FreeCalypso > hg > gsm-codec-lib
view libtwamr/c3_14pf.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 | 5fc9a2d12048 |
| children |
line wrap: on
line source
/* ******************************************************************************** * * 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 : c3_14pf.c * Purpose : Searches a 14 bit algebraic codebook containing 3 pulses * in a frame of 40 samples. * ******************************************************************************** */ /* ******************************************************************************** * MODULE INCLUDE FILE AND VERSION ID ******************************************************************************** */ #include "namespace.h" #include "c3_14pf.h" /* ******************************************************************************** * INCLUDE FILES ******************************************************************************** */ #include "typedef.h" #include "basic_op.h" #include "no_count.h" #include "inv_sqrt.h" #include "cnst.h" #include "cor_h.h" #include "set_sign.h" /* ******************************************************************************** * LOCAL VARIABLES AND TABLES ******************************************************************************** */ #define NB_PULSE 3 /* ******************************************************************************** * DECLARATION OF PROTOTYPES ******************************************************************************** */ static void search_3i40( Word16 dn[], /* i : correlation between target and h[] */ Word16 dn2[], /* i : maximum of corr. in each track. */ Word16 rr[][L_CODE],/* i : matrix of autocorrelation */ Word16 codvec[] /* o : algebraic codebook vector */ ); static Word16 build_code( Word16 codvec[], /* i : algebraic codebook vector */ Word16 dn_sign[], /* i : sign of dn[] */ Word16 cod[], /* o : algebraic (fixed) codebook excitation */ Word16 h[], /* i : impulse response of weighted synthesis filter */ Word16 y[], /* o : filtered fixed codebook excitation */ Word16 sign[] /* o : sign of 3 pulses */ ); /* ******************************************************************************** * PUBLIC PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: code_3i40_14bits() * * PURPOSE: Searches a 14 bit algebraic codebook containing 3 pulses * in a frame of 40 samples. * * DESCRIPTION: * The code length is 40, containing 3 nonzero pulses: i0...i2. * All pulses can have two possible amplitudes: +1 or -1. * Pulse i0 can have 8 possible positions, pulses i1 and i2 can have * 2x8=16 positions. * * i0 : 0, 5, 10, 15, 20, 25, 30, 35. * i1 : 1, 6, 11, 16, 21, 26, 31, 36. * 3, 8, 13, 18, 23, 28, 33, 38. * i2 : 2, 7, 12, 17, 22, 27, 32, 37. * 4, 9, 14, 19, 24, 29, 34, 39. * *************************************************************************/ Word16 code_3i40_14bits( Word16 x[], /* i : target vector */ Word16 h[], /* i : impulse response of weighted synthesis filter */ /* h[-L_subfr..-1] must be set to zero. */ Word16 T0, /* i : Pitch lag */ Word16 pitch_sharp, /* i : Last quantized pitch gain */ Word16 code[], /* o : Innovative codebook */ Word16 y[], /* o : filtered fixed codebook excitation */ Word16 * sign /* o : Signs of 3 pulses */ ) { Word16 codvec[NB_PULSE]; Word16 dn[L_CODE], dn2[L_CODE], dn_sign[L_CODE]; Word16 rr[L_CODE][L_CODE]; Word16 i, index, sharp; sharp = shl(pitch_sharp, 1); test (); if (sub(T0, L_CODE) < 0) { for (i = T0; i < L_CODE; i++) { h[i] = add(h[i], mult(h[i - T0], sharp)); move16 (); } } cor_h_x(h, x, dn, 1); set_sign(dn, dn_sign, dn2, 6); cor_h(h, dn_sign, rr); search_3i40(dn, dn2, rr, codvec); move16 (); /* function result */ index = build_code(codvec, dn_sign, code, h, y, sign); /*-----------------------------------------------------------------* * Compute innovation vector gain. * * Include fixed-gain pitch contribution into code[]. * *-----------------------------------------------------------------*/ test (); if (sub(T0, L_CODE) < 0) { for (i = T0; i < L_CODE; i++) { code[i] = add(code[i], mult(code[i - T0], sharp)); move16 (); } } return index; } /* ******************************************************************************** * PRIVATE PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION search_3i40() * * PURPOSE: Search the best codevector; determine positions of the 3 pulses * in the 40-sample frame. * *************************************************************************/ #define _1_2 (Word16)(32768L/2) #define _1_4 (Word16)(32768L/4) #define _1_8 (Word16)(32768L/8) #define _1_16 (Word16)(32768L/16) static void search_3i40( Word16 dn[], /* i : correlation between target and h[] */ Word16 dn2[], /* i : maximum of corr. in each track. */ Word16 rr[][L_CODE], /* i : matrix of autocorrelation */ Word16 codvec[] /* o : algebraic codebook vector */ ) { Word16 i0, i1, i2; Word16 ix = 0; /* initialization only needed to keep gcc silent */ Word16 ps = 0; /* initialization only needed to keep gcc silent */ Word16 i, pos, track1, track2, ipos[NB_PULSE]; Word16 psk, ps0, ps1, sq, sq1; Word16 alpk, alp, alp_16; Word32 s, alp0, alp1; psk = -1; move16 (); alpk = 1; move16 (); for (i = 0; i < NB_PULSE; i++) { codvec[i] = i; move16 (); } for (track1 = 1; track1 < 4; track1 += 2) { for (track2 = 2; track2 < 5; track2 += 2) { /* fix starting position */ ipos[0] = 0; move16 (); ipos[1] = track1; move16 (); ipos[2] = track2; move16 (); /*------------------------------------------------------------------* * main loop: try 3 tracks. * *------------------------------------------------------------------*/ for (i = 0; i < NB_PULSE; i++) { /*----------------------------------------------------------------* * i0 loop: try 8 positions. * *----------------------------------------------------------------*/ move16 (); /* account for ptr. init. (rr[io]) */ for (i0 = ipos[0]; i0 < L_CODE; i0 += STEP) { test (); if (dn2[i0] >= 0) { ps0 = dn[i0]; move16 (); alp0 = L_mult(rr[i0][i0], _1_4); /*----------------------------------------------------------------* * i1 loop: 8 positions. * *----------------------------------------------------------------*/ sq = -1; move16 (); alp = 1; move16 (); ps = 0; move16 (); ix = ipos[1]; move16 (); /* initialize 4 index for next loop. */ /*-------------------------------------------------------------------* * These index have low complexity address computation because * * they are, in fact, pointers with fixed increment. For example, * * "rr[i0][i2]" is a pointer initialized to "&rr[i0][ipos[2]]" * * and incremented by "STEP". * *-------------------------------------------------------------------*/ move16 (); /* account for ptr. init. (rr[i1]) */ move16 (); /* account for ptr. init. (dn[i1]) */ move16 (); /* account for ptr. init. (rr[io]) */ for (i1 = ipos[1]; i1 < L_CODE; i1 += STEP) { ps1 = add(ps0, dn[i1]); /* idx increment = STEP */ /* alp1 = alp0 + rr[i0][i1] + 1/2*rr[i1][i1]; */ alp1 = L_mac(alp0, rr[i1][i1], _1_4); /* idx incr = STEP */ alp1 = L_mac(alp1, rr[i0][i1], _1_2); /* idx incr = STEP */ sq1 = mult(ps1, ps1); alp_16 = round(alp1); s = L_msu(L_mult(alp, sq1), sq, alp_16); test (); if (s > 0) { sq = sq1; move16 (); ps = ps1; move16 (); alp = alp_16; move16 (); ix = i1; move16 (); } } i1 = ix; move16 (); /*----------------------------------------------------------------* * i2 loop: 8 