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android / platform / external / speex / 4fc6573 / . / libspeex / sb_celp.c
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/* Copyright (C) 2002 Jean-Marc Valin
File: sb_celp.c
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
- Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
- Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
- Neither the name of the Xiph.org Foundation nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR
CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <math.h>
#include "sb_celp.h"
#include "stdlib.h"
#include "filters.h"
#include "lpc.h"
#include "lsp.h"
#include "stack_alloc.h"
#include "cb_search.h"
#include "quant_lsp.h"
#include "vq.h"
#include "ltp.h"
#include "misc.h"
/* Default size for the encoder and decoder stack (can be changed at compile time).
This does not apply when using variable-size arrays or alloca. */
#ifndef SB_ENC_STACK
#define SB_ENC_STACK (10000*sizeof(spx_sig_t))
#endif
#ifndef SB_DEC_STACK
#define SB_DEC_STACK (6000*sizeof(spx_sig_t))
#endif
#ifdef DISABLE_WIDEBAND
void *sb_encoder_init(const SpeexMode *m)
{
speex_error("Wideband and Ultra-wideband are disabled");
return NULL;
}
void sb_encoder_destroy(void *state)
{
speex_error("Wideband and Ultra-wideband are disabled");
}
int sb_encode(void *state, void *vin, SpeexBits *bits)
{
speex_error("Wideband and Ultra-wideband are disabled");
return -2;
}
void *sb_decoder_init(const SpeexMode *m)
{
speex_error("Wideband and Ultra-wideband are disabled");
return NULL;
}
void sb_decoder_destroy(void *state)
{
speex_error("Wideband and Ultra-wideband are disabled");
}
int sb_decode(void *state, SpeexBits *bits, void *vout)
{
speex_error("Wideband and Ultra-wideband are disabled");
return -2;
}
int sb_encoder_ctl(void *state, int request, void *ptr)
{
speex_error("Wideband and Ultra-wideband are disabled");
return -2;
}
int sb_decoder_ctl(void *state, int request, void *ptr)
{
speex_error("Wideband and Ultra-wideband are disabled");
return -2;
}
#else
#ifndef M_PI
#define M_PI 3.14159265358979323846 /* pi */
#endif
#define sqr(x) ((x)*(x))
#define SUBMODE(x) st->submodes[st->submodeID]->x
#ifdef FIXED_POINT
static const spx_word16_t gc_quant_bound[16] = {125, 164, 215, 282, 370, 484, 635, 832, 1090, 1428, 1871, 2452, 3213, 4210, 5516, 7228};
#define LSP_MARGIN 410
#define LSP_DELTA1 6553
#define LSP_DELTA2 1638
#else
#define LSP_MARGIN .05
#define LSP_DELTA1 .2
#define LSP_DELTA2 .05
#endif
#define QMF_ORDER 64
#ifdef FIXED_POINT
static const spx_word16_t h0[64] = {2, -7, -7, 18, 15, -39, -25, 75, 35, -130, -41, 212, 38, -327, -17, 483, -32, -689, 124, 956, -283, -1307, 543, 1780, -973, -2467, 1733, 3633, -3339, -6409, 9059, 30153, 30153, 9059, -6409, -3339, 3633, 1733, -2467, -973, 1780, 543, -1307, -283, 956, 124, -689, -32, 483, -17, -327, 38, 212, -41, -130, 35, 75, -25, -39, 15, 18, -7, -7, 2};
static const spx_word16_t h1[64] = {2, 7, -7, -18, 15, 39, -25, -75, 35, 130, -41, -212, 38, 327, -17, -483, -32, 689, 124, -956, -283, 1307, 543, -1780, -973, 2467, 1733, -3633, -3339, 6409, 9059, -30153, 30153, -9059, -6409, 3339, 3633, -1733, -2467, 973, 1780, -543, -1307, 283, 956, -124, -689, 32, 483, 17, -327, -38, 212, 41, -130, -35, 75, 25, -39, -15, 18, 7, -7, -2};
#else
static const float h0[64] = {
3.596189e-05, -0.0001123515,
-0.0001104587, 0.0002790277,
0.0002298438, -0.0005953563,
-0.0003823631, 0.00113826,
0.0005308539, -0.001986177,
-0.0006243724, 0.003235877,
0.0005743159, -0.004989147,
-0.0002584767, 0.007367171,
-0.0004857935, -0.01050689,
0.001894714, 0.01459396,
-0.004313674, -0.01994365,
0.00828756, 0.02716055,
-0.01485397, -0.03764973,
0.026447, 0.05543245,
-0.05095487, -0.09779096,
0.1382363, 0.4600981,
0.4600981, 0.1382363,
-0.09779096, -0.05095487,
0.05543245, 0.026447,
-0.03764973, -0.01485397,
0.02716055, 0.00828756,
-0.01994365, -0.004313674,
0.01459396, 0.001894714,
-0.01050689, -0.0004857935,
0.007367171, -0.0002584767,
-0.004989147, 0.0005743159,
0.003235877, -0.0006243724,
-0.001986177, 0.0005308539,
0.00113826, -0.0003823631,
-0.0005953563, 0.0002298438,
0.0002790277, -0.0001104587,
-0.0001123515, 3.596189e-05
};
static const float h1[64] = {
3.596189e-05, 0.0001123515,
-0.0001104587, -0.0002790277,
0.0002298438, 0.0005953563,
-0.0003823631, -0.00113826,
0.0005308539, 0.001986177,
-0.0006243724, -0.003235877,
0.0005743159, 0.004989147,
-0.0002584767, -0.007367171,
-0.0004857935, 0.01050689,
0.001894714, -0.01459396,
-0.004313674, 0.01994365,
0.00828756, -0.02716055,
-0.01485397, 0.03764973,
0.026447, -0.05543245,
-0.05095487, 0.09779096,
0.1382363, -0.4600981,
0.4600981, -0.1382363,
-0.09779096, 0.05095487,
0.05543245, -0.026447,
-0.03764973, 0.01485397,
0.02716055, -0.00828756,
-0.01994365, 0.004313674,
0.01459396, -0.001894714,
-0.01050689, 0.0004857935,
0.007367171, 0.0002584767,
-0.004989147, -0.0005743159,
0.003235877, 0.0006243724,
-0.001986177, -0.0005308539,
0.00113826, 0.0003823631,
-0.0005953563, -0.0002298438,
0.0002790277, 0.0001104587,
