ref: 00626046473379e2be1594539504f8c43761ba61
dir: /libfaad/sbr_hfadj.c/
/* ** FAAD2 - Freeware Advanced Audio (AAC) Decoder including SBR decoding ** Copyright (C) 2003-2004 M. Bakker, Ahead Software AG, http://www.nero.com ** ** This program is free software; you can redistribute it and/or modify ** it under the terms of the GNU General Public License as published by ** the Free Software Foundation; either version 2 of the License, or ** (at your option) any later version. ** ** This program is distributed in the hope that it will be useful, ** but WITHOUT ANY WARRANTY; without even the implied warranty of ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ** GNU General Public License for more details. ** ** You should have received a copy of the GNU General Public License ** along with this program; if not, write to the Free Software ** Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. ** ** Any non-GPL usage of this software or parts of this software is strictly ** forbidden. ** ** Commercial non-GPL licensing of this software is possible. ** For more info contact Ahead Software through Mpeg4AAClicense@nero.com. ** ** $Id: sbr_hfadj.c,v 1.13 2004/03/19 10:37:55 menno Exp $ **/ /* High Frequency adjustment */ #include "common.h" #include "structs.h" #ifdef SBR_DEC #include "sbr_syntax.h" #include "sbr_hfadj.h" #include "sbr_noise.h" /* static function declarations */ static void map_noise_data(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch); static void map_sinusoids(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch); static void estimate_current_envelope(sbr_info *sbr, sbr_hfadj_info *adj, qmf_t Xsbr[MAX_NTSRHFG][64], uint8_t ch); static void calculate_gain(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch); #ifdef SBR_LOW_POWER static void calc_gain_groups(sbr_info *sbr, sbr_hfadj_info *adj, real_t *deg, uint8_t ch); static void aliasing_reduction(sbr_info *sbr, sbr_hfadj_info *adj, real_t *deg, uint8_t ch); #endif static void hf_assembly(sbr_info *sbr, sbr_hfadj_info *adj, qmf_t Xsbr[MAX_NTSRHFG][64], uint8_t ch); void hf_adjustment(sbr_info *sbr, qmf_t Xsbr[MAX_NTSRHFG][64] #ifdef SBR_LOW_POWER ,real_t *deg /* aliasing degree */ #endif ,uint8_t ch) { ALIGN sbr_hfadj_info adj = {{{0}}}; map_noise_data(sbr, &adj, ch); map_sinusoids(sbr, &adj, ch); estimate_current_envelope(sbr, &adj, Xsbr, ch); calculate_gain(sbr, &adj, ch); #ifdef SBR_LOW_POWER calc_gain_groups(sbr, &adj, deg, ch); aliasing_reduction(sbr, &adj, deg, ch); #endif hf_assembly(sbr, &adj, Xsbr, ch); } static void map_noise_data(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch) { uint8_t l, i; uint32_t m; for (l = 0; l < sbr->L_E[ch]; l++) { for (i = 0; i < sbr->N_Q; i++) { for (m = sbr->f_table_noise[i]; m < sbr->f_table_noise[i+1]; m++) { uint8_t k; adj->Q_div_mapped[m - sbr->kx][l] = 0; adj->Q_div2_mapped[m - sbr->kx][l] = 0; for (k = 0; k < 2; k++) { if ((sbr->t_E[ch][l] >= sbr->t_Q[ch][k]) && (sbr->t_E[ch][l+1] <= sbr->t_Q[ch][k+1])) { adj->Q_div_mapped[m - sbr->kx][l] = sbr->Q_div[ch][i][k]; adj->Q_div2_mapped[m - sbr->kx][l] = sbr->Q_div2[ch][i][k]; } } } } } } static void map_sinusoids(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch) { uint8_t l, i, m, k, k1, k2, delta_S, l_i, u_i; if (sbr->bs_frame_class[ch] == FIXFIX) { sbr->l_A[ch] = -1; } else if (sbr->bs_frame_class[ch] == VARFIX) { if (sbr->bs_pointer[ch] > 1) sbr->l_A[ch] = -1; else sbr->l_A[ch] = sbr->bs_pointer[ch] - 1; } else { if (sbr->bs_pointer[ch] == 