ref: 0feb3cab9fd2395f7de759c7dc36124a27269b9b
dir: /libfaac/filtbank.c/
/************************* MPEG-2 NBC Audio Decoder ************************** * * "This software module was originally developed by AT&T, Dolby Laboratories, Fraunhofer Gesellschaft IIS in the course of development of the MPEG-2 NBC/MPEG-4 Audio standard ISO/IEC 13818-7, 14496-1,2 and 3. This software module is an implementation of a part of one or more MPEG-2 NBC/MPEG-4 Audio tools as specified by the MPEG-2 NBC/MPEG-4 Audio standard. ISO/IEC gives users of the MPEG-2 NBC/MPEG-4 Audio standards free license to this software module or modifications thereof for use in hardware or software products claiming conformance to the MPEG-2 NBC/MPEG-4 Audio standards. Those intending to use this software module in hardware or software products are advised that this use may infringe existing patents. The original developer of this software module and his/her company, the subsequent editors and their companies, and ISO/IEC have no liability for use of this software module or modifications thereof in an implementation. Copyright is not released for non MPEG-2 NBC/MPEG-4 Audio conforming products.The original developer retains full right to use the code for his/her own purpose, assign or donate the code to a third party and to inhibit third party from using the code for non MPEG-2 NBC/MPEG-4 Audio conforming products. This copyright notice must be included in all copies or derivative works." Copyright(c)1996. * * ****************************************************************************/ /* * $Id: filtbank.c,v 1.10 2002/08/21 16:53:42 knik Exp $ */ /* * CHANGES: * 2001/01/17: menno: Added frequency cut off filter. * */ #include <math.h> #include <stdio.h> #include <stdlib.h> #include "coder.h" #include "filtbank.h" #include "frame.h" #include "fft.h" #include "util.h" #define TWOPI 2*M_PI void FilterBankInit(faacEncHandle hEncoder) { unsigned int i, channel; for (channel = 0; channel < hEncoder->numChannels; channel++) { hEncoder->freqBuff[channel] = (double*)AllocMemory(2*FRAME_LEN*sizeof(double)); hEncoder->overlapBuff[channel] = (double*)AllocMemory(FRAME_LEN*sizeof(double)); SetMemory(hEncoder->overlapBuff[channel], 0, FRAME_LEN*sizeof(double)); } hEncoder->sin_window_long = (double*)AllocMemory(BLOCK_LEN_LONG*sizeof(double)); hEncoder->sin_window_short = (double*)AllocMemory(BLOCK_LEN_SHORT*sizeof(double)); hEncoder->kbd_window_long = (double*)AllocMemory(BLOCK_LEN_LONG*sizeof(double)); hEncoder->kbd_window_short = (double*)AllocMemory(BLOCK_LEN_SHORT*sizeof(double)); for( i=0; i<BLOCK_LEN_LONG; i++ ) hEncoder->sin_window_long[i] = sin((M_PI/(2*BLOCK_LEN_LONG)) * (i + 0.5)); for( i=0; i<BLOCK_LEN_SHORT; i++ ) hEncoder->sin_window_short[i] = sin((M_PI/(2*BLOCK_LEN_SHORT)) * (i + 0.5)); CalculateKBDWindow(hEncoder->kbd_window_long, 4, BLOCK_LEN_LONG*2); CalculateKBDWindow(hEncoder->kbd_window_short, 6, BLOCK_LEN_SHORT*2); } void