private void recalc_divide_sub(
final LameInternalFlags gfc,
final GrInfo cod_info2,
GrInfo gi,
final int[] ix,
final int r01_bits[],
final int r01_div[],
final int r0_tbl[],
final int r1_tbl[]) {
int bigv = cod_info2.big_values;
for (int r2 = 2; r2 < Encoder.SBMAX_l + 1; r2++) {
int a2 = gfc.scalefac_band.l[r2];
if (a2 >= bigv) break;
int bits = r01_bits[r2 - 2] + cod_info2.count1bits;
if (gi.part2_3_length <= bits) break;
Bits bi = new Bits(bits);
int r2t = choose_table(ix, a2, bigv, bi);
bits = bi.bits;
if (gi.part2_3_length <= bits) continue;
gi.assign(cod_info2);
gi.part2_3_length = bits;
gi.region0_count = r01_div[r2 - 2];
gi.region1_count = r2 - 2 - r01_div[r2 - 2];
gi.table_select[0] = r0_tbl[r2 - 2];
gi.table_select[1] = r1_tbl[r2 - 2];
gi.table_select[2] = r2t;
}
}
/** count_bit */
public int noquant_count_bits(
final LameInternalFlags gfc, final GrInfo gi, CalcNoiseData prev_noise) {
final int[] ix = gi.l3_enc;
int i = Math.min(576, ((gi.max_nonzero_coeff + 2) >> 1) << 1);
if (prev_noise != null) prev_noise.sfb_count1 = 0;
/* Determine count1 region */
for (; i > 1; i -= 2) if ((ix[i - 1] | ix[i - 2]) != 0) break;
gi.count1 = i;
/* Determines the number of bits to encode the quadruples. */
int a1 = 0;
int a2 = 0;
for (; i > 3; i -= 4) {
int p;
/* hack to check if all values <= 1 */
if ((((long) ix[i - 1] | (long) ix[i - 2] | (long) ix[i - 3] | (long) ix[i - 4])
& 0xffffffffL)
> 1L) break;
p = ((ix[i - 4] * 2 + ix[i - 3]) * 2 + ix[i - 2]) * 2 + ix[i - 1];
a1 += Tables.t32l[p];
a2 += Tables.t33l[p];
}
int bits = a1;
gi.count1table_select = 0;
if (a1 > a2) {
bits = a2;
gi.count1table_select = 1;
}
gi.count1bits = bits;
gi.big_values = i;
if (i == 0) return bits;
if (gi.block_type == Encoder.SHORT_TYPE) {
a1 = 3 * gfc.scalefac_band.s[3];
if (a1 > gi.big_values) a1 = gi.big_values;
a2 = gi.big_values;
} else if (gi.block_type == Encoder.NORM_TYPE) {
assert (i <= 576); /* bv_scf has 576 entries (0..575) */
a1 = gi.region0_count = gfc.bv_scf[i - 2];
a2 = gi.region1_count = gfc.bv_scf[i - 1];
assert (a1 + a2 + 2 < Encoder.SBPSY_l);
a2 = gfc.scalefac_band.l[a1 + a2 + 2];
a1 = gfc.scalefac_band.l[a1 + 1];
if (a2 < i) {
Bits bi = new Bits(bits);
gi.table_select[2] = choose_table(ix, a2, i, bi);
bits = bi.bits;
}
} else {
gi.region0_count = 7;
/* gi.region1_count = SBPSY_l - 7 - 1; */
gi.region1_count = Encoder.SBMAX_l - 1 - 7 - 1;
a1 = gfc.scalefac_band.l[7 + 1];
a2 = i;
if (a1 > a2) {
a1 = a2;
}
}
/* have to allow for the case when bigvalues < region0 < region1 */
/* (and region0, region1 are ignored) */
a1 = Math.min(a1, i);
a2 = Math.min(a2, i);
assert (a1 >= 0);
assert (a2 >= 0);
/* Count the number of bits necessary to code the bigvalues region. */
if (0 < a1) {
Bits bi = new Bits(bits);
gi.table_select[0] = choose_table(ix, 0, a1, bi);
bits = bi.bits;
}
if (a1 < a2) {
Bits bi = new Bits(bits);
gi.table_select[1] = choose_table(ix, a1, a2, bi);
bits = bi.bits;
}
if (gfc.use_best_huffman == 2) {
gi.part2_3_length = bits;
best_huffman_divide(gfc, gi);
bits = gi.part2_3_length;
}
if (prev_noise != null) {
if (gi.block_type == Encoder.NORM_TYPE) {
int sfb = 0;
while (gfc.scalefac_band.l[sfb] < gi.big_values) {
sfb++;
}
prev_noise.sfb_count1 = sfb;
}
}
return bits;
}