positions. * *----------------------------------------------------------------*/ ps0 = ps; move16 (); alp0 = L_mult(alp, _1_4); sq = -1; move16 (); alp = 1; move16 (); ps = 0; move16 (); ix = ipos[2]; move16 (); /* initialize 4 index for next loop (see i1 loop) */ move16 (); /* account for ptr. init. (rr[i2]) */ move16 (); /* account for ptr. init. (rr[i1]) */ move16 (); /* account for ptr. init. (dn[i2]) */ move16 (); /* account for ptr. init. (rr[io]) */ for (i2 = ipos[2]; i2 < L_CODE; i2 += STEP) { ps1 = add(ps0, dn[i2]); /* index increment = STEP */ /* alp1 = alp0 + rr[i0][i2] + rr[i1][i2] + 1/2*rr[i2][i2]; */ alp1 = L_mac(alp0, rr[i2][i2], _1_16); /* idx incr = STEP */ alp1 = L_mac(alp1, rr[i1][i2], _1_8); /* idx incr = STEP */ alp1 = L_mac(alp1, rr[i0][i2], _1_8); /* idx incr = STEP */ sq1 = mult(ps1, ps1); alp_16 = round(alp1); s = L_msu(L_mult(alp, sq1), sq, alp_16); test (); if (s > 0) { sq = sq1; move16 (); ps = ps1; move16 (); alp = alp_16; move16 (); ix = i2; move16 (); } } i2 = ix; move16 (); /*----------------------------------------------------------------* * memorise codevector if this one is better than the last one. * *----------------------------------------------------------------*/ s = L_msu(L_mult(alpk, sq), psk, alp); test (); if (s > 0) { psk = sq; move16 (); alpk = alp; move16 (); codvec[0] = i0; move16 (); codvec[1] = i1; move16 (); codvec[2] = i2; move16 (); } } } /*----------------------------------------------------------------* * Cyclic permutation of i0, i1 and i2. * *----------------------------------------------------------------*/ pos = ipos[2]; move16 (); ipos[2] = ipos[1]; move16 (); ipos[1] = ipos[0]; move16 (); ipos[0] = pos; move16 (); } } } return; } /************************************************************************* * * FUNCTION: build_code() * * PURPOSE: Builds the codeword, the filtered codeword and index of the * codevector, based on the signs and positions of 3 pulses. * *************************************************************************/ static Word16 build_code( Word16 codvec[], /* i : position of pulses */ Word16 dn_sign[], /* i : sign of pulses */ Word16 cod[], /* o : innovative code vector */ Word16 h[], /* i : impulse response of weighted synthesis filter */ Word16 y[], /* o : filtered innovative code */ Word16 sign[] /* o : sign of 3 pulses */ ) { Word16 i, j, k, track, index, _sign[NB_PULSE], indx, rsign; Word16 *p0, *p1, *p2; Word32 s; for (i = 0; i < L_CODE; i++) { cod[i] = 0; move16 (); } indx = 0; move16 (); rsign = 0; move16 (); for (k = 0; k < NB_PULSE; k++) { i = codvec[k]; move16 (); /* read pulse position */ j = dn_sign[i]; move16 (); /* read sign */ index = mult(i, 6554); /* index = pos/5 */ /* track = pos%5 */ track = sub(i, extract_l(L_shr(L_mult(index, 5), 1))); test (); if (sub(track, 1) == 0) index = shl(index, 4); else if (sub(track, 2) == 0) { test (); track = 2; move16 (); index = shl(index, 8); } else if (sub(track, 3) == 0) { test (); test (); track = 1; move16 (); index = add(shl(index, 4), 8); } else if (sub(track, 4) == 0) { test (); test (); test (); track = 2; move16 (); index = add(shl(index, 8), 128); } test (); if (j > 0) { cod[i] = 8191; move16 (); _sign[k] = 32767; move16 (); rsign = add(rsign, shl(1, track)); } else { cod[i] = -8192; move16 (); _sign[k] = (Word16) - 32768L; move16 (); } indx = add(indx, index); } *sign = rsign; move16 (); p0 = h - codvec[0]; move16 (); p1 = h - codvec[1]; move16 (); p2 = h - codvec[2]; move16 (); for (i = 0; i < L_CODE; i++) { s = 0; move32 (); s = L_mac(s, *p0++, _sign[0]); s = L_mac(s, *p1++, _sign[1]); s = L_mac(s, *p2++, _sign[2]); y[i] = round(s); move16 (); } return indx; }