FilterBankEnd(faacEncHandle hEncoder) { unsigned int channel; for (channel = 0; channel < hEncoder->numChannels; channel++) { if (hEncoder->freqBuff[channel]) FreeMemory(hEncoder->freqBuff[channel]); if (hEncoder->overlapBuff[channel]) FreeMemory(hEncoder->overlapBuff[channel]); } if (hEncoder->sin_window_long) FreeMemory(hEncoder->sin_window_long); if (hEncoder->sin_window_short) FreeMemory(hEncoder->sin_window_short); if (hEncoder->kbd_window_long) FreeMemory(hEncoder->kbd_window_long); if (hEncoder->kbd_window_short) FreeMemory(hEncoder->kbd_window_short); } void FilterBank(faacEncHandle hEncoder, CoderInfo *coderInfo, double *p_in_data, double *p_out_mdct, double *p_overlap, int overlap_select) { double *p_o_buf, *first_window, *second_window; double *transf_buf; int k, i; int block_type = coderInfo->block_type; transf_buf = (double*)AllocMemory(2*BLOCK_LEN_LONG*sizeof(double)); /* create / shift old values */ /* We use p_overlap here as buffer holding the last frame time signal*/ if(overlap_select != MNON_OVERLAPPED) { memcpy(transf_buf, p_overlap, FRAME_LEN*sizeof(double)); memcpy(transf_buf+BLOCK_LEN_LONG, p_in_data, FRAME_LEN*sizeof(double)); memcpy(p_overlap, p_in_data, FRAME_LEN*sizeof(double)); } else { memcpy(transf_buf, p_in_data, 2*FRAME_LEN*sizeof(double)); } /* Window shape processing */ if(overlap_select != MNON_OVERLAPPED) { switch (coderInfo->prev_window_shape) { case SINE_WINDOW: if ( (block_type == ONLY_LONG_WINDOW) || (block_type == LONG_SHORT_WINDOW)) first_window = hEncoder->sin_window_long; else first_window = hEncoder->sin_window_short; break; case KBD_WINDOW: if ( (block_type == ONLY_LONG_WINDOW) || (block_type == LONG_SHORT_WINDOW)) first_window = hEncoder->kbd_window_long; else first_window = hEncoder->kbd_window_short; break; } switch (coderInfo->window_shape){ case SINE_WINDOW: if ( (block_type == ONLY_LONG_WINDOW) || (block_type == SHORT_LONG_WINDOW)) second_window = hEncoder->sin_window_long; else second_window = hEncoder->sin_window_short; break; case KBD_WINDOW: if ( (block_type == ONLY_LONG_WINDOW) || (block_type == SHORT_LONG_WINDOW)) second_window = hEncoder->kbd_window_long; else second_window = hEncoder->kbd_window_short; break; } } else { /* Always long block and sine window for LTP */ first_window = hEncoder->sin_window_long; second_window = hEncoder->sin_window_long; } /* Set ptr to transf-Buffer */ p_o_buf = transf_buf; /* Separate action for each Block Type */ switch (block_type) { case ONLY_LONG_WINDOW : for ( i = 0 ; i < BLOCK_LEN_LONG ; i++){ p_out_mdct[i] = p_o_buf[i] * first_window[i]; p_out_mdct[i+BLOCK_LEN_LONG] = p_o_buf[i+BLOCK_LEN_LONG] * second_window[BLOCK_LEN_LONG-i-1]; } MDCT( p_out_mdct, 2*BLOCK_LEN_LONG ); break; case LONG_SHORT_WINDOW : for ( i = 0 ; i < BLOCK_LEN_LONG ; i++) p_out_mdct[i] = p_o_buf[i] * first_window[i]; memcpy(p_out_mdct+BLOCK_LEN_LONG,p_o_buf+BLOCK_LEN_LONG,NFLAT_LS*sizeof(double)); for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++) p_out_mdct[i+BLOCK_LEN_LONG+NFLAT_LS] = p_o_buf[i+BLOCK_LEN_LONG+NFLAT_LS] * second_window[BLOCK_LEN_SHORT-i-1]; SetMemory(p_out_mdct+BLOCK_LEN_LONG+NFLAT_LS+BLOCK_LEN_SHORT,0,NFLAT_LS*sizeof(double)); MDCT( p_out_mdct, 2*BLOCK_LEN_LONG ); break; case SHORT_LONG_WINDOW : SetMemory(p_out_mdct,0,NFLAT_LS*sizeof(double)); for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++) p_out_mdct[i+NFLAT_LS] = p_o_buf[i+NFLAT_LS] * first_window[i]; memcpy(p_out_mdct+NFLAT_LS+BLOCK_LEN_SHORT,p_o_buf+NFLAT_LS+BLOCK_LEN_SHORT,NFLAT_LS*sizeof(double)); for ( i = 0 ; i < BLOCK_LEN_LONG ; i++) p_out_mdct[i+BLOCK_LEN_LONG] = p_o_buf[i+BLOCK_LEN_LONG] * second_window[BLOCK_LEN_LONG-i-1]; MDCT( p_out_mdct, 2*BLOCK_LEN_LONG ); break; case ONLY_SHORT_WINDOW : p_o_buf += NFLAT_LS; for ( k=0; k < MAX_SHORT_WINDOWS; k++ ) { for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++ ){ p_out_mdct[i] = p_o_buf[i] * first_window[i]; p_out_mdct[i+BLOCK_LEN_SHORT] = p_o_buf[i+BLOCK_LEN_SHORT] * second_window[BLOCK_LEN_SHORT-i-1]; } MDCT( p_out_mdct, 2*BLOCK_LEN_SHORT ); p_out_mdct += BLOCK_LEN_SHORT; p_o_buf += BLOCK_LEN_SHORT; first_window = second_window; } break; } if (transf_buf) FreeMemory(transf_buf); } void IFilterBank(faacEncHandle hEncoder, CoderInfo *coderInfo, double *p_in_data, double *p_out_data, double *p_overlap, int overlap_select) { double *o_buf, *transf_buf, *overlap_buf; double *first_window, *second_window; double *fp; int k, i; int block_type = coderInfo->block_type; transf_buf = (double*)AllocMemory(2*BLOCK_LEN_LONG*sizeof(double)); overlap_buf = (double*)AllocMemory(2*BLOCK_LEN_LONG*sizeof(double)); /* Window shape processing */ if (overlap_select != MNON_OVERLAPPED) { // switch (coderInfo->prev_window_shape){ // case SINE_WINDOW: if ( (block_type == ONLY_LONG_WINDOW) || (block_type == LONG_SHORT_WINDOW)) first_window = hEncoder->sin_window_long; else first_window = hEncoder->sin_window_short; // break; // case KBD_WINDOW: // if ( (block_type == ONLY_LONG_WINDOW) || (block_type == LONG_SHORT_WINDOW)) // first_window = hEncoder->kbd_window_long; // else // first_window = hEncoder->kbd_window_short; // break; // } // switch (coderInfo->window_shape){ // case SINE_WINDOW: if ( (block_type == ONLY_LONG_WINDOW) || (block_type == SHORT_LONG_WINDOW)) second_window = hEncoder->sin_window_long; else second_window = hEncoder->sin_window_short; // break; // case KBD_WINDOW: // if ( (block_type == ONLY_LONG_WINDOW) || (block_type == SHORT_LONG_WINDOW)) // second_window = hEncoder->kbd_window_long; // else // second_window = hEncoder->kbd_window_short; // break; // } } else { /* Always long block and sine window for LTP */ first_window = hEncoder->sin_window_long; second_window = hEncoder->sin_window_long; } /* Assemble overlap buffer */ memcpy(overlap_buf,p_overlap,BLOCK_LEN_LONG*sizeof(double)); o_buf = overlap_buf; /* Separate action for each