FreeCalypso > hg > gsm-codec-lib
view libtwamr/qgain795.c @ 498:65f672c43dc8
libgsmhr1/typedefs.h: import original
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Wed, 19 Jun 2024 00:49:48 +0000 |
parents | 2aa98051d445 |
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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 : qgain795.c * Purpose : pitch and codebook gain quantization for MR795 * ******************************************************************************** */ /* ******************************************************************************** * MODULE INCLUDE FILE AND VERSION ID ******************************************************************************** */ #include "namespace.h" #include "qgain795.h" /* ******************************************************************************** * INCLUDE FILES ******************************************************************************** */ #include "typedef.h" #include "basic_op.h" #include "oper_32b.h" #include "no_count.h" #include "cnst.h" #include "log2.h" #include "pow2.h" #include "sqrt_l.h" #include "g_adapt.h" #include "calc_en.h" #include "q_gain_p.h" #include "mac_32.h" #include "gains_tab.h" /* ******************************************************************************** * LOCAL PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: MR795_gain_code_quant3 * * PURPOSE: Pre-quantization of codebook gains, given three possible * LTP gains (using predicted codebook gain) * *************************************************************************/ static void MR795_gain_code_quant3( Word16 exp_gcode0, /* i : predicted CB gain (exponent), Q0 */ Word16 gcode0, /* i : predicted CB gain (norm.), Q14 */ Word16 g_pitch_cand[], /* i : Pitch gain candidates (3), Q14 */ Word16 g_pitch_cind[], /* i : Pitch gain cand. indices (3), Q0 */ Word16 frac_coeff[], /* i : coefficients (5), Q15 */ Word16 exp_coeff[], /* i : energy coefficients (5), Q0 */ /* coefficients from calc_filt_ener()*/ Word16 *gain_pit, /* o : Pitch gain, Q14 */ Word16 *gain_pit_ind, /* o : Pitch gain index, Q0 */ Word16 *gain_cod, /* o : Code gain, Q1 */ Word16 *gain_cod_ind, /* o : Code gain index, Q0 */ Word16 *qua_ener_MR122, /* o : quantized energy error, Q10 */ /* (for MR122 MA predictor update) */ Word16 *qua_ener /* o : quantized energy error, Q10 */ /* (for other MA predictor update) */ ) { const Word16 *p; Word16 i, j, cod_ind, pit_ind; Word16 e_max, exp_code; Word16 g_pitch, g2_pitch, g_code, g2_code_h, g2_code_l; Word16 g_pit_cod_h, g_pit_cod_l; Word16 coeff[5], coeff_lo[5]; Word16 exp_max[5]; Word32 L_tmp, L_tmp0, dist_min; /* * The error energy (sum) to be minimized consists of five terms, t[0..4]. * * t[0] = gp^2 * <y1 y1> * t[1] = -2*gp * <xn y1> * t[2] = gc^2 * <y2 y2> * t[3] = -2*gc * <xn y2> * t[4] = 2*gp*gc * <y1 y2> * */ /* determine the scaling exponent for g_code: ec = ec0 - 10 */ exp_code = sub(exp_gcode0, 10); /* calculate exp_max[i] = s[i]-1 */ exp_max[0] = sub(exp_coeff[0], 13); move16 (); exp_max[1] = sub(exp_coeff[1], 14); move16 (); exp_max[2] = add(exp_coeff[2], add(15, shl(exp_code, 1))); move16 (); exp_max[3] = add(exp_coeff[3], exp_code); move16 (); exp_max[4] = add(exp_coeff[4], add(exp_code,1)); move16 (); /*-------------------------------------------------------------------* * Find maximum exponent: * * ~~~~~~~~~~~~~~~~~~~~~~ * * * * For the sum operation, all terms must have the same scaling; * * that scaling should be low enough to prevent overflow. There- * * fore, the maximum scale is determined and