1*a58d3d2aSXin Li /* Copyright (c) 2011 Xiph.Org Foundation
2*a58d3d2aSXin Li Written by Jean-Marc Valin */
3*a58d3d2aSXin Li /*
4*a58d3d2aSXin Li Redistribution and use in source and binary forms, with or without
5*a58d3d2aSXin Li modification, are permitted provided that the following conditions
6*a58d3d2aSXin Li are met:
7*a58d3d2aSXin Li
8*a58d3d2aSXin Li - Redistributions of source code must retain the above copyright
9*a58d3d2aSXin Li notice, this list of conditions and the following disclaimer.
10*a58d3d2aSXin Li
11*a58d3d2aSXin Li - Redistributions in binary form must reproduce the above copyright
12*a58d3d2aSXin Li notice, this list of conditions and the following disclaimer in the
13*a58d3d2aSXin Li documentation and/or other materials provided with the distribution.
14*a58d3d2aSXin Li
15*a58d3d2aSXin Li THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
16*a58d3d2aSXin Li ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
17*a58d3d2aSXin Li LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
18*a58d3d2aSXin Li A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR
19*a58d3d2aSXin Li CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
20*a58d3d2aSXin Li EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
21*a58d3d2aSXin Li PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
22*a58d3d2aSXin Li PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
23*a58d3d2aSXin Li LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
24*a58d3d2aSXin Li NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
25*a58d3d2aSXin Li SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
26*a58d3d2aSXin Li */
27*a58d3d2aSXin Li
28*a58d3d2aSXin Li #ifdef HAVE_CONFIG_H
29*a58d3d2aSXin Li #include "config.h"
30*a58d3d2aSXin Li #endif
31*a58d3d2aSXin Li
32*a58d3d2aSXin Li #define ANALYSIS_C
33*a58d3d2aSXin Li
34*a58d3d2aSXin Li #ifdef MLP_TRAINING
35*a58d3d2aSXin Li #include <stdio.h>
36*a58d3d2aSXin Li #endif
37*a58d3d2aSXin Li
38*a58d3d2aSXin Li #include "mathops.h"
39*a58d3d2aSXin Li #include "kiss_fft.h"
40*a58d3d2aSXin Li #include "celt.h"
41*a58d3d2aSXin Li #include "modes.h"
42*a58d3d2aSXin Li #include "arch.h"
43*a58d3d2aSXin Li #include "quant_bands.h"
44*a58d3d2aSXin Li #include "analysis.h"
45*a58d3d2aSXin Li #include "mlp.h"
46*a58d3d2aSXin Li #include "stack_alloc.h"
47*a58d3d2aSXin Li #include "float_cast.h"
48*a58d3d2aSXin Li
49*a58d3d2aSXin Li #ifndef M_PI
50*a58d3d2aSXin Li #define M_PI 3.141592653
51*a58d3d2aSXin Li #endif
52*a58d3d2aSXin Li
53*a58d3d2aSXin Li #ifndef DISABLE_FLOAT_API
54*a58d3d2aSXin Li
55*a58d3d2aSXin Li #define TRANSITION_PENALTY 10
56*a58d3d2aSXin Li
57*a58d3d2aSXin Li static const float dct_table[128] = {
58*a58d3d2aSXin Li 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f,
