FreeCalypso > hg > gsm-codec-lib
view libtwamr/d_plsf_3.c @ 501:597b39aef484
libgsmhr1/mathhalf.h: rm unused declarations
for non-saturating functions
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Wed, 19 Jun 2024 00:54:44 +0000 |
parents | 05a46720af0f |
children |
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/* ******************************************************************************** * * GSM AMR-NB speech codec R98 Version 7.6.0 December 12, 2001 * R99 Version 3.3.0 * REL-4 Version 4.1.0 * ******************************************************************************** * * File : d_plsf_3.c * Purpose : Decodes the LSP parameters using the received * quantization indices. 1st order MA prediction and * split by 3 vector quantization (split-VQ) * ******************************************************************************** */ /* ******************************************************************************** * MODULE INCLUDE FILE AND VERSION ID ******************************************************************************** */ #include "namespace.h" #include "d_plsf.h" /* ******************************************************************************** * INCLUDE FILES ******************************************************************************** */ #include "typedef.h" #include "basic_op.h" #include "no_count.h" #include "lsp_lsf.h" #include "reorder.h" #include "memops.h" #include "q_plsf3_tab.h" /* ******************************************************************************** * LOCAL VARIABLES AND TABLES ******************************************************************************** */ /* ALPHA -> 0.9 */ /* ONE_ALPHA-> (1.0-ALPHA) */ #define ALPHA 29491 #define ONE_ALPHA 3277 /* ******************************************************************************** * PUBLIC PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: D_plsf_3() * * PURPOSE: Decodes the LSP parameters using the received quantization * indices.1st order MA prediction and split by 3 vector * quantization (split-VQ) * *************************************************************************/ void D_plsf_3( D_plsfState *st, /* i/o: State struct */ enum Mode mode, /* i : coder mode */ Word16 bfi, /* i : bad frame indicator (set to 1 if a */ /* bad frame is received) */ Word16 * indice, /* i : quantization indices of 3 submatrices, Q0 */ Word16 * lsp1_q /* o : quantized 1st LSP vector, Q15 */ ) { Word16 i, index; const Word16 *p_cb1, *p_cb2, *p_cb3, *p_dico; Word16 temp; Word16 lsf1_r[M]; Word16 lsf1_q[M]; test (); if (bfi != 0) /* if bad frame */ { /* use the past LSFs slightly shifted towards their mean */ for (i = 0; i < M; i++) { /* lsfi_q[i] = ALPHA*past_lsf_q[i] + ONE_ALPHA*mean_lsf3[i]; */ lsf1_q[i] = add(mult(st->past_lsf_q[i], ALPHA), mult(mean_lsf3[i], ONE_ALPHA)); move16 (); } /* estimate past quantized residual to be used in next frame */ test(); if (sub(mode, MRDTX) != 0) { for (i = 0; i < M; i++) { /* temp = mean_lsf3[i] + past_r2_q[i] * PRED_FAC; */ temp = add(mean_lsf3[i], mult(st->past_r_q[i], pred_fac[i])); st->past_r_q[i] = sub(lsf1_q[i], temp); move16 (); } } else { for (i = 0; i < M; i++) { /* temp = mean_lsf3[i] + past_r2_q[i]; */ temp = add(mean_lsf3[i], st->past_r_q[i]); st->past_r_q[i] = sub(lsf1_q[i], temp); move16 (); } } } else /* if good LSFs received */ { test (); test (); if (sub (mode, MR475) == 0 || sub (mode, MR515) == 0) { /* MR475, MR515 */ p_cb1 = dico1_lsf3; move16 (); p_cb2 = dico2_lsf3; move16 (); p_cb3 = mr515_3_lsf; move16 (); } else if (sub (mode, MR795) == 0) { /* MR795 */ test(); p_cb1 = mr795_1_lsf; move16 (); p_cb2 = dico2_lsf3; move16 (); p_cb3 = dico3_lsf3; move16 (); } else { /* MR59, MR67, MR74, MR102, MRDTX */ test(); p_cb1 = dico1_lsf3; move16 (); p_cb2 = dico2_lsf3; move16 (); p_cb3 = dico3_lsf3; move16 (); } /* decode prediction residuals from 3 received indices */ index = *indice++; move16 (); p_dico = &p_cb1[add(index, add(index, index))]; move16 (); lsf1_r[0] = *p_dico++; move16 (); lsf1_r[1] = *p_dico++; move16 (); lsf1_r[2] = *p_dico++; move16 (); index = *indice++; move16 (); test (); test (); if ((sub (mode, MR475) == 0) || (sub (mode, MR515) == 0)) { /* MR475, MR515 only using every second entry */ index = shl(index,1); } p_dico = &p_cb2[add(index, add(index, index))]; move16 (); lsf1_r[3] = *p_dico++; move16 (); lsf1_r[4] = *p_dico++; move16 (); lsf1_r[5] = *p_dico++; move16 (); index = *indice++; move16 (); p_dico = &p_cb3[shl(index, 2)]; move16 (); lsf1_r[6] = *p_dico++; move16 (); lsf1_r[7] = *p_dico++; move16 (); lsf1_r[8] = *p_dico++; move16 (); lsf1_r[9] = *p_dico++; move16 (); /* Compute quantized LSFs and update the past quantized residual */ if (sub(mode, MRDTX) != 0) for (i = 0; i < M; i++) { temp = add(mean_lsf3[i], mult(st->past_r_q[i], pred_fac[i])); lsf1_q[i] = add(lsf1_r[i], temp); move16 (); st->past_r_q[i] = lsf1_r[i]; move16 (); } else for (i = 0; i < M; i++) { temp = add(mean_lsf3[i], st->past_r_q[i]); lsf1_q[i] = add(lsf1_r[i], temp); move16 (); st->past_r_q[i] = lsf1_r[i]; move16 (); } } /* verification that LSFs has minimum distance of LSF_GAP Hz */ Reorder_lsf(lsf1_q, LSF_GAP, M); Copy (lsf1_q, st->past_lsf_q, M); /* convert LSFs to the cosine domain */ Lsf_lsp(lsf1_q, lsp1_q, M); return; } void Init_D_plsf_3(D_plsfState *st, /* i/o: State struct */ Word16 index /* i : past_rq_init[] index [0, 7] */) { Copy(&past_rq_init[index * M], st->past_r_q, M); }