-0.0001123515, -3.596189e-05
};
#endif
extern const spx_word16_t lpc_window[];
static void mix_and_saturate(spx_word32_t *x0, spx_word32_t *x1, spx_word16_t *out, int len)
{
int i;
for (i=0;i<len;i++)
{
spx_word32_t tmp;
#ifdef FIXED_POINT
tmp=PSHR(x0[i]-x1[i],SIG_SHIFT-1);
#else
tmp=2*(x0[i]-x1[i]);
#endif
if (tmp>32767)
out[i] = 32767;
else if (tmp<-32767)
out[i] = -32767;
else
out[i] = tmp;
}
}
void *sb_encoder_init(const SpeexMode *m)
{
int i;
SBEncState *st;
const SpeexSBMode *mode;
st = (SBEncState*)speex_alloc(sizeof(SBEncState));
if (!st)
return NULL;
#if defined(VAR_ARRAYS) || defined (USE_ALLOCA)
st->stack = NULL;
#else
st->stack = (char*)speex_alloc_scratch(SB_ENC_STACK);
#endif
st->mode = m;
mode = (const SpeexSBMode*)m->mode;
st->st_low = speex_encoder_init(mode->nb_mode);
st->full_frame_size = 2*mode->frameSize;
st->frame_size = mode->frameSize;
st->subframeSize = mode->subframeSize;
st->nbSubframes = mode->frameSize/mode->subframeSize;
st->windowSize = st->frame_size+st->subframeSize;
st->lpcSize=mode->lpcSize;
st->bufSize=mode->bufSize;
st->encode_submode = 1;
st->submodes=mode->submodes;
st->submodeSelect = st->submodeID=mode->defaultSubmode;
i=9;
speex_encoder_ctl(st->st_low, SPEEX_SET_QUALITY, &i);
st->lag_factor = mode->lag_factor;
st->lpc_floor = mode->lpc_floor;
st->gamma1=mode->gamma1;
st->gamma2=mode->gamma2;
st->first=1;
st->x0d=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->x1d=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->high=speex_alloc((st->full_frame_size)*sizeof(spx_sig_t));
st->y0=speex_alloc((st->full_frame_size)*sizeof(spx_sig_t));
st->y1=speex_alloc((st->full_frame_size)*sizeof(spx_sig_t));
st->h0_mem=speex_alloc((QMF_ORDER)*sizeof(spx_word16_t));
st->h1_mem=speex_alloc((QMF_ORDER)*sizeof(spx_word16_t));
st->g0_mem=speex_alloc((QMF_ORDER)*sizeof(spx_word32_t));
st->g1_mem=speex_alloc((QMF_ORDER)*sizeof(spx_word32_t));
st->excBuf=speex_alloc((st->bufSize)*sizeof(spx_sig_t));
st->exc = st->excBuf + st->bufSize - st->windowSize;
st->res=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->sw=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->target=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->window= lpc_window;
st->lagWindow = speex_alloc((st->lpcSize+1)*sizeof(spx_word16_t));
for (i=0;i<st->lpcSize+1;i++)
st->lagWindow[i]=16384*exp(-.5*sqr(2*M_PI*st->lag_factor*i));
st->autocorr = speex_alloc((st->lpcSize+1)*sizeof(spx_word16_t));
st->lpc = speex_alloc(st->lpcSize*sizeof(spx_coef_t));
st->bw_lpc1 = speex_alloc(st->lpcSize*sizeof(spx_coef_t));
st->bw_lpc2 = speex_alloc(st->lpcSize*sizeof(spx_coef_t));
st->lsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->qlsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->old_lsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->old_qlsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->interp_lsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->interp_qlsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->interp_lpc = speex_alloc(st->lpcSize*sizeof(spx_coef_t));
st->interp_qlpc = speex_alloc(st->lpcSize*sizeof(spx_coef_t));
st->pi_gain = speex_alloc((st->nbSubframes)*sizeof(spx_word32_t));
st->low_innov = speex_alloc((st->frame_size)*sizeof(spx_word32_t));
speex_encoder_ctl(st->st_low, SPEEX_SET_INNOVATION_SAVE, st->low_innov);
st->innov_save = NULL;
st->mem_sp = speex_alloc((st->lpcSize)*sizeof(spx_mem_t));
st->mem_sp2 = speex_alloc((st->lpcSize)*sizeof(spx_mem_t));
st->mem_sw = speex_alloc((st->lpcSize)*sizeof(spx_mem_t));
st->vbr_quality = 8;
st->vbr_enabled = 0;
st->vad_enabled = 0;
st->abr_enabled = 0;
st->relative_quality=0;
st->complexity=2;
speex_encoder_ctl(st->st_low, SPEEX_GET_SAMPLING_RATE, &st->sampling_rate);
st->sampling_rate*=2;
#ifdef ENABLE_VALGRIND
VALGRIND_MAKE_READABLE(st, (st->stack-(char*)st));
#endif
return st;
}
void sb_encoder_destroy(void *state)
{
SBEncState *st=(SBEncState*)state;
speex_encoder_destroy(st->st_low);
#if !(defined(VAR_ARRAYS) || defined (USE_ALLOCA))
speex_free_scratch(st->stack);
#endif
speex_free(st->x0d);
speex_free(st->x1d);
speex_free(st->high);
speex_free(st->y0);
speex_free(st->y1);
speex_free(st->h0_mem);
speex_free(st->h1_mem);
speex_free(st->g0_mem);
speex_free(st->g1_mem);
speex_free(st->excBuf);
speex_free(st->res);
speex_free(st->sw);
speex_free(st->target);
speex_free(st->lagWindow);
speex_free(st->autocorr);
speex_free(st->lpc);
speex_free(st->bw_lpc1);
speex_free(st->bw_lpc2);
speex_free(st->lsp);
speex_free(st->qlsp);
speex_free(st->old_lsp);
speex_free(st->old_qlsp);
speex_free(st->interp_lsp);
speex_free(st->interp_qlsp);
speex_free(st->interp_lpc);
speex_free(st->interp_qlpc);
speex_free(st->pi_gain);
speex_free(st->mem_sp);
speex_free(st->mem_sp2);
speex_free(st->mem_sw);
speex_free(st);
}
int sb_encode(void *state, void *vin, SpeexBits *bits)
{
SBEncState *st;
int i, roots, sub;
char *stack;
VARDECL(spx_mem_t *mem);
VARDECL(spx_sig_t *innov);
VARDECL(spx_word16_t *syn_resp);
VARDECL(spx_word32_t *low_pi_gain);
VARDECL(spx_sig_t *low_exc);