59*a58d3d2aSXin Li 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f, 0.250000f,
60*a58d3d2aSXin Li 0.351851f, 0.338330f, 0.311806f, 0.273300f, 0.224292f, 0.166664f, 0.102631f, 0.034654f,
61*a58d3d2aSXin Li -0.034654f,-0.102631f,-0.166664f,-0.224292f,-0.273300f,-0.311806f,-0.338330f,-0.351851f,
62*a58d3d2aSXin Li 0.346760f, 0.293969f, 0.196424f, 0.068975f,-0.068975f,-0.196424f,-0.293969f,-0.346760f,
63*a58d3d2aSXin Li -0.346760f,-0.293969f,-0.196424f,-0.068975f, 0.068975f, 0.196424f, 0.293969f, 0.346760f,
64*a58d3d2aSXin Li 0.338330f, 0.224292f, 0.034654f,-0.166664f,-0.311806f,-0.351851f,-0.273300f,-0.102631f,
65*a58d3d2aSXin Li 0.102631f, 0.273300f, 0.351851f, 0.311806f, 0.166664f,-0.034654f,-0.224292f,-0.338330f,
66*a58d3d2aSXin Li 0.326641f, 0.135299f,-0.135299f,-0.326641f,-0.326641f,-0.135299f, 0.135299f, 0.326641f,
67*a58d3d2aSXin Li 0.326641f, 0.135299f,-0.135299f,-0.326641f,-0.326641f,-0.135299f, 0.135299f, 0.326641f,
68*a58d3d2aSXin Li 0.311806f, 0.034654f,-0.273300f,-0.338330f,-0.102631f, 0.224292f, 0.351851f, 0.166664f,
69*a58d3d2aSXin Li -0.166664f,-0.351851f,-0.224292f, 0.102631f, 0.338330f, 0.273300f,-0.034654f,-0.311806f,
70*a58d3d2aSXin Li 0.293969f,-0.068975f,-0.346760f,-0.196424f, 0.196424f, 0.346760f, 0.068975f,-0.293969f,
71*a58d3d2aSXin Li -0.293969f, 0.068975f, 0.346760f, 0.196424f,-0.196424f,-0.346760f,-0.068975f, 0.293969f,
72*a58d3d2aSXin Li 0.273300f,-0.166664f,-0.338330f, 0.034654f, 0.351851f, 0.102631f,-0.311806f,-0.224292f,
73*a58d3d2aSXin Li 0.224292f, 0.311806f,-0.102631f,-0.351851f,-0.034654f, 0.338330f, 0.166664f,-0.273300f,
74*a58d3d2aSXin Li };
75*a58d3d2aSXin Li
76*a58d3d2aSXin Li static const float analysis_window[240] = {
77*a58d3d2aSXin Li 0.000043f, 0.000171f, 0.000385f, 0.000685f, 0.001071f, 0.001541f, 0.002098f, 0.002739f,
78*a58d3d2aSXin Li 0.003466f, 0.004278f, 0.005174f, 0.006156f, 0.007222f, 0.008373f, 0.009607f, 0.010926f,
79*a58d3d2aSXin Li 0.012329f, 0.013815f, 0.015385f, 0.017037f, 0.018772f, 0.020590f, 0.022490f, 0.024472f,
80*a58d3d2aSXin Li 0.026535f, 0.028679f, 0.030904f, 0.033210f, 0.035595f, 0.038060f, 0.040604f, 0.043227f,
81*a58d3d2aSXin Li 0.045928f, 0.048707f, 0.051564f, 0.054497f, 0.057506f, 0.060591f, 0.063752f, 0.066987f,
82*a58d3d2aSXin Li 0.070297f, 0.073680f, 0.077136f, 0.080665f, 0.084265f, 0.087937f, 0.091679f, 0.095492f,
83*a58d3d2aSXin Li 0.099373f, 0.103323f, 0.107342f, 0.111427f, 0.115579f, 0.119797f, 0.124080f, 0.128428f,
84*a58d3d2aSXin Li 0.132839f, 0.137313f, 0.141849f, 0.146447f, 0.151105f, 0.155823f, 0.160600f, 0.165435f,
85*a58d3d2aSXin Li 0.170327f, 0.175276f, 0.180280f, 0.185340f, 0.190453f, 0.195619f, 0.200838f, 0.206107f,
86*a58d3d2aSXin Li 0.211427f, 0.216797f, 0.222215f, 0.227680f, 0.233193f, 0.238751f, 0.244353f, 0.250000f,
