ref: 972a5284df9d375bafdde74f33b3aac75df06d18
dir: /libfaac/aacquant.c/
/* * FAAC - Freeware Advanced Audio Coder * Copyright (C) 2001 Menno Bakker * Copyright (C) 2002, 2003 Krzysztof Nikiel * * 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 * * $Id: aacquant.c,v 1.33 2012/03/01 18:34:17 knik Exp $ */ #include <math.h> #include <stdlib.h> #include <faac.h> #include "aacquant.h" #include "coder.h" #include "huffman.h" #include "psych.h" #include "util.h" #define TAKEHIRO_IEEE754_HACK 1 #define XRPOW_FTOI(src,dest) ((dest) = (int)(src)) #define QUANTFAC(rx) adj43[rx] #define ROUNDFAC 0.4054 static int FixNoise(CoderInfo *coderInfo, const double *xr, double *xr_pow, int *xi, double *xmin, double *pow43, double *adj43); static void CalcAllowedDist(CoderInfo *coderInfo, PsyInfo *psyInfo, double *xr, double *xmin, int quality); void AACQuantizeInit(CoderInfo *coderInfo, unsigned int numChannels, AACQuantCfg *aacquantCfg) { unsigned int channel, i; aacquantCfg->pow43 = (double*)AllocMemory(PRECALC_SIZE*sizeof(double)); aacquantCfg->adj43 = (double*)AllocMemory(PRECALC_SIZE*sizeof(double)); aacquantCfg->pow43[0] = 0.0; for(i=1;i<PRECALC_SIZE;i++) aacquantCfg->pow43[i] = pow((double)i, 4.0/3.0); #if TAKEHIRO_IEEE754_HACK aacquantCfg->adj43[0] = 0.0; for (i = 1; i < PRECALC_SIZE; i++) aacquantCfg->adj43[i] = i - 0.5 - pow(0.5 * (aacquantCfg->pow43[i - 1] + aacquantCfg->pow43[i]),0.75); #else // !TAKEHIRO_IEEE754_HACK for (i = 0; i < PRECALC_SIZE-1; i++) aacquantCfg->adj43[i] = (i + 1) - pow(0.5 * (aacquantCfg->pow43[i] + aacquantCfg->pow43[i + 1]), 0.75); aacquantCfg->adj43[i] = 0.5; #endif for (channel = 0; channel < numChannels; channel++) { coderInfo[channel].requantFreq = (double*)AllocMemory(BLOCK_LEN_LONG*sizeof(double)); } } void AACQuantizeEnd(CoderInfo *coderInfo, unsigned int numChannels, AACQuantCfg *aacquantCfg) { unsigned int channel; if (aacquantCfg->pow43) { FreeMemory(aacquantCfg->pow43); aacquantCfg->pow43 = NULL; } if (aacquantCfg->adj43) { FreeMemory(aacquantCfg->adj43); aacquantCfg->adj43 = NULL; } for (channel = 0; channel < numChannels; channel++) { if (coderInfo[channel].requantFreq) FreeMemory(coderInfo[channel].requantFreq); } } static void BalanceEnergy(CoderInfo *coderInfo, const double *xr, const int *xi, double *pow43) { const double ifqstep = pow(2.0, 0.25); const double logstep_1 = 1.0 / log(ifqstep); int sb; int nsfb = coderInfo->nr_of_sfb; int start, end; int l; double en0, enq; int shift; for (sb = 0; sb < nsfb; sb++) { double qfac_1; start = coderInfo->sfb_offset[sb]; end = coderInfo->sfb_offset[sb+1]; qfac_1 = pow(2.0, -0.25*(coderInfo->scale_factor[sb] - coderInfo->global_gain)); en0 = 0.0; enq = 0.0; for (l = start; l < end; l++) { double xq; if (!sb && !xi[l]) continue; xq = pow43[xi[l]]; en0 += xr[l] * xr[l]; enq += xq * xq; } if (enq == 0.0) continue; enq *= qfac_1 * qfac_1; shift = (int)(log(sqrt(enq / en0)) * logstep_1 + 1000.5); shift -= 