const SpeexSBMode *mode;
int dtx;
spx_word16_t *in = vin;
st = (SBEncState*)state;
stack=st->stack;
mode = (const SpeexSBMode*)(st->mode->mode);
{
VARDECL(spx_word16_t *low);
ALLOC(low, st->frame_size, spx_word16_t);
/* Compute the two sub-bands by filtering with h0 and h1*/
qmf_decomp(in, h0, st->x0d, st->x1d, st->full_frame_size, QMF_ORDER, st->h0_mem, stack);
for (i=0;i<st->frame_size;i++)
low[i] = SATURATE(PSHR(st->x0d[i],SIG_SHIFT),32767);
/* Encode the narrowband part*/
speex_encode_native(st->st_low, low, bits);
for (i=0;i<st->frame_size;i++)
st->x0d[i] = SHL(low[i],SIG_SHIFT);
}
/* High-band buffering / sync with low band */
for (i=0;i<st->windowSize-st->frame_size;i++)
st->high[i] = st->high[st->frame_size+i];
for (i=0;i<st->frame_size;i++)
st->high[st->windowSize-st->frame_size+i]=SATURATE(st->x1d[i],536854528);
speex_move(st->excBuf, st->excBuf+st->frame_size, (st->bufSize-st->frame_size)*sizeof(spx_sig_t));
ALLOC(low_pi_gain, st->nbSubframes, spx_word32_t);
ALLOC(low_exc, st->frame_size, spx_sig_t);
speex_encoder_ctl(st->st_low, SPEEX_GET_PI_GAIN, low_pi_gain);
speex_encoder_ctl(st->st_low, SPEEX_GET_EXC, low_exc);
speex_encoder_ctl(st->st_low, SPEEX_GET_LOW_MODE, &dtx);
if (dtx==0)
dtx=1;
else
dtx=0;
{
VARDECL(spx_word16_t *w_sig);
ALLOC(w_sig, st->windowSize, spx_word16_t);
/* Window for analysis */
for (i=0;i<st->windowSize;i++)
w_sig[i] = SHR(MULT16_16(SHR((spx_word32_t)(st->high[i]),SIG_SHIFT),st->window[i]),SIG_SHIFT);
/* Compute auto-correlation */
_spx_autocorr(w_sig, st->autocorr, st->lpcSize+1, st->windowSize);
}
st->autocorr[0] = ADD16(st->autocorr[0],MULT16_16_Q15(st->autocorr[0],st->lpc_floor)); /* Noise floor in auto-correlation domain */
/* Lag windowing: equivalent to filtering in the power-spectrum domain */
for (i=0;i<st->lpcSize+1;i++)
st->autocorr[i] = MULT16_16_Q14(st->autocorr[i],st->lagWindow[i]);
/* Levinson-Durbin */
_spx_lpc(st->lpc, st->autocorr, st->lpcSize);
/* LPC to LSPs (x-domain) transform */
roots=lpc_to_lsp (st->lpc, st->lpcSize, st->lsp, 15, LSP_DELTA1, stack);
if (roots!=st->lpcSize)
{
roots = lpc_to_lsp (st->lpc, st->lpcSize, st->lsp, 11, LSP_DELTA2, stack);
if (roots!=st->lpcSize) {
/*If we can't find all LSP's, do some damage control and use a flat filter*/
for (i=0;i<st->lpcSize;i++)
{
st->lsp[i]=LSP_SCALING*M_PI*((float)(i+1))/(st->lpcSize+1);
}
}
}
/* VBR code */
if ((st->vbr_enabled || st->vad_enabled) && !dtx)
{
float e_low=0, e_high=0;
float ratio;
if (st->abr_enabled)
{
float qual_change=0;
if (st->abr_drift2 * st->abr_drift > 0)
{
/* Only adapt if long-term and short-term drift are the same sign */
qual_change = -.00001*st->abr_drift/(1+st->abr_count);
if (qual_change>.1)
qual_change=.1;
if (qual_change<-.1)
qual_change=-.1;
}
st->vbr_quality += qual_change;
if (st->vbr_quality>10)
st->vbr_quality=10;
if (st->vbr_quality<0)
st->vbr_quality=0;
}
/*FIXME: Are the two signals (low, high) in sync? */
e_low = compute_rms(st->x0d, st->frame_size);
e_high = compute_rms(st->high, st->frame_size);
ratio = 2*log((1+e_high)/(1+e_low));
speex_encoder_ctl(st->st_low, SPEEX_GET_RELATIVE_QUALITY, &st->relative_quality);
if (ratio<-4)
ratio=-4;
if (ratio>2)
ratio=2;
/*if (ratio>-2)*/
if (st->vbr_enabled)
{
int modeid;
modeid = mode->nb_modes-1;
st->relative_quality+=1.0*(ratio+2);
if (st->relative_quality<-1)
st->relative_quality=-1;
while (modeid)
{
int v1;
float thresh;
v1=(int)floor(st->vbr_quality);
if (v1==10)
thresh = mode->vbr_thresh[modeid][v1];
else
thresh = (st->vbr_quality-v1) * mode->vbr_thresh[modeid][v1+1] +
(1+v1-st->vbr_quality) * mode->vbr_thresh[modeid][v1];
if (st->relative_quality >= thresh)
break;
modeid--;
}
speex_encoder_ctl(state, SPEEX_SET_HIGH_MODE, &modeid);
if (st->abr_enabled)
{
int bitrate;
speex_encoder_ctl(state, SPEEX_GET_BITRATE, &bitrate);
st->abr_drift+=(bitrate-st->abr_enabled);
st->abr_drift2 = .95*st->abr_drift2 + .05*(bitrate-st->abr_enabled);
st->abr_count += 1.0;
}
} else {
/* VAD only */
int modeid;
if (st->relative_quality<2.0)
modeid=1;
else
modeid=st->submodeSelect;
/*speex_encoder_ctl(state, SPEEX_SET_MODE, &mode);*/
st->submodeID=modeid;
}
/*fprintf (stderr, "%f %f\n", ratio, low_qual);*/
}
if (st->encode_submode)
{
speex_bits_pack(bits, 1, 1);
if (dtx)
speex_bits_pack(bits, 0, SB_SUBMODE_BITS);
else
speex_bits_pack(bits, st->submodeID, SB_SUBMODE_BITS);
}
/* If null mode (no transmission), just set a couple things to zero*/
if (dtx || st->submodes[st->submodeID] == NULL)
{
for (i=0;i<st->frame_size;i++)
st->exc[i]=st->sw[i]=VERY_SMALL;
for (i=0;i<st->lpcSize;i++)
st->mem_sw[i]=0;
st->first=1;
/* Final signal synthesis from excitation */
iir_mem2(st->exc, st->interp_qlpc, st->high, st->frame_size, st->lpcSize, st->mem_sp);
#ifdef RESYNTH
/* Reconstruct the original */
fir_mem_up(st->x0d, h0, st->y0, st->full_frame_size, QMF_ORDER, st->g0_mem, stack);
fir_mem_up(st->high, h1, st->y1, st->full_frame_size, QMF_ORDER, st->g1_mem, stack);
for (i=0;i<st->full_frame_size;i++)
in[i]=SHR(st->y0[i]-st->y1[i], SIG_SHIFT-1);
#endif
if (dtx)
return 0;
else
return 1;
