forked from KolibriOS/kolibrios
3eda462807
Programs: fasm updated to 1.67.14, small fixes in desktop, stackcfg, calc, board, pipes, freecell, big cleanup of unused programs, added some applications from 0.6.3.0 distr... git-svn-id: svn://kolibrios.org@205 a494cfbc-eb01-0410-851d-a64ba20cac60
351 lines
10 KiB
C
351 lines
10 KiB
C
#include "layer3.h"
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#include <string.h>
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#include <math.h>
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#ifndef min
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#define max(a,b) (((a) > (b)) ? (a) : (b))
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#define min(a,b) (((a) < (b)) ? (a) : (b))
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#endif
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extern int m_frame_size, m_pcm_size;
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// shared
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SAMPLE m_sample[2][2][576];//- sample union of int/float sample[ch][gr][576]
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int m_nsb_limit;
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SBT_PROC m_sbt_proc;
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XFORM_PROC m_xform_proc;
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int m_channels; //(mode == 3) ? 1 : 2
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int m_ms_mode, m_is_mode;
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int m_sfBandIndex[2][22];// [long/short][cb]
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int m_nBand[2][22];
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int m_band_limit;
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int m_band_limit21; // limit for sf band 21
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int m_band_limit12; // limit for sf band 12 short
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int m_band_limit_nsb;
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int m_ncbl_mixed;
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SIDE_INFO m_side_info;
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SCALE_FACTOR m_scale_fac[2][2]; // [gr][ch]
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CB_INFO m_cb_info[2][2]; // [gr][ch]
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IS_SF_INFO m_is_sf_info;
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#define NBUF (8*1024)
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#define BUF_TRIGGER (NBUF-1500)
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int m_gr;
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int m_main_pos_bit;
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byte m_buf[NBUF];
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int m_buf_ptr0, m_buf_ptr1;
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int m_nsamp[2][2]; // must start = 0, for m_nsamp[igr_prev]
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float m_yout[576]; // hybrid out, sbt in
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//extern "l3side.c"
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int L3get_side_info1();
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int L3get_side_info2(int gr);
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//extern "l3sf.c"
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void L3get_scale_factor1(int gr, int ch);
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void L3get_scale_factor2(int gr, int ch);
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void huffman(void *xy, int n, int ntable);
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int huffman_quad(void *vwxy, int n, int nbits, int ntable);
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void dequant(SAMPLE sample[], int gr, int ch);
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void antialias(void *x, int n);
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void ms_process(void *x, int n);
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void is_process1(void *x, SCALE_FACTOR* sf,
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CB_INFO cb_info[2], int nsamp);
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void is_process2(void *x, SCALE_FACTOR * sf,
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CB_INFO cb_info[2], int nsamp);
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//extern "l3hybrid.c"
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int hybrid(void *xin, void *xprev, float *y,
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int btype, int nlong, int ntot, int nprev);
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int hybrid_sum(void *xin, void *xin_left, float *y,
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int btype, int nlong, int ntot);
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void sum_f_bands(void *a, void *b, int n);
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void freq_invert(float *y, int n); /* xform, */
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void L3decode_main(MPEG_HEADER* h, byte *pcm, int gr);
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void L3decode_reset()
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{
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m_buf_ptr0 = m_buf_ptr1 = 0;
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}
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void L3decode_frame(MPEG_HEADER* h, byte* mpeg, byte* pcm)
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{
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int crc_size, side_size;
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int copy_size;
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if (h->mode == 1) {
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m_ms_mode = h->mode_ext >> 1;
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m_is_mode = h->mode_ext & 1;
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}
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else {
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m_ms_mode = 0;
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m_is_mode = 0;
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}
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crc_size = (h->error_prot) ? 2 : 0;
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bitget_init(mpeg + 4 + crc_size);
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if (h->version == 1)
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side_size = L3get_side_info1();
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else
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side_size = L3get_side_info2(m_gr);
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m_buf_ptr0 = m_buf_ptr1 - m_side_info.main_data_begin;/* decode start point */
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if (m_buf_ptr1 > BUF_TRIGGER) { /* shift buffer */
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memmove(m_buf, m_buf + m_buf_ptr0, m_side_info.main_data_begin);
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m_buf_ptr0 = 0;
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m_buf_ptr1 = m_side_info.main_data_begin;
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}
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copy_size = m_frame_size - (4 + crc_size + side_size);
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//24/02/02 X-MaD
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if (copy_size < 0) { copy_size = copy_size * -1; }
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//if (copy_size < 0) { copy_size = 0; }
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//__try {
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memmove(m_buf + m_buf_ptr1, mpeg + (4 + crc_size + side_size), copy_size);
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//} __except(0){
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// m_buf_ptr1 = 0;
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//}
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m_buf_ptr1 += copy_size;
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//24/02/02 X-MaD
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if (m_buf_ptr0 >= 0) {
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m_main_pos_bit = m_buf_ptr0 << 3;
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if (h->version == 1) {
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L3decode_main(h, pcm, 0);
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L3decode_main(h, pcm + (m_pcm_size / 2), 1);
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}
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else {