0) sbr->l_A[ch] = -1; else sbr->l_A[ch] = sbr->L_E[ch] + 1 - sbr->bs_pointer[ch]; } for (l = 0; l < 5; l++) { for (i = 0; i < 64; i++) { adj->S_index_mapped[i][l] = 0; adj->S_mapped[i][l] = 0; } } for (l = 0; l < sbr->L_E[ch]; l++) { for (i = 0; i < sbr->N_high; i++) { for (m = sbr->f_table_res[HI_RES][i]; m < sbr->f_table_res[HI_RES][i+1]; m++) { uint8_t delta_step = 0; if ((l >= sbr->l_A[ch]) || ((sbr->bs_add_harmonic_prev[ch][i]) && (sbr->bs_add_harmonic_flag_prev[ch]))) { delta_step = 1; } if (m == (int32_t)((real_t)(sbr->f_table_res[HI_RES][i+1]+sbr->f_table_res[HI_RES][i])/2.)) { adj->S_index_mapped[m - sbr->kx][l] = delta_step * sbr->bs_add_harmonic[ch][i]; } else { adj->S_index_mapped[m - sbr->kx][l] = 0; } } } } for (l = 0; l < sbr->L_E[ch]; l++) { for (i = 0; i < sbr->N_high; i++) { if (sbr->f[ch][l] == 1) { k1 = i; k2 = i + 1; } else { for (k1 = 0; k1 < sbr->N_low; k1++) { if ((sbr->f_table_res[HI_RES][i] >= sbr->f_table_res[LO_RES][k1]) && (sbr->f_table_res[HI_RES][i+1] <= sbr->f_table_res[LO_RES][k1+1])) { break; } } for (k2 = 0; k2 < sbr->N_low; k2++) { if ((sbr->f_table_res[HI_RES][i+1] >= sbr->f_table_res[LO_RES][k2]) && (sbr->f_table_res[HI_RES][i+2] <= sbr->f_table_res[LO_RES][k2+1])) { break; } } } l_i = sbr->f_table_res[sbr->f[ch][l]][k1]; u_i = sbr->f_table_res[sbr->f[ch][l]][k2]; delta_S = 0; for (k = l_i; k < u_i; k++) { if (adj->S_index_mapped[k - sbr->kx][l] == 1) delta_S = 1; } for (m = l_i; m < u_i; m++) { adj->S_mapped[m - sbr->kx][l] = delta_S; } } } } static void estimate_current_envelope(sbr_info *sbr, sbr_hfadj_info *adj, qmf_t Xsbr[MAX_NTSRHFG][64], uint8_t ch) { uint8_t m, l, j, k, k_l, k_h, p; real_t nrg, div; if (sbr->bs_interpol_freq == 1) { for (l = 0; l < sbr->L_E[ch]; l++) { uint8_t i, l_i, u_i; l_i = sbr->t_E[ch][l]; u_i = sbr->t_E[ch][l+1]; div = (real_t)(u_i - l_i); for (m = 0; m < sbr->M; m++) { nrg = 0; for (i = l_i + sbr->tHFAdj; i < u_i + sbr->tHFAdj; i++) { #ifdef FIXED_POINT #ifdef SBR_LOW_POWER nrg += ((QMF_RE(Xsbr[i][m + sbr->kx])+(1<<(REAL_BITS-1)))>>REAL_BITS)*((QMF_RE(Xsbr[i][m + sbr->kx])+(1<<(REAL_BITS-1)))>>REAL_BITS); #else nrg += ((QMF_RE(Xsbr[i][m + sbr->kx])+(1<<(REAL_BITS-1)))>>REAL_BITS)*((QMF_RE(Xsbr[i][m + sbr->kx])+(1<<(REAL_BITS-1)))>>REAL_BITS) + ((QMF_IM(Xsbr[i][m + sbr->kx])+(1<<(REAL_BITS-1)))>>REAL_BITS)*((QMF_IM(Xsbr[i][m + sbr->kx])+(1<<(REAL_BITS-1)))>>REAL_BITS); #endif #else nrg += MUL_R(QMF_RE(Xsbr[i][m + sbr->kx]), QMF_RE(Xsbr[i][m + sbr->kx])) #ifndef SBR_LOW_POWER + MUL_R(QMF_IM(Xsbr[i][m + sbr->kx]), QMF_IM(Xsbr[i][m + sbr->kx])) #endif ; #endif } sbr->E_curr[ch][m][l] = nrg / div; #ifdef SBR_LOW_POWER #ifdef FIXED_POINT sbr->E_curr[ch][m][l] <<= 1; #else sbr->E_curr[ch][m][l] *= 2; #endif #endif } } } else { for (l = 0; l < sbr->L_E[ch]; l++) { for (p = 0; p < sbr->n[sbr->f[ch][l]]; p++) { k_l = sbr->f_table_res[sbr->f[ch][l]][p]; k_h = sbr->f_table_res[sbr->f[ch][l]][p+1]; for (k = k_l; k < k_h; k++) { uint8_t i, l_i, u_i; nrg = 0; l_i = sbr->t_E[ch][l]; u_i = sbr->t_E[ch][l+1]; div = (real_t)((u_i - l_i)*(k_h - k_l)); for (i = l_i + sbr->tHFAdj; i < u_i + sbr->tHFAdj; i++) { for (j = k_l; j < k_h; j++) { #ifdef FIXED_POINT #ifdef SBR_LOW_POWER nrg += ((QMF_RE(Xsbr[i][j])+(1<<(REAL_BITS-1)))>>REAL_BITS)*((QMF_RE(Xsbr[i][j])+(1<<(REAL_BITS-1)))>>REAL_BITS); #else nrg += ((QMF_RE(Xsbr[i][j])+(1<<(REAL_BITS-1)))>>REAL_BITS)*((QMF_RE(Xsbr[i][j])+(1<<(REAL_BITS-1)))>>REAL_BITS) + ((QMF_IM(Xsbr[i][j])+(1<<(REAL_BITS-1)))>>REAL_BITS)*((QMF_IM(Xsbr[i][j])+(1<<(REAL_BITS-1)))>>REAL_BITS); #endif #else nrg += MUL_R(QMF_RE(Xsbr[i][j]), QMF_RE(Xsbr[i][j])) #ifndef SBR_LOW_POWER + MUL_R(QMF_IM(Xsbr[i][j]), QMF_IM(Xsbr[i][j])) #endif ; #endif } } sbr->E_curr[ch][k - sbr->kx][l] = nrg / div; #ifdef SBR_LOW_POWER #ifdef FIXED_POINT sbr->E_curr[ch][k - sbr->kx][l] <<= 1; #else sbr->E_curr[ch][k - sbr->kx][l] *= 2; #endif #endif } } } } } #ifdef FIXED_POINT #define step(shift) \ if ((0x40000000l >> shift) + root <= value) \ { \ value -= (0x40000000l >> shift) + root; \ root = (root >> 1) | (0x40000000l >> shift); \ } else { \ root = root >> 1; \ } /* fixed point square root approximation */ real_t sbr_sqrt(real_t value) { real_t root = 0; step( 0); step( 2); step( 4); step( 6); step( 8); step(10); step(12); step(14); step(16); step(18); step(20); step(22); step(24); step(26); step(28); step(30); if (root < value) ++root; root <<= (REAL_BITS/2); return root; } real_t SBR_SQRT_Q2(real_t value) { real_t root = 0; step( 0); step( 2); step( 4); step( 6); step( 8); step(10); step(12); step(14); step(16); step(18); step(20); step(22); step(24); step(26); step(28); step(30); if (root < value) ++root; root <<= (Q2_BITS/2); return root; } real_t sbr_sqrt_int(real_t value) { real_t root = 0; step( 0); step( 2); step( 4); step( 6); step( 8); step(10); step(12); step(14); step(16); step(18); step(20); step(22); step(24); step(26); step(28); step(30); if (root < value) ++root; return root; } #define SBR_SQRT_FIX(A) sbr_sqrt(A) #define SBR_SQRT_INT(A) sbr_sqrt_int(A) #endif #ifdef FIXED_POINT #define EPS (1) /* smallest number available in fixed point */ #else #define EPS (1e-12) #endif #ifdef FIXED_POINT #define ONE (REAL_CONST(1)>>10) #else #define ONE (1) #endif #ifdef FIXED_POINT uint8_t G_max_is_biggest(real_t G, real_t G_max, uint8_t G_is_frac, uint8_t G_max_is_frac) { if ((G_is_frac == 1 && G_max_is_frac == 1) || ((G_is_frac == 0 && G_max_is_frac == 0))) { if (G_max > G) return 1; } else if (G_is_frac) { if (G_max > REAL_CONST(1)) { return 1; } else if (G_max > (G << (FRAC_BITS-REAL_BITS))) { return 1; } } else if (G_max_is_frac) { if (G > REAL_CONST(1)) { return 0; } else if (G > (G_max >> (FRAC_BITS-REAL_BITS))) { return 0; } else { return 1; } } return 0; } /* frac */ real_t div_G_max_G(real_t G, real_t G_max, uint8_t G_is_frac, uint8_t G_max_is_frac, uint8_t *is_real) { *is_real = 0; if (G_is_frac == 1) { /* divide by a frac */ return ((int64_t)G_max << FRAC_BITS)/G; } else { /* divide by a real but answer is a frac */ if (G_max_is_frac == 1) { /* G_max is already a frac */ if (G < REAL_CONST(1)) { *is_real = 1; return ((int64_t)G_max >> 3)/G; } else { return ((int64_t)G_max << REAL_BITS)/G; } } else { /* turn G_max into a frac before dividing */ return ((int64_t)G_max << REAL_BITS+(FRAC_BITS-REAL_BITS))/G; } } } static void calculate_gain(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch) { uint8_t m, l, k, i; ALIGN real_t Q_M_lim[64]; ALIGN real_t G_lim[64]; ALIGN real_t G_boost; ALIGN real_t S_M[64]; ALIGN uint8_t table_map_res_to_m[64]; ALIGN uint8_t G_is_frac[64]; ALIGN uint8_t Q_M_is_real[64]; for (l = 0; l < sbr->L_E[ch]; l++) { real_t delta = (l == sbr->l_A[ch] || l == sbr->prevEnvIsShort[ch]) ? 