FreeCalypso > hg > efr-experiments
view src/q_plsf_5.c @ 6:6119d2c1e7d9
EFR2 encoder: mimic 5 ms delay of AMR
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Wed, 03 Apr 2024 07:14:01 +0000 |
parents | 56410792419a |
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/************************************************************************* * FUNCTION: Q_plsf_5() * * PURPOSE: Quantization of 2 sets of LSF parameters using 1st order MA * prediction and split by 5 matrix quantization (split-MQ) * * DESCRIPTION: * * p[i] = pred_factor*past_r2q[i]; i=0,...,m-1 * r1[i]= lsf1[i] - p[i]; i=0,...,m-1 * r2[i]= lsf2[i] - p[i]; i=0,...,m-1 * where: * lsf1[i] 1st mean-removed LSF vector. * lsf2[i] 2nd mean-removed LSF vector. * r1[i] 1st residual prediction vector. * r2[i] 2nd residual prediction vector. * past_r2q[i] Past quantized residual (2nd vector). * * The residual vectors r1[i] and r2[i] are jointly quantized using * split-MQ with 5 codebooks. Each 4th dimension submatrix contains 2 * elements from each residual vector. The 5 submatrices are as follows: * {r1[0], r1[1], r2[0], r2[1]}; {r1[2], r1[3], r2[2], r2[3]}; * {r1[4], r1[5], r2[4], r2[5]}; {r1[6], r1[7], r2[6], r2[7]}; * {r1[8], r1[9], r2[8], r2[9]}; * *************************************************************************/ #include "typedef.h" #include "basic_op.h" #include "count.h" #include "sig_proc.h" #include "cnst.h" #include "dtx.h" /* Locals functions */ void Lsf_wt ( Word16 *lsf, /* input : LSF vector */ Word16 *wf2 /* output: square of weighting factors */ ); Word16 Vq_subvec ( /* output: return quantization index */ Word16 *lsf_r1, /* input : 1st LSF residual vector */ Word16 *lsf_r2, /* input : and LSF residual vector */ const Word16 *dico,/* input : quantization codebook */ Word16 *wf1, /* input : 1st LSF weighting factors */ Word16 *wf2, /* input : 2nd LSF weighting factors */ Word16 dico_size /* input : size of quantization codebook */ ); Word16 Vq_subvec_s ( /* output: return quantization index */ Word16 *lsf_r1, /* input : 1st LSF residual vector */ Word16 *lsf_r2, /* input : and LSF residual vector */ const Word16 *dico,/* input : quantization codebook */ Word16 *wf1, /* input : 1st LSF weighting factors */ Word16 *wf2, /* input : 2nd LSF weighting factors */ Word16 dico_size /* input : size of quantization codebook */ ); /* M ->order of linear prediction filter */ /* LSF_GAP -> Minimum distance between LSF after quantization */ /* 50 Hz = 205 */ /* PRED_FAC -> Predcition factor */ #define M 10 #define LSF_GAP 205 #define PRED_FAC 21299 #include "q_plsf_5.tab" /* Codebooks of LSF prediction residual */ /* Past quantized prediction error */ Word16 past_r2_q[M]; extern Word16 lsf_old_tx[DTX_HANGOVER][M]; void Q_plsf_5 ( Word16 *lsp1, /* input : 1st LSP vector */ Word16 *lsp2, /* input : 2nd LSP vector */ Word16 *lsp1_q, /* output: quantized 1st LSP vector */ Word16 *lsp2_q, /* output: quantized 2nd LSP vector */ Word16 *indice, /* output: quantization indices of 5 matrices */ Word16 txdtx_ctrl /* input : tx dtx control word */ ) { Word16 i; Word16 lsf1[M], lsf2[M], wf1[M], wf2[M], lsf_p[M], lsf_r1[M], lsf_r2[M]; Word16 lsf1_q[M], lsf2_q[M]; Word16 lsf_aver[M]; static Word16 lsf_p_CN[M]; /* convert LSFs to normalize frequency domain 0..16384 */ Lsp_lsf (lsp1, lsf1, M); Lsp_lsf (lsp2, lsf2, M); /* Update LSF CN quantizer "memory" */ logic16 (); logic16 (); test (); test (); if ((txdtx_ctrl & TX_SP_FLAG) == 0 && (txdtx_ctrl & TX_PREV_HANGOVER_ACTIVE) != 0) { update_lsf_p_CN (lsf_old_tx, lsf_p_CN); } logic16 (); test (); if ((txdtx_ctrl & TX_SID_UPDATE) != 0) { /* New SID frame is to be sent: Compute average of the current LSFs and the LSFs in the history */ aver_lsf_history (lsf_old_tx, lsf1, lsf2, lsf_aver); } /* Update LSF history with unquantized LSFs when no speech activity is present */ logic16 (); test (); if ((txdtx_ctrl & TX_SP_FLAG) == 0) { update_lsf_history (lsf1, lsf2, lsf_old_tx); } logic16 (); test (); if ((txdtx_ctrl & TX_SID_UPDATE) != 0) { /* Compute LSF weighting factors for lsf2, using averaged LSFs */ /* Set LSF weighting factors for lsf1 to zero */ /* Replace lsf1 and lsf2 by the averaged LSFs */ Lsf_wt (lsf_aver, wf2); for (i = 0; i < M; i++) { wf1[i] = 0; move16 (); lsf1[i] = lsf_aver[i]; move16 (); lsf2[i] = lsf_aver[i]; move16 (); } } else { /* Compute LSF weighting factors */ Lsf_wt (lsf1, wf1); Lsf_wt (lsf2, wf2); } /* Compute predicted LSF and prediction error */ logic16 (); test (); if ((txdtx_ctrl & TX_SP_FLAG) != 0) { for (i = 0; i < M; i++) { lsf_p[i] = add (mean_lsf[i], mult (past_r2_q[i], PRED_FAC)); move16 (); lsf_r1[i] = sub (lsf1[i], lsf_p[i]); move16 (); lsf_r2[i] = sub (lsf2[i], lsf_p[i]); move16 (); } } else { for (i = 0; i < M; i++) { lsf_r1[i] = sub (lsf1[i], lsf_p_CN[i]); move16 (); lsf_r2[i] = sub (lsf2[i], lsf_p_CN[i]); move16 (); } } /*---- Split-VQ of prediction error ----*/ indice[0] = Vq_subvec (&lsf_r1[0], &lsf_r2[0], dico1_lsf, &wf1[0], &wf2[0], DICO1_SIZE); move16 (); indice[1] = Vq_subvec (&lsf_r1[2], &lsf_r2[2], dico2_lsf, &wf1[2], &wf2[2], DICO2_SIZE); move16 (); indice[2] = Vq_subvec_s (&lsf_r1[4], &lsf_r2[4], dico3_lsf, &wf1[4], &wf2[4], DICO3_SIZE); move16 (); indice[3] = Vq_subvec (&lsf_r1[6], &lsf_r2[6], dico4_lsf, &wf1[6], &wf2[6], DICO4_SIZE); move16 (); indice[4] = Vq_subvec (&lsf_r1[8], &lsf_r2[8], dico5_lsf, &wf1[8], &wf2[8], DICO5_SIZE); move16 (); /* Compute quantized LSFs and update the past quantized residual */ /* In case of no speech activity, skip computing the quantized LSFs, and set past_r2_q to zero (initial value) */ logic16 (); test (); if ((txdtx_ctrl & TX_SP_FLAG) != 0) { for (i = 0; i < M; i++) { lsf1_q[i] = add (lsf_r1[i], lsf_p[i]); move16 (); lsf2_q[i] = add (lsf_r2[i], lsf_p[i]); move16 (); past_r2_q[i] = lsf_r2[i]; move16 (); } /* verification that LSFs has minimum distance of LSF_GAP */ Reorder_lsf (lsf1_q, LSF_GAP, M); Reorder_lsf (lsf2_q, LSF_GAP, M); /* Update LSF history with quantized LSFs when hangover period is active */ logic16 (); test (); if ((txdtx_ctrl & TX_HANGOVER_ACTIVE) != 0) { update_lsf_history (lsf1_q, lsf2_q, lsf_old_tx); } /* convert LSFs to the cosine domain */ Lsf_lsp (lsf1_q, lsp1_q, M); Lsf_lsp (lsf2_q, lsp2_q, M); } else { for (i = 0; i < M; i++) { past_r2_q[i] = 0; move16 (); } } return; } /* Quantization of a 4 dimensional subvector */ Word16 Vq_subvec ( /* output: return quantization index */ Word16 *lsf_r1, /* input : 1st LSF residual vector */ Word16 *lsf_r2, /* input : and LSF residual vector */ const Word16 *dico, /* input : quantization codebook */ Word16 *wf1, /* input : 1st LSF weighting factors */ Word16 *wf2, /* input : 2nd LSF weighting factors */ Word16 dico_size /* input : size of quantization codebook */ ) { Word16 i, index, temp; const Word16 *p_dico; Word32 dist_min, dist; dist_min = MAX_32; move32 (); p_dico = dico; move16 (); for (i = 0; i < dico_size; i++) { temp = sub (lsf_r1[0], *p_dico++); temp = mult (wf1[0], temp); dist = L_mult (temp, temp); temp = sub (lsf_r1[1], *p_dico++); temp = mult (wf1[1], temp); dist = L_mac (dist, temp, temp); temp = sub (lsf_r2[0], *p_dico++); temp = mult (wf2[0], temp); dist = L_mac (dist, temp, temp); temp = sub (lsf_r2[1], *p_dico++); temp = mult (wf2[1], temp); dist = L_mac (dist, temp, temp); test (); if (L_sub (dist, dist_min) < (Word32) 0) { dist_min = dist; move32 (); index = i; move16 (); } } /* Reading the selected vector */ p_dico = &dico[shl (index, 2)]; move16 (); lsf_r1[0] = *p_dico++; move16 (); lsf_r1[1] = *p_dico++; move16 (); lsf_r2[0] = *p_dico++; move16 (); lsf_r2[1] = *p_dico++; move16 (); return index; } /* Quantization of a 4 dimensional subvector with a signed codebook */ Word16 Vq_subvec_s ( /* output: return quantization index */ Word16 *lsf_r1, /* input : 1st LSF residual vector */ Word16 *lsf_r2, /* input : and LSF residual vector */ const Word16 *dico, /* input : quantization codebook */ Word16 *wf1, /* input : 1st LSF weighting factors */ Word16 *wf2, /* input : 2nd LSF weighting factors */ Word16 dico_size) /* input : size of quantization codebook */ { Word16 i, index, sign, temp; const Word16 *p_dico; Word32 dist_min, dist; dist_min = MAX_32; move32 (); p_dico = dico; move16 (); for (i = 0; i < dico_size; i++) { /* test positive */ temp = sub (lsf_r1[0], *p_dico++); temp = mult (wf1[0], temp); dist = L_mult (temp, temp); temp = sub (lsf_r1[1], *p_dico++); temp = mult (wf1[1], temp); dist = L_mac (dist, temp, temp); temp = sub (lsf_r2[0], *p_dico++); temp = mult (wf2[0], temp); dist = L_mac (dist, temp, temp); temp = sub (lsf_r2[1], *p_dico++); temp = mult (wf2[1], temp); dist = L_mac (dist, temp, temp); test (); if (L_sub (dist, dist_min) < (Word32) 0) { dist_min = dist; move32 (); index = i; move16 (); sign = 0; move16 (); } /* test negative */ p_dico -= 4; move16 (); temp = add (lsf_r1[0], *p_dico++); temp = mult (wf1[0], temp); dist = L_mult (temp, temp); temp = add (lsf_r1[1], *p_dico++); temp = mult (wf1[1], temp); dist = L_mac (dist, temp, temp); temp = add (lsf_r2[0], *p_dico++); temp = mult (wf2[0], temp); dist = L_mac (dist, temp, temp); temp = add (lsf_r2[1], *p_dico++); temp = mult (wf2[1], temp); dist = L_mac (dist, temp, temp); test (); if (L_sub (dist, dist_min) < (Word32) 0) { dist_min = dist; move32 (); index = i; move16 (); sign = 1; move16 (); } } /* Reading the selected vector */ p_dico = &dico[shl (index, 2)]; move16 (); test (); if (sign == 0) { lsf_r1[0] = *p_dico++; move16 (); lsf_r1[1] = *p_dico++; move16 (); lsf_r2[0] = *p_dico++; move16 (); lsf_r2[1] = *p_dico++; move16 (); } else { lsf_r1[0] = negate (*p_dico++); move16 (); lsf_r1[1] = negate (*p_dico++); move16 (); lsf_r2[0] = negate (*p_dico++); move16 (); lsf_r2[1] = negate (*p_dico++); move16 (); } index = shl (index, 1); index = add (index, sign); return index; } /**************************************************** * FUNCTION Lsf_wt * * * **************************************************** * Compute LSF weighting factors * * * * d[i] = lsf[i+1] - lsf[i-1] * * * * The weighting factors are approximated by two line segment. * * * * First segment passes by the following 2 points: * * * * d[i] = 0Hz wf[i] = 3.347 * * d[i] = 450Hz wf[i] = 1.8 * * * * Second segment passes by the following 2 points: * * * * d[i] = 450Hz wf[i] = 1.8 * * d[i] = 1500Hz wf[i] = 1.0 * * * * if( d[i] < 450Hz ) * * wf[i] = 3.347 - ( (3.347-1.8) / (450-0)) * d[i] * * else * * wf[i] = 1.8 - ( (1.8-1.0) / (1500-450)) * (d[i] - 450) * * * * * * if( d[i] < 1843) * * wf[i] = 3427 - (28160*d[i])>>15 * * else * * wf[i] = 1843 - (6242*(d[i]-1843))>>15 * * * *--------------------------------------------------------------------------*/ void Lsf_wt ( Word16 *lsf, /* input : LSF vector */ Word16 *wf) /* output: square of weighting factors */ { Word16 temp; Word16 i; /* wf[0] = lsf[1] - 0 */ wf[0] = lsf[1]; move16 (); for (i = 1; i < 9; i++) { wf[i] = sub (lsf[i + 1], lsf[i - 1]); move16 (); } /* wf[9] = 0.5 - lsf[8] */ wf[9] = sub (16384, lsf[8]);move16 (); for (i = 0; i < 10; i++) { temp = sub (wf[i], 1843); test (); if (temp < 0) { wf[i] = sub (3427, mult (wf[i], 28160)); move16 (); } else { wf[i] = sub (1843, mult (temp, 6242)); move16 (); } wf[i] = shl (wf[i], 3); move16 (); } return; }