/* * quantize_pvt source file * * Copyright (c) 1999-2002 Takehiro Tominaga * Copyright (c) 2000-2002 Robert Hegemann * Copyright (c) 2001 Naoki Shibata * Copyright (c) 2002-2005 Gabriel Bouvigne * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library 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. */ /* $Id: quantize_pvt.c,v 1.131.2.1 2005/11/20 14:08:25 bouvigne Exp $ */ #ifdef HAVE_CONFIG_H # include <config.h> #endif #include <assert.h> #include "util.h" #include "lame-analysis.h" #include "tables.h" #include "reservoir.h" #include "quantize_pvt.h" #ifdef WITH_DMALLOC #include <dmalloc.h> #endif #define NSATHSCALE 100 /* Assuming dynamic range=96dB, this value should be 92 */ /* The following table is used to implement the scalefactor partitioning for MPEG2 as described in section 2.4.3.2 of the IS. The indexing corresponds to the way the tables are presented in the IS: [table_number][row_in_table][column of nr_of_sfb] */ const int nr_of_sfb_block [6] [3] [4] = { { {6, 5, 5, 5}, {9, 9, 9, 9}, {6, 9, 9, 9} }, { {6, 5, 7, 3}, {9, 9, 12, 6}, {6, 9, 12, 6} }, { {11, 10, 0, 0}, {18, 18, 0, 0}, {15,18,0,0} }, { {7, 7, 7, 0}, {12, 12, 12, 0}, {6, 15, 12, 0} }, { {6, 6, 6, 3}, {12, 9, 9, 6}, {6, 12, 9, 6} }, { {8, 8, 5, 0}, {15,12,9,0}, {6,18,9,0} } }; /* Table B.6: layer3 preemphasis */ const int pretab [SBMAX_l] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 3, 3, 3, 2, 0 }; /* Here are MPEG1 Table B.8 and MPEG2 Table B.1 -- Layer III scalefactor bands. Index into this using a method such as: idx = fr_ps->header->sampling_frequency + (fr_ps->header->version * 3) */ const scalefac_struct sfBandIndex[9] = { { /* Table B.2.b: 22.05 kHz */ {0,6,12,18,24,30,36,44,54,66,80,96,116,140,168,200,238,284,336,396,464,522,576}, {0,4,8,12,18,24,32,42,56,74,100,132,174,192} }, { /* Table B.2.c: 24 kHz */ /* docs: 332. mpg123(broken): 330 */ {0,6,12,18,24,30,36,44,54,66,80,96,114,136,162,194,232,278, 332, 394,464,540,576}, {0,4,8,12,18,26,36,48,62,80,104,136,180,192} }, { /* Table B.2.a: 16 kHz */ {0,6,12,18,24,30,36,44,54,66,80,96,116,140,168,200,238,284,336,396,464,522,576}, {0,4,8,12,18,26,36,48,62,80,104,134,174,192} }, { /* Table B.8.b: 44.1 kHz */ {0,4,8,12,16,20,24,30,36,44,52,62,74,90,110,134,162,196,238,288,342,418,576}, {0,4,8,12,16,22,30,40,52,66,84,106,136,192} }, { /* Table B.8.c: 48 kHz */ {0,4,8,12,16,20,24,30,36,42,50,60,72,88,106,128,156,190,230,276,330,384,576}, {0,4,8,12,16,22,28,38,50,64,80,100,126,192} }, { /* Table B.8.a: 32 kHz */ {0,4,8,12,16,20,24,30,36,44,54,66,82,102,126,156,194,240,296,364,448,550,576}, {0,4,8,12,16,22,30,42,58,78,104,138,180,192} }, { /* MPEG-2.5 11.025 kHz */ {0,6,12,18,24,30,36,44,54,66,80,96,116,140,168,200,238,284,336,396,464,522,576}, {0/3,12/3,24/3,36/3,54/3,78/3,108/3,144/3,186/3,240/3,312/3,402/3,522/3,576/3} }, { /* MPEG-2.5 12 kHz */ {0,6,12,18,24,30,36,44,54,66,80,96,116,140,168,200,238,284,336,396,464,522,576}, {0/3,12/3,24/3,36/3,54/3,78/3,108/3,144/3,186/3,240/3,312/3,402/3,522/3,576/3} }, { /* MPEG-2.5 8 kHz */ {0,12,24,36,48,60,72,88,108,132,160,192,232,280,336,400,476,566,568,570,572,574,576}, {0/3,24/3,48/3,72/3,108/3,156/3,216/3,288/3,372/3,480/3,486/3,492/3,498/3,576/3} } }; FLOAT pow20[Q_MAX+Q_MAX2+1]; FLOAT ipow20[Q_MAX]; FLOAT pow43[PRECALC_SIZE]; /* initialized in first call to iteration_init */ #ifdef TAKEHIRO_IEEE754_HACK FLOAT adj43asm[PRECALC_SIZE]; #else FLOAT adj43[PRECALC_SIZE]; #endif /* compute the ATH for each scalefactor band cd range: 0..96db Input: 3.3kHz signal 32767 amplitude (3.3kHz is where ATH is smallest = -5db) longblocks: sfb=12 en0/bw=-11db max_en0 = 1.3db shortblocks: sfb=5 -9db 0db Input: 1 1 1 1 1 1 1 -1 -1 -1 -1 -1 -1 -1 (repeated) longblocks: amp=1 sfb=12 en0/bw=-103 db max_en0 = -92db amp=32767 sfb=12 -12 db -1.4db Input: 1 1 1 1 1 1 1 -1 -1 -1 -1 -1 -1 -1 (repeated) shortblocks: amp=1 sfb=5 en0/bw= -99 -86 amp=32767 sfb=5 -9 db 4db MAX energy of largest wave at 3.3kHz = 1db AVE energy of largest wave at 3.3kHz = -11db Let's take AVE: -11db = maximum signal in sfb=12. Dynamic range of CD: 96db. Therefor energy of smallest audible wave in sfb=12 = -11 - 96 = -107db = ATH at 3.3kHz. ATH formula for this wave: -5db. To adjust to LAME scaling, we need ATH = ATH_formula - 103 (db) ATH = ATH * 2.5e-10 (ener) */ static FLOAT ATHmdct( lame_global_flags *gfp, FLOAT f ) { FLOAT ath; ath = ATHformula( f , gfp ); if (gfp->psymodel == PSY_NSPSYTUNE) { ath -= NSATHSCALE; } else { ath -= 114; } /* modify the MDCT scaling for the ATH and convert to energy */ ath = pow( 10.0, ath/10.0 + gfp->ATHlower); return ath; } static void compute_ath( lame_global_flags *gfp ) { FLOAT *ATH_l = gfp->internal_flags->ATH->l; FLOAT *ATH_psfb21 = gfp->internal_flags->ATH->psfb21; FLOAT *ATH_s = gfp->internal_flags->ATH->s; FLOAT *ATH_psfb12 = gfp->internal_flags->ATH->psfb12; lame_internal_flags *gfc = gfp->internal_flags; int sfb, i, start, end; FLOAT ATH_f; FLOAT samp_freq = gfp->out_samplerate; for (sfb = 0; sfb < SBMAX_l; sfb++) { start = gfc->scalefac_band.l[ sfb ]; end = gfc->scalefac_band.l[ sfb+1 ]; ATH_l[sfb]=FLOAT_MAX; for (i = start ; i < end; i++) { FLOAT freq = i*samp_freq/(2*576); ATH_f = ATHmdct( gfp, freq ); /* freq in kHz */ ATH_l[sfb] = Min( ATH_l[sfb], ATH_f ); } if (gfp->psymodel == PSY_GPSYCHO) ATH_l[sfb] *= (gfc->scalefac_band.l[sfb+1] - gfc->scalefac_band.l[sfb]); } for (sfb = 0; sfb < PSFB21; sfb++) { start = gfc->scalefac_band.psfb21[ sfb ]; end = gfc->scalefac_band.psfb21[ sfb+1 ]; ATH_psfb21[sfb]=FLOAT_MAX; for (i = start ; i < end; i++) { FLOAT freq = i*samp_freq/(2*576); ATH_f = ATHmdct( gfp, freq ); /* freq in kHz */ ATH_psfb21[sfb] = Min( ATH_psfb21[sfb], ATH_f ); } } for (sfb = 0; sfb < SBMAX_s; sfb++){ start = gfc->scalefac_band.s[ sfb ]; end = gfc->scalefac_band.s[ sfb+1 ]; ATH_s[sfb] = FLOAT_MAX; for (i = start ; i < end; i++) { FLOAT freq = i*samp_freq/(2*192); ATH_f = ATHmdct( gfp, freq ); /* freq in kHz */ ATH_s[sfb] = Min( ATH_s[sfb], ATH_f ); } ATH_s[sfb] *= (gfc->scalefac_band.s[sfb+1] - gfc->scalefac_band.s[sfb]); } for (sfb = 0; sfb < PSFB12; sfb++) { start = gfc->scalefac_band.psfb12[ sfb ]; end = gfc->scalefac_band.psfb12[ sfb+1 ]; ATH_psfb12[sfb]=FLOAT_MAX; for (i = start ; i < end; i++) { FLOAT freq = i*samp_freq/(2*192); ATH_f = ATHmdct( gfp, freq ); /* freq in kHz */ ATH_psfb12[sfb] = Min( ATH_psfb12[sfb], ATH_f ); } /*not sure about the following*/ ATH_psfb12[sfb] *= (gfc->scalefac_band.s[13] - gfc->scalefac_band.s[12]); } /* no-ATH mode: * reduce ATH to -200 dB */ if (gfp->noATH) { for (sfb = 0; sfb < SBMAX_l; sfb++) { ATH_l[sfb] = 1E-37; } for (sfb = 0; sfb < PSFB21; sfb++) { ATH_psfb21[sfb] = 1E-37; } for (sfb = 0; sfb < SBMAX_s; sfb++) { ATH_s[sfb] = 1E-37; } for (sfb = 0; sfb < PSFB12; sfb++) { ATH_psfb12[sfb] = 1E-37; } } /* work in progress, don't rely on it too much */ gfc->ATH-> floor = 10. * log10( ATHmdct( gfp, -1. ) ); /* { FLOAT g=10000, t=1e30, x; for ( f = 100; f < 10000; f++ ) { x = ATHmdct( gfp, f ); if ( t > x ) t = x, g = f; } printf("min=%g\n", g); }*/ } /************************************************************************/ /* initialization for iteration_loop */ /************************************************************************/ void iteration_init( lame_global_flags *gfp) { lame_internal_flags *gfc=gfp->internal_flags; III_side_info_t * const l3_side = &gfc->l3_side; int i; if ( gfc->iteration_init_init==0 ) { gfc->iteration_init_init=1; l3_side->main_data_begin = 0; compute_ath(gfp); pow43[0] = 0.0; for(i=1;i<PRECALC_SIZE;i++) pow43[i] = pow((FLOAT)i, 4.0/3.0); #ifdef TAKEHIRO_IEEE754_HACK adj43asm[0] = 0.0; for (i = 1; i < PRECALC_SIZE; i++) adj43asm[i] = i - 0.5 - pow(0.5 * (pow43[i - 1] + pow43[i]),0.75); #else for (i = 0; i < PRECALC_SIZE-1; i++) adj43[i] = (i + 1) - pow(0.5 * (pow43[i] + pow43[i + 1]), 0.75); adj43[i] = 0.5; #endif for (i = 0; i < Q_MAX; i++) ipow20[i] = pow(2.0, (double)(i - 210) * -0.1875); for (i = 0; i <= Q_MAX+Q_MAX2; i++) pow20[i] = pow(2.0, (double)(i - 210 - Q_MAX2) * 0.25); huffman_init(gfc); quantize_init(gfc); init_xrpow_core_init(gfc); if (gfp->psymodel == PSY_NSPSYTUNE) { FLOAT bass, alto, treble, sfb21; i = (gfp->exp_nspsytune >> 2) & 63; if (i >= 32) i -= 64; bass = pow(10, i / 4.0 / 10.0); i = (gfp->exp_nspsytune >> 8) & 63; if (i >= 32) i -= 64; alto = pow(10, i / 4.0 / 10.0); i = (gfp->exp_nspsytune >> 14) & 63; if (i >= 32) i -= 64; treble = pow(10, i / 4.0 / 10.0); /* to be compatible with Naoki's original code, the next 6 bits * define only the amount of changing treble for sfb21 */ i = (gfp->exp_nspsytune >> 20) & 63; if (i >= 32) i -= 64; sfb21 = treble * pow(10, i / 4.0 / 10.0); for (i = 0; i < SBMAX_l; i++) { FLOAT f; if (i <= 6) f = bass; else if (i <= 13) f = alto; else if (i <= 20) f = treble; else f = sfb21; gfc->nsPsy.longfact[i] = f; } for (i = 0; i < SBMAX_s; i++) { FLOAT f; if (i <= 5) f = bass; else if (i <= 10) f = alto; else if (i <= 11) f = treble; else f = sfb21; gfc->nsPsy.shortfact[i] = f; } } else { for (i = 0; i < SBMAX_l; i++) gfc->nsPsy.longfact[i] = 1.0; for (i = 0; i < SBMAX_s; i++) gfc->nsPsy.shortfact[i] = 1.0; } } } /************************************************************************ * allocate bits among 2 channels based on PE * mt 6/99 * bugfixes rh 8/01: often allocated more than the allowed 4095 bits ************************************************************************/ int on_pe( lame_global_flags *gfp, FLOAT pe[][2], III_side_info_t *l3_side, int targ_bits[2], int mean_bits, int gr, int cbr ) { lame_internal_flags * gfc = gfp->internal_flags; gr_info * cod_info; int extra_bits, tbits, bits; int add_bits[2]; int max_bits; /* maximum allowed bits for this granule */ int ch; /* allocate targ_bits for granule */ ResvMaxBits( gfp, mean_bits, &tbits, &extra_bits, cbr); max_bits = tbits + extra_bits; if (max_bits > MAX_BITS) /* hard limit per granule */ max_bits = MAX_BITS; for ( bits = 0, ch = 0; ch < gfc->channels_out; ++ch ) { /****************************************************************** * allocate bits for each channel ******************************************************************/ cod_info = &l3_side->tt[gr][ch]; targ_bits[ch] = Min( MAX_BITS, tbits/gfc->channels_out ); if (gfp->psymodel == PSY_NSPSYTUNE) { add_bits[ch] = targ_bits[ch] * pe[gr][ch] / 700.0 - targ_bits[ch]; } else { add_bits[ch] = (pe[gr][ch]-750) / 1.4; /* short blocks us a little extra, no matter what the pe */ if ( cod_info->block_type == SHORT_TYPE ) { if (add_bits[ch] < mean_bits/4) add_bits[ch] = mean_bits/4; } } /* at most increase bits by 1.5*average */ if (add_bits[ch] > mean_bits*3/4) add_bits[ch] = mean_bits*3/4; if (add_bits[ch] < 0) add_bits[ch] = 0; if (add_bits[ch]+targ_bits[ch] > MAX_BITS) add_bits[ch] = Max( 0, MAX_BITS-targ_bits[ch] ); bits += add_bits[ch]; } if (bits > extra_bits) { for ( ch = 0; ch < gfc->channels_out; ++ch ) { add_bits[ch] = extra_bits * add_bits[ch] / bits; } } for ( ch = 0; ch < gfc->channels_out; ++ch ) { targ_bits[ch] += add_bits[ch]; extra_bits -= add_bits[ch]; assert( targ_bits[ch] <= MAX_BITS ); } assert( max_bits <= MAX_BITS ); return max_bits; } void reduce_side(int targ_bits[2],FLOAT ms_ener_ratio,int mean_bits,int max_bits) { int move_bits; FLOAT fac; /* ms_ener_ratio = 0: allocate 66/33 mid/side fac=.33 * ms_ener_ratio =.5: allocate 50/50 mid/side fac= 0 */ /* 75/25 split is fac=.5 */ /* float fac = .50*(.5-ms_ener_ratio[gr])/.5;*/ fac = .33*(.5-ms_ener_ratio)/.5; if (fac<0) fac=0; if (fac>.5) fac=.5; /* number of bits to