all coefficients are * * re-scaled: * * * * e_max = max(exp_max[i]) + 1; * * e = exp_max[i]-e_max; e <= 0! * * c[i] = c[i]*2^e * *-------------------------------------------------------------------*/ e_max = exp_max[0]; move16 (); for (i = 1; i < 5; i++) /* implemented flattened */ { move16(); test(); if (sub(exp_max[i], e_max) > 0) { e_max = exp_max[i]; move16 (); } } e_max = add(e_max, 1); /* To avoid overflow */ for (i = 0; i < 5; i++) { j = sub(e_max, exp_max[i]); L_tmp = L_deposit_h(frac_coeff[i]); L_tmp = L_shr(L_tmp, j); L_Extract(L_tmp, &coeff[i], &coeff_lo[i]); } /*-------------------------------------------------------------------* * Codebook search: * * ~~~~~~~~~~~~~~~~ * * * * For each of the candiates LTP gains in g_pitch_cand[], the terms * * t[0..4] are calculated from the values in the table (and the * * pitch gain candidate) and summed up; the result is the mean * * squared error for the LPT/CB gain pair. The index for the mini- * * mum MSE is stored and finally used to retrieve the quantized CB * * gain * *-------------------------------------------------------------------*/ /* start with "infinite" MSE */ dist_min = MAX_32; move16 (); cod_ind = 0; move16 (); pit_ind = 0; move16 (); /* loop through LTP gain candidates */ for (j = 0; j < 3; j++) { /* pre-calculate terms only dependent on pitch gain */ g_pitch = g_pitch_cand[j]; move16 (); g2_pitch = mult(g_pitch, g_pitch); L_tmp0 = Mpy_32_16( coeff[0], coeff_lo[0], g2_pitch); L_tmp0 = Mac_32_16(L_tmp0, coeff[1], coeff_lo[1], g_pitch); p = &qua_gain_code[0]; for (i = 0; i < NB_QUA_CODE; i++) { g_code = *p++; move16 (); /* this is g_fac Q11 */ p++; /* skip log2(g_fac) */ p++; /* skip 20*log10(g_fac) */ g_code = mult(g_code, gcode0); L_tmp = L_mult (g_code, g_code); L_Extract (L_tmp, &g2_code_h, &g2_code_l); L_tmp = L_mult(g_code, g_pitch); L_Extract (L_tmp, &g_pit_cod_h, &g_pit_cod_l); L_tmp = Mac_32 (L_tmp0, coeff[2], coeff_lo[2], g2_code_h, g2_code_l); L_tmp = Mac_32_16(L_tmp, coeff[3], coeff_lo[3], g_code); L_tmp = Mac_32 (L_tmp, coeff[4], coeff_lo[4], g_pit_cod_h, g_pit_cod_l); /* store table index if MSE for this index is lower than the minimum MSE seen so far; also store the pitch gain for this (so far) lowest MSE */ test (); if (L_sub(L_tmp, dist_min) < (Word32) 0) { dist_min = L_tmp; move32 (); cod_ind = i; move16 (); pit_ind = j; move16 (); } } } /*------------------------------------------------------------------* * read quantized gains and new values for MA predictor memories * * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * *------------------------------------------------------------------*/ /* Read the quantized gains */ p = &qua_gain_code[add (add (cod_ind, cod_ind), cod_ind)]; move16 (); g_code = *p++; move16(); *qua_ener_MR122 = *p++; move16(); *qua_ener = *p; move16(); /*------------------------------------------------------------------* * calculate final fixed codebook gain: * * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * * * gc = gc0 * g * *------------------------------------------------------------------*/ L_tmp = L_mult(g_code, gcode0); L_tmp = L_shr(L_tmp, sub(9, exp_gcode0)); *gain_cod = extract_h(L_tmp); *gain_cod_ind = cod_ind; move16 (); *gain_pit = g_pitch_cand[pit_ind]; move16 (); *gain_pit_ind = g_pitch_cind[pit_ind]; move16 (); } /************************************************************************* * * FUNCTION: MR795_gain_code_quant_mod * * PURPOSE: Modified quantization of the MR795 codebook gain * * Uses pre-computed energy coefficients in