FreeCalypso > hg > gsm-codec-lib
view libtwamr/c8_31pf.c @ 483:4f13db3a7086
doc/Utils-overview: document new utilities
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Mon, 20 May 2024 01:26:12 +0000 |
parents | dfd5f159574b |
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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 : c8_31pf.c * Purpose : Searches a 31 bit algebraic codebook containing * : 8 pulses in a frame of 40 samples. * : in the same manner as GSM-EFR * ******************************************************************************** */ /* ******************************************************************************** * MODULE INCLUDE FILE AND VERSION ID ******************************************************************************** */ #include "namespace.h" #include "c8_31pf.h" /* ******************************************************************************** * INCLUDE FILES ******************************************************************************** */ #include "typedef.h" #include "basic_op.h" #include "no_count.h" #include "cnst.h" #include "inv_sqrt.h" #include "cor_h.h" #include "set_sign.h" #include "s10_8pf.h" /* ******************************************************************************** * LOCAL VARIABLES AND TABLES ******************************************************************************** */ #define NB_PULSE 8 /* define values/representation for output codevector and sign */ #define POS_CODE 8191 #define NEG_CODE 8191 #define POS_SIGN 32767 #define NEG_SIGN (Word16) (-32768L) /* ******************************************************************************** * LOCAL PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: build_code() * * PURPOSE: Builds the codeword, the filtered codeword and a * linear uncombined version of the index of the * codevector, based on the signs and positions of 8 pulses. * *************************************************************************/ static void build_code ( Word16 codvec[], /* i : position of pulses */ Word16 sign[], /* i : sign of d[n] */ Word16 cod[], /* o : innovative code vector */ Word16 h[], /* i : impulse response of weighted synthesis filter*/ Word16 y[], /* o : filtered innovative code */ Word16 sign_indx[], /* o : signs of 4 pulses (signs only) */ Word16 pos_indx[] /* o : position index of 8 pulses(position only) */ ) { Word16 i, j, k, track, sign_index, pos_index, _sign[NB_PULSE]; Word16 *p0, *p1, *p2, *p3, *p4, *p5, *p6, *p7; Word32 s; for (i = 0; i < L_CODE; i++) { cod[i] = 0; move16 (); } for (i = 0; i < NB_TRACK_MR102; i++) { pos_indx[i] = -1; move16 (); sign_indx[i] = -1; move16 (); } for (k = 0; k < NB_PULSE; k++) { /* read pulse position */ i = codvec[k]; move16 (); /* read sign */ j = sign[i]; move16 (); pos_index = shr(i, 2); /* index = pos/4 */ track = i & 3; logic16 (); /* track = pos%4 */ test (); if (j > 0) { cod[i] = add (cod[i], POS_CODE); move16 (); _sign[k] = POS_SIGN; move16 (); sign_index = 0; /* bit=0 -> positive pulse */ move16 (); } else { cod[i] = sub (cod[i], NEG_CODE); move16 (); _sign[k] = NEG_SIGN; move16 (); sign_index = 1; move16 (); /* bit=1 => negative pulse */ /* index = add (index, 8); 1 = negative old code */ } test (); move16 (); if (pos_indx[track] < 0) { /* first set first NB_TRACK pulses */ pos_indx[track] = pos_index; move16 (); sign_indx[track] = sign_index; move16 (); } else { /* 2nd row of pulses , test if positions needs to be switched */ test (); logic16 (); logic16 (); if (((sign_index ^ sign_indx[track]) & 1) == 0) { /* sign of 1st pulse == sign of 2nd pulse */ test (); if (sub (pos_indx[track], pos_index) <= 0) { /* no swap */ pos_indx[track + NB_TRACK_MR102] = pos_index; move16 (); } else { /* swap*/ pos_indx[track + NB_TRACK_MR102] = pos_indx[track]; move16 (); pos_indx[track] = pos_index; move16 (); sign_indx[track] = sign_index; move16 (); } } else { /* sign of 1st pulse != sign of 2nd pulse */ test (); if (sub (pos_indx[track], pos_index) <= 0) { /*swap*/ pos_indx[track + NB_TRACK_MR102] = pos_indx[track]; move16 (); pos_indx[track] = pos_index; move16 (); sign_indx[track] = sign_index; move16 (); } else { /*no swap */ pos_indx[track + NB_TRACK_MR102] = pos_index; move16 (); } } } } p0 = h - codvec[0]; move16 (); p1 = h - codvec[1]; move16 (); p2 = h - codvec[2]; move16 (); p3 = h - codvec[3]; move16 (); p4 = h - codvec[4]; move16 (); p5 = h - codvec[5]; move16 (); p6 = h - codvec[6]; move16 (); p7 = h - codvec[7]; 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]); s = L_mac (s, *p3++, _sign[3]); s = L_mac (s, *p4++, _sign[4]); s = L_mac (s, *p5++, _sign[5]); s = L_mac (s, *p6++, _sign[6]); s = L_mac (s, *p7++, _sign[7]); y[i] = round (s); move16 (); } } /************************************************************************* * * FUNCTION: