/** Also calculates the number of bits necessary to code the scalefactors. */
public boolean scale_bitcount(final GrInfo cod_info) {
int k, sfb, max_slen1 = 0, max_slen2 = 0;
/* maximum values */
int[] tab;
final int[] scalefac = cod_info.scalefac;
assert (all_scalefactors_not_negative(scalefac, cod_info.sfbmax));
if (cod_info.block_type == Encoder.SHORT_TYPE) {
tab = scale_short;
if (cod_info.mixed_block_flag != 0) tab = scale_mixed;
} else {
/* block_type == 1,2,or 3 */
tab = scale_long;
if (0 == cod_info.preflag) {
for (sfb = 11; sfb < Encoder.SBPSY_l; sfb++) if (scalefac[sfb] < qupvt.pretab[sfb]) break;
if (sfb == Encoder.SBPSY_l) {
cod_info.preflag = 1;
for (sfb = 11; sfb < Encoder.SBPSY_l; sfb++) scalefac[sfb] -= qupvt.pretab[sfb];
}
}
}
for (sfb = 0; sfb < cod_info.sfbdivide; sfb++)
if (max_slen1 < scalefac[sfb]) max_slen1 = scalefac[sfb];
for (; sfb < cod_info.sfbmax; sfb++) if (max_slen2 < scalefac[sfb]) max_slen2 = scalefac[sfb];
/*
* from Takehiro TOMINAGA <*****@*****.**> 10/99 loop over *all*
* posible values of scalefac_compress to find the one which uses the
* smallest number of bits. ISO would stop at first valid index
*/
cod_info.part2_length = QuantizePVT.LARGE_BITS;
for (k = 0; k < 16; k++) {
if (max_slen1 < slen1_n[k] && max_slen2 < slen2_n[k] && cod_info.part2_length > tab[k]) {
cod_info.part2_length = tab[k];
cod_info.scalefac_compress = k;
}
}
return cod_info.part2_length == QuantizePVT.LARGE_BITS;
}
private void scfsi_calc(int ch, final IIISideInfo l3_side) {
int sfb;
final GrInfo gi = l3_side.tt[1][ch];
final GrInfo g0 = l3_side.tt[0][ch];
for (int i = 0; i < Tables.scfsi_band.length - 1; i++) {
for (sfb = Tables.scfsi_band[i]; sfb < Tables.scfsi_band[i + 1]; sfb++) {
if (g0.scalefac[sfb] != gi.scalefac[sfb] && gi.scalefac[sfb] >= 0) break;
}
if (sfb == Tables.scfsi_band[i + 1]) {
for (sfb = Tables.scfsi_band[i]; sfb < Tables.scfsi_band[i + 1]; sfb++) {
gi.scalefac[sfb] = -1;
}
l3_side.scfsi[ch][i] = 1;
}
}
int s1 = 0;
int c1 = 0;
for (sfb = 0; sfb < 11; sfb++) {
if (gi.scalefac[sfb] == -1) continue;
c1++;
if (s1 < gi.scalefac[sfb]) s1 = gi.scalefac[sfb];
}
int s2 = 0;
int c2 = 0;
for (; sfb < Encoder.SBPSY_l; sfb++) {
if (gi.scalefac[sfb] == -1) continue;
c2++;
if (s2 < gi.scalefac[sfb]) s2 = gi.scalefac[sfb];
}
for (int i = 0; i < 16; i++) {
if (s1 < slen1_n[i] && s2 < slen2_n[i]) {
final int c = slen1_tab[i] * c1 + slen2_tab[i] * c2;
if (gi.part2_length > c) {
gi.part2_length = c;
gi.scalefac_compress = i;
}
}
}
}
/**
* Also counts the number of bits to encode the scalefacs but for MPEG 2 Lower sampling
* frequencies (24, 22.05 and 16 kHz.)
*
* <p>This is reverse-engineered from section 2.4.3.2 of the MPEG2 IS, "Audio Decoding Layer III"
*/
public boolean scale_bitcount_lsf(final LameInternalFlags gfc, final GrInfo cod_info) {
int table_number, row_in_table, partition, nr_sfb, window;
boolean over;
int i, sfb, max_sfac[] = new int[4];
final int[] partition_table;
final int[] scalefac = cod_info.scalefac;
/*
* Set partition table. Note that should try to use table one, but do
* not yet...
*/
if (cod_info.preflag != 0) table_number = 2;
else table_number = 0;
for (i = 0; i < 4; i++) max_sfac[i] = 0;
if (cod_info.block_type == Encoder.SHORT_TYPE) {
row_in_table = 1;
partition_table = qupvt.nr_of_sfb_block[table_number][row_in_table];
for (sfb = 0, partition = 0; partition < 4; partition++) {
nr_sfb = partition_table[partition] / 3;
for (i = 0; i < nr_sfb; i++, sfb++)
for (window = 0; window < 3; window++)
if (scalefac[sfb * 3 + window] > max_sfac[partition])
max_sfac[partition] = scalefac[sfb * 3 + window];
}
} else {
row_in_table = 0;
partition_table = qupvt.nr_of_sfb_block[table_number][row_in_table];
for (sfb = 0, partition = 0; partition < 4; partition++) {
nr_sfb = partition_table[partition];
for (i = 0; i < nr_sfb; i++, sfb++)
if (scalefac[sfb] > max_sfac[partition]) max_sfac[partition] = scalefac[sfb];
}
}
for (over = false, partition = 0; partition < 4; partition++) {
if (max_sfac[partition] > max_range_sfac_tab[table_number][partition]) over = true;
}
if (!over) {
int slen1, slen2, slen3, slen4;
cod_info.sfb_partition_table = qupvt.nr_of_sfb_block[table_number][row_in_table];
for (partition = 0; partition < 4; partition++)
cod_info.slen[partition] = log2tab[max_sfac[partition]];
/* set scalefac_compress */
slen1 = cod_info.slen[0];
slen2 = cod_info.slen[1];
slen3 = cod_info.slen[2];
slen4 = cod_info.slen[3];
switch (table_number) {
case 0:
cod_info.scalefac_compress = (((slen1 * 5) + slen2) << 4) + (slen3 << 2) + slen4;
break;
case 1:
cod_info.scalefac_compress = 400 + (((slen1 * 5) + slen2) << 2) + slen3;
break;
case 2:
cod_info.scalefac_compress = 500 + (slen1 * 3) + slen2;
break;
default:
System.err.printf("intensity stereo not implemented yet\n");
break;
}
}
if (!over) {
assert (cod_info.sfb_partition_table != null);
cod_info.part2_length = 0;
for (partition = 0; partition < 4; partition++)
cod_info.part2_length += cod_info.slen[partition] * cod_info.sfb_partition_table[partition];
}
return over;
}