87*a58d3d2aSXin Li 0.255689f, 0.261421f, 0.267193f, 0.273005f, 0.278856f, 0.284744f, 0.290670f, 0.296632f,
88*a58d3d2aSXin Li 0.302628f, 0.308658f, 0.314721f, 0.320816f, 0.326941f, 0.333097f, 0.339280f, 0.345492f,
89*a58d3d2aSXin Li 0.351729f, 0.357992f, 0.364280f, 0.370590f, 0.376923f, 0.383277f, 0.389651f, 0.396044f,
90*a58d3d2aSXin Li 0.402455f, 0.408882f, 0.415325f, 0.421783f, 0.428254f, 0.434737f, 0.441231f, 0.447736f,
91*a58d3d2aSXin Li 0.454249f, 0.460770f, 0.467298f, 0.473832f, 0.480370f, 0.486912f, 0.493455f, 0.500000f,
92*a58d3d2aSXin Li 0.506545f, 0.513088f, 0.519630f, 0.526168f, 0.532702f, 0.539230f, 0.545751f, 0.552264f,
93*a58d3d2aSXin Li 0.558769f, 0.565263f, 0.571746f, 0.578217f, 0.584675f, 0.591118f, 0.597545f, 0.603956f,
94*a58d3d2aSXin Li 0.610349f, 0.616723f, 0.623077f, 0.629410f, 0.635720f, 0.642008f, 0.648271f, 0.654508f,
95*a58d3d2aSXin Li 0.660720f, 0.666903f, 0.673059f, 0.679184f, 0.685279f, 0.691342f, 0.697372f, 0.703368f,
96*a58d3d2aSXin Li 0.709330f, 0.715256f, 0.721144f, 0.726995f, 0.732807f, 0.738579f, 0.744311f, 0.750000f,
97*a58d3d2aSXin Li 0.755647f, 0.761249f, 0.766807f, 0.772320f, 0.777785f, 0.783203f, 0.788573f, 0.793893f,
98*a58d3d2aSXin Li 0.799162f, 0.804381f, 0.809547f, 0.814660f, 0.819720f, 0.824724f, 0.829673f, 0.834565f,
99*a58d3d2aSXin Li 0.839400f, 0.844177f, 0.848895f, 0.853553f, 0.858151f, 0.862687f, 0.867161f, 0.871572f,
100*a58d3d2aSXin Li 0.875920f, 0.880203f, 0.884421f, 0.888573f, 0.892658f, 0.896677f, 0.900627f, 0.904508f,
101*a58d3d2aSXin Li 0.908321f, 0.912063f, 0.915735f, 0.919335f, 0.922864f, 0.926320f, 0.929703f, 0.933013f,
102*a58d3d2aSXin Li 0.936248f, 0.939409f, 0.942494f, 0.945503f, 0.948436f, 0.951293f, 0.954072f, 0.956773f,
103*a58d3d2aSXin Li 0.959396f, 0.961940f, 0.964405f, 0.966790f, 0.969096f, 0.971321f, 0.973465f, 0.975528f,
104*a58d3d2aSXin Li 0.977510f, 0.979410f, 0.981228f, 0.982963f, 0.984615f, 0.986185f, 0.987671f, 0.989074f,
105*a58d3d2aSXin Li 0.990393f, 0.991627f, 0.992778f, 0.993844f, 0.994826f, 0.995722f, 0.996534f, 0.997261f,
106*a58d3d2aSXin Li 0.997902f, 0.998459f, 0.998929f, 0.999315f, 0.999615f, 0.999829f, 0.999957f, 1.000000f,
107*a58d3d2aSXin Li };
108*a58d3d2aSXin Li
109*a58d3d2aSXin Li static const int tbands[NB_TBANDS+1] = {
110*a58d3d2aSXin Li 4, 8, 12, 16, 20, 24, 28, 32, 40, 48, 56, 64, 80, 96, 112, 136, 160, 192, 240
111*a58d3d2aSXin Li };
112*a58d3d2aSXin Li
113*a58d3d2aSXin Li #define NB_TONAL_SKIP_BANDS 9
114*a58d3d2aSXin Li
silk_resampler_down2_hp(opus_val32 * S,opus_val32 * out,const opus_val32 * in,int inLen)115*a58d3d2aSXin Li static opus_val32 silk_resampler_down2_hp(
116*a58d3d2aSXin Li opus_val32 *S, /* I/O State vector [ 2 ] */
117*a58d3d2aSXin Li opus_val32 *out, /* O Output signal [ floor(len/2) ] */
118*a58d3d2aSXin Li const opus_val32 *in, /* I Input signal [ len ] */