0 : 1; for (i = 0; i < sbr->n[sbr->f[ch][l]]; i++) { for (m = sbr->f_table_res[sbr->f[ch][l]][i]; m < sbr->f_table_res[sbr->f[ch][l]][i+1]; m++) { table_map_res_to_m[m - sbr->kx] = i; } } for (k = 0; k < sbr->N_L[sbr->bs_limiter_bands]; k++) { real_t G_max; real_t den = 0; real_t den_int = 0; real_t den_real = 0; real_t acc1 = 0; real_t acc1_coef = 0; real_t acct = 0; real_t acc2 = 0; uint8_t G_max_infinite = 0; uint8_t min_pow = 0; uint8_t G_max_is_frac = 0; uint8_t ml1, ml2; ml1 = sbr->f_table_lim[sbr->bs_limiter_bands][k]; ml2 = sbr->f_table_lim[sbr->bs_limiter_bands][k+1]; /* calculate the accumulated E_orig and E_curr over the limiter band */ for (m = ml1; m < ml2; m++) { /* E_orig: integer */ if (sbr->E_orig[ch][table_map_res_to_m[m]][l] > (1<<4)) { acc1 += (sbr->E_orig[ch][table_map_res_to_m[m]][l]>>4); } else { acc1_coef += (sbr->E_orig[ch][table_map_res_to_m[m]][l] << (COEF_BITS-4)); if (acc1_coef > COEF_CONST(3)) { acc1 += (acc1_coef+(1<<(COEF_BITS-1)))>>COEF_BITS; acc1_coef = 0; } } /* E_curr: integer */ acc2 += sbr->E_curr[ch][m][l]; } acc1 += (acc1_coef+(1<<(COEF_BITS-1)))>>COEF_BITS; /* G_max: fixed point */ if ((acc2 == 0) && (acc1 > 3)) /* chosen 3 here, kind of arbitrary but it works (0 doesn't) */ { G_max = 0xFFFFFFF; G_max_infinite = 1; } else if (acc2 == 0) { G_max = 0; G_max_infinite = 0; } else { G_max_infinite = 0; switch (sbr->bs_limiter_gains) { case 0: acct = acc1 >> 1; break; case 2: acct = acc1 << 1; break; case 3: acct = acc1; G_max_infinite = 1; break; default: acct = acc1; break; } if (acc2 > acct) { G_max_is_frac = 1; G_max = (((int64_t)acct)<<FRAC_BITS) / acc2; } else { G_max_is_frac = 0; G_max = (((int64_t)acct)<<REAL_BITS) / acc2; } } for (m = ml1; m < ml2; m++) { real_t Q_M, G; real_t Q_div1, Q_div2; real_t E_orig; /* set to 1 to start with */ uint8_t G_max_biggest = 1; /* Q_mapped: fixed point */ /* Q_div1: [0..1] FRAC_CONST */ Q_div1 = adj->Q_div_mapped[m][l]; /* Q_div2: [0..1] FRAC_CONST */ Q_div2 = adj->Q_div2_mapped[m][l]; /* E_orig: integer */ E_orig = sbr->E_orig[ch][table_map_res_to_m[m]][l]; /* Q_M: REAL */ /* S_M: integer */ if ((E_orig > (1<<22)) && (Q_div2 > FRAC_CONST(0.8))) { /* Q_M will not fit in a real */ Q_M = ((int64_t)(E_orig>>4) * Q_div2) >> FRAC_BITS; Q_M_is_real[m] = 0; S_M[m] = adj->S_index_mapped[m][l] * MUL_F((E_orig>>4), Q_div1); } else if (E_orig > (1<<4)) { Q_M = ((int64_t)(E_orig>>4) * Q_div2) >> (FRAC_BITS-REAL_BITS); Q_M_is_real[m] = 1; S_M[m] = adj->S_index_mapped[m][l] * MUL_F((E_orig>>4), Q_div1); } else { Q_M = ((int64_t)E_orig * Q_div2) >> (FRAC_BITS-REAL_BITS); Q_M >>= 4; Q_M_is_real[m] = 1; S_M[m] = adj->S_index_mapped[m][l] * MUL_F(E_orig, Q_div1); S_M[m] >>= 4; } /* G: fixed point */ if (sbr->E_curr[ch][m][l] != 0) { /* E_curr = INT */ if (sbr->E_curr[ch][m][l] > (E_orig>>4)) { /*frac*/ G = (((int64_t)E_orig)<<(FRAC_BITS-4)) / sbr->E_curr[ch][m][l]; G_is_frac[m] = 1; } else { /*real*/ G = (((int64_t)E_orig)<<(REAL_BITS-4)) / sbr->E_curr[ch][m][l]; G_is_frac[m] = 0; } } else { /* E_curr == 0, check if E_orig happens to be really big */ if (G_max_is_frac == 0) { if ((E_orig<<4) > (G_max>>REAL_BITS)) { G_max_biggest = 0; } } else { /* G_max is fractional type */ if (E_orig != 0) { G_max_biggest = 0; } } G = (E_orig << (REAL_BITS-4+10)); G_is_frac[m] = 0; } if (adj->S_mapped[m][l] == 1) { G = MUL_F(G, Q_div2); } else if (delta == 1) { G = MUL_F(G, Q_div1); } /* limit the additional noise energy level */ /* and apply the limiter */ /* if we still have the default value for G_max_biggest -> compute */ if (G_max_biggest != 0) G_max_biggest = G_max_is_biggest(G, G_max, G_is_frac[m], G_max_is_frac); /* G_lim: fixed point */ /* Q_M_lim: REAL/INT */ if (G_max_infinite || G_max_biggest) { Q_M_lim[m] = Q_M; G_lim[m] = G; } else { real_t tmp; uint8_t is_real = 