src/share/replaygain_analysis/replaygain_analysis.c - platform/external/flac - Gitiles

 /*
  *  ReplayGainAnalysis - analyzes input samples and give the recommended dB change
  *  Copyright (C) 2001 David Robinson and Glen Sawyer
  *
  *  This library is free software; you can redistribute it and/or
  *  modify it under the terms of the GNU Lesser General Public
  *  License as published by the Free Software Foundation; either
  *  version 2.1 of the License, or (at your option) any later version.
  *
  *  This library 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
  *  Lesser General Public License for more details.
  *
  *  You should have received a copy of the GNU Lesser General Public
  *  License along with this library; if not, write to the Free Software
  *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
  *
  *  concept and filter values by David Robinson (David@Robinson.org)
  *    -- blame him if you think the idea is flawed
  *  original coding by Glen Sawyer (glensawyer@hotmail.com)
  *    -- blame him if you think this runs too slowly, or the coding is otherwise flawed
  *
  *  lots of code improvements by Frank Klemm ( http://www.uni-jena.de/~pfk/mpp/ )
  *    -- credit him for all the _good_ programming ;)
  *
  *  minor cosmetic tweaks to integrate with FLAC by Josh Coalson
  *
  *
  *  For an explanation of the concepts and the basic algorithms involved, go to:
  *    http://www.replaygain.org/
  */

 /*
  *  Here's the deal. Call
  *
  *    InitGainAnalysis ( long samplefreq );
  *
  *  to initialize everything. Call
  *
  *    AnalyzeSamples ( const Float_t*  left_samples,
  *                     const Float_t*  right_samples,
  *                     size_t          num_samples,
  *                     int             num_channels );
  *
  *  as many times as you want, with as many or as few samples as you want.
  *  If mono, pass the sample buffer in through left_samples, leave
  *  right_samples NULL, and make sure num_channels = 1.
  *
  *    GetTitleGain()
  *
  *  will return the recommended dB level change for all samples analyzed
  *  SINCE THE LAST TIME you called GetTitleGain() OR InitGainAnalysis().
  *
  *    GetAlbumGain()
  *
  *  will return the recommended dB level change for all samples analyzed
  *  since InitGainAnalysis() was called and finalized with GetTitleGain().
  *
  *  Pseudo-code to process an album:
  *
  *    Float_t       l_samples [4096];
  *    Float_t       r_samples [4096];
  *    size_t        num_samples;
  *    unsigned int  num_songs;
  *    unsigned int  i;
  *
  *    InitGainAnalysis ( 44100 );
  *    for ( i = 1; i <= num_songs; i++ ) {
  *        while ( ( num_samples = getSongSamples ( song[i], left_samples, right_samples ) ) > 0 )
  *            AnalyzeSamples ( left_samples, right_samples, num_samples, 2 );
  *        fprintf ("Recommended dB change for song %2d: %+6.2f dB\n", i, GetTitleGain() );
  *    }
  *    fprintf ("Recommended dB change for whole album: %+6.2f dB\n", GetAlbumGain() );
  */

 /*
  *  So here's the main source of potential code confusion:
  *
  *  The filters applied to the incoming samples are IIR filters,
  *  meaning they rely on up to <filter order> number of previous samples
  *  AND up to <filter order> number of previous filtered samples.
  *
  *  I set up the AnalyzeSamples routine to minimize memory usage and interface
  *  complexity. The speed isn't compromised too much (I don't think), but the
  *  internal complexity is higher than it should be for such a relatively
  *  simple routine.
  *
  *  Optimization/clarity suggestions are welcome.
  */

 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <math.h>

 #include "replaygain_analysis.h"

 typedef unsigned short  Uint16_t;
 typedef signed short    Int16_t;
 typedef unsigned int    Uint32_t;
 typedef signed int      Int32_t;

 #define YULE_ORDER         10
 #define BUTTER_ORDER        2
 #define RMS_PERCENTILE      0.95        /* percentile which is louder than the proposed level */
 #define MAX_SAMP_FREQ   48000.          /* maximum allowed sample frequency [Hz] */
 #define RMS_WINDOW_TIME     0.050       /* Time slice size [s] */
 #define STEPS_per_dB      100.          /* Table entries per dB */
 #define MAX_dB            120.          /* Table entries for 0...MAX_dB (normal max. values are 70...80 dB) */

 #define MAX_ORDER               (BUTTER_ORDER > YULE_ORDER ? BUTTER_ORDER : YULE_ORDER)
 /* [JEC] the following was originally #defined as:
  *   (size_t) (MAX_SAMP_FREQ * RMS_WINDOW_TIME)
  * but that seemed to fail to take into account the ceil() part of the
  * sampleWindow calculation in ResetSampleFrequency(), and was causing
  * buffer overflows for 48kHz analysis, hence the +1.
  */
 #define MAX_SAMPLES_PER_WINDOW  (size_t) (MAX_SAMP_FREQ * RMS_WINDOW_TIME + 1.)   /* max. Samples per Time slice */
 #define PINK_REF                64.82 /* 298640883795 */                          /* calibration value */