119*a58d3d2aSXin Li int inLen /* I Number of input samples */
120*a58d3d2aSXin Li )
121*a58d3d2aSXin Li {
122*a58d3d2aSXin Li int k, len2 = inLen/2;
123*a58d3d2aSXin Li opus_val32 in32, out32, out32_hp, Y, X;
124*a58d3d2aSXin Li opus_val64 hp_ener = 0;
125*a58d3d2aSXin Li /* Internal variables and state are in Q10 format */
126*a58d3d2aSXin Li for( k = 0; k < len2; k++ ) {
127*a58d3d2aSXin Li /* Convert to Q10 */
128*a58d3d2aSXin Li in32 = in[ 2 * k ];
129*a58d3d2aSXin Li
130*a58d3d2aSXin Li /* All-pass section for even input sample */
131*a58d3d2aSXin Li Y = SUB32( in32, S[ 0 ] );
132*a58d3d2aSXin Li X = MULT16_32_Q15(QCONST16(0.6074371f, 15), Y);
133*a58d3d2aSXin Li out32 = ADD32( S[ 0 ], X );
134*a58d3d2aSXin Li S[ 0 ] = ADD32( in32, X );
135*a58d3d2aSXin Li out32_hp = out32;
136*a58d3d2aSXin Li /* Convert to Q10 */
137*a58d3d2aSXin Li in32 = in[ 2 * k + 1 ];
138*a58d3d2aSXin Li
139*a58d3d2aSXin Li /* All-pass section for odd input sample, and add to output of previous section */
140*a58d3d2aSXin Li Y = SUB32( in32, S[ 1 ] );
141*a58d3d2aSXin Li X = MULT16_32_Q15(QCONST16(0.15063f, 15), Y);
142*a58d3d2aSXin Li out32 = ADD32( out32, S[ 1 ] );
143*a58d3d2aSXin Li out32 = ADD32( out32, X );
144*a58d3d2aSXin Li S[ 1 ] = ADD32( in32, X );
145*a58d3d2aSXin Li
146*a58d3d2aSXin Li Y = SUB32( -in32, S[ 2 ] );
147*a58d3d2aSXin Li X = MULT16_32_Q15(QCONST16(0.15063f, 15), Y);
148*a58d3d2aSXin Li out32_hp = ADD32( out32_hp, S[ 2 ] );
149*a58d3d2aSXin Li out32_hp = ADD32( out32_hp, X );
150*a58d3d2aSXin Li S[ 2 ] = ADD32( -in32, X );
151*a58d3d2aSXin Li
152*a58d3d2aSXin Li if(__builtin_add_overflow(hp_ener, out32_hp*(opus_val64)out32_hp, &hp_ener))
153*a58d3d2aSXin Li {
154*a58d3d2aSXin Li hp_ener = UINT64_MAX;
155*a58d3d2aSXin Li }
156*a58d3d2aSXin Li /* Add, convert back to int16 and store to output */
157*a58d3d2aSXin Li out[ k ] = HALF32(out32);
158*a58d3d2aSXin Li }
159*a58d3d2aSXin Li #ifdef FIXED_POINT
160*a58d3d2aSXin Li /* len2 can be up to 480, so we shift by 8 more to make it fit. */
161*a58d3d2aSXin Li hp_ener = hp_ener >> (2*SIG_SHIFT + 8);
162*a58d3d2aSXin Li #endif
163*a58d3d2aSXin Li return (opus_val32)hp_ener;
164*a58d3d2aSXin Li }
165*a58d3d2aSXin Li
downmix_and_resample(downmix_func downmix,const void * _x,opus_val32 * y,opus_val32 S[3],int subframe,int offset,int c1,int c2,int C,int Fs)166*a58d3d2aSXin Li static opus_val32 downmix_and_resample(downmix_func downmix, const void *_x, opus_val32 *y, opus_val32 S[3], int subframe, int offset, int c1, int c2, int C, int Fs)
167*a58d3d2aSXin Li {
168*a58d3d2aSXin Li VARDECL(opus_val32, tmp);
169*a58d3d2aSXin Li opus_val32 scale;
170*a58d3d2aSXin Li int j;
171*a58d3d2aSXin Li opus_val32 ret = 0;
172*a58d3d2aSXin Li SAVE_STACK;
173*a58d3d2aSXin Li
