[i] = (float) (pow (10.0, 0.05 * (frac * gp[j + 1] + (1.0 - frac) * gp[j] + gpreamp)) * scale);
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}
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}
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else
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{
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for (i = 0; i < mid; i++)
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{
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f = ((double)i + 0.5) / (double)mid;
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while ((f > fp[j + 1]) && (j < _nfreqs))
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j++;
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frac = (f - fp[j]) / (fp[j + 1] - fp[j]);
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A[i] = (float) (pow (10.0, 0.05 * (frac * gp[j + 1] + (1.0 - frac) * gp[j] + gpreamp)) * scale);
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}
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}
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if (ctfmode == 0)
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{
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int k;
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int low;
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int high;
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double lowmag;
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double highmag;
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double flow4;
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double fhigh4;
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if (N & 1)
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{
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low = (int)(fp[1] * mid);
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high = (int)(fp[_nfreqs] * mid + 0.5);
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lowmag = A[low];
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highmag = A[high];
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flow4 = pow((double)low / (double)mid, 4.0);
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fhigh4 = pow((double)high / (double)mid, 4.0);
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k = low;
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while (--k >= 0)
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{
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f = (double)k / (double)mid;
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lowmag *= (f * f * f * f) / flow4;
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if (lowmag < 1.0e-20) lowmag = 1.0e-20;
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A[k] = (float) lowmag;
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}
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k = high;
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while (++k <= mid)
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{
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f = (double)k / (double)mid;
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highmag *= fhigh4 / (f * f * f * f);
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if (highmag < 1.0e-20) highmag = 1.0e-20;
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A[k] = (float) highmag;
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}
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}
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else
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{
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low = (int)(fp[1] * mid - 0.5);
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high = (int)(fp[_nfreqs] * mid - 0.5);
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lowmag = A[low];
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highmag = A[high];
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flow4 = pow((double)low / (double)mid, 4.0);
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fhigh4 = pow((double)high / (double)mid, 4.0);
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k = low;
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while (--k >= 0)
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{
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f = (double)k / (double)mid;
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lowmag *= (f * f * f * f) / flow4;
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if (lowmag < 1.0e-20) lowmag = 1.0e-20;
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A[k] = (float) lowmag;
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}
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k = high;
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while (++k < mid)
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{
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f = (double)k / (double)mid;
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highmag *= fhigh4 / (f * f * f * f);
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if (highmag < 1.0e-20) highmag = 1.0e-20;
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A[k] = (float) highmag;
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}
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}
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}
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impulse.resize(2 * N);
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if (N & 1)
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FIR::fir_fsamp_odd(impulse, N, A.data(), 1, 1.0, wintype);
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else
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FIR::fir_fsamp(impulse, N, A.data(), 1, 1.0, wintype);
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delete[] sary;
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}
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/********************************************************************************************************
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* *
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* Partitioned Overlap-Save Equalizer *
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* *
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********************************************************************************************************/
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EQP::EQP(
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int _run,
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int _size,
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int _nc,
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int _mp,
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float *_in,
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float *_out,
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int _nfreqs,
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float* _F,
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float* _G,
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int _ctfmode,
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int _wintype,
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int _samplerate
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)
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{
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// NOTE: 'nc' must be >= 'size'
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std::vector<float> impulse;
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run = _run;
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size = _size;
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nc = _nc;
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mp = _mp;
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in = _in;
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out = _out;
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nfreqs = _nfreqs;
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F.resize(nfreqs + 1);
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G.resize(nfreqs + 1);
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std::copy(_F, _F + (_nfreqs + 1), F.begin());
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std::copy(_G, _G + (_nfreqs + 1), G.begin());
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ctfmode = _ctfmode;
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wintype = _wintype;
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samplerate = (double) _samplerate;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore = new FIRCORE(size, in, out, mp, impulse);
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}
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EQP::~EQP()
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{
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delete (fircore);
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}
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void EQP::flush()
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{
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fircore->flush();
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}
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void EQP::execute()
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{
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if (run)
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fircore->execute();
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else
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std::copy(in, in + size * 2, out);
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}
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void EQP::setBuffers(float* _in, float* _out)
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{
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in = _in;
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out = _out;
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fircore->setBuffers(in, out);
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}
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void EQP::setSamplerate(int rate)
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{
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std::vector<float> impulse;
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samplerate = rate;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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void EQP::setSize(int _size)
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{
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std::vector<float> impulse;
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size = _size;
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fircore->setSize(size);
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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/********************************************************************************************************
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* *
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* Partitioned Overlap-Save Equalizer: Public Properties *
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* *
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********************************************************************************************************/
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void EQP::setRun(int _run)
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{
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run = _run;
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}
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void EQP::setNC(int _nc)
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{
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std::vector<float> impulse;
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if (nc != _nc)
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{
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nc = _nc;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setNc(impulse);
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}
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}
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void EQP::setMP(int _mp)
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{
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if (mp != _mp)
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{
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mp = _mp;
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fircore->setMp(mp);
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}
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}
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void EQP::setProfile(int _nfreqs, const float* _F, const float* _G)
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{
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std::vector<float> impulse;
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nfreqs = _nfreqs;
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F.resize(nfreqs + 1);
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G.resize(nfreqs + 1);
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std::copy(_F, _F + (_nfreqs + 1), F.begin());
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std::copy(_G, _G + (_nfreqs + 1), G.begin());
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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void EQP::setCtfmode(int _mode)
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{
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std::vector<float> impulse;
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ctfmode = _mode;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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void EQP::setWintype(int _wintype)
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{
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std::vector<float> impulse;
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wintype = _wintype;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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void EQP::setGrphEQ(const int *rxeq)
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{ // three band equalizer (legacy compatibility)
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std::vector<float> impulse;
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nfreqs = 4;
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F.resize(nfreqs + 1);
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G.resize(nfreqs + 1);
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F[1] = 150.0;
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F[2] = 400.0;
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F[3] = 1500.0;
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F[4] = 6000.0;
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G[0] = (float)rxeq[0];
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G[1] = (float)rxeq[1];
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G[2] = (float)rxeq[1];
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G[3] = (float)rxeq[2];
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G[4] = (float)rxeq[3];
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ctfmode = 0;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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void EQP::setGrphEQ10(const int *rxeq)
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{ // ten band equalizer (legacy compatibility)
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std::vector<float> impulse;
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nfreqs = 10;
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F.resize(nfreqs + 1);
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G.resize(nfreqs + 1);
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F[1] = 32.0;
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F[2] = 63.0;
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F[3] = 125.0;
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F[4] = 250.0;
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F[5] = 500.0;
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F[6] = 1000.0;
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F[7] = 2000.0;
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F[8] = 4000.0;
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F[9] = 8000.0;
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F[10] = 16000.0;
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for (int i = 0; i <= nfreqs; i++)
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G[i] = (float)rxeq[i];
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ctfmode = 0;
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eq_impulse (impulse, nc, nfreqs, F.data(), G.data(), samplerate, 1.0 / (2.0 * size), ctfmode, wintype);
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fircore->setImpulse(impulse, 1);
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}
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} // namespace WDSP
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