FreeCalypso > hg > gsm-codec-lib
view libgsmefr/g_pitch.c @ 282:9ee8ad3d4d30
frtest: rm gsmfr-hand-test and gsmfr-max-out utils
These hack programs were never properly documented and were written
only as part of a debug chase, in pursuit of a bug that ultimately
turned out to be in our then-hacky patch to osmo-bts-sysmo,
before beginning of proper patches in Osmocom. These hack programs
need to be dropped from the present sw package because they depend
on old libgsm, and we are eliminating that dependency.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sun, 14 Apr 2024 05:44:47 +0000 |
| parents | 827661987b41 |
| children |
line wrap: on
line source
/************************************************************************* * * FUNCTION: G_pitch * * PURPOSE: Compute the pitch (adaptive codebook) gain. Result in 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] * *************************************************************************/ #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" Word16 G_pitch ( /* (o) : Gain of pitch lag saturated to 1.2 */ Word16 xn[], /* (i) : Pitch target. */ Word16 y1[], /* (i) : Filtered adaptive codebook. */ Word16 L_subfr /* : Length of subframe. */ ) { Word16 i; Word16 xy, yy, exp_xy, exp_yy, gain; Word32 s; Word16 scaled_y1[80]; /* Usually dynamic allocation of (L_subfr) */ /* divide by 2 "y1[]" to avoid overflow */ for (i = 0; i < L_subfr; i++) { scaled_y1[i] = shr (y1[i], 2); move16 (); } /* Compute scalar product <y1[],y1[]> */ s = 0L; move32 (); /* Avoid case of all zeros */ for (i = 0; i < L_subfr; i++) { s = L_mac (s, y1[i], y1[i]); } test (); if (s != MAX_32) /* Test for overflow */ { s++; /* Avoid case of all zeros */ 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++) { Carry = 0; move16 (); s = L_macNs (s, xn[i], y1[i]); test (); if (Overflow != 0) { break; } } 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); } /* 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 = add (exp_xy, 3 - 1); /* Denormalization of division */ i = sub (i, exp_yy); gain = shr (gain, i); /* if(gain >1.2) gain = 1.2 */ test (); if (gain > 4915) { gain = 4915; move16 (); } return (gain); }