move from side channel to mid channel */ /* move_bits = fac*targ_bits[1]; */ move_bits = fac*.5*(targ_bits[0]+targ_bits[1]); if (move_bits > MAX_BITS - targ_bits[0]) { move_bits = MAX_BITS - targ_bits[0]; } if (move_bits<0) move_bits=0; if (targ_bits[1] >= 125) { /* dont reduce side channel below 125 bits */ if (targ_bits[1]-move_bits > 125) { /* if mid channel already has 2x more than average, dont bother */ /* mean_bits = bits per granule (for both channels) */ if (targ_bits[0] < mean_bits) targ_bits[0] += move_bits; targ_bits[1] -= move_bits; } else { targ_bits[0] += targ_bits[1] - 125; targ_bits[1] = 125; } } move_bits=targ_bits[0]+targ_bits[1]; if (move_bits > max_bits) { targ_bits[0]=(max_bits*targ_bits[0])/move_bits; targ_bits[1]=(max_bits*targ_bits[1])/move_bits; } assert (targ_bits[0] <= MAX_BITS); assert (targ_bits[1] <= MAX_BITS); } /** * Robert Hegemann 2001-04-27: * this adjusts the ATH, keeping the original noise floor * affects the higher frequencies more than the lower ones */ FLOAT athAdjust( FLOAT a, FLOAT x, FLOAT athFloor ) { /* work in progress */ FLOAT const o = 90.30873362; FLOAT const p = 94.82444863; FLOAT u = FAST_LOG10_X(x, 10.0); FLOAT v = a*a; FLOAT w = 0.0; u -= athFloor; /* undo scaling */ if ( v > 1E-20 ) w = 1. + FAST_LOG10_X(v, 10.0 / o); if ( w < 0 ) w = 0.; u *= w; u += athFloor + o-p; /* redo scaling */ return pow( 10., 0.1*u ); } /*************************************************************************/ /* calc_xmin */ /*************************************************************************/ /* Calculate the allowed distortion for each scalefactor band, as determined by the psychoacoustic model. xmin(sb) = ratio(sb) * en(sb) / bw(sb) returns number of sfb's with energy > ATH */ int calc_xmin( lame_global_flags *gfp, const III_psy_ratio * const ratio, gr_info * const cod_info, FLOAT * pxmin ) { lame_internal_flags *gfc = gfp->internal_flags; int sfb, gsfb, j=0, ath_over=0, k; ATH_t * ATH = gfc->ATH; const FLOAT *xr = cod_info->xr; int max_nonzero; for (gsfb = 0; gsfb < cod_info->psy_lmax; gsfb++) { FLOAT en0, xmin; int width, l; if (gfp->VBR == vbr_rh || gfp->VBR == vbr_mtrh) xmin = athAdjust(ATH->adjust, ATH->l[gsfb], ATH->floor); else xmin = ATH->adjust * ATH->l[gsfb]; width = cod_info->width[gsfb]; l = width >> 1; en0 = 0.0; do { en0 += xr[j] * xr[j]; j++; en0 += xr[j] * xr[j]; j++; } while (--l > 0); if (en0 > xmin) ath_over++; if (!gfp->ATHonly) { FLOAT x = ratio->en.l[gsfb]; if (x > 0.0) { x = en0 * ratio->thm.l[gsfb] * gfc->masking_lower / x; if (xmin < x) xmin = x; } } *pxmin++ = xmin * gfc->nsPsy.longfact[gsfb]; } /* end of long block loop */ /*use this function to determine the highest non-zero coeff*/ max_nonzero = 575; if (cod_info->block_type == NORM_TYPE) { k = 576; while (k-- && !xr[k]){ max_nonzero = k; } } cod_info->max_nonzero_coeff = max_nonzero; for (sfb = cod_info->sfb_smin; gsfb < cod_info->psymax; sfb++, gsfb += 3) { int width, b; FLOAT tmpATH; if ( gfp->VBR == vbr_rh || gfp->VBR == vbr_mtrh ) tmpATH = athAdjust( ATH->adjust, ATH->s[sfb], ATH->floor ); else tmpATH = ATH->adjust * ATH->s[sfb]; width = cod_info->width[gsfb]; for ( b = 0; b < 3; b++ ) { FLOAT en0 = 0.0, xmin; int l = width >> 1; do { en0 += xr[j] * xr[j]; j++; en0 += xr[j] * xr[j]; j++; } while (--l > 0); if (en0 > tmpATH) ath_over++; xmin = tmpATH; if (!gfp->ATHonly && !gfp->ATHshort) { FLOAT x = ratio->en.s[sfb][b]; if (x > 0.0) x = en0 * ratio->thm.s[sfb][b] * gfc->masking_lower / x; if (xmin < x) xmin = x; } *pxmin++ = xmin * gfc->nsPsy.shortfact[sfb]; } /* b */ if (gfp->useTemporal) { if (pxmin[-3] > pxmin[-3+1]) pxmin[-3+1] += (pxmin[-3] - pxmin[-3+1]) * gfc->decay; if (pxmin[-3+1] > pxmin[-3+2]) pxmin[-3+2] += (pxmin[-3+1] - pxmin[-3+2]) * gfc->decay; } } /* end of short block sfb loop */ return ath_over; } FLOAT calc_noise_core_c( const gr_info * const cod_info, int *startline, int l, FLOAT step) { FLOAT noise = 0; int j = *startline; const int *ix = cod_info->l3_enc; if (j> cod_info->count1) { while (l--) { FLOAT temp; temp = cod_info->xr[j];j++; noise += temp * temp; temp = cod_info->xr[j];j++; noise += temp * temp; } } else if (j> cod_info->big_values) { FLOAT ix01[2]; ix01[0] = 0; ix01[1] = step; while (l--) { FLOAT temp; temp = fabs(cod_info->xr[j]) - ix01[ix[j]];j++; noise += temp * temp; temp = fabs(cod_info->xr[j]) - ix01[ix[j]];j++; noise += temp * temp; } } else { while (l--) { FLOAT temp; temp = fabs(cod_info->xr[j]) - pow43[ix[j]] * step;j++; noise += temp * temp; temp = fabs(cod_info->xr[j]) - pow43[ix[j]] * step;j++; noise += temp * temp; } } *startline = j; return noise; } /*************************************************************************/ /* calc_noise */ /*************************************************************************/ /* -oo dB => -1.00 */ /* - 6 dB => -0.97 */ /* - 3 dB => -0.80 */ /* - 2 dB => -0.64 */ /* - 1 dB => -0.38 */ /* 0 dB => 0.00 */ /* + 1 dB => +0.49 */ /* + 2 dB => +1.06 */ /* + 3 dB => +1.68 */ /* + 6 dB => +3.69 */ /* +10 dB => +6.45 */ int calc_noise( const lame_internal_flags * const gfc, const gr_info * const cod_info, const FLOAT * l3_xmin, FLOAT * distort, calc_noise_result * const res, calc_noise_data * prev_noise) { int sfb, l, over=0; FLOAT over_noise_db = 0; FLOAT tot_noise_db = 0; /* 0 dB relative to masking */ FLOAT max_noise = -20.0; /* -200 dB relative to masking */ int j = 0; const int *ix = cod_info->l3_enc; const int *scalefac = cod_info->scalefac; FLOAT sfb_noise[39]; res->over_SSD = 0; for (sfb = 0; sfb < cod_info->psymax; sfb++) { int s = cod_info->global_gain - (((*scalefac++) + (cod_info->preflag ? pretab[sfb] : 0)) << (cod_info->scalefac_scale + 1)) - cod_info->subblock_gain[cod_info->window[sfb]] * 8; FLOAT noise = 0.0; if (prev_noise && (prev_noise->step[sfb] == s)){ /* use previously computed values */ noise = prev_noise->noise[sfb]; j += cod_info->width[sfb]; *distort++ = noise / *l3_xmin++; noise = prev_noise->noise_log[sfb]; } else { FLOAT step = POW20(s); l = cod_info->width[sfb] >> 1; if ((j+cod_info->width[sfb])>cod_info->max_nonzero_coeff) { int usefullsize; usefullsize = cod_info->max_nonzero_coeff - j +1; if (usefullsize > 0) l = usefullsize >> 1; else l = 0; } noise = calc_noise_core_c(cod_info, &j, l, step); if (prev_noise) { /* save noise values */ prev_noise->step[sfb] = s; prev_noise->noise[sfb] = noise; } noise = *distort++ = noise / *l3_xmin++; /* multiplying here is adding in dB, but can overflow */ noise = FAST_LOG10(Max(noise,1E-20)); if (prev_noise) { /* save noise values */ prev_noise->noise_log[sfb] = noise; } } if (prev_noise) { /* save noise values */ prev_noise->global_gain = cod_info->global_gain;; } /*tot_noise *= Max(noise, 1E-20); */ tot_noise_db += noise; if (noise > 0.0) { int tmp; tmp = Max((int)(noise*10 + .5), 1); res->over_SSD += tmp*tmp; over++; /* multiplying here is adding in dB -but can overflow */ /*over_noise *= noise; */ over_noise_db += noise; } max_noise=Max(max_noise,noise); sfb_noise[sfb] = noise; } res->over_count = over; res->tot_noise = tot_noise_db; res->over_noise = over_noise_db; res->max_noise = max_noise; return over; } #ifdef HAVE_GTK /************************************************************************ * * set_pinfo() * * updates plotting data * * Mark Taylor 2000-??-?? * * Robert Hegemann: moved noise/distortion calc into it * ************************************************************************/ static void set_pinfo ( lame_global_flags *gfp, gr_info * const cod_info, const III_psy_ratio * const ratio, const int gr, const int ch ) { lame_internal_flags *gfc=gfp->internal_flags; int sfb, sfb2; int j,i,l,start,end,bw; FLOAT en0,en1; FLOAT ifqstep = ( cod_info->scalefac_scale == 0 ) ? .5 : 1.0; int* scalefac = cod_info->scalefac; FLOAT l3_xmin[SFBMAX], xfsf[SFBMAX]; calc_noise_result noise; calc_xmin (gfp, ratio, cod_info, l3_xmin); calc_noise (gfc, cod_info, l3_xmin, xfsf, &noise, 0); j = 0; sfb2 = cod_info->sfb_lmax; if (cod_info->block_type != SHORT_TYPE && !cod_info->mixed_block_flag) sfb2 = 22; for (sfb = 0; sfb < sfb2; sfb++) { start = gfc->scalefac_band.l[ sfb ]; end = gfc->scalefac_band.l[ sfb+1 ]; bw = end - start; for ( en0 = 0.0; j < end; j++ ) en0 += cod_info->xr[j] * cod_info->xr[j]; en0/=bw; /* convert to MDCT units */ en1=1e15; /* scaling so it shows up on FFT plot */ gfc->pinfo-> en[gr][ch][sfb] = en1*en0; gfc->pinfo->xfsf[gr][ch][sfb] = en1*l3_xmin[sfb]*xfsf[sfb]/bw; if (ratio->en.l[sfb]>0 && !gfp->ATHonly) en0 = en0/ratio->en.l[sfb]; else en0=0.0; gfc->pinfo->thr[gr][ch][sfb] = en1*Max(en0*ratio->thm.l[sfb],gfc->ATH->l[sfb]); /* there is no scalefactor bands >= SBPSY_l */ gfc->pinfo->LAMEsfb[gr][ch][sfb] = 0; if (cod_info->preflag && sfb>=11) gfc->pinfo->LAMEsfb[gr][ch][sfb] = -ifqstep*pretab[sfb]; if (sfb<SBPSY_l) { assert(scalefac[sfb]>=0); /* scfsi should be decoded by caller side*/ gfc->pinfo->LAMEsfb[gr][ch][sfb] -= ifqstep*scalefac[sfb]; } } /* for sfb */ if (cod_info->block_type == SHORT_TYPE) { sfb2 = sfb; for (sfb = cod_info->sfb_smin; sfb < SBMAX_s; sfb++ ) { start = gfc->scalefac_band.s[ sfb ]; end = gfc->scalefac_band.s[ sfb + 1 ]; bw = end - start; for ( i = 0; i < 3; i++ ) { for ( en0 = 0.0, l = start; l < end; l++ ) { en0 += cod_info->xr[j] * cod_info->xr[j]; j++; } en0=Max(en0/bw,1e-20); /* convert to MDCT units */ en1=1e15; /* scaling so it shows up on FFT plot */ gfc->pinfo-> en_s[gr][ch][3*sfb+i] = en1*en0; gfc->pinfo->xfsf_s[gr][ch][3*sfb+i] = en1*l3_xmin[sfb2]*xfsf[sfb2]/bw; if (ratio->en.s[sfb][i]>0) en0 = en0/ratio->en.s[sfb][i]; else en0=0.0; if (gfp->ATHonly || gfp->ATHshort) en0=0; gfc->pinfo->thr_s[gr][ch][3*sfb+i] = en1*Max(en0*ratio->thm.s[sfb][i],gfc->ATH->s[sfb]); /* there is no scalefactor bands >= SBPSY_s */ gfc->pinfo->LAMEsfb_s[gr][ch][3*sfb+i] = -2.0*cod_info->subblock_gain[i]; if (sfb < SBPSY_s) { gfc->pinfo->LAMEsfb_s[gr][ch][3*sfb+i] -= ifqstep*scalefac[sfb2]; } sfb2++; } } } /* block type short */ gfc->pinfo->LAMEqss [gr][ch] = cod_info->global_gain; gfc->pinfo->LAMEmainbits[gr][ch] = cod_info->part2_3_length + cod_info->part2_length; gfc->pinfo->LAMEsfbits [gr][ch] = cod_info->part2_length; gfc->pinfo->over [gr][ch] = noise.over_count; gfc->pinfo->max_noise [gr][ch] = noise.max_noise * 10.0; gfc->pinfo->over_noise[gr][ch] = noise.over_noise * 10.0; gfc->pinfo->tot_noise [gr][ch] = noise.tot_noise * 10.0; gfc->pinfo->over_SSD [gr][ch] = noise.over_SSD; } /************************************************************************ * * set_frame_pinfo() * * updates plotting data for a whole frame * * Robert Hegemann 2000-10-21 * ************************************************************************/ void set_frame_pinfo( lame_global_flags *gfp, III_psy_ratio ratio [2][2]) { lame_internal_flags *gfc=gfp->internal_flags; int ch; int gr; gfc->masking_lower = 1.0; /* for every granule and channel patch l3_enc and set info */ for (gr = 0; gr < gfc->mode_gr; gr ++) { for (ch = 0; ch < gfc->channels_out; ch ++) { gr_info *cod_info = &gfc->l3_side.tt[gr][ch]; int scalefac_sav[SFBMAX]; memcpy(scalefac_sav, cod_info->scalefac, sizeof(scalefac_sav)); /* reconstruct the scalefactors in case SCFSI was used */ if (gr == 1) { int sfb; for (sfb = 0; sfb < cod_info->sfb_lmax; sfb++) { if (cod_info->scalefac[sfb] < 0) /* scfsi */ cod_info->scalefac[sfb] = gfc->l3_side.tt[0][ch].scalefac[sfb]; } } set_pinfo (gfp, cod_info, &ratio[gr][ch], gr, ch); memcpy(cod_info->scalefac, scalefac_sav, sizeof(scalefac_sav)); } /* for ch */ } /* for gr */ } #endif /* ifdef HAVE_GTK */