 static Float_t          linprebuf [MAX_ORDER * 2];
 static Float_t*         linpre;                                          /* left input samples, with pre-buffer */
 static Float_t          lstepbuf  [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
 static Float_t*         lstep;                                           /* left "first step" (i.e. post first filter) samples */
 static Float_t          loutbuf   [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
 static Float_t*         lout;                                            /* left "out" (i.e. post second filter) samples */
 static Float_t          rinprebuf [MAX_ORDER * 2];
 static Float_t*         rinpre;                                          /* right input samples ... */
 static Float_t          rstepbuf  [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
 static Float_t*         rstep;
 static Float_t          routbuf   [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
 static Float_t*         rout;
 static unsigned int              sampleWindow;                           /* number of samples required to reach number of milliseconds required for RMS window */
 static unsigned long    totsamp;
 static double           lsum;
 static double           rsum;
 static int              freqindex;
 static Uint32_t  A [(size_t)(STEPS_per_dB * MAX_dB)];
 static Uint32_t  B [(size_t)(STEPS_per_dB * MAX_dB)];

 /* for each filter:
    [0] 48 kHz, [1] 44.1 kHz, [2] 32 kHz, [3] 24 kHz, [4] 22050 Hz, [5] 16 kHz, [6] 12 kHz, [7] is 11025 Hz, [8] 8 kHz */

 #ifdef WIN32
 #pragma warning ( disable : 4305 )
 #endif

 static const Float_t  AYule [9] [11] = {
     { 1., -3.84664617118067,  7.81501653005538,-11.34170355132042, 13.05504219327545,-12.28759895145294,  9.48293806319790, -5.87257861775999,  2.75465861874613, -0.86984376593551, 0.13919314567432 },
     { 1., -3.47845948550071,  6.36317777566148, -8.54751527471874,  9.47693607801280, -8.81498681370155,  6.85401540936998, -4.39470996079559,  2.19611684890774, -0.75104302451432, 0.13149317958808 },
     { 1., -2.37898834973084,  2.84868151156327, -2.64577170229825,  2.23697657451713, -1.67148153367602,  1.00595954808547, -0.45953458054983,  0.16378164858596, -0.05032077717131, 0.02347897407020 },
     { 1., -1.61273165137247,  1.07977492259970, -0.25656257754070, -0.16276719120440, -0.22638893773906,  0.39120800788284, -0.22138138954925,  0.04500235387352,  0.02005851806501, 0.00302439095741 },
     { 1., -1.49858979367799,  0.87350271418188,  0.12205022308084, -0.80774944671438,  0.47854794562326, -0.12453458140019, -0.04067510197014,  0.08333755284107, -0.04237348025746, 0.02977207319925 },
     { 1., -0.62820619233671,  0.29661783706366, -0.37256372942400,  0.00213767857124, -0.42029820170918,  0.22199650564824,  0.00613424350682,  0.06747620744683,  0.05784820375801, 0.03222754072173 },
     { 1., -1.04800335126349,  0.29156311971249, -0.26806001042947,  0.00819999645858,  0.45054734505008, -0.33032403314006,  0.06739368333110, -0.04784254229033,  0.01639907836189, 0.01807364323573 },
     { 1., -0.51035327095184, -0.31863563325245, -0.20256413484477,  0.14728154134330,  0.38952639978999, -0.23313271880868, -0.05246019024463, -0.02505961724053,  0.02442357316099, 0.01818801111503 },
     { 1., -0.25049871956020, -0.43193942311114, -0.03424681017675, -0.04678328784242,  0.26408300200955,  0.15113130533216, -0.17556493366449, -0.18823009262115,  0.05477720428674, 0.04704409688120 }
 };

 static const Float_t  BYule [9] [11] = {
     { 0.03857599435200, -0.02160367184185, -0.00123395316851, -0.00009291677959, -0.01655260341619,  0.02161526843274, -0.02074045215285,  0.00594298065125,  0.00306428023191,  0.00012025322027,  0.00288463683916 },
     { 0.05418656406430, -0.02911007808948, -0.00848709379851, -0.00851165645469, -0.00834990904936,  0.02245293253339, -0.02596338512915,  0.01624864962975, -0.00240879051584,  0.00674613682247, -0.00187763777362 },
     { 0.15457299681924, -0.09331049056315, -0.06247880153653,  0.02163541888798, -0.05588393329856,  0.04781476674921,  0.00222312597743,  0.03174092540049, -0.01390589421898,  0.00651420667831, -0.00881362733839 },
     { 0.30296907319327, -0.22613988682123, -0.08587323730772,  0.03282930172664, -0.00915702933434, -0.02364141202522, -0.00584456039913,  0.06276101321749, -0.00000828086748,  0.00205861885564, -0.02950134983287 },
     { 0.33642304856132, -0.25572241425570, -0.11828570177555,  0.11921148675203, -0.07834489609479, -0.00469977914380, -0.00589500224440,  0.05724228140351,  0.00832043980773, -0.01635381384540, -0.01760176568150 },
     { 0.44915256608450, -0.14351757464547, -0.22784394429749, -0.01419140100551,  0.04078262797139, -0.12398163381748,  0.04097565135648,  0.10478503600251, -0.01863887810927, -0.03193428438915,  0.00541907748707 },
     { 0.56619470757641, -0.75464456939302,  0.16242137742230,  0.16744243493672, -0.18901604199609,  0.30931782841830, -0.27562961986224,  0.00647310677246,  0.08647503780351, -0.03788984554840, -0.00588215443421 },
     { 0.58100494960553, -0.53174909058578, -0.14289799034253,  0.17520704835522,  0.02377945217615,  0.15558449135573, -0.25344790059353,  0.01628462406333,  0.06920467763959, -0.03721611395801, -0.00749618797172 },
     { 0.53648789255105, -0.42163034350696, -0.00275953611929,  0.04267842219415, -0.10214864179676,  0.14590772289388, -0.02459864859345, -0.11202315195388, -0.04060034127000,  0.04788665548180, -0.02217936801134 }
 };

