FreeCalypso > hg > gsm-codec-lib
view libgsmefr/d_plsf_5.c @ 585:3c6bf0d26ee7 default tip
TW-TS-005 reader: fix maximum line length bug
TW-TS-005 section 4.1 states:
The maximum allowed length of each line is 80 characters, not
including the OS-specific newline encoding.
The implementation of this line length limit in the TW-TS-005 hex file
reader function in the present suite was wrong, such that lines of
the full maximum length could not be read. Fix it.
Note that this bug affects comment lines too, not just actual RTP
payloads. Neither Annex A nor Annex B features an RTP payload format
that goes to the maximum of 40 bytes, but if a comment line goes to
the maximum allowed length of 80 characters not including the
terminating newline, the bug will be triggered, necessitating
the present fix.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Tue, 25 Feb 2025 07:49:28 +0000 |
| parents | cc08498ed21b |
| children |
line wrap: on
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/************************************************************************* * * FUNCTION: D_plsf_5() * * PURPOSE: Decodes the 2 sets of LSP parameters in a frame using the * received quantization indices. * * DESCRIPTION: * The two sets of LSFs are quantized using split by 5 matrix * quantization (split-MQ) with 1st order MA prediction. * * See "q_plsf_5.c" for more details about the quantization procedure * *************************************************************************/ #include "gsm_efr.h" #include "typedef.h" #include "namespace.h" #include "basic_op.h" #include "no_count.h" #include "codec.h" #include "sig_proc.h" #include "memops.h" #include "q_plsf5_tab.h" /* Codebooks of LSF prediction residual */ #include "cnst.h" #include "dtx.h" #include "dec_state.h" /* M ->order of linear prediction filter */ /* LSF_GAP -> Minimum distance between LSF after quantization */ /* 50 Hz = 205 */ /* PRED_FAC -> Prediction factor = 0.65 */ /* ALPHA -> 0.9 */ /* ONE_ALPHA-> (1.0-ALPHA) */ #define M 10 #define LSF_GAP 205 #define PRED_FAC 21299 #define ALPHA 31128 #define ONE_ALPHA 1639 void D_plsf_5 ( struct EFR_decoder_state *st, const Word16 *indice, /* input : quantization indices of 5 submatrices */ Word16 *lsp1_q, /* output: quantized 1st LSP vector */ Word16 *lsp2_q, /* output: quantized 2nd LSP vector */ Word16 bfi, /* input : bad frame indicator (set to 1 if a bad frame is received) */ Word16 rxdtx_ctrl, /* input : RX DTX control word */ Word16 rx_dtx_state /* input : state of the comfort noise insertion period */ ) { Word16 i; const Word16 *p_dico; Word16 temp, sign; Word16 lsf1_r[M], lsf2_r[M]; Word16 lsf1_q[M], lsf2_q[M]; /* Update comfort noise LSF quantizer memory */ if ((rxdtx_ctrl & RX_UPD_SID_QUANT_MEM) != 0) { update_lsf_p_CN (st->lsf_old_rx, st->lsf_p_CN); } /* Handle cases of comfort noise LSF decoding in which past valid SID frames are repeated */ if (((rxdtx_ctrl & RX_NO_TRANSMISSION) != 0) || ((rxdtx_ctrl & RX_INVALID_SID_FRAME) != 0) || ((rxdtx_ctrl & RX_LOST_SID_FRAME) != 0)) { if ((rxdtx_ctrl & RX_NO_TRANSMISSION) != 0) { /* DTX active: no transmission. Interpolate LSF values in memory */ interpolate_CN_lsf (st->lsf_old_CN, st->lsf_new_CN, lsf2_q, rx_dtx_state); } else { /* Invalid or lost SID frame: use LSFs from last good SID frame */ for (i = 0; i < M; i++) { st->lsf_old_CN[i] = st->lsf_new_CN[i]; lsf2_q[i] = st->lsf_new_CN[i]; st->past_r2_q[i] = 0; } } for (i = 0; i < M; i++) { st->past_lsf_q[i] = lsf2_q[i]; } /* convert LSFs to the cosine domain */ Lsf_lsp (lsf2_q, lsp2_q, M); return; } 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_lsf[i]; */ lsf1_q[i] = add (mult (st->past_lsf_q[i], ALPHA), mult (mean_lsf[i], ONE_ALPHA)); lsf2_q[i] = lsf1_q[i]; } /* estimate past quantized residual to be used in next frame */ for (i = 0; i < M; i++) { /* temp = mean_lsf[i] + past_r2_q[i] * PRED_FAC; */ temp = add (mean_lsf[i], mult (st->past_r2_q[i], PRED_FAC)); st->past_r2_q[i] = sub (lsf2_q[i], temp); } } else /* if good LSFs received */ { /* decode prediction residuals from 5 received indices */ p_dico = &dico1_lsf[shl (indice[0], 2)]; lsf1_r[0] = *p_dico++; move16 (); lsf1_r[1] = *p_dico++; move16 (); lsf2_r[0] = *p_dico++; move16 (); lsf2_r[1] = *p_dico++; move16 (); p_dico = &dico2_lsf[shl (indice[1], 2)]; lsf1_r[2] = *p_dico++; move16 (); lsf1_r[3] = *p_dico++; move16 (); lsf2_r[2] = *p_dico++; move16 (); lsf2_r[3] = *p_dico++; move16 (); sign = indice[2] & 1; logic16 (); i = shr (indice[2], 1); p_dico = &dico3_lsf[shl (i, 2)]; move16 (); test (); if (sign == 0) { lsf1_r[4] = *p_dico++; move16 (); lsf1_r[5] = *p_dico++; move16 (); lsf2_r[4] = *p_dico++; move16 (); lsf2_r[5] = *p_dico++; move16 (); } else { lsf1_r[4] = negate (*p_dico++); move16 (); lsf1_r[5] = negate (*p_dico++); move16 (); lsf2_r[4] = negate (*p_dico++); move16 (); lsf2_r[5] = negate (*p_dico++); move16 (); } p_dico = &dico4_lsf[shl (indice[3], 2)];move16 (); lsf1_r[6] = *p_dico++; move16 (); lsf1_r[7] = *p_dico++; move16 (); lsf2_r[6] = *p_dico++; move16 (); lsf2_r[7] = *p_dico++; move16 (); p_dico = &dico5_lsf[shl (indice[4], 2)];move16 (); lsf1_r[8] = *p_dico++; move16 (); lsf1_r[9] = *p_dico++; move16 (); lsf2_r[8] = *p_dico++; move16 (); lsf2_r[9] = *p_dico++; move16 (); /* Compute quantized LSFs and update the past quantized residual */ /* Use lsf_p_CN as predicted LSF vector in case of no speech activity */ if ((rxdtx_ctrl & RX_SP_FLAG) != 0) { for (i = 0; i < M; i++) { temp = add (mean_lsf[i], mult (st->past_r2_q[i], PRED_FAC)); lsf1_q[i] = add (lsf1_r[i], temp); lsf2_q[i] = add (lsf2_r[i], temp); st->past_r2_q[i] = lsf2_r[i]; } } else { /* Valid SID frame */ for (i = 0; i < M; i++) { lsf2_q[i] = add (lsf2_r[i], st->lsf_p_CN[i]); /* Use the dequantized values of lsf2 also for lsf1 */ lsf1_q[i] = lsf2_q[i]; st->past_r2_q[i] = 0; } } } /* verification that LSFs have minimum distance of LSF_GAP Hz */ Reorder_lsf (lsf1_q, LSF_GAP, M); Reorder_lsf (lsf2_q, LSF_GAP, M); if ((rxdtx_ctrl & RX_FIRST_SID_UPDATE) != 0) { for (i = 0; i < M; i++) { st->lsf_new_CN[i] = lsf2_q[i]; } } if ((rxdtx_ctrl & RX_CONT_SID_UPDATE) != 0) { for (i = 0; i < M; i++) { st->lsf_old_CN[i] = st->lsf_new_CN[i]; st->lsf_new_CN[i] = lsf2_q[i]; } } if ((rxdtx_ctrl & RX_SP_FLAG) != 0) { /* Update lsf history with quantized LSFs when speech activity is present. If the current frame is a bad one, update with most recent good comfort noise LSFs */ if (bfi==0) { update_lsf_history (lsf1_q, lsf2_q, st->lsf_old_rx); } else { update_lsf_history (st->lsf_new_CN, st->lsf_new_CN, st->lsf_old_rx); } for (i = 0; i < M; i++) { st->lsf_old_CN[i] = lsf2_q[i]; } } else { interpolate_CN_lsf (st->lsf_old_CN, st->lsf_new_CN, lsf2_q, rx_dtx_state); } for (i = 0; i < M; i++) { st->past_lsf_q[i] = lsf2_q[i]; } /* convert LSFs to the cosine domain */ Lsf_lsp (lsf1_q, lsp1_q, M); Lsf_lsp (lsf2_q, lsp2_q, M); return; }