compress_code() * * PURPOSE: compression of three indeces [0..9] to one 10 bit index * minimizing the phase shift of a bit error. * *************************************************************************/ static Word16 compress10 ( Word16 pos_indxA, /* i : signs of 4 pulses (signs only) */ Word16 pos_indxB, /* i : position index of 8 pulses (pos only) */ Word16 pos_indxC) /* i : position and sign of 8 pulses (compressed) */ { Word16 indx, ia,ib,ic; ia = shr(pos_indxA, 1); ib = extract_l(L_shr(L_mult(shr(pos_indxB, 1), 5), 1)); ic = extract_l(L_shr(L_mult(shr(pos_indxC, 1), 25), 1)); indx = shl(add(ia, add(ib, ic)), 3); ia = pos_indxA & 1; logic16 (); ib = shl((pos_indxB & 1), 1); logic16 (); ic = shl((pos_indxC & 1), 2); logic16 (); indx = add(indx , add(ia, add(ib, ic))); return indx; } /************************************************************************* * * FUNCTION: compress_code() * * PURPOSE: compression of the linear codewords to 4+three indeces * one bit from each pulse is made robust to errors by * minimizing the phase shift of a bit error. * 4 signs (one for each track) * i0,i4,i1 => one index (7+3) bits, 3 LSBs more robust * i2,i6,i5 => one index (7+3) bits, 3 LSBs more robust * i3,i7 => one index (5+2) bits, 2-3 LSbs more robust * *************************************************************************/ static void compress_code ( Word16 sign_indx[], /* i : signs of 4 pulses (signs only) */ Word16 pos_indx[], /* i : position index of 8 pulses (position only) */ Word16 indx[]) /* o : position and sign of 8 pulses (compressed) */ { Word16 i, ia, ib, ic; for (i = 0; i < NB_TRACK_MR102; i++) { indx[i] = sign_indx[i]; move16 (); } /* First index indx[NB_TRACK] = (ia/2+(ib/2)*5 +(ic/2)*25)*8 + ia%2 + (ib%2)*2 + (ic%2)*4; */ move16 (); indx[NB_TRACK_MR102] = compress10(pos_indx[0],pos_indx[4],pos_indx[1]); /* Second index indx[NB_TRACK+1] = (ia/2+(ib/2)*5 +(ic/2)*25)*8 + ia%2 + (ib%2)*2 + (ic%2)*4; */ move16 (); indx[NB_TRACK_MR102+1]= compress10(pos_indx[2],pos_indx[6],pos_indx[5]); /* Third index if ((ib/2)%2 == 1) indx[NB_TRACK+2] = ((((4-ia/2) + (ib/2)*5)*32+12)/25)*4 + ia%2 + (ib%2)*2; else indx[NB_TRACK+2] = ((((ia/2) + (ib/2)*5)*32+12)/25)*4 + ia%2 + (ib%2)*2; */ ib = shr(pos_indx[7], 1) & 1; logic16 (); test (); if (sub(ib, 1) == 0) ia = sub(4, shr(pos_indx[3], 1)); else ia = shr(pos_indx[3], 1); ib = extract_l(L_shr(L_mult(shr(pos_indx[7], 1), 5), 1)); ib = add(shl(add(ia, ib), 5), 12); ic = shl(mult(ib, 1311), 2); ia = pos_indx[3] & 1; logic16 (); ib = shl((pos_indx[7] & 1), 1); logic16 (); indx[NB_TRACK_MR102+2] = add(ia, add(ib, ic)); } /* ******************************************************************************** * PUBLIC PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: code_8i40_31bits() * * PURPOSE: Searches a 31 bit algebraic codebook containing 8 pulses * in a frame of 40 samples. * * DESCRIPTION: * The code contains 8 nonzero pulses: i0...i7. * All pulses can have two possible amplitudes: +1 or -1. * The 40 positions in a subframe are divided into 4 tracks of * interleaved positions. Each track contains two pulses. * The pulses can have the following possible positions: * * i0, i4 : 0, 4, 8, 12, 16, 20, 24, 28, 32, 36 * i1, i5 : 1, 5, 9, 13, 17, 21, 25, 29, 33, 37 * i2, i6 : 2, 6, 10, 14, 18, 22, 26, 30, 34, 38 * i3, i7 : 3, 7, 11, 15, 19, 23, 27, 31, 35, 39 * * Each pair of pulses require 1 bit for their signs. The positions * are encoded together 3,3 and 2 resulting in * (7+3) + (7+3) + (5+2) bits for their * positions. This results in a 31 (4 sign and 27 pos) bit codebook. * The function determines the optimal pulse signs and positions, builds * the codevector, and computes the filtered codevector. * *************************************************************************/ void code_8i40_31bits ( Word16 x[], /* i : target vector */ Word16 cn[], /* i : residual after long term prediction */ Word16 h[], /* i : impulse response of weighted synthesis filter */ Word16 cod[], /* o : algebraic (fixed) codebook excitation */ Word16 y[], /* o : filtered fixed codebook excitation */ Word16 indx[] /* o : 7 Word16, index of 8 pulses (signs+positions) */ ) { Word16 ipos[NB_PULSE], pos_max[NB_TRACK_MR102], codvec[NB_PULSE]; Word16 dn[L_CODE], sign[L_CODE]; Word16 rr[L_CODE][L_CODE]; Word16 linear_signs[NB_TRACK_MR102]; Word16 linear_codewords[NB_PULSE]; cor_h_x2 (h, x, dn, 2, NB_TRACK_MR102, STEP_MR102); /* 2 = use GSMEFR scaling */ set_sign12k2 (dn, cn, sign, pos_max, NB_TRACK_MR102, ipos, STEP_MR102); /* same setsign alg as GSM-EFR new constants though*/ cor_h (h, sign, rr); search_10and8i40 (NB_PULSE, STEP_MR102, NB_TRACK_MR102, dn, rr, ipos, pos_max, codvec); build_code (codvec, sign, cod, h, y, linear_signs, linear_codewords); compress_code (linear_signs, linear_codewords, indx); return; }