 static const Float_t  AButter [9] [3] = {
     { 1., -1.97223372919527, 0.97261396931306 },
     { 1., -1.96977855582618, 0.97022847566350 },
     { 1., -1.95835380975398, 0.95920349965459 },
     { 1., -1.95002759149878, 0.95124613669835 },
     { 1., -1.94561023566527, 0.94705070426118 },
     { 1., -1.92783286977036, 0.93034775234268 },
     { 1., -1.91858953033784, 0.92177618768381 },
     { 1., -1.91542108074780, 0.91885558323625 },
     { 1., -1.88903307939452, 0.89487434461664 }
 };

 static const Float_t  BButter [9] [3] = {
     { 0.98621192462708, -1.97242384925416, 0.98621192462708 },
     { 0.98500175787242, -1.97000351574484, 0.98500175787242 },
     { 0.97938932735214, -1.95877865470428, 0.97938932735214 },
     { 0.97531843204928, -1.95063686409857, 0.97531843204928 },
     { 0.97316523498161, -1.94633046996323, 0.97316523498161 },
     { 0.96454515552826, -1.92909031105652, 0.96454515552826 },
     { 0.96009142950541, -1.92018285901082, 0.96009142950541 },
     { 0.95856916599601, -1.91713833199203, 0.95856916599601 },
     { 0.94597685600279, -1.89195371200558, 0.94597685600279 }
 };

 #ifdef WIN32
 #pragma warning ( default : 4305 )
 #endif

 /* When calling this procedure, make sure that ip[-order] and op[-order] point to real data! */

 static void
 filter ( const Float_t* input, Float_t* output, size_t nSamples, const Float_t* a, const Float_t* b, size_t order )
 {
     double  y;
     size_t  i;
     size_t  k;

     for ( i = 0; i < nSamples; i++ ) {
         y = input[i] * b[0];
         for ( k = 1; k <= order; k++ )
             y += input[i-k] * b[k] - output[i-k] * a[k];
         output[i] = (Float_t)y;
     }
 }

 /* returns a INIT_GAIN_ANALYSIS_OK if successful, INIT_GAIN_ANALYSIS_ERROR if not */

 int
 ResetSampleFrequency ( long samplefreq ) {
     int  i;

     /* zero out initial values */
     for ( i = 0; i < MAX_ORDER; i++ )
         linprebuf[i] = lstepbuf[i] = loutbuf[i] = rinprebuf[i] = rstepbuf[i] = routbuf[i] = 0.;

     switch ( (int)(samplefreq) ) {
         case 48000: freqindex = 0; break;
         case 44100: freqindex = 1; break;
         case 32000: freqindex = 2; break;
         case 24000: freqindex = 3; break;
         case 22050: freqindex = 4; break;
         case 16000: freqindex = 5; break;
         case 12000: freqindex = 6; break;
         case 11025: freqindex = 7; break;
         case  8000: freqindex = 8; break;
         default:    return INIT_GAIN_ANALYSIS_ERROR;
     }

     sampleWindow = (int) ceil (samplefreq * RMS_WINDOW_TIME);

     lsum         = 0.;
     rsum         = 0.;
     totsamp      = 0;

     memset ( A, 0, sizeof(A) );

 	return INIT_GAIN_ANALYSIS_OK;
 }

 int
 InitGainAnalysis ( long samplefreq )
 {
 	if (ResetSampleFrequency(samplefreq) != INIT_GAIN_ANALYSIS_OK) {
 		return INIT_GAIN_ANALYSIS_ERROR;
 	}

     linpre       = linprebuf + MAX_ORDER;
     rinpre       = rinprebuf + MAX_ORDER;
     lstep        = lstepbuf  + MAX_ORDER;
     rstep        = rstepbuf  + MAX_ORDER;
     lout         = loutbuf   + MAX_ORDER;
     rout         = routbuf   + MAX_ORDER;

     memset ( B, 0, sizeof(B) );

     return INIT_GAIN_ANALYSIS_OK;
 }

 /* returns GAIN_ANALYSIS_OK if successful, GAIN_ANALYSIS_ERROR if not */

 int
 AnalyzeSamples ( const Float_t* left_samples, const Float_t* right_samples, size_t num_samples, int num_channels )
 {
     const Float_t*  curleft;
     const Float_t*  curright;
     long            batchsamples;
     long            cursamples;
     long            cursamplepos;
     int             i;

     if ( num_samples == 0 )
         return GAIN_ANALYSIS_OK;

     cursamplepos = 0;
     batchsamples = num_samples;

     switch ( num_channels) {
     case  1: right_samples = left_samples;
     case  2: break;
     default: return GAIN_ANALYSIS_ERROR;
     }