}
/* LSP quantization */
SUBMODE(lsp_quant)(st->lsp, st->qlsp, st->lpcSize, bits);
if (st->first)
{
for (i=0;i<st->lpcSize;i++)
st->old_lsp[i] = st->lsp[i];
for (i=0;i<st->lpcSize;i++)
st->old_qlsp[i] = st->qlsp[i];
}
ALLOC(mem, st->lpcSize, spx_mem_t);
ALLOC(syn_resp, st->subframeSize, spx_word16_t);
ALLOC(innov, st->subframeSize, spx_sig_t);
for (sub=0;sub<st->nbSubframes;sub++)
{
spx_sig_t *exc, *sp, *res, *target, *sw, *innov_save=NULL;
spx_word16_t filter_ratio;
int offset;
spx_word32_t rl, rh;
spx_word16_t eh=0;
offset = st->subframeSize*sub;
sp=st->high+offset;
exc=st->exc+offset;
res=st->res+offset;
target=st->target+offset;
sw=st->sw+offset;
/* Pointer for saving innovation */
if (st->innov_save)
{
innov_save = st->innov_save+2*offset;
for (i=0;i<2*st->subframeSize;i++)
innov_save[i]=0;
}
/* LSP interpolation (quantized and unquantized) */
lsp_interpolate(st->old_lsp, st->lsp, st->interp_lsp, st->lpcSize, sub, st->nbSubframes);
lsp_interpolate(st->old_qlsp, st->qlsp, st->interp_qlsp, st->lpcSize, sub, st->nbSubframes);
lsp_enforce_margin(st->interp_lsp, st->lpcSize, LSP_MARGIN);
lsp_enforce_margin(st->interp_qlsp, st->lpcSize, LSP_MARGIN);
lsp_to_lpc(st->interp_lsp, st->interp_lpc, st->lpcSize,stack);
lsp_to_lpc(st->interp_qlsp, st->interp_qlpc, st->lpcSize, stack);
bw_lpc(st->gamma1, st->interp_lpc, st->bw_lpc1, st->lpcSize);
bw_lpc(st->gamma2, st->interp_lpc, st->bw_lpc2, st->lpcSize);
/* Compute mid-band (4000 Hz for wideband) response of low-band and high-band
filters */
st->pi_gain[sub]=LPC_SCALING;
rh = LPC_SCALING;
for (i=0;i<st->lpcSize;i+=2)
{
rh += st->interp_qlpc[i+1] - st->interp_qlpc[i];
st->pi_gain[sub] += st->interp_qlpc[i] + st->interp_qlpc[i+1];
}
rl = low_pi_gain[sub];
#ifdef FIXED_POINT
filter_ratio=DIV32_16(SHL(rl+82,2),SHR(82+rh,5));
#else
filter_ratio=(rl+.01)/(rh+.01);
#endif
/* Compute "real excitation" */
fir_mem2(sp, st->interp_qlpc, exc, st->subframeSize, st->lpcSize, st->mem_sp2);
/* Compute energy of low-band and high-band excitation */
eh = compute_rms(exc, st->subframeSize);
if (!SUBMODE(innovation_quant)) {/* 1 for spectral folding excitation, 0 for stochastic */
float g;
spx_word16_t el;
el = compute_rms(st->low_innov+offset, st->subframeSize);
/* Gain to use if we want to use the low-band excitation for high-band */
g=eh/(.01+el);
#if 0
{
char *tmp_stack=stack;
float *tmp_sig;
float g2;
ALLOC(tmp_sig, st->subframeSize, spx_sig_t);
for (i=0;i<st->lpcSize;i++)
mem[i]=st->mem_sp[i];
iir_mem2(st->low_innov+offset, st->interp_qlpc, tmp_sig, st->subframeSize, st->lpcSize, mem);
g2 = compute_rms(sp, st->subframeSize)/(.01+compute_rms(tmp_sig, st->subframeSize));
/*fprintf (stderr, "gains: %f %f\n", g, g2);*/
g = g2;
stack = tmp_stack;
}
#endif
#ifdef FIXED_POINT
g *= filter_ratio/128.;
#else
g *= filter_ratio;
#endif
/*print_vec(&g, 1, "gain factor");*/
/* Gain quantization */
{
int quant = (int) floor(.5 + 10 + 8.0 * log((g+.0001)));
/*speex_warning_int("tata", quant);*/
if (quant<0)
quant=0;
if (quant>31)
quant=31;
speex_bits_pack(bits, quant, 5);
}
} else {
spx_word16_t gc;
spx_word32_t scale;
spx_word16_t el;
el = compute_rms(low_exc+offset, st->subframeSize);
gc = DIV32_16(MULT16_16(filter_ratio,1+eh),1+el);
/* This is a kludge that cleans up a historical bug */
if (st->subframeSize==80)
gc *= 0.70711;
/*printf ("%f %f %f %f\n", el, eh, filter_ratio, gc);*/
#ifdef FIXED_POINT
{
int qgc = scal_quant(gc, gc_quant_bound, 16);
speex_bits_pack(bits, qgc, 4);
gc = MULT16_32_Q15(28626,gc_quant_bound[qgc]);
}
#else
{
int qgc = (int)floor(.5+3.7*(log(gc)+0.15556));
if (qgc<0)
qgc=0;
if (qgc>15)
qgc=15;
speex_bits_pack(bits, qgc, 4);
gc = exp((1/3.7)*qgc-0.15556);
}
#endif
if (st->subframeSize==80)
gc *= 1.4142;
scale = SHL(MULT16_16(DIV32_16(SHL(gc,SIG_SHIFT-4),filter_ratio),(1+el)),4);
compute_impulse_response(st->interp_qlpc, st->bw_lpc1, st->bw_lpc2, syn_resp, st->subframeSize, st->lpcSize, stack);
/* Reset excitation */
for (i=0;i<st->subframeSize;i++)
exc[i]=VERY_SMALL;
/* Compute zero response (ringing) of A(z/g1) / ( A(z/g2) * Aq(z) ) */
for (i=0;i<st->lpcSize;i++)
mem[i]=st->mem_sp[i];
iir_mem2(exc, st->interp_qlpc, exc, st->subframeSize, st->lpcSize, mem);
for (i=0;i<st->lpcSize;i++)
mem[i]=st->mem_sw[i];
filter_mem2(exc, st->bw_lpc1, st->bw_lpc2, res, st->subframeSize, st->lpcSize, mem);
/* Compute weighted signal */
for (i=0;i<st->lpcSize;i++)
mem[i]=st->mem_sw[i];
filter_mem2(sp, st->bw_lpc1, st->bw_lpc2, sw, st->subframeSize, st->lpcSize, mem);
/* Compute target signal */
for (i=0;i<st->subframeSize;i++)
target[i]=sw[i]-res[i];
for (i=0;i<st->subframeSize;i++)
exc[i]=0;
signal_div(target, target, scale, st->subframeSize);
/* Reset excitation */
for (i=0;i<st->subframeSize;i++)
innov[i]=0;
/*print_vec(target, st->subframeSize, "\ntarget");*/
SUBMODE(innovation_quant)(target, st->interp_qlpc, st->bw_lpc1, st->bw_lpc2,
SUBMODE(innovation_params), st->lpcSize, st->subframeSize,
innov, syn_resp, bits, stack, (st->complexity+1)>>1, SUBMODE(double_codebook));
/*print_vec(target, st->subframeSize, "after");*/