frac_en[]/exp_en[] * * frac_en[0]*2^exp_en[0] = <res res> // LP residual energy * frac_en[1]*2^exp_en[1] = <exc exc> // LTP residual energy * frac_en[2]*2^exp_en[2] = <exc code> // LTP/CB innovation dot product * frac_en[3]*2^exp_en[3] = <code code> // CB innovation energy * *************************************************************************/ static Word16 MR795_gain_code_quant_mod( /* o : index of quantization. */ Word16 gain_pit, /* i : pitch gain, Q14 */ Word16 exp_gcode0, /* i : predicted CB gain (exponent), Q0 */ Word16 gcode0, /* i : predicted CB gain (norm.), Q14 */ Word16 frac_en[], /* i : energy coefficients (4), fraction part, Q15 */ Word16 exp_en[], /* i : energy coefficients (4), eponent part, Q0 */ Word16 alpha, /* i : gain adaptor factor (>0), Q15 */ Word16 gain_cod_unq, /* i : Code gain (unquantized) */ /* (scaling: Q10 - exp_gcode0) */ Word16 *gain_cod, /* i/o: Code gain (pre-/quantized), Q1 */ Word16 *qua_ener_MR122, /* o : quantized energy error, Q10 */ /* (for MR122 MA predictor update) */ Word16 *qua_ener /* o : quantized energy error, Q10 */ /* (for other MA predictor update) */ ) { const Word16 *p; Word16 i, index, tmp; Word16 one_alpha; Word16 exp, e_max; Word16 g2_pitch, g_code; Word16 g2_code_h, g2_code_l; Word16 d2_code_h, d2_code_l; Word16 coeff[5], coeff_lo[5], exp_coeff[5]; Word32 L_tmp, L_t0, L_t1, dist_min; Word16 gain_code; /* Steps in calculation of the error criterion (dist): --------------------------------------------------- underlined = constant; alp = FLP value of alpha, alpha = FIP ---------- ExEn = gp^2 * LtpEn + 2.0*gp*gc[i] * XC + gc[i]^2 * InnEn; ------------ ------ -- ----- aExEn= alp * ExEn = alp*gp^2*LtpEn + 2.0*alp*gp*XC* gc[i] + alp*InnEn* gc[i]^2 -------------- ------------- --------- = t[1] + t[2] + t[3] dist = d1 + d2; d1 = (1.0 - alp) * InnEn * (gcu - gc[i])^2 = t[4] ------------------- --- d2 = alp * (ResEn - 2.0 * sqrt(ResEn*ExEn) + ExEn); --- ----- --- ----- = alp * (sqrt(ExEn) - sqrt(ResEn))^2 --- ----------- = (sqrt(aExEn) - sqrt(alp*ResEn))^2 --------------- = (sqrt(aExEn) - t[0] )^2 ---- */ /* * calculate scalings of the constant terms */ gain_code = shl (*gain_cod, sub (10, exp_gcode0)); /* Q1 -> Q11 (-ec0) */ g2_pitch = mult (gain_pit, gain_pit); /* Q14 -> Q13 */ /* 0 < alpha <= 0.5 => 0.5 <= 1-alpha < 1, i.e one_alpha is normalized */ one_alpha = add (sub (32767, alpha), 1); /* 32768 - alpha */ /* alpha <= 0.5 -> mult. by 2 to keep precision; compensate in exponent */ tmp = extract_h (L_shl (L_mult (alpha, frac_en[1]), 1)); /* directly store in 32 bit variable because no further mult. required */ L_t1 = L_mult (tmp, g2_pitch); move16 (); exp_coeff[1] = sub (exp_en[1], 15); move16 (); tmp = extract_h (L_shl (L_mult (alpha, frac_en[2]), 1)); coeff[2] = mult (tmp, gain_pit); move16 (); exp = sub (exp_gcode0, 10); exp_coeff[2] = add (exp_en[2], exp); move16 (); /* alpha <= 0.5 -> mult. by 2 to keep precision; compensate in exponent */ coeff[3] = extract_h (L_shl (L_mult (alpha, frac_en[3]), 1)); exp = sub (shl (exp_gcode0, 1), 7); exp_coeff[3] = add (exp_en[3], exp); move16 (); coeff[4] = mult (one_alpha, frac_en[3]); move16 (); exp_coeff[4] = add (exp_coeff[3], 1); move16 (); L_tmp = L_mult (alpha, frac_en[0]); /* sqrt_l returns normalized value and 2*exponent -> result = val >> (exp/2) exp_coeff holds 2*exponent for c[0] */ /* directly store in 32 bit variable because no further mult. required */ L_t0 = sqrt_l_exp (L_tmp, &exp); /* normalization included in sqrt_l_exp */ move32 (); /* function result */ exp = add (exp, 