1000; shift += coderInfo->scale_factor[sb]; coderInfo->scale_factor[sb] = shift; } } static void UpdateRequant(CoderInfo *coderInfo, int *xi, double *pow43) { double *requant_xr = coderInfo->requantFreq; int sb; int i; for (sb = 0; sb < coderInfo->nr_of_sfb; sb++) { double invQuantFac = pow(2.0, -0.25*(coderInfo->scale_factor[sb] - coderInfo->global_gain)); int start = coderInfo->sfb_offset[sb]; int end = coderInfo->sfb_offset[sb + 1]; for (i = start; i < end; i++) requant_xr[i] = pow43[xi[i]] * invQuantFac; } } int AACQuantize(CoderInfo *coderInfo, PsyInfo *psyInfo, ChannelInfo *channelInfo, int *cb_width, int num_cb, double *xr, AACQuantCfg *aacquantCfg) { int sb, i, do_q = 0; int bits = 0, sign; double xr_pow[FRAME_LEN]; double xmin[MAX_SCFAC_BANDS]; int xi[FRAME_LEN]; /* Use local copy's */ int *scale_factor = coderInfo->scale_factor; /* Set all scalefactors to 0 */ coderInfo->global_gain = 0; for (sb = 0; sb < coderInfo->nr_of_sfb; sb++) scale_factor[sb] = 0; /* Compute xr_pow */ for (i = 0; i < FRAME_LEN; i++) { double temp = fabs(xr[i]); xr_pow[i] = sqrt(temp * sqrt(temp)); do_q += (temp > 1E-20); } if (do_q) { CalcAllowedDist(coderInfo, psyInfo, xr, xmin, aacquantCfg->quality); coderInfo->global_gain = 0; FixNoise(coderInfo, xr, xr_pow, xi, xmin, aacquantCfg->pow43, aacquantCfg->adj43); BalanceEnergy(coderInfo, xr, xi, aacquantCfg->pow43); UpdateRequant(coderInfo, xi, aacquantCfg->pow43); for ( i = 0; i < FRAME_LEN; i++ ) { sign = (xr[i] < 0) ? -1 : 1; xi[i] *= sign; coderInfo->requantFreq[i] *= sign; } } else { coderInfo->global_gain = 0; SetMemory(xi, 0, FRAME_LEN*sizeof(int)); } BitSearch(coderInfo, xi); /* offset the difference of common_scalefac and scalefactors by SF_OFFSET */ for (i = 0; i < coderInfo->nr_of_sfb; i++) { if ((coderInfo->book_vector[i]!=INTENSITY_HCB)&&(coderInfo->book_vector[i]!=INTENSITY_HCB2)) { scale_factor[i] = coderInfo->global_gain - scale_factor[i] + SF_OFFSET; } } coderInfo->global_gain = scale_factor[0]; #if 0 printf("global gain: %d\n", coderInfo->global_gain); for (i = 0; i < coderInfo->nr_of_sfb; i++) printf("sf %d: %d\n", i, coderInfo->scale_factor[i]); #endif // clamp to valid diff range { int previous_scale_factor = coderInfo->global_gain; int previous_is_factor = 0; for (i = 0; i < coderInfo->nr_of_sfb; i++) { if ((coderInfo->book_vector[i]==INTENSITY_HCB) || (coderInfo->book_vector[i]==INTENSITY_HCB2)) { const int diff = scale_factor[i] - previous_is_factor; if (diff < -60) scale_factor[i] = previous_is_factor - 60; else if (diff > 60) scale_factor[i] = previous_is_factor + 60; previous_is_factor = scale_factor[i]; // printf("sf %d: %d diff=%d **\n", i, coderInfo->scale_factor[i], diff); } else if (coderInfo->book_vector[i]) { const int diff = scale_factor[i] - previous_scale_factor; if (diff < -60) scale_factor[i] = previous_scale_factor - 60; else if (diff > 60) scale_factor[i] = previous_scale_factor + 60; previous_scale_factor = scale_factor[i]; // printf("sf %d: %d diff=%d\n", i, coderInfo->scale_factor[i], diff); } } } /* place the codewords and their respective lengths in arrays data[] and len[] respectively */ /* there are 'counter' elements in each array, and these are variable length arrays depending on the input */ #ifdef DRM coderInfo->iLenReordSpData = 0; /* init length of reordered spectral data */ coderInfo->iLenLongestCW = 0; /* init length of longest codeword */ coderInfo->cur_cw = 0; /* init codeword counter */ #endif coderInfo->spectral_count = 0; sb = 0; for(i = 0; i < coderInfo->nr_of_sfb; i++) { OutputBits( coderInfo, #ifdef DRM &coderInfo->book_vector[i], /* needed for VCB11 */ #else coderInfo->book_vector[i], #endif xi, coderInfo->sfb_offset[i], coderInfo->sfb_offset[i+1]-coderInfo->sfb_offset[i]); if (coderInfo->book_vector[i]) sb = i; } // FIXME: Check those max_sfb/nr_of_sfb. Isn't it the same? coderInfo->max_sfb = coderInfo->nr_of_sfb = sb + 1; return bits; } #if TAKEHIRO_IEEE754_HACK typedef union { float f; int i; } fi_union; #define MAGIC_FLOAT (65536*(128)) #define MAGIC_INT 0x4b000000 #if 0 static void Quantize(const double *xp, int *pi, double istep) { int j; fi_union *fi; fi = (fi_union *)pi; for (j = FRAME_LEN/4 - 1; j >= 0; --j) { double x0 = istep * xp[0]; double x1 = istep * xp[1]; double x2 = istep * xp[2]; double x3 = istep * xp[3]; x0 += MAGIC_FLOAT; fi[0].f = x0; x1 += MAGIC_FLOAT; fi[1].f = x1; x2 += MAGIC_FLOAT; fi[2].f = x2; x3 += MAGIC_FLOAT; fi[3].f = x3; fi[0].f = x0 + (adj43asm - MAGIC_INT)[fi[0].i]; fi[1].f = x1 + (adj43asm - MAGIC_INT)[fi[1].i]; fi[2].f = x2 + (adj43asm - MAGIC_INT)[fi[2].i]; fi[3].f = x3 + (adj43asm - MAGIC_INT)[fi[3].i]; fi[0].i -= MAGIC_INT; fi[1].i -= MAGIC_INT; fi[2].i -= MAGIC_INT; fi[3].i -= MAGIC_INT; fi += 4; xp += 4; } } #endif static void QuantizeBand(const double *xp, int *pi, double istep, int offset, int end, double *adj43) { int j; fi_union *fi; fi = (fi_union *)pi; for (j = offset; j < end; j++) { double x0 = istep * xp[j]; x0 += MAGIC_FLOAT; fi[j].f = (float)x0; fi[j].f = x0 + (adj43 - MAGIC_INT)[fi[j].i]; fi[j].i -= MAGIC_INT; } } #else #if 0 static void Quantize(const double *xr, int *ix, double istep) { int j; for (j = FRAME_LEN/8; j > 0; --j) { double x1, x2, x3, x4, x5, x6, x7, x8; int rx1, rx2, rx3, rx4, rx5, rx6, rx7, rx8; x1 = *xr++ * istep; x2 = *xr++ * istep; XRPOW_FTOI(x1, rx1); x3 = *xr++ * istep; XRPOW_FTOI(x2, rx2); x4 = *xr++ * istep; XRPOW_FTOI(x3, rx3); x5 = *xr++ * istep; XRPOW_FTOI(x4, rx4); x6 = *xr++ * istep; XRPOW_FTOI(x5, rx5); x7 = *xr++ * istep; XRPOW_FTOI(x6, rx6); x8 = *xr++ * istep; XRPOW_FTOI(x7, rx7); x1 += QUANTFAC(rx1); XRPOW_FTOI(x8, rx8); x2 += QUANTFAC(rx2); XRPOW_FTOI(x1,*ix++); x3 += QUANTFAC(rx3); XRPOW_FTOI(x2,*ix++); x4 += QUANTFAC(rx4); XRPOW_FTOI(x3,*ix++); x5 += QUANTFAC(rx5); XRPOW_FTOI(x4,*ix++); x6 += QUANTFAC(rx6); XRPOW_FTOI(x5,*ix++); x7 += QUANTFAC(rx7); XRPOW_FTOI(x6,*ix++); x8 += QUANTFAC(rx8); XRPOW_FTOI(x7,*ix++); XRPOW_FTOI(x8,*ix++); } } #endif static void QuantizeBand(const double *xp, int *ix, double istep, int offset, int end, double *adj43) { int j; for (j = offset; j < end; j++) { double x0 = istep * xp[j]; x0 += adj43[(int)x0]; ix[j] = (int)x0; } } #endif static void CalcAllowedDist(CoderInfo *coderInfo, PsyInfo *psyInfo, double *xr, double *xmin, int quality) { int sfb, start, end, l; const double globalthr = 132.0 / (double)quality; int last = coderInfo->lastx; int lastsb = 0; int *cb_offset = coderInfo->sfb_offset; int num_cb = coderInfo->nr_of_sfb; double avgenrg = coderInfo->avgenrg; for (sfb = 0; sfb < num_cb; sfb++) { if (last > cb_offset[sfb]) lastsb = sfb; } for (sfb = 0; sfb < num_cb; sfb++) { double thr, tmp; double enrg = 0.0; start = cb_offset[sfb]; end = cb_offset[sfb + 1]; if (sfb > lastsb) { xmin[sfb] = 0; continue; } if (coderInfo->block_type != ONLY_SHORT_WINDOW) { double enmax = -1.0; double lmax; lmax = start; for (l = start; l < end; l++) { if (enmax < (xr[l] * xr[l])) { enmax = xr[l] * xr[l]; lmax = l; } } start = lmax - 2; end = lmax + 3; if (start < 0) start = 0; if (end > last) end = last; } for (l = start; l < end; l++) { enrg += xr[l]*xr[l]; } thr = enrg/((double)(end-start)*avgenrg); thr = pow(thr, 0.1*(lastsb-sfb)/lastsb + 0.3); tmp = 1.0 - ((double)start / (double)last); tmp = tmp * tmp * tmp + 0.075; thr = 1.0 / (1.4*thr + tmp); xmin[sfb] = ((coderInfo->block_type == ONLY_SHORT_WINDOW) ? 0.65 : 1.12) * globalthr * thr; } } static int FixNoise(CoderInfo *coderInfo, const double *xr, double *xr_pow, int *xi, double *xmin, double *pow43, double *adj43) { int i, sb; int start, end; double diffvol; double tmp; const double ifqstep = pow(2.0, 0.1875); const double log_ifqstep = 1.0 / log(ifqstep); const double maxstep = 0.05; for (sb = 0; sb < coderInfo->nr_of_sfb; sb++) { double sfacfix; double fixstep = 0.25; int sfac; double fac; int dist; double sfacfix0 = 1.0, dist0 = 1e50; double maxx; start = coderInfo->sfb_offset[sb]; end = coderInfo->sfb_offset[sb+1]; if (!xmin[sb]) goto nullsfb; maxx = 0.0; for (i = start; i < end; i++) { if (xr_pow[i] > maxx) maxx = xr_pow[i]; } //printf("band %d: maxx: %f\n", sb, maxx); if (maxx < 10.0) { nullsfb: for (i = start; i < end; i++) xi[i] = 0; coderInfo->scale_factor[sb] = 10; continue; } sfacfix = 1.0 / maxx; sfac = (int)(log(sfacfix) * log_ifqstep - 0.5); for (i = start; i < end; i++) xr_pow[i] *= sfacfix; maxx *= sfacfix; coderInfo->scale_factor[sb] = sfac; QuantizeBand(xr_pow, xi, IPOW20(coderInfo->global_gain), start, end, adj43); //printf("\tsfac: %d\n", sfac); calcdist: diffvol = 0.0; for (i = start; i < end; i++) { tmp = xi[i]; diffvol += tmp * tmp; // ~x^(3/2) } if (diffvol < 1e-6) diffvol = 1e-6; tmp = pow(diffvol / (double)(end - start), -0.666); if (fabs(fixstep) > maxstep) { double dd = 0.5*(tmp / xmin[sb] - 1.0); if (fabs(dd) < fabs(fixstep)) { fixstep = dd; if (fabs(fixstep) < maxstep) fixstep = maxstep * ((fixstep > 0) ? 