0; if (G == 0) tmp = 0xFFF; else tmp = div_G_max_G(G, G_max, G_is_frac[m], G_max_is_frac, &is_real); if (is_real == 0) Q_M_lim[m] = MUL_F(Q_M, tmp); else Q_M_lim[m] = MUL_R(Q_M, tmp); G_lim[m] = G_max; G_is_frac[m] = G_max_is_frac; } /* E_curr: integer/coef */ if (G_is_frac[m] == 0) { if (sbr->E_curr[ch][m][l] < (1<<(25-REAL_BITS))) { den_real += sbr->E_curr[ch][m][l] * G_lim[m]; } else { den_int += MUL_R(sbr->E_curr[ch][m][l], G_lim[m]); } } else { den_int += MUL_F(sbr->E_curr[ch][m][l], G_lim[m]); } den_int += S_M[m]; if ((!adj->S_index_mapped[m][l]) && (l != sbr->l_A[ch])) { if (Q_M_is_real[m] == 1) { if (Q_M_lim[m] > REAL_CONST(100)) den_int += (Q_M_lim[m]>>REAL_BITS); else den_real += Q_M_lim[m]; } else { den_int += Q_M_lim[m]; } } } den = den_int + ((den_real+(1<<(REAL_BITS-1)))>>REAL_BITS); /* G_boost: fixed point */ if ((den + EPS) == 0 || den == 0) G_boost = REAL_CONST(1);//REAL_CONST(2.51188643); else if (acc1 > (den<<1)+(den>>1)) G_boost = REAL_CONST(2.51188643); else G_boost = (((int64_t)(acc1 + EPS))<<REAL_BITS)/(den + EPS); G_boost = min(G_boost, REAL_CONST(2.51188643) /* 1.584893192 ^ 2 */); for (m = ml1; m < ml2; m++) { /* apply compensation to gain, noise floor sf's and sinusoid levels */ #ifndef SBR_LOW_POWER /* G_lim_boost: fixed point */ if (G_is_frac[m] == 0) { adj->G_lim_boost[l][m] = SBR_SQRT_Q2(MUL_SHIFT6(G_lim[m], G_boost)); } else { adj->G_lim_boost[l][m] = SBR_SQRT_Q2(MUL_SHIFT23(G_lim[m], G_boost)); } #else /* sqrt() will be done after the aliasing reduction to save a * few multiplies */ /* G_lim_boost: fixed point */ if (G_is_frac[m] == 0) { adj->G_lim_boost[l][m] = MUL_SHIFT6(G_lim[m], G_boost); } else { adj->G_lim_boost[l][m] = MUL_SHIFT23(G_lim[m], G_boost); } #endif /* Q_M_lim_boost: integer */ /* Q_M_lim_boost: REAL */ if (Q_M_is_real[m]) { adj->Q_M_lim_boost[l][m] = SBR_SQRT_FIX(MUL_R(Q_M_lim[m], G_boost)); } else { adj->Q_M_lim_boost[l][m] = SBR_SQRT_INT(MUL_R(Q_M_lim[m], G_boost)); adj->Q_M_lim_boost[l][m] <<= REAL_BITS; } /* S_M_boost: integer */ if (adj->S_index_mapped[m][l]) { adj->S_M_boost[l][m] = SBR_SQRT_INT(MUL_R(S_M[m], G_boost)); } else { adj->S_M_boost[l][m] = 0; } } } } } #else static void calculate_gain(sbr_info *sbr, sbr_hfadj_info *adj, uint8_t ch) { static real_t limGain[] = { 0.5, 1.0, 2.0, 1e10 }; uint8_t m, l, k, i; ALIGN real_t Q_M_lim[64]; ALIGN real_t G_lim[64]; ALIGN real_t G_boost; ALIGN real_t S_M[64]; ALIGN uint8_t table_map_res_to_m[64]; for (l = 0; l < sbr->L_E[ch]; l++) { real_t delta = (l == sbr->l_A[ch] || l == sbr->prevEnvIsShort[ch]) ? 0 : 1; for (i = 0; i < sbr->n[sbr->f[ch][l]]; i++) { for (m = sbr->f_table_res[sbr->f[ch][l]][i]; m < sbr->f_table_res[sbr->f[ch][l]][i+1]; m++) { table_map_res_to_m[m - sbr->kx] = i; } } for (k = 0; k < sbr->N_L[sbr->bs_limiter_bands]; k++) { real_t G_max; real_t den = 0; real_t acc1 = 0; real_t acc2 = 0; uint8_t ml1, ml2; ml1 = sbr->f_table_lim[sbr->bs_limiter_bands][k]; ml2 = sbr->f_table_lim[sbr->bs_limiter_bands][k+1]; /* calculate the accumulated E_orig and E_curr over the limiter band */ for (m = ml1; m < ml2; m++) { acc1 += sbr->E_orig[ch][table_map_res_to_m[m]][l]; acc2 += sbr->E_curr[ch][m][l]; } G_max = ((EPS + acc1)/(EPS + acc2)) * limGain[sbr->bs_limiter_gains]; G_max = min(G_max, 1e10); for (m = ml1; m < ml2; m++) { real_t Q_M, G; real_t Q_div, Q_div2; /* Q_div: [0..1] (1/(1+Q_mapped)) */ Q_div = adj->Q_div_mapped[m][l]; /* Q_div2: [0..1] (Q_mapped/(1+Q_mapped)) */ Q_div2 = adj->Q_div2_mapped[m][l]; Q_M = sbr->E_orig[ch][table_map_res_to_m[m]][l] * Q_div2; /* 12-Nov: Changed S_mapped to S_index_mapped */ if (adj->S_index_mapped[m][l] == 0) { S_M[m] = 0; } else { S_M[m] = sbr->E_orig[ch][table_map_res_to_m[m]][l] * Q_div; } G = sbr->E_orig[ch][table_map_res_to_m[m]][l] / (1.0 + sbr->E_curr[ch][m][l]); if ((adj->S_mapped[m][l] == 0) && (delta == 1)) G *= Q_div; else if (adj->S_mapped[m][l] == 1) G *= Q_div2; /* limit the additional noise energy level */ /* and apply the limiter */ if (G_max > G) { Q_M_lim[m] = Q_M; G_lim[m] = G; } else { Q_M_lim[m] = Q_M * G_max / G; /* equivalent to code below */ G_lim[m] = G_max; } den += sbr->E_curr[ch][m][l] * G_lim[m]; if (adj->S_index_mapped[m][l]) den += S_M[m]; else if (l != sbr->l_A[ch]) den += Q_M_lim[m]; } /* G_boost: [0..2.51188643] */ G_boost = (acc1 + EPS) / (den + EPS); G_boost = min(G_boost, 2.51188643 /* 1.584893192 ^ 2 */); for (m = ml1; m < ml2; m++) { /* apply compensation to gain, noise floor sf's and sinusoid levels */ #ifndef SBR_LOW_POWER adj->G_lim_boost[l][m] = sqrt(G_lim[m] * G_boost); #else /* sqrt() will be done after the aliasing reduction to save a * few multiplies */ adj->G_lim_boost[l][m] = G_lim[m] * G_boost; #endif adj->Q_M_lim_boost[l][m] = sqrt(Q_M_lim[m] * G_boost); if (adj->S_index_mapped[m][l]) { adj->S_M_boost[l][m] = sqrt(S_M[m] * G_boost); } else { adj->S_M_boost[l][m] = 0; } } } } } #endif #ifdef SBR_LOW_POWER static void calc_gain_groups(sbr_info *sbr, sbr_hfadj_info *adj, real_t *deg, uint8_t ch) { uint8_t l, k, i; uint8_t grouping; for (l = 0; l < sbr->L_E[ch]; l++) { i = 0; grouping = 0; for (k = sbr->kx; k < sbr->kx + sbr->M - 1; k++) { if (deg[k + 1] && adj->S_mapped[k-sbr->kx][l] == 0) { if (grouping == 0) { sbr->f_group[l][i] = k; grouping = 1; i++; } } else { if (grouping) { if (adj->S_mapped[k-sbr->kx][l]) { sbr->f_group[l][i] = k; } else { sbr->f_group[l][i] = k + 1; } grouping = 0; i++; } } } if (grouping) { sbr->f_group[l][i] = sbr->kx + sbr->M; i++; } sbr->N_G[l] = (uint8_t)(i >> 1); } } static void aliasing_reduction(sbr_info *sbr, sbr_hfadj_info *adj, real_t *deg, uint8_t ch) { uint8_t l, k, m; real_t E_total, E_total_est, G_target, acc; for (l = 0; l < sbr->L_E[ch]; l++) { for (k = 0; k < sbr->N_G[l]; k++) { E_total_est = E_total = 0; for (m = sbr->f_group[l][k<<1]; m < sbr->f_group[l][(k<<1) + 1]; m++) { /* E_curr: integer */ /* G_lim_boost: fixed point */ /* E_total_est: integer */ /* E_total: integer */ E_total_est += sbr->E_curr[ch][m-sbr->kx][l]; #ifdef FIXED_POINT E_total += MUL_Q2(sbr->E_curr[ch][m-sbr->kx][l], adj->G_lim_boost[l][m-sbr->kx]); #else E_total += sbr->E_curr[ch][m-sbr->kx][l] * adj->G_lim_boost[l][m-sbr->kx]; #endif } /* G_target: fixed point */ if ((E_total_est + EPS) == 0) { G_target = 0; } else { #ifdef FIXED_POINT G_target = (((int64_t)(E_total))<<Q2_BITS)/(E_total_est + EPS); #else G_target = E_total / (E_total_est + EPS); #endif } acc = 0; for (m = sbr->f_group[l][(k<<1)]; m < sbr->f_group[l][(k<<1) + 1]; m++) { real_t alpha; /* alpha: (COEF) fixed point */ if (m < sbr->kx + sbr->M - 1) { alpha = max(deg[m], deg[m + 1]); } else { alpha = deg[m]; } adj->G_lim_boost[l][m-sbr->kx] = MUL_C(alpha, G_target) + MUL_C((COEF_CONST(1)-alpha), adj->G_lim_boost[l][m-sbr->kx]); /* acc: integer */ #ifdef FIXED_POINT acc += MUL_Q2(adj->G_lim_boost[l][m-sbr->kx], sbr->E_curr[ch][m-sbr->kx][l]); #else acc += adj->G_lim_boost[l][m-sbr->kx] * sbr->E_curr[ch][m-sbr->kx][l]; #endif } /* acc: fixed point */ if (acc + EPS == 0) { acc = 0; } else { #ifdef FIXED_POINT acc = (((int64_t)(E_total))<<Q2_BITS)/(acc + EPS); #else acc = E_total / (acc + EPS); #endif } for(m = sbr->f_group[l][(k<<1)]; m < sbr->f_group[l][(k<<1) + 1]; m++) { #ifdef FIXED_POINT adj->G_lim_boost[l][m-sbr->kx] = MUL_Q2(acc, adj->G_lim_boost[l][m-sbr->kx]); #else adj->G_lim_boost[l][m-sbr->kx] = acc * adj->G_lim_boost[l][m-sbr->kx]; #endif } } } for (l = 0; l < sbr->L_E[ch]; l++) { for (k = 0; k < sbr->N_L[sbr->bs_limiter_bands]; k++) { for (m = sbr->f_table_lim[sbr->bs_limiter_bands][k]; m < sbr->f_table_lim[sbr->bs_limiter_bands][k+1]; m++) { #ifdef FIXED_POINT adj->G_lim_boost[l][m] = SBR_SQRT_Q2(adj->G_lim_boost[l][m]); #else adj->G_lim_boost[l][m] = sqrt(adj->G_lim_boost[l][m]); #endif } } } } #endif static void hf_assembly(sbr_info *sbr, sbr_hfadj_info *adj, qmf_t Xsbr[MAX_NTSRHFG][64], uint8_t ch) { static real_t h_smooth[] = { FRAC_CONST(0.03183050093751), FRAC_CONST(0.11516383427084), FRAC_CONST(0.21816949906249), FRAC_CONST(0.30150283239582), FRAC_CONST(0.33333333333333) }; static int8_t phi_re[] = { 1, 0, -1, 0 }; static int8_t phi_im[] = { 0, 1, 0, -1 }; uint8_t m, l, i, n; uint16_t fIndexNoise = 0; uint8_t fIndexSine = 0; uint8_t assembly_reset = 0; real_t *temp; real_t G_filt, Q_filt; uint8_t h_SL; if (sbr->Reset == 1) { assembly_reset = 1; fIndexNoise = 0; } else { fIndexNoise = sbr->index_noise_prev[ch]; } fIndexSine = sbr->psi_is_prev[ch]; for (l = 0; l < sbr->L_E[ch]; l++) { uint8_t no_noise = (l == sbr->l_A[ch] || l == sbr->prevEnvIsShort[ch]) ? 1 : 0; #ifdef SBR_LOW_POWER h_SL = 0; #else h_SL = (sbr->bs_smoothing_mode == 1) ? 0 : 4; h_SL = (no_noise ? 0 : h_SL); #endif if (assembly_reset) { for (n = 0; n < 4; n++) { memcpy(sbr->G_temp_prev[ch][n], adj->G_lim_boost[l], sbr->M*sizeof(real_t)); memcpy(sbr->Q_temp_prev[ch][n], adj->Q_M_lim_boost[l], sbr->M*sizeof(real_t)); } assembly_reset = 0; } for (i = sbr->t_E[ch][l]; i < sbr->t_E[ch][l+1]; i++) { #ifdef SBR_LOW_POWER uint8_t i_min1, i_plus1; uint8_t sinusoids = 0; #endif memcpy(sbr->G_temp_prev[ch][4], adj->G_lim_boost[l], sbr->M*sizeof(real_t)); memcpy(sbr->Q_temp_prev[ch][4], adj->Q_M_lim_boost[l], sbr->M*sizeof(real_t)); for (m = 0; m < sbr->M; m++) { qmf_t psi; G_filt = 0; Q_filt = 0; #ifndef SBR_LOW_POWER if (h_SL != 0) { for (n = 0; n <= 4; n++) { G_filt += MUL_F(sbr->G_temp_prev[ch][n][m], h_smooth[n]); Q_filt += MUL_F(sbr->Q_temp_prev[ch][n][m], h_smooth[n]); } } else { #endif G_filt = sbr->G_temp_prev[ch][4][m]; Q_filt = sbr->Q_temp_prev[ch][4][m]; #ifndef SBR_LOW_POWER } #endif Q_filt = (adj->S_M_boost[l][m] != 0 || no_noise) ? 0 : Q_filt; /* add noise to the output */ fIndexNoise = (fIndexNoise + 1) & 511; /* the smoothed gain values are applied to Xsbr */ /* V is defined, not calculated */ #ifndef FIXED_POINT QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) = G_filt * QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) + MUL_F(Q_filt, RE(V[fIndexNoise])); #else QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) = MUL_Q2(G_filt, QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx])) + MUL_F(Q_filt, RE(V[fIndexNoise])); #endif if (sbr->bs_extension_id == 3 && sbr->bs_extension_data == 42) QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) = 16428320; #ifndef SBR_LOW_POWER #ifndef FIXED_POINT QMF_IM(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) = G_filt * QMF_IM(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) + MUL_F(Q_filt, IM(V[fIndexNoise])); #else