signal_mul(innov, innov, scale, st->subframeSize);
for (i=0;i<st->subframeSize;i++)
exc[i] = ADD32(exc[i], innov[i]);
if (st->innov_save)
{
for (i=0;i<st->subframeSize;i++)
innov_save[2*i]=innov[i];
}
if (SUBMODE(double_codebook)) {
char *tmp_stack=stack;
VARDECL(spx_sig_t *innov2);
ALLOC(innov2, st->subframeSize, spx_sig_t);
for (i=0;i<st->subframeSize;i++)
innov2[i]=0;
for (i=0;i<st->subframeSize;i++)
target[i]*=2.5;
SUBMODE(innovation_quant)(target, st->interp_qlpc, st->bw_lpc1, st->bw_lpc2,
SUBMODE(innovation_params), st->lpcSize, st->subframeSize,
innov2, syn_resp, bits, stack, (st->complexity+1)>>1, 0);
for (i=0;i<st->subframeSize;i++)
innov2[i]*=scale*(1/2.5)/SIG_SCALING;
for (i=0;i<st->subframeSize;i++)
exc[i] = ADD32(exc[i],innov2[i]);
stack = tmp_stack;
}
}
/*Keep the previous memory*/
for (i=0;i<st->lpcSize;i++)
mem[i]=st->mem_sp[i];
/* Final signal synthesis from excitation */
iir_mem2(exc, st->interp_qlpc, sp, st->subframeSize, st->lpcSize, st->mem_sp);
/* Compute weighted signal again, from synthesized speech (not sure it's the right thing) */
filter_mem2(sp, st->bw_lpc1, st->bw_lpc2, sw, st->subframeSize, st->lpcSize, st->mem_sw);
}
#ifdef RESYNTH
/* Reconstruct the original */
fir_mem_up(st->x0d, h0, st->y0, st->full_frame_size, QMF_ORDER, st->g0_mem, stack);
fir_mem_up(st->high, h1, st->y1, st->full_frame_size, QMF_ORDER, st->g1_mem, stack);
for (i=0;i<st->full_frame_size;i++)
in[i]=SHR(st->y0[i]-st->y1[i], SIG_SHIFT-1);
#endif
for (i=0;i<st->lpcSize;i++)
st->old_lsp[i] = st->lsp[i];
for (i=0;i<st->lpcSize;i++)
st->old_qlsp[i] = st->qlsp[i];
st->first=0;
return 1;
}
void *sb_decoder_init(const SpeexMode *m)
{
SBDecState *st;
const SpeexSBMode *mode;
st = (SBDecState*)speex_alloc(sizeof(SBDecState));
if (!st)
return NULL;
#if defined(VAR_ARRAYS) || defined (USE_ALLOCA)
st->stack = NULL;
#else
st->stack = (char*)speex_alloc_scratch(SB_DEC_STACK);
#endif
st->mode = m;
mode=(const SpeexSBMode*)m->mode;
st->encode_submode = 1;
st->st_low = speex_decoder_init(mode->nb_mode);
st->full_frame_size = 2*mode->frameSize;
st->frame_size = mode->frameSize;
st->subframeSize = mode->subframeSize;
st->nbSubframes = mode->frameSize/mode->subframeSize;
st->lpcSize=mode->lpcSize;
speex_decoder_ctl(st->st_low, SPEEX_GET_SAMPLING_RATE, &st->sampling_rate);
st->sampling_rate*=2;
st->submodes=mode->submodes;
st->submodeID=mode->defaultSubmode;
st->first=1;
st->x0d=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->x1d=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->high=speex_alloc((st->full_frame_size)*sizeof(spx_sig_t));
st->y0=speex_alloc((st->full_frame_size)*sizeof(spx_sig_t));
st->y1=speex_alloc((st->full_frame_size)*sizeof(spx_sig_t));
st->g0_mem=speex_alloc((QMF_ORDER)*sizeof(spx_word32_t));
st->g1_mem=speex_alloc((QMF_ORDER)*sizeof(spx_word32_t));
st->exc=speex_alloc((st->frame_size)*sizeof(spx_sig_t));
st->qlsp = speex_alloc((st->lpcSize)*sizeof(spx_lsp_t));
st->old_qlsp = speex_alloc((st->lpcSize)*sizeof(spx_lsp_t));
st->interp_qlsp = speex_alloc(st->lpcSize*sizeof(spx_lsp_t));
st->interp_qlpc = speex_alloc(st->lpcSize*sizeof(spx_coef_t));
st->pi_gain = speex_alloc((st->nbSubframes)*sizeof(spx_word32_t));
st->mem_sp = speex_alloc((2*st->lpcSize)*sizeof(spx_mem_t));
st->low_innov = speex_alloc((st->frame_size)*sizeof(spx_word32_t));
speex_decoder_ctl(st->st_low, SPEEX_SET_INNOVATION_SAVE, st->low_innov);
st->innov_save = NULL;
st->lpc_enh_enabled=0;
st->seed = 1000;
#ifdef ENABLE_VALGRIND
VALGRIND_MAKE_READABLE(st, (st->stack-(char*)st));
#endif
return st;
}
void sb_decoder_destroy(void *state)
{
SBDecState *st;
st = (SBDecState*)state;
speex_decoder_destroy(st->st_low);
#if !(defined(VAR_ARRAYS) || defined (USE_ALLOCA))
speex_free_scratch(st->stack);
#endif
speex_free(st->x0d);
speex_free(st->x1d);
speex_free(st->high);
speex_free(st->y0);
speex_free(st->y1);
speex_free(st->g0_mem);
speex_free(st->g1_mem);
speex_free(st->exc);
speex_free(st->qlsp);
speex_free(st->old_qlsp);
speex_free(st->interp_qlsp);
speex_free(st->interp_qlpc);
speex_free(st->pi_gain);
speex_free(st->mem_sp);
speex_free(state);
}
static void sb_decode_lost(SBDecState *st, spx_word16_t *out, int dtx, char *stack)
{
int i;
VARDECL(spx_coef_t *awk1);
VARDECL(spx_coef_t *awk2);
VARDECL(spx_coef_t *awk3);
int saved_modeid=0;
if (dtx)
{
saved_modeid=st->submodeID;
st->submodeID=1;
} else {
bw_lpc(GAMMA_SCALING*0.99, st->interp_qlpc, st->interp_qlpc, st->lpcSize);
}
st->first=1;
ALLOC(awk1, st->lpcSize+1, spx_coef_t);
ALLOC(awk2, st->lpcSize+1, spx_coef_t);
ALLOC(awk3, st->lpcSize+1, spx_coef_t);
if (st->lpc_enh_enabled)
{
spx_word16_t k1,k2,k3;
if (st->submodes[st->submodeID] != NULL)
{
k1=SUBMODE(lpc_enh_k1);
k2=SUBMODE(lpc_enh_k2);
k3=SUBMODE(lpc_enh_k3);
} else {
k1=k2=.7*GAMMA_SCALING;
k3 = 0;
}
bw_lpc(k1, st->interp_qlpc, awk1, st->lpcSize);
bw_lpc(k2, st->interp_qlpc, awk2, st->lpcSize);
bw_lpc(k3, st->interp_qlpc, awk3, st->lpcSize);
/*fprintf (stderr, "%f %f %f\n", k1, k2, k3);*/
}
/* Final signal synthesis from excitation */
if (!dtx)
{
