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// ------------------------------------------------------------------------
//
// Copyright (C) 2010-2011 Fons Adriaensen <fons@linuxaudio.org>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
//
// ------------------------------------------------------------------------
#ifndef _EBU_R128_PROC_H
#define _EBU_R128_PROC_H
#define MAXCH 5
namespace Fons {
class Ebu_r128_fst
{
private:
friend class Ebu_r128_proc;
void reset (void) { _z1 = _z2 = _z3 = _z4 = 0; }
float _z1, _z2, _z3, _z4;
};
class Ebu_r128_hist
{
private:
Ebu_r128_hist (void);
~Ebu_r128_hist (void);
friend class Ebu_r128_proc;
void reset (void);
void initstat (void);
void addpoint (float v);
float integrate (int ind);
void calc_integ (float *vi, float *th);
void calc_range (float *v0, float *v1, float *th);
int *_histc;
int _count;
int _error;
static float _bin_power [100];
};
class Ebu_r128_proc
{
public:
Ebu_r128_proc (void);
~Ebu_r128_proc (void);
void init (int nchan, float fsamp);
void reset (void);
void process (int nfram, const float *const *input);
void integr_reset (void);
void integr_pause (void) { _integr = false; }
void integr_start (void) { _integr = true; }
float loudness_M (void) const { return _loudness_M; }
float maxloudn_M (void) const { return _maxloudn_M; }
float loudness_S (void) const { return _loudness_S; }
float maxloudn_S (void) const { return _maxloudn_S; }
float integrated (void) const { return _integrated; }
float integ_thr (void) const { return _integ_thr; }
float range_min (void) const { return _range_min; }
float range_max (void) const { return _range_max; }
float range_thr (void) const { return _range_thr; }
const int *histogram_M (void) const { return _hist_M._histc; }
const int *histogram_S (void) const { return _hist_S._histc; }
int hist_M_count (void) const { return _hist_M._count; }
int hist_S_count (void) const { return _hist_S._count; }
private:
float addfrags (int nfrag);
void detect_init (float fsamp);
void detect_reset (void);
float detect_process (int nfram);
bool _integr; // Integration on/off.
int _nchan; // Number of channels, 2 or 5.
float _fsamp; // Sample rate.
int _fragm; // Fragmenst size, 1/20 second.
int _frcnt; // Number of samples remaining in current fragment.
float _frpwr; // Power accumulated for current fragment.
float _power [64]; // Array of fragment powers.
int _wrind; // Write index into _frpwr
int _div1; // M period counter, 200 ms;
int _div2; // S period counter, 1s;
float _loudness_M;
float _maxloudn_M;
float _loudness_S;
float _maxloudn_S;
float _integrated;
float _integ_thr;
float _range_min;
float _range_max;
float _range_thr;
// Filter coefficients and states.
float _a0, _a1, _a2;
float _b1, _b2;
float _c3, _c4;
float const *_ipp [MAXCH];
Ebu_r128_fst _fst [MAXCH];
Ebu_r128_hist _hist_M;
Ebu_r128_hist _hist_S;
// Default channel gains.
static float _chan_gain [5];
};
};
#endif
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