     if ( num_samples < MAX_ORDER ) {
         memcpy ( linprebuf + MAX_ORDER, left_samples , num_samples * sizeof(Float_t) );
         memcpy ( rinprebuf + MAX_ORDER, right_samples, num_samples * sizeof(Float_t) );
     }
     else {
         memcpy ( linprebuf + MAX_ORDER, left_samples,  MAX_ORDER   * sizeof(Float_t) );
         memcpy ( rinprebuf + MAX_ORDER, right_samples, MAX_ORDER   * sizeof(Float_t) );
     }

     while ( batchsamples > 0 ) {
         cursamples = batchsamples > (long)(sampleWindow-totsamp)  ?  (long)(sampleWindow - totsamp)  :  batchsamples;
         if ( cursamplepos < MAX_ORDER ) {
             curleft  = linpre+cursamplepos;
             curright = rinpre+cursamplepos;
             if (cursamples > MAX_ORDER - cursamplepos )
                 cursamples = MAX_ORDER - cursamplepos;
         }
         else {
             curleft  = left_samples  + cursamplepos;
             curright = right_samples + cursamplepos;
         }

         filter ( curleft , lstep + totsamp, cursamples, AYule[freqindex], BYule[freqindex], YULE_ORDER );
         filter ( curright, rstep + totsamp, cursamples, AYule[freqindex], BYule[freqindex], YULE_ORDER );

         filter ( lstep + totsamp, lout + totsamp, cursamples, AButter[freqindex], BButter[freqindex], BUTTER_ORDER );
         filter ( rstep + totsamp, rout + totsamp, cursamples, AButter[freqindex], BButter[freqindex], BUTTER_ORDER );

         for ( i = 0; i < cursamples; i++ ) {             /* Get the squared values */
             lsum += lout [totsamp+i] * lout [totsamp+i];
             rsum += rout [totsamp+i] * rout [totsamp+i];
         }

         batchsamples -= cursamples;
         cursamplepos += cursamples;
         totsamp      += cursamples;
         if ( totsamp == sampleWindow ) {  /* Get the Root Mean Square (RMS) for this set of samples */
             double  val  = STEPS_per_dB * 10. * log10 ( (lsum+rsum) / totsamp * 0.5 + 1.e-37 );
             int     ival = (int) val;
             if ( ival <                     0 ) ival = 0;
             if ( ival >= (int)(sizeof(A)/sizeof(*A)) ) ival = (int)(sizeof(A)/sizeof(*A)) - 1;
             A [ival]++;
             lsum = rsum = 0.;
             memmove ( loutbuf , loutbuf  + totsamp, MAX_ORDER * sizeof(Float_t) );
             memmove ( routbuf , routbuf  + totsamp, MAX_ORDER * sizeof(Float_t) );
             memmove ( lstepbuf, lstepbuf + totsamp, MAX_ORDER * sizeof(Float_t) );
             memmove ( rstepbuf, rstepbuf + totsamp, MAX_ORDER * sizeof(Float_t) );
             totsamp = 0;
         }
         if ( totsamp > sampleWindow )   /* somehow I really screwed up: Error in programming! Contact author about totsamp > sampleWindow */
             return GAIN_ANALYSIS_ERROR;
     }
     if ( num_samples < MAX_ORDER ) {
         memmove ( linprebuf,                           linprebuf + num_samples, (MAX_ORDER-num_samples) * sizeof(Float_t) );
         memmove ( rinprebuf,                           rinprebuf + num_samples, (MAX_ORDER-num_samples) * sizeof(Float_t) );
         memcpy  ( linprebuf + MAX_ORDER - num_samples, left_samples,          num_samples             * sizeof(Float_t) );
         memcpy  ( rinprebuf + MAX_ORDER - num_samples, right_samples,         num_samples             * sizeof(Float_t) );
     }
     else {
         memcpy  ( linprebuf, left_samples  + num_samples - MAX_ORDER, MAX_ORDER * sizeof(Float_t) );
         memcpy  ( rinprebuf, right_samples + num_samples - MAX_ORDER, MAX_ORDER * sizeof(Float_t) );
     }

     return GAIN_ANALYSIS_OK;
 }


 static Float_t
 analyzeResult ( Uint32_t* Array, size_t len )
 {
     Uint32_t  elems;
     Int32_t   upper;
     size_t    i;

     elems = 0;
     for ( i = 0; i < len; i++ )
         elems += Array[i];
     if ( elems == 0 )
         return GAIN_NOT_ENOUGH_SAMPLES;

     upper = (Int32_t) ceil (elems * (1. - RMS_PERCENTILE));
     for ( i = len; i-- > 0; ) {
         if ( (upper -= Array[i]) <= 0 )
             break;
     }

     return (Float_t) ((Float_t)PINK_REF - (Float_t)i / (Float_t)STEPS_per_dB);
 }


 Float_t
 GetTitleGain ( void )
 {
     Float_t  retval;
     unsigned int    i;

     retval = analyzeResult ( A, sizeof(A)/sizeof(*A) );

     for ( i = 0; i < sizeof(A)/sizeof(*A); i++ ) {
         B[i] += A[i];
         A[i]  = 0;
     }

     for ( i = 0; i < MAX_ORDER; i++ )
         linprebuf[i] = lstepbuf[i] = loutbuf[i] = rinprebuf[i] = rstepbuf[i] = routbuf[i] = 0.f;

     totsamp = 0;
     lsum    = rsum = 0.;
     return retval;
 }


 Float_t
 GetAlbumGain ( void )
 {
     return analyzeResult ( B, sizeof(B)/sizeof(*B) );
 }