spx_word16_t low_ener;
low_ener = .9*compute_rms(st->exc, st->frame_size);
for (i=0;i<st->frame_size;i++)
st->exc[i] = speex_rand(low_ener, &st->seed);
}
for (i=0;i<st->frame_size;i++)
st->high[i]=st->exc[i];
if (st->lpc_enh_enabled)
{
/* Use enhanced LPC filter */
filter_mem2(st->high, awk2, awk1, st->high, st->frame_size, st->lpcSize,
st->mem_sp+st->lpcSize);
filter_mem2(st->high, awk3, st->interp_qlpc, st->high, st->frame_size, st->lpcSize,
st->mem_sp);
} else {
/* Use regular filter */
for (i=0;i<st->lpcSize;i++)
st->mem_sp[st->lpcSize+i] = 0;
iir_mem2(st->high, st->interp_qlpc, st->high, st->frame_size, st->lpcSize,
st->mem_sp);
}
/*iir_mem2(st->exc, st->interp_qlpc, st->high, st->frame_size, st->lpcSize, st->mem_sp);*/
/* Reconstruct the original */
fir_mem_up(st->x0d, h0, st->y0, st->full_frame_size, QMF_ORDER, st->g0_mem, stack);
fir_mem_up(st->high, h1, st->y1, st->full_frame_size, QMF_ORDER, st->g1_mem, stack);
mix_and_saturate(st->y0, st->y1, out, st->full_frame_size);
if (dtx)
{
st->submodeID=saved_modeid;
}
return;
}
int sb_decode(void *state, SpeexBits *bits, void *vout)
{
int i, sub;
SBDecState *st;
int wideband;
int ret;
char *stack;
VARDECL(spx_word32_t *low_pi_gain);
VARDECL(spx_sig_t *low_exc);
VARDECL(spx_coef_t *awk1);
VARDECL(spx_coef_t *awk2);
VARDECL(spx_coef_t *awk3);
int dtx;
const SpeexSBMode *mode;
spx_word16_t *out = vout;
st = (SBDecState*)state;
stack=st->stack;
mode = (const SpeexSBMode*)(st->mode->mode);
{
VARDECL(spx_word16_t *low);
ALLOC(low, st->frame_size, spx_word16_t);
/* Decode the low-band */
ret = speex_decode_native(st->st_low, bits, low);
for (i=0;i<st->frame_size;i++)
st->x0d[i] = SHL((spx_sig_t)low[i], SIG_SHIFT);
}
speex_decoder_ctl(st->st_low, SPEEX_GET_DTX_STATUS, &dtx);
/* If error decoding the narrowband part, propagate error */
if (ret!=0)
{
return ret;
}
if (!bits)
{
sb_decode_lost(st, out, dtx, stack);
return 0;
}
if (st->encode_submode)
{
/*Check "wideband bit"*/
if (speex_bits_remaining(bits)>0)
wideband = speex_bits_peek(bits);
else
wideband = 0;
if (wideband)
{
/*Regular wideband frame, read the submode*/
wideband = speex_bits_unpack_unsigned(bits, 1);
st->submodeID = speex_bits_unpack_unsigned(bits, SB_SUBMODE_BITS);
} else
{
/*Was a narrowband frame, set "null submode"*/
st->submodeID = 0;
}
if (st->submodeID != 0 && st->submodes[st->submodeID] == NULL)
{
speex_warning("Invalid mode encountered: corrupted stream?");
return -2;
}
}
/* If null mode (no transmission), just set a couple things to zero*/
if (st->submodes[st->submodeID] == NULL)
{
if (dtx)
{
sb_decode_lost(st, out, 1, stack);
return 0;
}
for (i=0;i<st->frame_size;i++)
st->exc[i]=VERY_SMALL;
st->first=1;
/* Final signal synthesis from excitation */
iir_mem2(st->exc, st->interp_qlpc, st->high, st->frame_size, st->lpcSize, st->mem_sp);
fir_mem_up(st->x0d, h0, st->y0, st->full_frame_size, QMF_ORDER, st->g0_mem, stack);
fir_mem_up(st->high, h1, st->y1, st->full_frame_size, QMF_ORDER, st->g1_mem, stack);
mix_and_saturate(st->y0, st->y1, out, st->full_frame_size);
return 0;
}
for (i=0;i<st->frame_size;i++)
st->exc[i]=0;
ALLOC(low_pi_gain, st->nbSubframes, spx_word32_t);
ALLOC(low_exc, st->frame_size, spx_sig_t);
speex_decoder_ctl(st->st_low, SPEEX_GET_PI_GAIN, low_pi_gain);
speex_decoder_ctl(st->st_low, SPEEX_GET_EXC, low_exc);
SUBMODE(lsp_unquant)(st->qlsp, st->lpcSize, bits);
if (st->first)
{
for (i=0;i<st->lpcSize;i++)
st->old_qlsp[i] = st->qlsp[i];
}
ALLOC(awk1, st->lpcSize+1, spx_coef_t);
ALLOC(awk2, st->lpcSize+1, spx_coef_t);
ALLOC(awk3, st->lpcSize+1, spx_coef_t);
for (sub=0;sub<st->nbSubframes;sub++)
{
spx_sig_t *exc, *sp, *innov_save=NULL;
spx_word16_t filter_ratio;
spx_word16_t el=0;
int offset;
spx_word32_t rl=0,rh=0;
offset = st->subframeSize*sub;
sp=st->high+offset;
exc=st->exc+offset;
/* Pointer for saving innovation */
if (st->innov_save)
{
innov_save = st->innov_save+2*offset;
for (i=0;i<2*st->subframeSize;i++)
innov_save[i]=0;
}
/* LSP interpolation */
lsp_interpolate(st->old_qlsp, st->qlsp, st->interp_qlsp, st->lpcSize, sub, st->nbSubframes);
lsp_enforce_margin(st->interp_qlsp, st->lpcSize, LSP_MARGIN);
/* LSP to LPC */
lsp_to_lpc(st->interp_qlsp, st->interp_qlpc, st->lpcSize, stack);
if (st->lpc_enh_enabled)
{
spx_word16_t k1,k2,k3;
k1=SUBMODE(lpc_enh_k1);
k2=SUBMODE(lpc_enh_k2);
k3=SUBMODE(lpc_enh_k3);
bw_lpc(k1, st->interp_qlpc, awk1, st->lpcSize);
bw_lpc(k2, st->interp_qlpc, awk2, st->lpcSize);
bw_lpc(k3, st->interp_qlpc, awk3, st->lpcSize);
/*fprintf (stderr, "%f %f %f\n", k1, k2, k3);*/
}
/* Calculate reponse ratio between the low and high filter in the middle
of the band (4000 Hz) */
st->pi_gain[sub]=LPC_SCALING;
rh = LPC_SCALING;
for (i=0;i<st->lpcSize;i+=2)
{
rh += st->interp_qlpc[i+1] - st->interp_qlpc[i];
st->pi_gain[sub] += st->interp_qlpc[i] + st->interp_qlpc[i+1];
}
rl = low_pi_gain[sub];
#ifdef FIXED_POINT
filter_ratio=DIV32_16(SHL(rl+82,2),SHR(82+rh,5));
#else
filter_ratio=(rl+.01)/(rh+.01);
#endif
for (i=0;i<st->subframeSize;i++)
exc[i]=0;
if (!SUBMODE(innovation_unquant))
{
float g;
