FreeCalypso > hg > gsm-codec-lib
view libgsmefr/pitch_ol.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 | 509ba99f5136 |
| children | b4531e7227ca |
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/************************************************************************* * * FUNCTION: Pitch_ol * * PURPOSE: Compute the open loop pitch lag. * * DESCRIPTION: * The open-loop pitch lag is determined based on the perceptually * weighted speech signal. This is done in the following steps: * - find three maxima of the correlation <sw[n],sw[n-T]> in the * follwing three ranges of T : [18,35], [36,71], and [72, 143] * - divide each maximum by <sw[n-t], sw[n-t]> where t is the delay at * that maximum correlation. * - select the delay of maximum normalized correlation (among the * three candidates) while favoring the lower delay ranges. * *************************************************************************/ #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" #define THRESHOLD 27853 /* local function */ static Word16 Lag_max ( /* output: lag found */ Word16 scal_sig[], /* input : scaled signal */ Word16 scal_fac, /* input : scaled signal factor */ Word16 L_frame, /* input : length of frame to compute pitch */ Word16 lag_max, /* input : maximum lag */ Word16 lag_min, /* input : minimum lag */ Word16 *cor_max); /* output: normalized correlation of selected lag */ Word16 Pitch_ol ( /* output: open loop pitch lag */ Word16 signal[], /* input : signal used to compute the open loop pitch */ /* signal[-pit_max] to signal[-1] should be known */ Word16 pit_min, /* input : minimum pitch lag */ Word16 pit_max, /* input : maximum pitch lag */ Word16 L_frame /* input : length of frame to compute pitch */ ) { Word16 i, j; Word16 max1, max2, max3; Word16 p_max1, p_max2, p_max3; Word32 t0; /* Scaled signal */ /* Can be allocated with memory allocation of(pit_max+L_frame) */ Word16 scaled_signal[512]; Word16 *scal_sig, scal_fac; scal_sig = &scaled_signal[pit_max]; move16 (); t0 = 0L; move32 (); for (i = -pit_max; i < L_frame; i++) { t0 = L_mac (t0, signal[i], signal[i]); } /*--------------------------------------------------------* * Scaling of input signal. * * * * if Overflow -> scal_sig[i] = signal[i]>>2 * * else if t0 < 1^22 -> scal_sig[i] = signal[i]<<2 * * else -> scal_sig[i] = signal[i] * *--------------------------------------------------------*/ /*--------------------------------------------------------* * Verification for risk of overflow. * *--------------------------------------------------------*/ test (); test (); if (L_sub (t0, MAX_32) == 0L) /* Test for overflow */ { for (i = -pit_max; i < L_frame; i++) { scal_sig[i] = shr (signal[i], 3); move16 (); } scal_fac = 3; move16 (); } else if (L_sub (t0, (Word32) 1048576L) < (Word32) 0) /* if (t0 < 2^20) */ { for (i = -pit_max; i < L_frame; i++) { scal_sig[i] = shl (signal[i], 3); move16 (); } scal_fac = -3; move16 (); } else { for (i = -pit_max; i < L_frame; i++) { scal_sig[i] = signal[i]; move16 (); } scal_fac = 0; move16 (); } /*--------------------------------------------------------------------* * The pitch lag search is divided in three sections. * * Each section cannot have a pitch multiple. * * We find a maximum for each section. * * We compare the maximum of each section by favoring small lags. * * * * First section: lag delay = pit_max downto 4*pit_min * * Second section: lag delay = 4*pit_min-1 downto 2*pit_min * * Third section: lag delay = 2*pit_min-1 downto pit_min * *-------------------------------------------------------------------*/ j = shl (pit_min, 2); p_max1 = Lag_max (scal_sig, scal_fac, L_frame, pit_max, j, &max1); i = sub (j, 1); j = shl (pit_min, 1); p_max2 = Lag_max (scal_sig, scal_fac, L_frame, i, j, &max2); i = sub (j, 1); p_max3 = Lag_max (scal_sig, scal_fac, L_frame, i, pit_min, &max3); /*--------------------------------------------------------------------* * Compare the 3 sections maximum, and favor small lag. * *-------------------------------------------------------------------*/ test (); if (sub (mult (max1, THRESHOLD), max2) < 0) { max1 = max2; move16 (); p_max1 = p_max2; move16 (); } test (); if (sub (mult (max1, THRESHOLD), max3) < 0) { p_max1 = p_max3; move16 (); } return (p_max1); } /************************************************************************* * * FUNCTION: Lag_max * * PURPOSE: Find the lag that has maximum correlation of scal_sig[] in a * given delay range. * * DESCRIPTION: * The correlation is given by * cor[t] = <scal_sig[n],scal_sig[n-t]>, t=lag_min,...,lag_max * The functions outputs the maximum correlation after normalization * and the corresponding lag. * *************************************************************************/ static Word16 Lag_max ( /* output: lag found */ Word16 scal_sig[], /* input : scaled signal. */ Word16 scal_fac, /* input : scaled signal factor. */ Word16 L_frame, /* input : length of frame to compute pitch */ Word16 lag_max, /* input : maximum lag */ Word16 lag_min, /* input : minimum lag */ Word16 *cor_max) /* output: normalized correlation of selected lag */ { Word16 i, j; Word16 *p, *p1; Word32 max, t0; Word16 max_h, max_l, ener_h, ener_l; Word16 p_max; max = MIN_32; move32 (); for (i = lag_max; i >= lag_min; i--) { p = scal_sig; move16 (); p1 = &scal_sig[-i]; move16 (); t0 = 0; move32 (); for (j = 0; j < L_frame; j++, p++, p1++) { t0 = L_mac (t0, *p, *p1); } test (); if (L_sub (t0, max) >= 0) { max = t0; move32 (); p_max = i; move16 (); } } /* compute energy */ t0 = 0; move32 (); p = &scal_sig[-p_max]; move16 (); for (i = 0; i < L_frame; i++, p++) { t0 = L_mac (t0, *p, *p); } /* 1/sqrt(energy) */ t0 = Inv_sqrt (t0); t0 = L_shl (t0, 1); /* max = max/sqrt(energy) */ L_Extract (max, &max_h, &max_l); L_Extract (t0, &ener_h, &ener_l); t0 = Mpy_32 (max_h, max_l, ener_h, ener_l); t0 = L_shr (t0, scal_fac); *cor_max = extract_h (L_shl (t0, 15)); move16 (); /* divide by 2 */ return (p_max); }