/** 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;
}
/**
* Find the optimal way to store the scalefactors. Only call this routine after final scalefactors
* have been chosen and the channel/granule will not be re-encoded.
*/
public void best_scalefac_store(
final LameInternalFlags gfc, final int gr, final int ch, final IIISideInfo l3_side) {
/* use scalefac_scale if we can */
final GrInfo gi = l3_side.tt[gr][ch];
int sfb, i, j, l;
int recalc = 0;
/*
* remove scalefacs from bands with ix=0. This idea comes from the AAC
* ISO docs. added mt 3/00
*/
/* check if l3_enc=0 */
j = 0;
for (sfb = 0; sfb < gi.sfbmax; sfb++) {
final int width = gi.width[sfb];
assert (width >= 0);
j += width;
for (l = -width; l < 0; l++) {
if (gi.l3_enc[l + j] != 0) break;
}
if (l == 0) gi.scalefac[sfb] = recalc = -2; /* anything goes. */
/*
* only best_scalefac_store and calc_scfsi know--and only they
* should know--about the magic number -2.
*/
}
if (0 == gi.scalefac_scale && 0 == gi.preflag) {
int s = 0;
for (sfb = 0; sfb < gi.sfbmax; sfb++) if (gi.scalefac[sfb] > 0) s |= gi.scalefac[sfb];
if (0 == (s & 1) && s != 0) {
for (sfb = 0; sfb < gi.sfbmax; sfb++) if (gi.scalefac[sfb] > 0) gi.scalefac[sfb] >>= 1;
gi.scalefac_scale = recalc = 1;
}
}
if (0 == gi.preflag && gi.block_type != Encoder.SHORT_TYPE && gfc.mode_gr == 2) {
for (sfb = 11; sfb < Encoder.SBPSY_l; sfb++)
if (gi.scalefac[sfb] < qupvt.pretab[sfb] && gi.scalefac[sfb] != -2) break;
if (sfb == Encoder.SBPSY_l) {
for (sfb = 11; sfb < Encoder.SBPSY_l; sfb++)
if (gi.scalefac[sfb] > 0) gi.scalefac[sfb] -= qupvt.pretab[sfb];
gi.preflag = recalc = 1;
}
}
for (i = 0; i < 4; i++) l3_side.scfsi[ch][i] = 0;
if (gfc.mode_gr == 2
&& gr == 1
&& l3_side.tt[0][ch].block_type != Encoder.SHORT_TYPE
&& l3_side.tt[1][ch].block_type != Encoder.SHORT_TYPE) {
scfsi_calc(ch, l3_side);
recalc = 0;
}
for (sfb = 0; sfb < gi.sfbmax; sfb++) {
if (gi.scalefac[sfb] == -2) {
gi.scalefac[sfb] = 0; /* if anything goes, then 0 is a good choice */
}
}
if (recalc != 0) {
if (gfc.mode_gr == 2) {
scale_bitcount(gi);
} else {
scale_bitcount_lsf(gfc, gi);
}
}
}