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L3decode_main(h, pcm, m_gr);
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m_gr = m_gr ^ 1;
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}
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}
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}
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void L3decode_main(MPEG_HEADER* h, byte *pcm, int gr)
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{
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int ch;
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int n1, n2, n3, n4, nn2, nn3, nn4;
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int bit0, qbits, m0;
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for (ch = 0; ch < m_channels; ch ++) {
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bitget_init(m_buf + (m_main_pos_bit >> 3));
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bit0 = (m_main_pos_bit & 7);
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if (bit0) bitget(bit0);
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m_main_pos_bit += m_side_info.gr[gr][ch].part2_3_length;
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bitget_init_end(m_buf + ((m_main_pos_bit + 39) >> 3));
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// scale factors
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if (h->version == 1)
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L3get_scale_factor1(gr, ch);
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else
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L3get_scale_factor2(gr, ch);
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// huff data
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n1 = m_sfBandIndex[0][m_side_info.gr[gr][ch].region0_count];
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n2 = m_sfBandIndex[0][m_side_info.gr[gr][ch].region0_count
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+ m_side_info.gr[gr][ch].region1_count + 1];
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n3 = m_side_info.gr[gr][ch].big_values;
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n3 = n3 + n3;
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if (n3 > m_band_limit) n3 = m_band_limit;
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if (n2 > n3) n2 = n3;
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if (n1 > n3) n1 = n3;
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nn3 = n3 - n2;
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nn2 = n2 - n1;
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huffman(m_sample[ch][gr], n1, m_side_info.gr[gr][ch].table_select[0]);
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huffman(m_sample[ch][gr] + n1, nn2, m_side_info.gr[gr][ch].table_select[1]);
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huffman(m_sample[ch][gr] + n2, nn3, m_side_info.gr[gr][ch].table_select[2]);
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qbits = m_side_info.gr[gr][ch].part2_3_length - (bitget_bits_used() - bit0);
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nn4 = huffman_quad(m_sample[ch][gr] + n3, m_band_limit - n3, qbits,
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m_side_info.gr[gr][ch].count1table_select);
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n4 = n3 + nn4;
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m_nsamp[gr][ch] = n4;
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// limit n4 or allow deqaunt to sf band 22
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if (m_side_info.gr[gr][ch].block_type == 2)
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n4 = min(n4, m_band_limit12);
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else
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n4 = min(n4, m_band_limit21);
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if (n4 < 576)
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memset(m_sample[ch][gr] + n4, 0, sizeof(SAMPLE) * (576 - n4));
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if (bitget_overrun())
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memset(m_sample[ch][gr], 0, sizeof(SAMPLE) * (576));
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}
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// dequant
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for (ch = 0; ch < m_channels; ch++) {
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dequant(m_sample[ch][gr], gr, ch);
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}
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// ms stereo processing
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if (m_ms_mode) {
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if (m_is_mode == 0) {
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m0 = m_nsamp[gr][0]; // process to longer of left/right
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if (m0 < m_nsamp[gr][1])
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m0 = m_nsamp[gr][1];
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}
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else {// process to last cb in right
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m0 = m_sfBandIndex[m_cb_info[gr][1].cbtype][m_cb_info[gr][1].cbmax];
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}
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ms_process(m_sample[0][gr], m0);
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}
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// is stereo processing
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if (m_is_mode) {
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if (h->version == 1)
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is_process1(m_sample[0][gr], &m_scale_fac[gr][1],
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m_cb_info[gr], m_nsamp[gr][0]);
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else
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is_process2(m_sample[0][gr], &m_scale_fac[gr][1],
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m_cb_info[gr], m_nsamp[gr][0]);
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}
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// adjust ms and is modes to max of left/right
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if (m_ms_mode || m_is_mode) {
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if (m_nsamp[gr][0] < m_nsamp[gr][1])
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m_nsamp[gr][0] = m_nsamp[gr][1];
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else
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m_nsamp[gr][1] = m_nsamp[gr][0];
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}
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// antialias
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for (ch = 0; ch < m_channels; ch ++) {
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if (m_cb_info[gr][ch].ncbl == 0)
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continue; // have no long blocks
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if (m_side_info.gr[gr][ch].mixed_block_flag)
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n1 = 1; // 1 -> 36 samples
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else
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n1 = (m_nsamp[gr][ch] + 7) / 18;
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if (n1 > 31)
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n1 = 31;
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antialias(m_sample[ch][gr], n1);
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n1 = 18 * n1 + 8; // update number of samples
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if (n1 > m_nsamp[gr][ch])
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m_nsamp[gr][ch] = n1;
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}
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// hybrid + sbt
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m_xform_proc(pcm, gr);
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}
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void xform_mono(void *pcm, int igr)
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{
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int igr_prev, n1, n2;
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// hybrid + sbt
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n1 = n2 = m_nsamp[igr][0]; // total number bands
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if (m_side_info.gr[igr][0].block_type == 2) { // long bands
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if (m_side_info.gr[igr][0].mixed_block_flag)
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n1 = m_sfBandIndex[0][m_ncbl_mixed - 1];