47); exp_coeff[0] = sub (exp_en[0], exp); move16 (); /* * Determine the maximum exponent occuring in the distance calculation * and adjust all fractions accordingly (including a safety margin) * */ /* find max(e[1..4],e[0]+31) */ e_max = add (exp_coeff[0], 31); for (i = 1; i <= 4; i++) { test (); if (sub (exp_coeff[i], e_max) > 0) { e_max = exp_coeff[i]; move16 (); } } /* scale c[1] (requires no further multiplication) */ tmp = sub (e_max, exp_coeff[1]); L_t1 = L_shr(L_t1, tmp); /* scale c[2..4] (used in Mpy_32_16 in the quantizer loop) */ for (i = 2; i <= 4; i++) { tmp = sub (e_max, exp_coeff[i]); L_tmp = L_deposit_h(coeff[i]); L_tmp = L_shr(L_tmp, tmp); L_Extract(L_tmp, &coeff[i], &coeff_lo[i]); } /* scale c[0] (requires no further multiplication) */ exp = sub (e_max, 31); /* new exponent */ tmp = sub (exp, exp_coeff[0]); L_t0 = L_shr (L_t0, shr (tmp, 1)); /* perform correction by 1/sqrt(2) if exponent difference is odd */ test (); logic16 (); if ((tmp & 0x1) != 0) { L_Extract(L_t0, &coeff[0], &coeff_lo[0]); L_t0 = Mpy_32_16(coeff[0], coeff_lo[0], 23170); /* 23170 Q15 = 1/sqrt(2)*/ } /* search the quantizer table for the lowest value of the search criterion */ dist_min = MAX_32; move32 (); index = 0; move16 (); p = &qua_gain_code[0]; move16 (); for (i = 0; i < NB_QUA_CODE; i++) { g_code = *p++; move16 (); /* this is g_fac (Q11) */ p++; /* skip log2(g_fac) */ p++; /* skip 20*log10(g_fac) */ g_code = mult (g_code, gcode0); /* only continue if gc[i] < 2.0*gc which is equiv. to g_code (Q10-ec0) < gain_code (Q11-ec0) */ test (); if (sub (g_code, gain_code) >= 0) break; L_tmp = L_mult (g_code, g_code); L_Extract (L_tmp, &g2_code_h, &g2_code_l); tmp = sub (g_code, gain_cod_unq); L_tmp = L_mult (tmp, tmp); L_Extract (L_tmp, &d2_code_h, &d2_code_l); /* t2, t3, t4 */ L_tmp = Mac_32_16 (L_t1, coeff[2], coeff_lo[2], g_code); L_tmp = Mac_32(L_tmp, coeff[3], coeff_lo[3], g2_code_h, g2_code_l); L_tmp = sqrt_l_exp (L_tmp, &exp); L_tmp = L_shr (L_tmp, shr (exp, 1)); /* d2 */ tmp = round (L_sub (L_tmp, L_t0)); L_tmp = L_mult (tmp, tmp); /* dist */ L_tmp = Mac_32(L_tmp, coeff[4], coeff_lo[4], d2_code_h, d2_code_l); /* store table index if distance measure for this index is lower than the minimum seen so far */ test (); if (L_sub (L_tmp, dist_min) < (Word32) 0) { dist_min = L_tmp; move16 (); index = i; move16 (); } } /*------------------------------------------------------------------* * read quantized gains and new values for MA predictor memories * * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * *------------------------------------------------------------------*/ /* Read the quantized gains */ p = &qua_gain_code[add (add (index, index), index)]; move16 (); g_code = *p++; move16(); *qua_ener_MR122 = *p++; move16(); *qua_ener = *p; move16(); /*------------------------------------------------------------------* * calculate final fixed codebook gain: * * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * * * gc = gc0 * g * *------------------------------------------------------------------*/ L_tmp = L_mult(g_code, gcode0); L_tmp = L_shr(L_tmp, sub(9, exp_gcode0)); *gain_cod = extract_h(L_tmp); return index; } /* ******************************************************************************** * PUBLIC PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: MR795_gain_quant * * PURPOSE: pitch and codebook quantization for MR795 * *************************************************************************/ void MR795_gain_quant( GainAdaptState *adapt_st, /* i/o: gain adapter state structure */ Word16 