QMF_IM(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) = MUL_Q2(G_filt, QMF_IM(Xsbr[i + sbr->tHFAdj][m+sbr->kx])) + MUL_F(Q_filt, IM(V[fIndexNoise])); #endif #endif { int8_t rev = (((m + sbr->kx) & 1) ? -1 : 1); QMF_RE(psi) = adj->S_M_boost[l][m] * phi_re[fIndexSine]; #ifdef FIXED_POINT QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) += (QMF_RE(psi) << REAL_BITS); #else QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) += QMF_RE(psi); #endif #ifndef SBR_LOW_POWER QMF_IM(psi) = rev * adj->S_M_boost[l][m] * phi_im[fIndexSine]; #ifdef FIXED_POINT QMF_IM(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) += (QMF_IM(psi) << REAL_BITS); #else QMF_IM(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) += QMF_IM(psi); #endif #else i_min1 = (fIndexSine - 1) & 3; i_plus1 = (fIndexSine + 1) & 3; #ifndef FIXED_POINT if ((m == 0) && (phi_re[i_plus1] != 0)) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx - 1]) += (rev*phi_re[i_plus1] * MUL_F(adj->S_M_boost[l][0], FRAC_CONST(0.00815))); if (sbr->M != 0) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_plus1] * MUL_F(adj->S_M_boost[l][1], FRAC_CONST(0.00815))); } } if ((m > 0) && (m < sbr->M - 1) && (sinusoids < 16) && (phi_re[i_min1] != 0)) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_min1] * MUL_F(adj->S_M_boost[l][m - 1], FRAC_CONST(0.00815))); } if ((m > 0) && (m < sbr->M - 1) && (sinusoids < 16) && (phi_re[i_plus1] != 0)) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_plus1] * MUL_F(adj->S_M_boost[l][m + 1], FRAC_CONST(0.00815))); } if ((m == sbr->M - 1) && (sinusoids < 16) && (phi_re[i_min1] != 0)) { if (m > 0) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_min1] * MUL_F(adj->S_M_boost[l][m - 1], FRAC_CONST(0.00815))); } if (m + sbr->kx < 64) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx + 1]) += (rev*phi_re[i_min1] * MUL_F(adj->S_M_boost[l][m], FRAC_CONST(0.00815))); } } #else if ((m == 0) && (phi_re[i_plus1] != 0)) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx - 1]) += (rev*phi_re[i_plus1] * MUL_F((adj->S_M_boost[l][0]<<REAL_BITS), FRAC_CONST(0.00815))); if (sbr->M != 0) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_plus1] * MUL_F((adj->S_M_boost[l][1]<<REAL_BITS), FRAC_CONST(0.00815))); } } if ((m > 0) && (m < sbr->M - 1) && (sinusoids < 16) && (phi_re[i_min1] != 0)) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_min1] * MUL_F((adj->S_M_boost[l][m - 1]<<REAL_BITS), FRAC_CONST(0.00815))); } if ((m > 0) && (m < sbr->M - 1) && (sinusoids < 16) && (phi_re[i_plus1] != 0)) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_plus1] * MUL_F((adj->S_M_boost[l][m + 1]<<REAL_BITS), FRAC_CONST(0.00815))); } if ((m == sbr->M - 1) && (sinusoids < 16) && (phi_re[i_min1] != 0)) { if (m > 0) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx]) -= (rev*phi_re[i_min1] * MUL_F((adj->S_M_boost[l][m - 1]<<REAL_BITS), FRAC_CONST(0.00815))); } if (m + sbr->kx < 64) { QMF_RE(Xsbr[i + sbr->tHFAdj][m+sbr->kx + 1]) += (rev*phi_re[i_min1] * MUL_F((adj->S_M_boost[l][m]<<REAL_BITS), FRAC_CONST(0.00815))); } } #endif if (adj->S_M_boost[l][m] != 0) sinusoids++; #endif } } fIndexSine = (fIndexSine + 1) & 3; temp = sbr->G_temp_prev[ch][0]; for (n = 0; n < 4; n++) sbr->G_temp_prev[ch][n] = sbr->G_temp_prev[ch][n+1]; sbr->G_temp_prev[ch][4] = temp; temp = sbr->Q_temp_prev[ch][0]; for (n = 0; n < 4; n++) sbr->Q_temp_prev[ch][n] = sbr->Q_temp_prev[ch][n+1]; sbr->Q_temp_prev[ch][4] = temp; } } sbr->index_noise_prev[ch] = fIndexNoise; sbr->psi_is_prev[ch] = fIndexSine; } #endif