ref: 2602c130a189a32170d56580bb1bd2ae53fe29f0
dir: /libfaac/psychkni.c/
/* * FAAC - Freeware Advanced Audio Coder * Copyright (C) 2002 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: psychkni.c,v 1.18 2009/06/05 16:32:15 menno Exp $ */ #include <stdio.h> #include <stdlib.h> #include <math.h> #include "psych.h" #include "coder.h" #include "fft.h" #include "util.h" #include "frame.h" typedef float psyfloat; typedef struct { /* bandwidth */ int bandS; int lastband; /* SFB energy */ psyfloat *fftEnrgS[8]; psyfloat *fftEnrgNextS[8]; psyfloat *fftEnrgNext2S[8]; psyfloat *fftEnrgPrevS[8]; } psydata_t; static void Hann(GlobalPsyInfo * gpsyInfo, double *inSamples, int size) { int i; /* Applying Hann window */ if (size == BLOCK_LEN_LONG * 2) { for (i = 0; i < size; i++) inSamples[i] *= gpsyInfo->hannWindow[i]; } else { for (i = 0; i < size; i++) inSamples[i] *= gpsyInfo->hannWindowS[i]; } } static void PsyCheckShort(PsyInfo * psyInfo) { double totvol = 0.0; double totchg, totchg2; psydata_t *psydata = psyInfo->data; int lastband = psydata->lastband; int firstband = 1; int sfb; /* long/short block switch */ totchg = totchg2 = 0.0; for (sfb = 0; sfb < lastband; sfb++) { int win; double volb[16]; double vavg[13]; double maxdif = 0.0; double totmaxdif = 0.0; double e, v; // previous frame for (win = 0; win < 4; win++) { e = psydata->fftEnrgPrevS[win + 4][sfb]; volb[win] = sqrt(e); totvol += e; } // current frame for (win = 0; win < 8; win++) { e = psydata->fftEnrgS[win][sfb]; volb[win + 4] = sqrt(e); totvol += e; } // next frame for (win = 0; win < 4; win++) { e = psydata->fftEnrgNextS[win][sfb]; volb[win + 12] = sqrt(e); totvol += e; } // ignore lowest SFBs if (sfb < firstband) continue; v = 0.0; for (win = 0; win < 4; win++) { v += volb[win]; } vavg[0] = 0.25 * v; for (win = 1; win < 13; win++) { v -= volb[win - 1]; v += volb[win + 3]; vavg[win] = 0.25 * v; } for (win = 0; win < 8; win++) { int i; double mina, maxv; double voldif; double totvoldif; mina = vavg[win]; for (i = 1; i < 5; i++) mina = min(mina, vavg[win + i]); maxv = volb[win + 2]; for (i = 3; i < 6; i++) maxv = max(maxv, volb[win + i]); if (!maxv || !mina) continue; voldif = (maxv - mina) / mina; totvoldif = (maxv - mina) * (maxv - mina); if (voldif > maxdif) maxdif = voldif; if (totvoldif > totmaxdif) totmaxdif = totvoldif; } totchg += maxdif; totchg2 += totmaxdif; } totvol = sqrt(totvol); totchg2 = sqrt(totchg2); totchg = totchg / lastband; if (totvol) totchg2 /= totvol; else totchg2 = 0.0; psyInfo->block_type = ((totchg > 1.0) && (totchg2 > 0.04)) ? ONLY_SHORT_WINDOW : ONLY_LONG_WINDOW; #if 0 { static int total = 0, shorts = 0; char *flash = " "; total++; if (psyInfo->block_type == ONLY_SHORT_WINDOW) { flash = "****"; shorts++; } printf("totchg: %s %g %g\t%g\n", flash, totchg, totchg2, (double)shorts/total); } #endif } static void PsyInit(GlobalPsyInfo * gpsyInfo, PsyInfo * psyInfo, unsigned int numChannels, unsigned int sampleRate, int *cb_width_long, int num_cb_long, int *cb_width_short, int num_cb_short) { unsigned int channel; int i, j, size; gpsyInfo->hannWindow = (double *) AllocMemory(2 * BLOCK_LEN_LONG * sizeof(double)); gpsyInfo->hannWindowS = (double *) AllocMemory(2 * BLOCK_LEN_SHORT * sizeof(double)); for (i = 0; i < BLOCK_LEN_LONG * 2; i++) gpsyInfo->hannWindow[i] = 0.5 * (1 - cos(2.0 * M_PI * (i + 0.5) / (BLOCK_LEN_LONG * 2))); for (i = 0; i < BLOCK_LEN_SHORT * 2; i++) gpsyInfo->hannWindowS[i] = 0.5 * (1 - cos(2.0 * M_PI * (i + 0.5) / (BLOCK_LEN_SHORT * 2))); gpsyInfo->sampleRate = (double) sampleRate; for (channel = 0; channel < numChannels; channel++) { psydata_t *psydata = AllocMemory(sizeof(psydata_t)); psyInfo[channel].data = psydata; } size = BLOCK_LEN_LONG; for (channel = 0; channel < numChannels; channel++) { psyInfo[channel].size = size; psyInfo[channel].prevSamples = (double *) AllocMemory(size * sizeof(double)); memset(psyInfo[channel].prevSamples, 0, size * sizeof(double)); } size = BLOCK_LEN_SHORT; for (channel = 0; channel < numChannels; channel++) { psydata_t *psydata = psyInfo[channel].data; psyInfo[channel].sizeS = size; for (j = 0; j < 8; j++) { psydata->fftEnrgPrevS[j] = (psyfloat *) AllocMemory(NSFB_SHORT * sizeof(psyfloat)); memset(psydata->fftEnrgPrevS[j], 0, NSFB_SHORT * sizeof(psyfloat)); psydata->fftEnrgS[j] = (psyfloat *) AllocMemory(NSFB_SHORT * sizeof(psyfloat)); memset(psydata->fftEnrgS[j], 0, NSFB_SHORT * sizeof(psyfloat)); psydata->fftEnrgNextS[j] = (psyfloat *) AllocMemory(NSFB_SHORT * sizeof(psyfloat)); memset(psydata->fftEnrgNextS[j], 0, NSFB_SHORT * sizeof(psyfloat)); psydata->fftEnrgNext2S[j] = (psyfloat *) AllocMemory(NSFB_SHORT * sizeof(psyfloat)); memset(psydata->fftEnrgNext2S[j], 0, NSFB_SHORT * sizeof(psyfloat)); } } } static void PsyEnd(GlobalPsyInfo * gpsyInfo, PsyInfo * psyInfo, unsigned int numChannels) { unsigned int channel; int j; if (gpsyInfo->hannWindow) FreeMemory(gpsyInfo->hannWindow); if (gpsyInfo->hannWindowS) FreeMemory(gpsyInfo->hannWindowS); for (channel = 0; channel < numChannels; channel++) { if (psyInfo[channel].prevSamples) FreeMemory(psyInfo[channel].prevSamples); } for (channel = 0; channel < numChannels; channel++) { psydata_t *psydata = psyInfo[channel].data; for (j = 0; j < 8; j++) { if (psydata->fftEnrgPrevS[j]) FreeMemory(psydata->fftEnrgPrevS[j]); if (psydata->fftEnrgS[j]) FreeMemory(psydata->fftEnrgS[j]); if (psydata->fftEnrgNextS[j]) FreeMemory(psydata->fftEnrgNextS[j]); if (psydata->fftEnrgNext2S[j]) FreeMemory(psydata->fftEnrgNext2S[j]); } } for (channel = 0; channel < numChannels; channel++) { if (psyInfo[channel].data) FreeMemory(psyInfo[channel].data); } } /* Do psychoacoustical analysis */ static void PsyCalculate(ChannelInfo * channelInfo, GlobalPsyInfo * gpsyInfo, PsyInfo * psyInfo, int *cb_width_long, int num_cb_long, int *cb_width_short, int num_cb_short, unsigned int numChannels) { unsigned int channel; for (channel = 0; channel < numChannels; channel++) { if (channelInfo[channel].present) { if (channelInfo[channel].cpe && channelInfo[channel].ch_is_left) { /* CPE */ int leftChan = channel; int rightChan = channelInfo[channel].paired_ch; PsyCheckShort(&psyInfo[leftChan]); PsyCheckShort(&psyInfo[rightChan]); } else