res[], /* i : LP residual, Q0 */ Word16 exc[], /* i : LTP excitation (unfiltered), Q0 */ Word16 code[], /* i : CB innovation (unfiltered), Q13 */ Word16 frac_coeff[], /* i : coefficients (5), Q15 */ Word16 exp_coeff[], /* i : energy coefficients (5), Q0 */ /* coefficients from calc_filt_ener() */ Word16 exp_code_en, /* i : innovation energy (exponent), Q0 */ Word16 frac_code_en, /* i : innovation energy (fraction), Q15 */ Word16 exp_gcode0, /* i : predicted CB gain (exponent), Q0 */ Word16 frac_gcode0, /* i : predicted CB gain (fraction), Q15 */ Word16 L_subfr, /* i : Subframe length */ Word16 cod_gain_frac, /* i : opt. codebook gain (fraction),Q15 */ Word16 cod_gain_exp, /* i : opt. codebook gain (exponent), Q0 */ Word16 gp_limit, /* i : pitch gain limit */ Word16 *gain_pit, /* i/o: Pitch gain, Q14 */ Word16 *gain_cod, /* o : Code gain, Q1 */ Word16 *qua_ener_MR122, /* o : quantized energy error, Q10 */ /* (for MR122 MA predictor update) */ Word16 *qua_ener, /* o : quantized energy error, Q10 */ /* (for other MA predictor update) */ Word16 **anap /* o : Index of quantization */ /* (first gain pitch, then code pitch)*/ ) { Word16 frac_en[4]; Word16 exp_en[4]; Word16 ltpg, alpha, gcode0; Word16 g_pitch_cand[3]; /* pitch gain candidates Q14 */ Word16 g_pitch_cind[3]; /* pitch gain indices Q0 */ Word16 gain_pit_index; Word16 gain_cod_index; Word16 exp; Word16 gain_cod_unq; /* code gain (unq.) Q(10-exp_gcode0) */ /* get list of candidate quantized pitch gain values * and corresponding quantization indices */ gain_pit_index = q_gain_pitch (MR795, gp_limit, gain_pit, g_pitch_cand, g_pitch_cind); move16 (); /* function result */ /*-------------------------------------------------------------------* * predicted codebook gain * * ~~~~~~~~~~~~~~~~~~~~~~~ * * gc0 = 2^exp_gcode0 + 2^frac_gcode0 * * * * gcode0 (Q14) = 2^14*2^frac_gcode0 = gc0 * 2^(14-exp_gcode0) * *-------------------------------------------------------------------*/ gcode0 = extract_l(Pow2(14, frac_gcode0)); /* Q14 */ /* pre-quantization of codebook gain * (using three pitch gain candidates); * result: best guess of pitch gain and code gain */ MR795_gain_code_quant3( exp_gcode0, gcode0, g_pitch_cand, g_pitch_cind, frac_coeff, exp_coeff, gain_pit, &gain_pit_index, gain_cod, &gain_cod_index, qua_ener_MR122, qua_ener); /* calculation of energy coefficients and LTP coding gain */ calc_unfilt_energies(res, exc, code, *gain_pit, L_subfr, frac_en, exp_en, <pg); /* run gain adaptor, calculate alpha factor to balance LTP/CB gain * (this includes the gain adaptor update) * Note: ltpg = 0 if frac_en[0] == 0, so the update is OK in that case */ gain_adapt(adapt_st, ltpg, *gain_cod, &alpha); /* if this is a very low energy signal (threshold: see * calc_unfilt_energies) or alpha <= 0 then don't run the modified quantizer */ test (); move16 (); test (); if (frac_en[0] != 0 && alpha > 0) { /* innovation energy <cod cod> was already computed in gc_pred() */ /* (this overwrites the LtpResEn which is no longer needed) */ frac_en[3] = frac_code_en; move16 (); exp_en[3] = exp_code_en; move16 (); /* store optimum codebook gain in Q(10-exp_gcode0) */ exp = add (sub (cod_gain_exp, exp_gcode0), 10); gain_cod_unq = shl (cod_gain_frac, exp); /* run quantization with modified criterion */ gain_cod_index = MR795_gain_code_quant_mod( *gain_pit, exp_gcode0, gcode0, frac_en, exp_en, alpha, gain_cod_unq, gain_cod, qua_ener_MR122, qua_ener); move16 (); /* function result */ } *(*anap)++ = gain_pit_index; move16 (); *(*anap)++ = gain_cod_index; move16 (); }