 /* end of replaygain_analysis.c */
	/*
	* ReplayGainAnalysis - analyzes input samples and give the recommended dB change
	* Copyright (C) 2001 David Robinson and Glen Sawyer
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2.1 of the License, or (at your option) any later version.
	*
	* This library 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
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
	*
	* concept and filter values by David Robinson (David@Robinson.org)
	* -- blame him if you think the idea is flawed
	* original coding by Glen Sawyer (glensawyer@hotmail.com)
	* -- blame him if you think this runs too slowly, or the coding is otherwise flawed
	*
	* lots of code improvements by Frank Klemm ( http://www.uni-jena.de/~pfk/mpp/ )
	* -- credit him for all the _good_ programming ;)
	*
	* minor cosmetic tweaks to integrate with FLAC by Josh Coalson
	*
	*
	* For an explanation of the concepts and the basic algorithms involved, go to:
	* http://www.replaygain.org/
	*/

	/*
	* Here's the deal. Call
	*
	* InitGainAnalysis ( long samplefreq );
	*
	* to initialize everything. Call
	*
	* AnalyzeSamples ( const Float_t* left_samples,
	* const Float_t* right_samples,
	* size_t num_samples,
	* int num_channels );
	*
	* as many times as you want, with as many or as few samples as you want.
	* If mono, pass the sample buffer in through left_samples, leave
	* right_samples NULL, and make sure num_channels = 1.
	*
	* GetTitleGain()
	*
	* will return the recommended dB level change for all samples analyzed
	* SINCE THE LAST TIME you called GetTitleGain() OR InitGainAnalysis().
	*
	* GetAlbumGain()
	*
	* will return the recommended dB level change for all samples analyzed
	* since InitGainAnalysis() was called and finalized with GetTitleGain().
	*
	* Pseudo-code to process an album:
	*
	* Float_t l_samples [4096];
	* Float_t r_samples [4096];
	* size_t num_samples;
	* unsigned int num_songs;
	* unsigned int i;
	*
	* InitGainAnalysis ( 44100 );
	* for ( i = 1; i <= num_songs; i++ ) {
	* while ( ( num_samples = getSongSamples ( song[i], left_samples, right_samples ) ) > 0 )
	* AnalyzeSamples ( left_samples, right_samples, num_samples, 2 );
	* fprintf ("Recommended dB change for song %2d: %+6.2f dB\n", i, GetTitleGain() );
	* }
	* fprintf ("Recommended dB change for whole album: %+6.2f dB\n", GetAlbumGain() );
	*/

	/*
	* So here's the main source of potential code confusion:
	*
	* The filters applied to the incoming samples are IIR filters,
	* meaning they rely on up to <filter order> number of previous samples
	* AND up to <filter order> number of previous filtered samples.
	*
	* I set up the AnalyzeSamples routine to minimize memory usage and interface
	* complexity. The speed isn't compromised too much (I don't think), but the
	* internal complexity is higher than it should be for such a relatively
	* simple routine.
	*
	* Optimization/clarity suggestions are welcome.
	*/

	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include <math.h>

	#include "replaygain_analysis.h"

	typedef unsigned short Uint16_t;
	typedef signed short Int16_t;
	typedef unsigned int Uint32_t;
	typedef signed int Int32_t;

	#define YULE_ORDER 10
	#define BUTTER_ORDER 2
	#define RMS_PERCENTILE 0.95 /* percentile which is louder than the proposed level */
	#define MAX_SAMP_FREQ 48000. /* maximum allowed sample frequency [Hz] */
	#define RMS_WINDOW_TIME 0.050 /* Time slice size [s] */
	#define STEPS_per_dB 100. /* Table entries per dB */
	#define MAX_dB 120. /* Table entries for 0...MAX_dB (normal max. values are 70...80 dB) */

	#define MAX_ORDER (BUTTER_ORDER > YULE_ORDER ? BUTTER_ORDER : YULE_ORDER)
	/* [JEC] the following was originally #defined as:
	* (size_t) (MAX_SAMP_FREQ * RMS_WINDOW_TIME)
	* but that seemed to fail to take into account the ceil() part of the
	* sampleWindow calculation in ResetSampleFrequency(), and was causing
	* buffer overflows for 48kHz analysis, hence the +1.
	*/
	#define MAX_SAMPLES_PER_WINDOW (size_t) (MAX_SAMP_FREQ * RMS_WINDOW_TIME + 1.) /* max. Samples per Time slice */
	#define PINK_REF 64.82 /* 298640883795 / / calibration value */

	static Float_t linprebuf [MAX_ORDER * 2];
	static Float_t* linpre; /* left input samples, with pre-buffer */
	static Float_t lstepbuf [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
	static Float_t* lstep; /* left "first step" (i.e. post first filter) samples */
	static Float_t loutbuf [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
	static Float_t* lout; /* left "out" (i.e. post second filter) samples */
	static Float_t rinprebuf [MAX_ORDER * 2];
	static Float_t* rinpre; /* right input samples ... */
	static Float_t rstepbuf [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
	static Float_t* rstep;
	static Float_t routbuf [MAX_SAMPLES_PER_WINDOW + MAX_ORDER];
	static Float_t* rout;
	static unsigned int sampleWindow; /* number of samples required to reach number of milliseconds required for RMS window */
	static unsigned long totsamp;
	static double lsum;
	static double rsum;
	static int freqindex;
	static Uint32_t A [(size_t)(STEPS_per_dB * MAX_dB)];
	static Uint32_t B [(size_t)(STEPS_per_dB * MAX_dB)];