int quant;
quant = speex_bits_unpack_unsigned(bits, 5);
g= exp(((float)quant-10)/8.0);
#ifdef FIXED_POINT
g /= filter_ratio/128.;
#else
g /= filter_ratio;
#endif
/* High-band excitation using the low-band excitation and a gain */
#if 0
for (i=0;i<st->subframeSize;i++)
exc[i]=mode->folding_gain*g*st->low_innov[offset+i];
#else
{
float tmp=1;
/*static tmp1=0,tmp2=0;
static int seed=1;
el = compute_rms(low_innov+offset, st->subframeSize);*/
for (i=0;i<st->subframeSize;i++)
{
float e=tmp*g*mode->folding_gain*st->low_innov[offset+i];
tmp *= -1;
exc[i] = e;
/*float r = speex_rand(g*el,&seed);
exc[i] = .5*(r+tmp2 + e-tmp1);
tmp1 = e;
tmp2 = r;*/
}
}
/*speex_rand_vec(mode->folding_gain*g*el, exc, st->subframeSize);*/
#endif
} else {
spx_word16_t gc;
spx_word32_t scale;
int qgc = speex_bits_unpack_unsigned(bits, 4);
el = compute_rms(low_exc+offset, st->subframeSize);
#ifdef FIXED_POINT
gc = MULT16_32_Q15(28626,gc_quant_bound[qgc]);
#else
gc = exp((1/3.7)*qgc-0.15556);
#endif
if (st->subframeSize==80)
gc *= 1.4142;
scale = SHL(MULT16_16(DIV32_16(SHL(gc,SIG_SHIFT-4),filter_ratio),(1+el)),4);
SUBMODE(innovation_unquant)(exc, SUBMODE(innovation_params), st->subframeSize,
bits, stack);
signal_mul(exc,exc,scale,st->subframeSize);
if (SUBMODE(double_codebook)) {
char *tmp_stack=stack;
VARDECL(spx_sig_t *innov2);
ALLOC(innov2, st->subframeSize, spx_sig_t);
for (i=0;i<st->subframeSize;i++)
innov2[i]=0;
SUBMODE(innovation_unquant)(innov2, SUBMODE(innovation_params), st->subframeSize,
bits, stack);
for (i=0;i<st->subframeSize;i++)
innov2[i]*=scale/(float)SIG_SCALING*(1/2.5);
for (i=0;i<st->subframeSize;i++)
exc[i] = ADD32(exc[i],innov2[i]);
stack = tmp_stack;
}
}
if (st->innov_save)
{
for (i=0;i<st->subframeSize;i++)
innov_save[2*i]=exc[i];
}
for (i=0;i<st->subframeSize;i++)
sp[i]=exc[i];
if (st->lpc_enh_enabled)
{
/* Use enhanced LPC filter */
filter_mem2(sp, awk2, awk1, sp, st->subframeSize, st->lpcSize,
st->mem_sp+st->lpcSize);
filter_mem2(sp, awk3, st->interp_qlpc, sp, st->subframeSize, st->lpcSize,
st->mem_sp);
} else {
/* Use regular filter */
for (i=0;i<st->lpcSize;i++)
st->mem_sp[st->lpcSize+i] = 0;
iir_mem2(sp, st->interp_qlpc, sp, st->subframeSize, st->lpcSize,
st->mem_sp);
}
/*iir_mem2(exc, st->interp_qlpc, sp, st->subframeSize, st->lpcSize, st->mem_sp);*/
}
fir_mem_up(st->x0d, h0, st->y0, st->full_frame_size, QMF_ORDER, st->g0_mem, stack);
fir_mem_up(st->high, h1, st->y1, st->full_frame_size, QMF_ORDER, st->g1_mem, stack);
mix_and_saturate(st->y0, st->y1, out, st->full_frame_size);
for (i=0;i<st->lpcSize;i++)
st->old_qlsp[i] = st->qlsp[i];
st->first=0;
return 0;
}
int sb_encoder_ctl(void *state, int request, void *ptr)
{
SBEncState *st;
st=(SBEncState*)state;
switch(request)
{
case SPEEX_GET_FRAME_SIZE:
(*(int*)ptr) = st->full_frame_size;
break;
case SPEEX_SET_HIGH_MODE:
st->submodeSelect = st->submodeID = (*(int*)ptr);
break;
case SPEEX_SET_LOW_MODE:
speex_encoder_ctl(st->st_low, SPEEX_SET_LOW_MODE, ptr);
break;
case SPEEX_SET_DTX:
speex_encoder_ctl(st->st_low, SPEEX_SET_DTX, ptr);
break;
case SPEEX_GET_DTX:
speex_encoder_ctl(st->st_low, SPEEX_GET_DTX, ptr);
break;
case SPEEX_GET_LOW_MODE:
speex_encoder_ctl(st->st_low, SPEEX_GET_LOW_MODE, ptr);
break;
case SPEEX_SET_MODE:
speex_encoder_ctl(st, SPEEX_SET_QUALITY, ptr);
break;
case SPEEX_SET_VBR:
st->vbr_enabled = (*(int*)ptr);
speex_encoder_ctl(st->st_low, SPEEX_SET_VBR, ptr);
break;
case SPEEX_GET_VBR:
(*(int*)ptr) = st->vbr_enabled;
break;
case SPEEX_SET_VAD:
st->vad_enabled = (*(int*)ptr);
speex_encoder_ctl(st->st_low, SPEEX_SET_VAD, ptr);
break;
case SPEEX_GET_VAD:
(*(int*)ptr) = st->vad_enabled;
break;
case SPEEX_SET_VBR_QUALITY:
{
int q;
float qual = (*(float*)ptr)+.6;
st->vbr_quality = (*(float*)ptr);
if (qual>10)
qual=10;
q=(int)floor(.5+*(float*)ptr);
if (q>10)
q=10;
speex_encoder_ctl(st->st_low, SPEEX_SET_VBR_QUALITY, &qual);
speex_encoder_ctl(state, SPEEX_SET_QUALITY, &q);
break;
}
case SPEEX_GET_VBR_QUALITY:
(*(float*)ptr) = st->vbr_quality;
break;
case SPEEX_SET_ABR:
st->abr_enabled = (*(int*)ptr);
st->vbr_enabled = 1;
speex_encoder_ctl(st->st_low, SPEEX_SET_VBR, &st->vbr_enabled);
{
int i=10, rate, target;
float vbr_qual;
target = (*(int*)ptr);
while (i>=0)
{
speex_encoder_ctl(st, SPEEX_SET_QUALITY, &i);
speex_encoder_ctl(st, SPEEX_GET_BITRATE, &rate);
if (rate <= target)
break;
i--;
}
vbr_qual=i;
if (vbr_qual<0)
vbr_qual=0;
speex_encoder_ctl(st, SPEEX_SET_VBR_QUALITY, &vbr_qual);
st->abr_count=0;
st->abr_drift=0;
st->abr_drift2=0;
}
break;
case SPEEX_GET_ABR:
(*(int*)ptr) = st->abr_enabled;
break;
case SPEEX_SET_QUALITY:
{
int nb_qual;
int quality = (*(int*)ptr);
if (quality < 0)
quality = 0;
if (quality > 10)
quality = 10;
st->submodeSelect = st->submodeID = ((const SpeexSBMode*)(st->mode->mode))->quality_map[quality];
nb_qual = ((const SpeexSBMode*)(st->mode->mode))->low_quality_map[quality];
speex_encoder_ctl(st->st_low, SPEEX_SET_MODE, &nb_qual);
}
break;
case SPEEX_SET_COMPLEXITY:
speex_encoder_ctl(st->st_low, SPEEX_SET_COMPLEXITY, ptr);
st->complexity = (*(int*)ptr);
if (st->complexity<1)