Block Type */ switch( block_type ) { case ONLY_LONG_WINDOW : memcpy(transf_buf, p_in_data,BLOCK_LEN_LONG*sizeof(double)); IMDCT( transf_buf, 2*BLOCK_LEN_LONG ); for ( i = 0 ; i < BLOCK_LEN_LONG ; i++) transf_buf[i] *= first_window[i]; if (overlap_select != MNON_OVERLAPPED) { for ( i = 0 ; i < BLOCK_LEN_LONG; i++ ){ o_buf[i] += transf_buf[i]; o_buf[i+BLOCK_LEN_LONG] = transf_buf[i+BLOCK_LEN_LONG] * second_window[BLOCK_LEN_LONG-i-1]; } } else { /* overlap_select == NON_OVERLAPPED */ for ( i = 0 ; i < BLOCK_LEN_LONG; i++ ) transf_buf[i+BLOCK_LEN_LONG] *= second_window[BLOCK_LEN_LONG-i-1]; } break; case LONG_SHORT_WINDOW : memcpy(transf_buf, p_in_data,BLOCK_LEN_LONG*sizeof(double)); IMDCT( transf_buf, 2*BLOCK_LEN_LONG ); for ( i = 0 ; i < BLOCK_LEN_LONG ; i++) transf_buf[i] *= first_window[i]; if (overlap_select != MNON_OVERLAPPED) { for ( i = 0 ; i < BLOCK_LEN_LONG; i++ ) o_buf[i] += transf_buf[i]; memcpy(o_buf+BLOCK_LEN_LONG,transf_buf+BLOCK_LEN_LONG,NFLAT_LS*sizeof(double)); for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++) o_buf[i+BLOCK_LEN_LONG+NFLAT_LS] = transf_buf[i+BLOCK_LEN_LONG+NFLAT_LS] * second_window[BLOCK_LEN_SHORT-i-1]; SetMemory(o_buf+BLOCK_LEN_LONG+NFLAT_LS+BLOCK_LEN_SHORT,0,NFLAT_LS*sizeof(double)); } else { /* overlap_select == NON_OVERLAPPED */ for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++) transf_buf[i+BLOCK_LEN_LONG+NFLAT_LS] *= second_window[BLOCK_LEN_SHORT-i-1]; SetMemory(transf_buf+BLOCK_LEN_LONG+NFLAT_LS+BLOCK_LEN_SHORT,0,NFLAT_LS*sizeof(double)); } break; case SHORT_LONG_WINDOW : memcpy(transf_buf, p_in_data,BLOCK_LEN_LONG*sizeof(double)); IMDCT( transf_buf, 2*BLOCK_LEN_LONG ); for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++) transf_buf[i+NFLAT_LS] *= first_window[i]; if (overlap_select != MNON_OVERLAPPED) { for ( i = 0 ; i < BLOCK_LEN_SHORT; i++ ) o_buf[i+NFLAT_LS] += transf_buf[i+NFLAT_LS]; memcpy(o_buf+BLOCK_LEN_SHORT+NFLAT_LS,transf_buf+BLOCK_LEN_SHORT+NFLAT_LS,NFLAT_LS*sizeof(double)); for ( i = 0 ; i < BLOCK_LEN_LONG ; i++) o_buf[i+BLOCK_LEN_LONG] = transf_buf[i+BLOCK_LEN_LONG] * second_window[BLOCK_LEN_LONG-i-1]; } else { /* overlap_select == NON_OVERLAPPED */ SetMemory(transf_buf,0,NFLAT_LS*sizeof(double)); for ( i = 0 ; i < BLOCK_LEN_LONG ; i++) transf_buf[i+BLOCK_LEN_LONG] *= second_window[BLOCK_LEN_LONG-i-1]; } break; case ONLY_SHORT_WINDOW : if (overlap_select != MNON_OVERLAPPED) { fp = o_buf + NFLAT_LS; } else { /* overlap_select == NON_OVERLAPPED */ fp = transf_buf; } for ( k=0; k < MAX_SHORT_WINDOWS; k++ ) { memcpy(transf_buf,p_in_data,BLOCK_LEN_SHORT*sizeof(double)); IMDCT( transf_buf, 2*BLOCK_LEN_SHORT ); p_in_data += BLOCK_LEN_SHORT; if (overlap_select != MNON_OVERLAPPED) { for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++){ transf_buf[i] *= first_window[i]; fp[i] += transf_buf[i]; fp[i+BLOCK_LEN_SHORT] = transf_buf[i+BLOCK_LEN_SHORT] * second_window[BLOCK_LEN_SHORT-i-1]; } fp += BLOCK_LEN_SHORT; } else { /* overlap_select == NON_OVERLAPPED */ for ( i = 0 ; i < BLOCK_LEN_SHORT ; i++){ fp[i] *= first_window[i]; fp[i+BLOCK_LEN_SHORT] *= second_window[BLOCK_LEN_SHORT-i-1]; } fp += 2*BLOCK_LEN_SHORT; } first_window = second_window; } SetMemory(o_buf+BLOCK_LEN_LONG+NFLAT_LS+BLOCK_LEN_SHORT,0,NFLAT_LS*sizeof(double)); break; } if (overlap_select != MNON_OVERLAPPED) memcpy(p_out_data,o_buf,BLOCK_LEN_LONG*sizeof(double)); else /* overlap_select == NON_OVERLAPPED */ memcpy(p_out_data,transf_buf,2*BLOCK_LEN_LONG*sizeof(double)); /* save unused output data */ memcpy(p_overlap,o_buf+BLOCK_LEN_LONG,BLOCK_LEN_LONG*sizeof(double)); if (overlap_buf) FreeMemory(overlap_buf); if (transf_buf) FreeMemory(transf_buf); } void specFilter(double *freqBuff, int sampleRate, int lowpassFreq, int specLen ) { int lowpass,xlowpass; /* calculate the last line which is not zero */ lowpass = (lowpassFreq * specLen) / (sampleRate>>1) + 1; xlowpass = (lowpass < specLen) ? lowpass : specLen ; SetMemory(freqBuff+xlowpass,0,(specLen-xlowpass)*sizeof(double)); } static double Izero(double x) { const double IzeroEPSILON = 1E-41; /* Max error acceptable in Izero */ double sum, u, halfx, temp; int n; sum = u = n = 1; halfx = x/2.0; do { temp = halfx/(double)n; n += 1; temp *= temp; u *= temp; sum += u; } while (u >= IzeroEPSILON*sum); return(sum); } static void CalculateKBDWindow(double* win, double alpha, int length) { int i; double IBeta; double tmp; double sum = 0.0; alpha *= M_PI; IBeta = 1.0/Izero(alpha); /* calculate lower half of Kaiser Bessel window */ for(i=0; i<(length>>1); i++) { tmp = 4.0*(double)i/(double)length - 1.0; win[i] = Izero(alpha*sqrt(1.0-tmp*tmp))*IBeta; sum += win[i]; } sum = 1.0/sum; tmp = 0.0; /* calculate lower half of window */ for(i=0; i<(length>>1); i++) { tmp += win[i]; win[i] = sqrt(tmp*sum); } } static void MDCT(double *data, int N) { double *xi, *xr; double tempr, tempi, c, s, cold, cfreq, sfreq; /* temps for pre and post twiddle */ double freq = TWOPI / N; double cosfreq8, sinfreq8; int i, n; xi = (double*)AllocMemory((N >> 2)*sizeof(double)); xr = (double*)AllocMemory((N >> 2)*sizeof(double)); /* prepare for recurrence relation in pre-twiddle */ cfreq = cos (freq); sfreq = sin (freq); cosfreq8 = cos (freq * 0.125); sinfreq8 = sin (freq * 0.125); c = cosfreq8; s = sinfreq8; for (i = 0; i < (N >> 2); i++) { /* calculate real and imaginary parts of g(n) or G(p) */ n = (N >> 1) - 1 - 2 * i; if (i < (N >> 3)) tempr = data [(N >> 2) + n] + data [N + (N >> 2) - 1 - n]; /* use second form of e(n) for n = N / 2 - 1 - 2i */ else tempr = data [(N >> 2) + n] - data [(N >> 2) - 1 - n]; /* use first form of e(n) for n = N / 2 - 1 - 2i */ n = 2 * i; if (i < (N >> 3)) tempi = data [(N >> 2) + n] - data [(N >> 2) - 1 - n]; /* use first form of e(n) for n=2i */ else tempi = data [(N >> 2) + n] + data [N + (N >> 2) - 1 - n]; /* use second form of e(n) for n=2i*/ /* calculate pre-twiddled FFT input */ xr[i] = tempr * c + tempi * s; xi[i] = tempi * c - tempr * s; /* use recurrence to prepare cosine and sine for next value of i */ cold = c; c = c * cfreq - s * sfreq; s = s * cfreq + cold * sfreq; } /* Perform in-place complex FFT of length N/4 */ switch (N) { case 256: fft(xr, xi, 6); break; case 2048: fft(xr, xi, 9); } /* prepare for recurrence relations in post-twiddle */ c = cosfreq8; s = sinfreq8; /* post-twiddle FFT output and then get output data */ for (i = 0; i < (N >> 2); i++) { /* get post-twiddled FFT output */ tempr = 2. * (xr[i] * c + xi[i] * s); tempi = 2. * (xi[i] * c - xr[i] * s); /* fill in output values */ data [2 * i] = -tempr; /* first half even */ data [(N >> 1) - 1 - 2 * i] = tempi; /* first half odd */ data [(N >> 1) + 2 * i] = -tempi; /* second half even */ data [N - 1 - 2 * i] = tempr; /* second half odd */ /* use recurrence to prepare cosine and sine for next value of i */ cold = c; c = c * cfreq - s * sfreq; s = s * cfreq + cold * sfreq; } if (xr) FreeMemory(xr); if (xi) FreeMemory(xi); } static void IMDCT(double *data, int N) { double *xi, *xr; double tempr, tempi, c, s, cold, cfreq, sfreq; /* temps for pre and post twiddle */ double freq = 2.0 * M_PI / N; double fac, cosfreq8, sinfreq8; int i; xi = (double*)AllocMemory((N >> 2)*sizeof(double)); xr = (double*)AllocMemory((N >> 2)*sizeof(double)); /* Choosing to allocate 2/N factor to Inverse Xform! */ fac = 2. / N; /* remaining 2/N from 4/N IFFT factor */ /* prepare for recurrence relation in pre-twiddle */ cfreq = cos (freq); sfreq = sin (freq); cosfreq8 = cos (freq * 0.125); sinfreq8 = sin (freq * 0.125); c = cosfreq8; s = sinfreq8; for (i = 0; i < (N >> 2); i++) { /* calculate real and imaginary parts of g(n) or G(p) */ tempr = -data[2 * i]; tempi = data[(N >> 1) - 1 - 2 * i]; /* calculate pre-twiddled FFT input */ xr[i] = tempr * c - tempi * s; xi[i] = tempi * c + tempr * s; /* use recurrence to prepare cosine and sine for next value of i */ cold = c; c = c * cfreq - s * sfreq; s = s * cfreq + cold * sfreq; } /* Perform in-place complex IFFT of length N/4 */ switch (N) { case 256: ffti(xr, xi, 6); break; case 2048: ffti(xr, xi, 9); } /* prepare for recurrence relations in post-twiddle */ c = cosfreq8; s = sinfreq8; /* post-twiddle FFT output and then get output data */ for (i = 0; i < (N >> 2); i++) { /* get post-twiddled FFT output */ tempr = fac * (xr[i] * c - xi[i] * s); tempi = fac * (xi[i] * c + xr[i] * s); /* fill in output values */ data [(N >> 1) + (N >> 2) - 1 - 2 * i] = tempr; if (i < (N >> 3)) data [(N >> 1) + (N >> 2) + 2 * i] = tempr; else data [2 * i - (N >> 2)] = -tempr; data [(N >> 2) + 2 * i] = tempi; if (i < (N >> 3)) data [(N >> 2) - 1 - 2 * i] = -tempi; else data [(N >> 2) + N - 1 - 2*i] = tempi; /* use recurrence to prepare cosine and sine for next value of i */ cold = c; c = c * cfreq - s * sfreq; s = s * cfreq + cold * sfreq; } if (xr) FreeMemory(xr); if (xi) FreeMemory(xi); }