	/* for each filter:
	[0] 48 kHz, [1] 44.1 kHz, [2] 32 kHz, [3] 24 kHz, [4] 22050 Hz, [5] 16 kHz, [6] 12 kHz, [7] is 11025 Hz, [8] 8 kHz */

	#ifdef WIN32
	#pragma warning ( disable : 4305 )
	#endif

	static const Float_t AYule [9] [11] = {
	{ 1., -3.84664617118067, 7.81501653005538,-11.34170355132042, 13.05504219327545,-12.28759895145294, 9.48293806319790, -5.87257861775999, 2.75465861874613, -0.86984376593551, 0.13919314567432 },
	{ 1., -3.47845948550071, 6.36317777566148, -8.54751527471874, 9.47693607801280, -8.81498681370155, 6.85401540936998, -4.39470996079559, 2.19611684890774, -0.75104302451432, 0.13149317958808 },
	{ 1., -2.37898834973084, 2.84868151156327, -2.64577170229825, 2.23697657451713, -1.67148153367602, 1.00595954808547, -0.45953458054983, 0.16378164858596, -0.05032077717131, 0.02347897407020 },
	{ 1., -1.61273165137247, 1.07977492259970, -0.25656257754070, -0.16276719120440, -0.22638893773906, 0.39120800788284, -0.22138138954925, 0.04500235387352, 0.02005851806501, 0.00302439095741 },
	{ 1., -1.49858979367799, 0.87350271418188, 0.12205022308084, -0.80774944671438, 0.47854794562326, -0.12453458140019, -0.04067510197014, 0.08333755284107, -0.04237348025746, 0.02977207319925 },
	{ 1., -0.62820619233671, 0.29661783706366, -0.37256372942400, 0.00213767857124, -0.42029820170918, 0.22199650564824, 0.00613424350682, 0.06747620744683, 0.05784820375801, 0.03222754072173 },
	{ 1., -1.04800335126349, 0.29156311971249, -0.26806001042947, 0.00819999645858, 0.45054734505008, -0.33032403314006, 0.06739368333110, -0.04784254229033, 0.01639907836189, 0.01807364323573 },
	{ 1., -0.51035327095184, -0.31863563325245, -0.20256413484477, 0.14728154134330, 0.38952639978999, -0.23313271880868, -0.05246019024463, -0.02505961724053, 0.02442357316099, 0.01818801111503 },
	{ 1., -0.25049871956020, -0.43193942311114, -0.03424681017675, -0.04678328784242, 0.26408300200955, 0.15113130533216, -0.17556493366449, -0.18823009262115, 0.05477720428674, 0.04704409688120 }
	};

	static const Float_t BYule [9] [11] = {
	{ 0.03857599435200, -0.02160367184185, -0.00123395316851, -0.00009291677959, -0.01655260341619, 0.02161526843274, -0.02074045215285, 0.00594298065125, 0.00306428023191, 0.00012025322027, 0.00288463683916 },
	{ 0.05418656406430, -0.02911007808948, -0.00848709379851, -0.00851165645469, -0.00834990904936, 0.02245293253339, -0.02596338512915, 0.01624864962975, -0.00240879051584, 0.00674613682247, -0.00187763777362 },
	{ 0.15457299681924, -0.09331049056315, -0.06247880153653, 0.02163541888798, -0.05588393329856, 0.04781476674921, 0.00222312597743, 0.03174092540049, -0.01390589421898, 0.00651420667831, -0.00881362733839 },
	{ 0.30296907319327, -0.22613988682123, -0.08587323730772, 0.03282930172664, -0.00915702933434, -0.02364141202522, -0.00584456039913, 0.06276101321749, -0.00000828086748, 0.00205861885564, -0.02950134983287 },
	{ 0.33642304856132, -0.25572241425570, -0.11828570177555, 0.11921148675203, -0.07834489609479, -0.00469977914380, -0.00589500224440, 0.05724228140351, 0.00832043980773, -0.01635381384540, -0.01760176568150 },
	{ 0.44915256608450, -0.14351757464547, -0.22784394429749, -0.01419140100551, 0.04078262797139, -0.12398163381748, 0.04097565135648, 0.10478503600251, -0.01863887810927, -0.03193428438915, 0.00541907748707 },
	{ 0.56619470757641, -0.75464456939302, 0.16242137742230, 0.16744243493672, -0.18901604199609, 0.30931782841830, -0.27562961986224, 0.00647310677246, 0.08647503780351, -0.03788984554840, -0.00588215443421 },
	{ 0.58100494960553, -0.53174909058578, -0.14289799034253, 0.17520704835522, 0.02377945217615, 0.15558449135573, -0.25344790059353, 0.01628462406333, 0.06920467763959, -0.03721611395801, -0.00749618797172 },
	{ 0.53648789255105, -0.42163034350696, -0.00275953611929, 0.04267842219415, -0.10214864179676, 0.14590772289388, -0.02459864859345, -0.11202315195388, -0.04060034127000, 0.04788665548180, -0.02217936801134 }
	};