st->complexity=1;
break;
case SPEEX_GET_COMPLEXITY:
(*(int*)ptr) = st->complexity;
break;
case SPEEX_SET_BITRATE:
{
int i=10, rate, target;
target = (*(int*)ptr);
while (i>=0)
{
speex_encoder_ctl(st, SPEEX_SET_QUALITY, &i);
speex_encoder_ctl(st, SPEEX_GET_BITRATE, &rate);
if (rate <= target)
break;
i--;
}
}
break;
case SPEEX_GET_BITRATE:
speex_encoder_ctl(st->st_low, request, ptr);
/*fprintf (stderr, "before: %d\n", (*(int*)ptr));*/
if (st->submodes[st->submodeID])
(*(int*)ptr) += st->sampling_rate*SUBMODE(bits_per_frame)/st->full_frame_size;
else
(*(int*)ptr) += st->sampling_rate*(SB_SUBMODE_BITS+1)/st->full_frame_size;
/*fprintf (stderr, "after: %d\n", (*(int*)ptr));*/
break;
case SPEEX_SET_SAMPLING_RATE:
{
int tmp=(*(int*)ptr);
st->sampling_rate = tmp;
tmp>>=1;
speex_encoder_ctl(st->st_low, SPEEX_SET_SAMPLING_RATE, &tmp);
}
break;
case SPEEX_GET_SAMPLING_RATE:
(*(int*)ptr)=st->sampling_rate;
break;
case SPEEX_RESET_STATE:
{
int i;
st->first = 1;
for (i=0;i<st->lpcSize;i++)
st->lsp[i]=(M_PI*((float)(i+1)))/(st->lpcSize+1);
for (i=0;i<st->lpcSize;i++)
st->mem_sw[i]=st->mem_sp[i]=st->mem_sp2[i]=0;
for (i=0;i<st->bufSize;i++)
st->excBuf[i]=0;
for (i=0;i<QMF_ORDER;i++)
st->h0_mem[i]=st->h1_mem[i]=st->g0_mem[i]=st->g1_mem[i]=0;
}
break;
case SPEEX_SET_SUBMODE_ENCODING:
st->encode_submode = (*(int*)ptr);
speex_encoder_ctl(st->st_low, SPEEX_SET_SUBMODE_ENCODING, &ptr);
break;
case SPEEX_GET_SUBMODE_ENCODING:
(*(int*)ptr) = st->encode_submode;
break;
case SPEEX_GET_LOOKAHEAD:
speex_encoder_ctl(st->st_low, SPEEX_GET_LOOKAHEAD, ptr);
(*(int*)ptr) = 2*(*(int*)ptr) + QMF_ORDER - 1;
break;
case SPEEX_GET_PI_GAIN:
{
int i;
spx_word32_t *g = (spx_word32_t*)ptr;
for (i=0;i<st->nbSubframes;i++)
g[i]=st->pi_gain[i];
}
break;
case SPEEX_GET_EXC:
{
int i;
spx_sig_t *e = (spx_sig_t*)ptr;
for (i=0;i<st->full_frame_size;i++)
e[i]=0;
for (i=0;i<st->frame_size;i++)
e[2*i]=2*st->exc[i];
}
break;
case SPEEX_GET_INNOV:
{
int i;
spx_sig_t *e = (spx_sig_t*)ptr;
for (i=0;i<st->full_frame_size;i++)
e[i]=0;
for (i=0;i<st->frame_size;i++)
e[2*i]=2*st->exc[i];
}
break;
case SPEEX_GET_RELATIVE_QUALITY:
(*(float*)ptr)=st->relative_quality;
break;
case SPEEX_SET_INNOVATION_SAVE:
st->innov_save = ptr;
break;
default:
speex_warning_int("Unknown nb_ctl request: ", request);
return -1;
}
return 0;
}
int sb_decoder_ctl(void *state, int request, void *ptr)
{
SBDecState *st;
st=(SBDecState*)state;
switch(request)
{
case SPEEX_SET_HIGH_MODE:
st->submodeID = (*(int*)ptr);
break;
case SPEEX_SET_LOW_MODE:
speex_decoder_ctl(st->st_low, SPEEX_SET_LOW_MODE, ptr);
break;
case SPEEX_GET_LOW_MODE:
speex_decoder_ctl(st->st_low, SPEEX_GET_LOW_MODE, ptr);
break;
case SPEEX_GET_FRAME_SIZE:
(*(int*)ptr) = st->full_frame_size;
break;
case SPEEX_SET_ENH:
speex_decoder_ctl(st->st_low, request, ptr);
st->lpc_enh_enabled = *((int*)ptr);
break;
case SPEEX_GET_ENH:
*((int*)ptr) = st->lpc_enh_enabled;
break;
case SPEEX_SET_MODE:
case SPEEX_SET_QUALITY:
{
int nb_qual;
int quality = (*(int*)ptr);
if (quality < 0)
quality = 0;
if (quality > 10)
quality = 10;
st->submodeID = ((const SpeexSBMode*)(st->mode->mode))->quality_map[quality];
nb_qual = ((const SpeexSBMode*)(st->mode->mode))->low_quality_map[quality];
speex_decoder_ctl(st->st_low, SPEEX_SET_MODE, &nb_qual);
}
break;
case SPEEX_GET_BITRATE:
speex_decoder_ctl(st->st_low, request, ptr);
if (st->submodes[st->submodeID])
(*(int*)ptr) += st->sampling_rate*SUBMODE(bits_per_frame)/st->full_frame_size;
else
(*(int*)ptr) += st->sampling_rate*(SB_SUBMODE_BITS+1)/st->full_frame_size;
break;
case SPEEX_SET_SAMPLING_RATE:
{
int tmp=(*(int*)ptr);
st->sampling_rate = tmp;
tmp>>=1;
speex_decoder_ctl(st->st_low, SPEEX_SET_SAMPLING_RATE, &tmp);
}
break;
case SPEEX_GET_SAMPLING_RATE:
(*(int*)ptr)=st->sampling_rate;
break;
case SPEEX_SET_HANDLER:
speex_decoder_ctl(st->st_low, SPEEX_SET_HANDLER, ptr);
break;
case SPEEX_SET_USER_HANDLER:
speex_decoder_ctl(st->st_low, SPEEX_SET_USER_HANDLER, ptr);
break;
case SPEEX_RESET_STATE:
{
int i;
for (i=0;i<2*st->lpcSize;i++)
st->mem_sp[i]=0;
for (i=0;i<QMF_ORDER;i++)
st->g0_mem[i]=st->g1_mem[i]=0;
}
break;
case SPEEX_SET_SUBMODE_ENCODING:
st->encode_submode = (*(int*)ptr);
speex_decoder_ctl(st->st_low, SPEEX_SET_SUBMODE_ENCODING, &ptr);
break;
case SPEEX_GET_SUBMODE_ENCODING:
(*(int*)ptr) = st->encode_submode;
break;
case SPEEX_GET_PI_GAIN:
{
int i;
spx_word32_t *g = (spx_word32_t*)ptr;
for (i=0;i<st->nbSubframes;i++)
g[i]=st->pi_gain[i];
}
break;
case SPEEX_GET_EXC:
{
int i;
spx_sig_t *e = (spx_sig_t*)ptr;
for (i=0;i<st->full_frame_size;i++)
e[i]=0;
for (i=0;i<st->frame_size;i++)
e[2*i]=2*st->exc[i];
}
break;
case SPEEX_GET_INNOV:
{
int i;
spx_sig_t *e = (spx_sig_t*)ptr;
for (i=0;i<st->full_frame_size;i++)
e[i]=0;
for (i=0;i<st->frame_size;i++)
e[2*i]=2*st->exc[i];
}
break;
case SPEEX_GET_DTX_STATUS:
speex_decoder_ctl(st->st_low, SPEEX_GET_DTX_STATUS, ptr);
break;
case SPEEX_SET_INNOVATION_SAVE:
st->innov_save = ptr;
break;
default:
speex_warning_int("Unknown nb_ctl request: ", request);
return -1;
}
return 0;
}
#endif