1 : -1); } } if (fixstep > 0) { if (tmp < dist0) { dist0 = tmp; sfacfix0 = sfacfix; } else { if (fixstep > .1) fixstep = .1; } } else { dist0 = tmp; sfacfix0 = sfacfix; } dist = (tmp > xmin[sb]); fac = 0.0; if (fabs(fixstep) >= maxstep) { if ((dist && (fixstep < 0)) || (!dist && (fixstep > 0))) { fixstep = -0.5 * fixstep; } fac = 1.0 + fixstep; } else if (dist) { fac = 1.0 + fabs(fixstep); } if (fac != 0.0) { if (maxx * fac >= IXMAX_VAL) { // restore best noise fac = sfacfix0 / sfacfix; for (i = start; i < end; i++) xr_pow[i] *= fac; maxx *= fac; sfacfix *= fac; coderInfo->scale_factor[sb] = log(sfacfix) * log_ifqstep - 0.5; QuantizeBand(xr_pow, xi, IPOW20(coderInfo->global_gain), start, end, adj43); continue; } if (coderInfo->scale_factor[sb] < -10) { for (i = start; i < end; i++) xr_pow[i] *= fac; maxx *= fac; sfacfix *= fac; coderInfo->scale_factor[sb] = log(sfacfix) * log_ifqstep - 0.5; QuantizeBand(xr_pow, xi, IPOW20(coderInfo->global_gain), start, end, adj43); goto calcdist; } } } return 0; } int SortForGrouping(CoderInfo* coderInfo, PsyInfo *psyInfo, ChannelInfo *channelInfo, int *sfb_width_table, double *xr) { int i,j,ii; int index = 0; double xr_tmp[FRAME_LEN]; int group_offset=0; int k=0; int windowOffset = 0; /* set up local variables for used quantInfo elements */ int* sfb_offset = coderInfo->sfb_offset; int* nr_of_sfb = &(coderInfo->nr_of_sfb); int* window_group_length; int num_window_groups; *nr_of_sfb = coderInfo->max_sfb; /* Init to max_sfb */ window_group_length = coderInfo->window_group_length; num_window_groups = coderInfo->num_window_groups; /* calc org sfb_offset just for shortblock */ sfb_offset[k]=0; for (k=1 ; k <*nr_of_sfb+1; k++) { sfb_offset[k] = sfb_offset[k-1] + sfb_width_table[k-1]; } /* sort the input spectral coefficients */ index = 0; group_offset=0; for (i=0; i< num_window_groups; i++) { for (k=0; k<*nr_of_sfb; k++) { for (j=0; j < window_group_length[i]; j++) { for (ii=0;ii< sfb_width_table[k];ii++) xr_tmp[index++] = xr[ii+ sfb_offset[k] + BLOCK_LEN_SHORT*j +group_offset]; } } group_offset += BLOCK_LEN_SHORT*window_group_length[i]; } for (k=0; k<FRAME_LEN; k++){ xr[k] = xr_tmp[k]; } /* now calc the new sfb_offset table for the whole p_spectrum vector*/ index = 0; sfb_offset[index++] = 0; windowOffset = 0; for (i=0; i < num_window_groups; i++) { for (k=0 ; k <*nr_of_sfb; k++) { sfb_offset[index] = sfb_offset[index-1] + sfb_width_table[k]*window_group_length[i] ; index++; } windowOffset += window_group_length[i]; } *nr_of_sfb = *nr_of_sfb * num_window_groups; /* Number interleaved bands. */ return 0; } void CalcAvgEnrg(CoderInfo *coderInfo, const double *xr) { int end, l; int last = 0; double totenrg = 0.0; end = coderInfo->sfb_offset[coderInfo->nr_of_sfb]; for (l = 0; l < end; l++) { if (xr[l]) { last = l; totenrg += xr[l] * xr[l]; } } last++; coderInfo->lastx = last; coderInfo->avgenrg = totenrg / last; }