	static const Float_t AButter [9] [3] = {
	{ 1., -1.97223372919527, 0.97261396931306 },
	{ 1., -1.96977855582618, 0.97022847566350 },
	{ 1., -1.95835380975398, 0.95920349965459 },
	{ 1., -1.95002759149878, 0.95124613669835 },
	{ 1., -1.94561023566527, 0.94705070426118 },
	{ 1., -1.92783286977036, 0.93034775234268 },
	{ 1., -1.91858953033784, 0.92177618768381 },
	{ 1., -1.91542108074780, 0.91885558323625 },
	{ 1., -1.88903307939452, 0.89487434461664 }
	};

	static const Float_t BButter [9] [3] = {
	{ 0.98621192462708, -1.97242384925416, 0.98621192462708 },
	{ 0.98500175787242, -1.97000351574484, 0.98500175787242 },
	{ 0.97938932735214, -1.95877865470428, 0.97938932735214 },
	{ 0.97531843204928, -1.95063686409857, 0.97531843204928 },
	{ 0.97316523498161, -1.94633046996323, 0.97316523498161 },
	{ 0.96454515552826, -1.92909031105652, 0.96454515552826 },
	{ 0.96009142950541, -1.92018285901082, 0.96009142950541 },
	{ 0.95856916599601, -1.91713833199203, 0.95856916599601 },
	{ 0.94597685600279, -1.89195371200558, 0.94597685600279 }
	};

	#ifdef WIN32
	#pragma warning ( default : 4305 )
	#endif

	/* When calling this procedure, make sure that ip[-order] and op[-order] point to real data! */

	static void
	filter ( const Float_t* input, Float_t* output, size_t nSamples, const Float_t* a, const Float_t* b, size_t order )
	{
	double y;
	size_t i;
	size_t k;

	for ( i = 0; i < nSamples; i++ ) {
	y = input[i] * b[0];
	for ( k = 1; k <= order; k++ )
	y += input[i-k] * b[k] - output[i-k] * a[k];
	output[i] = (Float_t)y;
	}
	}

	/* returns a INIT_GAIN_ANALYSIS_OK if successful, INIT_GAIN_ANALYSIS_ERROR if not */

	int
	ResetSampleFrequency ( long samplefreq ) {
	int i;

	/* zero out initial values */
	for ( i = 0; i < MAX_ORDER; i++ )
	linprebuf[i] = lstepbuf[i] = loutbuf[i] = rinprebuf[i] = rstepbuf[i] = routbuf[i] = 0.;

	switch ( (int)(samplefreq) ) {
	case 48000: freqindex = 0; break;
	case 44100: freqindex = 1; break;
	case 32000: freqindex = 2; break;
	case 24000: freqindex = 3; break;
	case 22050: freqindex = 4; break;
	case 16000: freqindex = 5; break;
	case 12000: freqindex = 6; break;
	case 11025: freqindex = 7; break;
	case 8000: freqindex = 8; break;
	default: return INIT_GAIN_ANALYSIS_ERROR;
	}

	sampleWindow = (int) ceil (samplefreq * RMS_WINDOW_TIME);

	lsum = 0.;
	rsum = 0.;
	totsamp = 0;

	memset ( A, 0, sizeof(A) );

	return INIT_GAIN_ANALYSIS_OK;
	}

	int
	InitGainAnalysis ( long samplefreq )
	{
	if (ResetSampleFrequency(samplefreq) != INIT_GAIN_ANALYSIS_OK) {
	return INIT_GAIN_ANALYSIS_ERROR;
	}

	linpre = linprebuf + MAX_ORDER;
	rinpre = rinprebuf + MAX_ORDER;
	lstep = lstepbuf + MAX_ORDER;
	rstep = rstepbuf + MAX_ORDER;
	lout = loutbuf + MAX_ORDER;
	rout = routbuf + MAX_ORDER;

	memset ( B, 0, sizeof(B) );

	return INIT_GAIN_ANALYSIS_OK;
	}

	/* returns GAIN_ANALYSIS_OK if successful, GAIN_ANALYSIS_ERROR if not */

	int
	AnalyzeSamples ( const Float_t* left_samples, const Float_t* right_samples, size_t num_samples, int num_channels )
	{
	const Float_t* curleft;
	const Float_t* curright;
	long batchsamples;
	long cursamples;
	long cursamplepos;
	int i;

	if ( num_samples == 0 )
	return GAIN_ANALYSIS_OK;

	cursamplepos = 0;
	batchsamples = num_samples;

	switch ( num_channels) {
	case 1: right_samples = left_samples;
	case 2: break;
	default: return GAIN_ANALYSIS_ERROR;
	}

	if ( num_samples < MAX_ORDER ) {
	memcpy ( linprebuf + MAX_ORDER, left_samples , num_samples * sizeof(Float_t) );
	memcpy ( rinprebuf + MAX_ORDER, right_samples, num_samples * sizeof(Float_t) );
	}
	else {
	memcpy ( linprebuf + MAX_ORDER, left_samples, MAX_ORDER * sizeof(Float_t) );
	memcpy ( rinprebuf + MAX_ORDER, right_samples, MAX_ORDER * sizeof(Float_t) );
	}