if (!channelInfo[channel].cpe && channelInfo[channel].lfe) { /* LFE */ // Only set block type and it should be OK psyInfo[channel].block_type = ONLY_LONG_WINDOW; } else if (!channelInfo[channel].cpe) { /* SCE */ PsyCheckShort(&psyInfo[channel]); } } } } static void PsyBufferUpdate( FFT_Tables *fft_tables, GlobalPsyInfo * gpsyInfo, PsyInfo * psyInfo, double *newSamples, unsigned int bandwidth, int *cb_width_short, int num_cb_short) { int win; double transBuff[2 * BLOCK_LEN_LONG]; double transBuffS[2 * BLOCK_LEN_SHORT]; psydata_t *psydata = psyInfo->data; psyfloat *tmp; int sfb; psydata->bandS = psyInfo->sizeS * bandwidth * 2 / gpsyInfo->sampleRate; memcpy(transBuff, psyInfo->prevSamples, psyInfo->size * sizeof(double)); memcpy(transBuff + psyInfo->size, newSamples, psyInfo->size * sizeof(double)); for (win = 0; win < 8; win++) { int first = 0; int last = 0; memcpy(transBuffS, transBuff + (win * BLOCK_LEN_SHORT) + (BLOCK_LEN_LONG - BLOCK_LEN_SHORT) / 2, 2 * psyInfo->sizeS * sizeof(double)); Hann(gpsyInfo, transBuffS, 2 * psyInfo->sizeS); rfft( fft_tables, transBuffS, 8); // shift bufs tmp = psydata->fftEnrgPrevS[win]; psydata->fftEnrgPrevS[win] = psydata->fftEnrgS[win]; psydata->fftEnrgS[win] = psydata->fftEnrgNextS[win]; psydata->fftEnrgNextS[win] = psydata->fftEnrgNext2S[win]; psydata->fftEnrgNext2S[win] = tmp; for (sfb = 0; sfb < num_cb_short; sfb++) { double e; int l; first = last; last = first + cb_width_short[sfb]; if (first < 1) first = 1; //if (last > psydata->bandS) // band out of range if (first >= psydata->bandS) // band out of range break; e = 0.0; for (l = first; l < last; l++) { double a = transBuffS[l]; double b = transBuffS[l + psyInfo->sizeS]; e += a * a + b * b; } psydata->fftEnrgNext2S[win][sfb] = e; } psydata->lastband = sfb; for (; sfb < num_cb_short; sfb++) { psydata->fftEnrgNext2S[win][sfb] = 0; } } memcpy(psyInfo->prevSamples, newSamples, psyInfo->size * sizeof(double)); } static void BlockSwitch(CoderInfo * coderInfo, PsyInfo * psyInfo, unsigned int numChannels) { unsigned int channel; int desire = ONLY_LONG_WINDOW; /* Use the same block type for all channels If there is 1 channel that wants a short block, use a short block on all channels. */ for (channel = 0; channel < numChannels; channel++) { if (psyInfo[channel].block_type == ONLY_SHORT_WINDOW) desire = ONLY_SHORT_WINDOW; } for (channel = 0; channel < numChannels; channel++) { int lasttype = coderInfo[channel].block_type; if (desire == ONLY_SHORT_WINDOW || coderInfo[channel].desired_block_type == ONLY_SHORT_WINDOW) { if (lasttype == ONLY_LONG_WINDOW || lasttype == SHORT_LONG_WINDOW) coderInfo[channel].block_type = LONG_SHORT_WINDOW; else coderInfo[channel].block_type = ONLY_SHORT_WINDOW; } else { if (lasttype == ONLY_SHORT_WINDOW || lasttype == LONG_SHORT_WINDOW) coderInfo[channel].block_type = SHORT_LONG_WINDOW; else coderInfo[channel].block_type = ONLY_LONG_WINDOW; } coderInfo[channel].desired_block_type = desire; } } psymodel_t psymodel2 = { PsyInit, PsyEnd, PsyCalculate, PsyBufferUpdate, BlockSwitch };