FreeCalypso > hg > gsm-codec-lib
view libgsmefr/pitch_f6.c @ 183:452c1d5a6268
libgsmefr BFI w/o data: emit zero output after decoder reset
In real-life usage, each EFR decoder session will most likely begin
with lots of BFI frames before the first real frame arrives. However,
because the spec-defined home state of the decoder is speech rather
than CN, our regular logic for BFI w/o data would have to feed
pseudorandom noise to the decoder (in the "fixed codebook excitation
pulses" part), which is silly to do at the beginning of the decoder
session right out of reset. Therefore, let's check reset_flag_old,
and if we are still in the reset state, simply emit zero output.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Tue, 03 Jan 2023 00:12:18 +0000 |
parents | e0e53bfe1a8a |
children | d714168fb6dc |
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/************************************************************************* * * FUNCTION: Pitch_fr6() * * PURPOSE: Find the pitch period with 1/6 subsample resolution (closed loop). * * DESCRIPTION: * - find the normalized correlation between the target and filtered * past excitation in the search range. * - select the delay with maximum normalized correlation. * - interpolate the normalized correlation at fractions -3/6 to 3/6 * with step 1/6 around the chosen delay. * - The fraction which gives the maximum interpolated value is chosen. * *************************************************************************/ #include "gsm_efr.h" #include "typedef.h" #include "namespace.h" #include "basic_op.h" #include "oper_32b.h" #include "no_count.h" #include "sig_proc.h" #include "codec.h" /* L_inter = Length for fractional interpolation = nb.coeff/2 */ #define L_inter 4 /* Local functions */ static void Norm_Corr (Word16 exc[], Word16 xn[], Word16 h[], Word16 L_subfr, Word16 t_min, Word16 t_max, Word16 corr_norm[]); Word16 Pitch_fr6 ( /* (o) : pitch period. */ Word16 exc[], /* (i) : excitation buffer */ Word16 xn[], /* (i) : target vector */ Word16 h[], /* (i) : impulse response of synthesis and weighting filters */ Word16 L_subfr, /* (i) : Length of subframe */ Word16 t0_min, /* (i) : minimum value in the searched range. */ Word16 t0_max, /* (i) : maximum value in the searched range. */ Word16 i_subfr, /* (i) : indicator for first subframe. */ Word16 *pit_frac /* (o) : chosen fraction. */ ) { Word16 i; Word16 t_min, t_max; Word16 max, lag, frac; Word16 *corr; Word16 corr_int; Word16 corr_v[40]; /* Total length = t0_max-t0_min+1+2*L_inter */ /* Find interval to compute normalized correlation */ t_min = sub (t0_min, L_inter); t_max = add (t0_max, L_inter); corr = &corr_v[-t_min]; move16 (); /* Compute normalized correlation between target and filtered excitation */ Norm_Corr (exc, xn, h, L_subfr, t_min, t_max, corr); /* Find integer pitch */ max = corr[t0_min]; move16 (); lag = t0_min; move16 (); for (i = t0_min + 1; i <= t0_max; i++) { test (); if (sub (corr[i], max) >= 0) { max = corr[i]; move16 (); lag = i; move16 (); } } /* If first subframe and lag > 94 do not search fractional pitch */ test (); test (); if ((i_subfr == 0) && (sub (lag, 94) > 0)) { *pit_frac = 0; move16 (); return (lag); } /* Test the fractions around T0 and choose the one which maximizes */ /* the interpolated normalized correlation. */ max = Interpol_6 (&corr[lag], -3); frac = -3; move16 (); for (i = -2; i <= 3; i++) { corr_int = Interpol_6 (&corr[lag], i); move16 (); test (); if (sub (corr_int, max) > 0) { max = corr_int; move16 (); frac = i; move16 (); } } /* Limit the fraction value in the interval [-2,-1,0,1,2,3] */ test (); if (sub (frac, -3) == 0) { frac = 3; move16 (); lag = sub (lag, 1); } *pit_frac = frac; move16 (); return (lag); } /************************************************************************* * * FUNCTION: Norm_Corr() * * PURPOSE: Find the normalized correlation between the target vector * and the filtered past excitation. * * DESCRIPTION: * The normalized correlation is given by the correlation between the * target and filtered past excitation divided by the square root of * the energy of filtered excitation. * corr[k] = <x[], y_k[]>/sqrt(y_k[],y_k[]) * where x[] is the target vector and y_k[] is the filtered past * excitation at delay k. * *************************************************************************/ static void Norm_Corr (Word16 exc[], Word16 xn[], Word16 h[], Word16 L_subfr, Word16 t_min, Word16 t_max, Word16 corr_norm[]) { Word16 i, j, k; Word16 corr_h, corr_l, norm_h, norm_l; Word32 s; /* Usally dynamic allocation of (L_subfr) */ Word16 excf[80]; Word16 scaling, h_fac, *s_excf, scaled_excf[80]; k = -t_min; move16 (); /* compute the filtered excitation for the first delay t_min */ Convolve (&exc[k], h, excf, L_subfr); /* scale "excf[]" to avoid overflow */ for (j = 0; j < L_subfr; j++) { scaled_excf[j] = shr (excf[j], 2); move16 (); } /* Compute 1/sqrt(energy of excf[]) */ s = 0; move32 (); for (j = 0; j < L_subfr; j++) { s = L_mac (s, excf[j], excf[j]); } test (); if (L_sub (s, 67108864L) <= 0) /* if (s <= 2^26) */ { s_excf = excf; move16 (); h_fac = 15 - 12; move16 (); scaling = 0; move16 (); } else { /* "excf[]" is divided by 2 */ s_excf = scaled_excf; move16 (); h_fac = 15 - 12 - 2; move16 (); scaling = 2; move16 (); } /* loop for every possible period */ for (i = t_min; i <= t_max; i++) { /* Compute 1/sqrt(energy of excf[]) */ s = 0; move32 (); for (j = 0; j < L_subfr; j++) { s = L_mac (s, s_excf[j], s_excf[j]); } s = Inv_sqrt (s); move16 (); L_Extract (s, &norm_h, &norm_l); /* Compute correlation between xn[] and excf[] */ s = 0; move32 (); for (j = 0; j < L_subfr; j++) { s = L_mac (s, xn[j], s_excf[j]); } L_Extract (s, &corr_h, &corr_l); /* Normalize correlation = correlation * (1/sqrt(energy)) */ s = Mpy_32 (corr_h, corr_l, norm_h, norm_l); corr_norm[i] = extract_h (L_shl (s, 16)); move16 (); /* modify the filtered excitation excf[] for the next iteration */ test (); if (sub (i, t_max) != 0) { k--; for (j = L_subfr - 1; j > 0; j--) { s = L_mult (exc[k], h[j]); s = L_shl (s, h_fac); s_excf[j] = add (extract_h (s), s_excf[j - 1]); move16 (); } s_excf[0] = shr (exc[k], scaling); move16 (); } } return; }