	while ( batchsamples > 0 ) {
	cursamples = batchsamples > (long)(sampleWindow-totsamp) ? (long)(sampleWindow - totsamp) : batchsamples;
	if ( cursamplepos < MAX_ORDER ) {
	curleft = linpre+cursamplepos;
	curright = rinpre+cursamplepos;
	if (cursamples > MAX_ORDER - cursamplepos )
	cursamples = MAX_ORDER - cursamplepos;
	}
	else {
	curleft = left_samples + cursamplepos;
	curright = right_samples + cursamplepos;
	}

	filter ( curleft , lstep + totsamp, cursamples, AYule[freqindex], BYule[freqindex], YULE_ORDER );
	filter ( curright, rstep + totsamp, cursamples, AYule[freqindex], BYule[freqindex], YULE_ORDER );

	filter ( lstep + totsamp, lout + totsamp, cursamples, AButter[freqindex], BButter[freqindex], BUTTER_ORDER );
	filter ( rstep + totsamp, rout + totsamp, cursamples, AButter[freqindex], BButter[freqindex], BUTTER_ORDER );

	for ( i = 0; i < cursamples; i++ ) { /* Get the squared values */
	lsum += lout [totsamp+i] * lout [totsamp+i];
	rsum += rout [totsamp+i] * rout [totsamp+i];
	}

	batchsamples -= cursamples;
	cursamplepos += cursamples;
	totsamp += cursamples;
	if ( totsamp == sampleWindow ) { /* Get the Root Mean Square (RMS) for this set of samples */
	double val = STEPS_per_dB * 10. * log10 ( (lsum+rsum) / totsamp * 0.5 + 1.e-37 );
	int ival = (int) val;
	if ( ival < 0 ) ival = 0;
	if ( ival >= (int)(sizeof(A)/sizeof(A)) ) ival = (int)(sizeof(A)/sizeof(A)) - 1;
	A [ival]++;
	lsum = rsum = 0.;
	memmove ( loutbuf , loutbuf + totsamp, MAX_ORDER * sizeof(Float_t) );
	memmove ( routbuf , routbuf + totsamp, MAX_ORDER * sizeof(Float_t) );
	memmove ( lstepbuf, lstepbuf + totsamp, MAX_ORDER * sizeof(Float_t) );
	memmove ( rstepbuf, rstepbuf + totsamp, MAX_ORDER * sizeof(Float_t) );
	totsamp = 0;
	}
	if ( totsamp > sampleWindow ) /* somehow I really screwed up: Error in programming! Contact author about totsamp > sampleWindow */
	return GAIN_ANALYSIS_ERROR;
	}
	if ( num_samples < MAX_ORDER ) {
	memmove ( linprebuf, linprebuf + num_samples, (MAX_ORDER-num_samples) * sizeof(Float_t) );
	memmove ( rinprebuf, rinprebuf + num_samples, (MAX_ORDER-num_samples) * sizeof(Float_t) );
	memcpy ( linprebuf + MAX_ORDER - num_samples, left_samples, num_samples * sizeof(Float_t) );
	memcpy ( rinprebuf + MAX_ORDER - num_samples, right_samples, num_samples * sizeof(Float_t) );
	}
	else {
	memcpy ( linprebuf, left_samples + num_samples - MAX_ORDER, MAX_ORDER * sizeof(Float_t) );
	memcpy ( rinprebuf, right_samples + num_samples - MAX_ORDER, MAX_ORDER * sizeof(Float_t) );
	}

	return GAIN_ANALYSIS_OK;
	}


	static Float_t
	analyzeResult ( Uint32_t* Array, size_t len )
	{
	Uint32_t elems;
	Int32_t upper;
	size_t i;

	elems = 0;
	for ( i = 0; i < len; i++ )
	elems += Array[i];
	if ( elems == 0 )
	return GAIN_NOT_ENOUGH_SAMPLES;

	upper = (Int32_t) ceil (elems * (1. - RMS_PERCENTILE));
	for ( i = len; i-- > 0; ) {
	if ( (upper -= Array[i]) <= 0 )
	break;
	}

	return (Float_t) ((Float_t)PINK_REF - (Float_t)i / (Float_t)STEPS_per_dB);
	}


	Float_t
	GetTitleGain ( void )
	{
	Float_t retval;
	unsigned int i;

	retval = analyzeResult ( A, sizeof(A)/sizeof(*A) );

	for ( i = 0; i < sizeof(A)/sizeof(*A); i++ ) {
	B[i] += A[i];
	A[i] = 0;
	}

	for ( i = 0; i < MAX_ORDER; i++ )
	linprebuf[i] = lstepbuf[i] = loutbuf[i] = rinprebuf[i] = rstepbuf[i] = routbuf[i] = 0.f;

	totsamp = 0;
	lsum = rsum = 0.;
	return retval;
	}


	Float_t
	GetAlbumGain ( void )
	{
	return analyzeResult ( B, sizeof(B)/sizeof(*B) );
	}

	/* end of replaygain_analysis.c */