FreeCalypso > hg > gsm-codec-lib
view libtwamr/g_pitch.c @ 581:e2d5cad04cbf
libgsmhr1 RxFE: store CN R0+LPC separately from speech
In the original GSM 06.06 code the ECU for speech mode is entirely
separate from the CN generator, maintaining separate state. (The
main intertie between them is the speech vs CN state variable,
distinguishing between speech and CN BFIs, in addition to the
CN-specific function of distinguishing between initial and update
SIDs.)
In the present RxFE implementation I initially thought that we could
use the same saved_frame buffer for both ECU and CN, overwriting
just the first 4 params (R0 and LPC) when a valid SID comes in.
However, I now realize it was a bad idea: the original code has a
corner case (long sequence of speech-mode BFIs to put the ECU in
state 6, then SID and CN-mode BFIs, then a good speech frame) that
would be broken by that buffer reuse approach. We could eliminate
this corner case by resetting the ECU state when passing through
a CN insertion period, but doing so would needlessly increase
the behavioral diffs between GSM 06.06 and our version.
Solution: use a separate CN-specific buffer for CN R0+LPC parameters,
and match the behavior of GSM 06.06 code in this regard.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Thu, 13 Feb 2025 10:02:45 +0000 |
| parents | bd4f660eb75a |
| children |
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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 : g_pitch.c * Purpose : Compute the pitch (adaptive codebook) gain. * ******************************************************************************** */ /* ******************************************************************************** * MODULE INCLUDE FILE AND VERSION ID ******************************************************************************** */ #include "namespace.h" #include "g_pitch.h" /* ******************************************************************************** * INCLUDE FILES ******************************************************************************** */ #include "tw_amr.h" #include "typedef.h" #include "basic_op.h" #include "oper_32b.h" #include "no_count.h" #include "cnst.h" /* ******************************************************************************** * PUBLIC PROGRAM CODE ******************************************************************************** */ /************************************************************************* * * FUNCTION: G_pitch * * PURPOSE: Compute the pitch (adaptive codebook) gain. * Result in Q14 (NOTE: 12.2 bit exact using Q12) * * DESCRIPTION: * The adaptive codebook gain is given by * * g = <x[], y[]> / <y[], y[]> * * where x[] is the target vector, y[] is the filtered adaptive * codevector, and <> denotes dot product. * The gain is limited to the range [0,1.2] (=0..19661 Q14) * *************************************************************************/ Word16 G_pitch ( /* o : Gain of pitch lag saturated to 1.2 */ enum Mode mode, /* i : AMR mode */ Word16 xn[], /* i : Pitch target. */ Word16 y1[], /* i : Filtered adaptive codebook. */ Word16 g_coeff[], /* i : Correlations need for gain quantization */ Word16 L_subfr /* i : Length of subframe. */ ) { Word16 i; Word16 xy, yy, exp_xy, exp_yy, gain; Word32 s; Word16 scaled_y1[L_SUBFR]; /* Usually dynamic allocation of (L_subfr) */ /* divide "y1[]" by 4 to avoid overflow */ for (i = 0; i < L_subfr; i++) { scaled_y1[i] = shr (y1[i], 2); move16 (); } /* Compute scalar product <y1[],y1[]> */ /* Q12 scaling / MR122 */ Overflow = 0; move16 (); s = 1L; move32 (); /* Avoid case of all zeros */ for (i = 0; i < L_subfr; i++) { s = L_mac (s, y1[i], y1[i]); } test (); if (Overflow == 0) /* Test for overflow */ { exp_yy = norm_l (s); yy = round (L_shl (s, exp_yy)); } else { s = 1L; move32 (); /* Avoid case of all zeros */ for (i = 0; i < L_subfr; i++) { s = L_mac (s, scaled_y1[i], scaled_y1[i]); } exp_yy = norm_l (s); yy = round (L_shl (s, exp_yy)); exp_yy = sub (exp_yy, 4); } /* Compute scalar product <xn[],y1[]> */ Overflow = 0; move16 (); s = 1L; move32 (); /* Avoid case of all zeros */ for (i = 0; i < L_subfr; i++) { s = L_mac(s, xn[i], y1[i]); } test (); if (Overflow == 0) { exp_xy = norm_l (s); xy = round (L_shl (s, exp_xy)); } else { s = 1L; move32 (); /* Avoid case of all zeros */ for (i = 0; i < L_subfr; i++) { s = L_mac (s, xn[i], scaled_y1[i]); } exp_xy = norm_l (s); xy = round (L_shl (s, exp_xy)); exp_xy = sub (exp_xy, 2); } g_coeff[0] = yy; move16 (); g_coeff[1] = sub (15, exp_yy); move16 (); g_coeff[2] = xy; move16 (); g_coeff[3] = sub (15, exp_xy); move16 (); /* If (xy < 4) gain = 0 */ i = sub (xy, 4); test (); if (i < 0) return ((Word16) 0); /* compute gain = xy/yy */ xy = shr (xy, 1); /* Be sure xy < yy */ gain = div_s (xy, yy); i = sub (exp_xy, exp_yy); /* Denormalization of division */ gain = shr (gain, i); /* if(gain >1.2) gain = 1.2 */ test (); if (sub (gain, 19661) > 0) { gain = 19661; move16 (); } test (); if (sub(mode, MR122) == 0) { /* clear 2 LSBits */ gain = gain & 0xfffC; logic16 (); } return (gain); }