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else
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n1 = 0;
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}
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if (n1 > m_band_limit)
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n1 = m_band_limit;
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if (n2 > m_band_limit)
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n2 = m_band_limit;
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igr_prev = igr ^ 1;
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m_nsamp[igr][0] = hybrid(m_sample[0][igr], m_sample[0][igr_prev],
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m_yout, m_side_info.gr[igr][0].block_type, n1, n2, m_nsamp[igr_prev][0]);
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freq_invert(m_yout, m_nsamp[igr][0]);
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m_sbt_proc(m_yout, pcm, 0);
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}
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void xform_dual_right(void *pcm, int igr)
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{
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int igr_prev, n1, n2;
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// hybrid + sbt
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n1 = n2 = m_nsamp[igr][1]; // total number bands
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if (m_side_info.gr[igr][1].block_type == 2) { // long bands
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if (m_side_info.gr[igr][1].mixed_block_flag)
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n1 = m_sfBandIndex[0][m_ncbl_mixed - 1];
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else
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n1 = 0;
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}
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if (n1 > m_band_limit)
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n1 = m_band_limit;
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if (n2 > m_band_limit)
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n2 = m_band_limit;
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igr_prev = igr ^ 1;
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m_nsamp[igr][1] = hybrid(m_sample[1][igr], m_sample[1][igr_prev],
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m_yout, m_side_info.gr[igr][1].block_type, n1, n2, m_nsamp[igr_prev][1]);
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freq_invert(m_yout, m_nsamp[igr][1]);
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m_sbt_proc(m_yout, pcm, 0);
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}
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void xform_dual(void *pcm, int igr)
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{
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int ch;
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int igr_prev, n1, n2;
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// hybrid + sbt
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igr_prev = igr ^ 1;
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for (ch = 0; ch < m_channels; ch++) {
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n1 = n2 = m_nsamp[igr][ch]; // total number bands
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if (m_side_info.gr[igr][ch].block_type == 2) { // long bands
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if (m_side_info.gr[igr][ch].mixed_block_flag)
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n1 = m_sfBandIndex[0][m_ncbl_mixed - 1];
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else
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n1 = 0;
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}
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if (n1 > m_band_limit)
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n1 = m_band_limit;
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if (n2 > m_band_limit)
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n2 = m_band_limit;
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m_nsamp[igr][ch] = hybrid(m_sample[ch][igr], m_sample[ch][igr_prev],
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m_yout, m_side_info.gr[igr][ch].block_type, n1, n2, m_nsamp[igr_prev][ch]);
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freq_invert(m_yout, m_nsamp[igr][ch]);
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m_sbt_proc(m_yout, pcm, ch);
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}
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}
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void xform_dual_mono(void *pcm, int igr)
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{
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int igr_prev, n1, n2, n3;
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// hybrid + sbt
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igr_prev = igr ^ 1;
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if ((m_side_info.gr[igr][0].block_type == m_side_info.gr[igr][1].block_type)
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&& (m_side_info.gr[igr][0].mixed_block_flag == 0)
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&& (m_side_info.gr[igr][1].mixed_block_flag == 0)) {
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n2 = m_nsamp[igr][0]; // total number bands max of L R
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if (n2 < m_nsamp[igr][1])
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n2 = m_nsamp[igr][1];
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if (n2 > m_band_limit)
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n2 = m_band_limit;
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if (m_side_info.gr[igr][0].block_type == 2)
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n1 = 0;
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else
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n1 = n2; // n1 = number long bands
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sum_f_bands(m_sample[0][igr], m_sample[1][igr], n2);
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n3 = m_nsamp[igr][0] = hybrid(m_sample[0][igr], m_sample[0][igr_prev],
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m_yout, m_side_info.gr[igr][0].block_type, n1, n2, m_nsamp[igr_prev][0]);
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}
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else { // transform and then sum (not tested - never happens in test)
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// left chan
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n1 = n2 = m_nsamp[igr][0]; // total number bands
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if (m_side_info.gr[igr][0].block_type == 2) { // long bands
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if (m_side_info.gr[igr][0].mixed_block_flag)
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n1 = m_sfBandIndex[0][m_ncbl_mixed - 1];
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else
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n1 = 0;
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}
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n3 = m_nsamp[igr][0] = hybrid(m_sample[0][igr], m_sample[0][igr_prev],
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m_yout, m_side_info.gr[igr][0].block_type, n1, n2, m_nsamp[igr_prev][0]);
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// right chan
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n1 = n2 = m_nsamp[igr][1]; // total number bands
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if (m_side_info.gr[igr][1].block_type == 2) { // long bands
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if (m_side_info.gr[igr][1].mixed_block_flag)
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n1 = m_sfBandIndex[0][m_ncbl_mixed - 1];
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else
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n1 = 0;
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}
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m_nsamp[igr][1] = hybrid_sum(m_sample[1][igr], m_sample[0][igr],
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m_yout, m_side_info.gr[igr][1].block_type, n1, n2);
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if (n3 < m_nsamp[igr][1])
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n1 = m_nsamp[igr][1];
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}
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freq_invert(m_yout, n3);
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m_sbt_proc(m_yout, pcm, 0);
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}
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