174*a58d3d2aSXin Li if (subframe==0) return 0;
175*a58d3d2aSXin Li if (Fs == 48000)
176*a58d3d2aSXin Li {
177*a58d3d2aSXin Li subframe *= 2;
178*a58d3d2aSXin Li offset *= 2;
179*a58d3d2aSXin Li } else if (Fs == 16000) {
180*a58d3d2aSXin Li subframe = subframe*2/3;
181*a58d3d2aSXin Li offset = offset*2/3;
182*a58d3d2aSXin Li }
183*a58d3d2aSXin Li ALLOC(tmp, subframe, opus_val32);
184*a58d3d2aSXin Li
185*a58d3d2aSXin Li downmix(_x, tmp, subframe, offset, c1, c2, C);
186*a58d3d2aSXin Li #ifdef FIXED_POINT
187*a58d3d2aSXin Li scale = (1<<SIG_SHIFT);
188*a58d3d2aSXin Li #else
189*a58d3d2aSXin Li scale = 1.f/32768;
190*a58d3d2aSXin Li #endif
191*a58d3d2aSXin Li if (c2==-2)
192*a58d3d2aSXin Li scale /= C;
193*a58d3d2aSXin Li else if (c2>-1)
194*a58d3d2aSXin Li scale /= 2;
195*a58d3d2aSXin Li for (j=0;j<subframe;j++)
196*a58d3d2aSXin Li tmp[j] *= scale;
197*a58d3d2aSXin Li if (Fs == 48000)
198*a58d3d2aSXin Li {
199*a58d3d2aSXin Li ret = silk_resampler_down2_hp(S, y, tmp, subframe);
200*a58d3d2aSXin Li } else if (Fs == 24000) {
201*a58d3d2aSXin Li OPUS_COPY(y, tmp, subframe);
202*a58d3d2aSXin Li } else if (Fs == 16000) {
203*a58d3d2aSXin Li VARDECL(opus_val32, tmp3x);
204*a58d3d2aSXin Li ALLOC(tmp3x, 3*subframe, opus_val32);
205*a58d3d2aSXin Li /* Don't do this at home! This resampler is horrible and it's only (barely)
206*a58d3d2aSXin Li usable for the purpose of the analysis because we don't care about all
207*a58d3d2aSXin Li the aliasing between 8 kHz and 12 kHz. */
208*a58d3d2aSXin Li for (j=0;j<subframe;j++)
209*a58d3d2aSXin Li {
210*a58d3d2aSXin Li tmp3x[3*j] = tmp[j];
211*a58d3d2aSXin Li tmp3x[3*j+1] = tmp[j];
212*a58d3d2aSXin Li tmp3x[3*j+2] = tmp[j];
213*a58d3d2aSXin Li }
214*a58d3d2aSXin Li silk_resampler_down2_hp(S, y, tmp3x, 3*subframe);
215*a58d3d2aSXin Li }
216*a58d3d2aSXin Li RESTORE_STACK;
217*a58d3d2aSXin Li return ret;
218*a58d3d2aSXin Li }
219*a58d3d2aSXin Li
tonality_analysis_init(TonalityAnalysisState * tonal,opus_int32 Fs)220*a58d3d2aSXin Li void tonality_analysis_init(TonalityAnalysisState *tonal, opus_int32 Fs)
221*a58d3d2aSXin Li {
222*a58d3d2aSXin Li /* Initialize reusable fields. */
223*a58d3d2aSXin Li tonal->arch = opus_select_arch();
224*a58d3d2aSXin Li tonal->Fs = Fs;
225*a58d3d2aSXin Li /* Clear remaining fields. */
226*a58d3d2aSXin Li tonality_analysis_reset(tonal);
227*a58d3d2aSXin Li }
228*a58d3d2aSXin Li
tonality_analysis_reset(TonalityAnalysisState * tonal)229*a58d3d2aSXin Li void tonality_analysis_reset(TonalityAnalysisState *tonal)
230*a58d3d2aSXin Li {
231*a58d3d2aSXin Li /* Clear non-reusable fields. */
232*a58d3d2aSXin Li char *start = (char*)&tonal->TONALITY_ANALYSIS_RESET_START;
233*a58d3d2aSXin Li OPUS_CLEAR(start, sizeof(TonalityAnalysisState) - (start - (char*)tonal));
234*a58d3d2aSXin Li }
235*a58d3d2aSXin Li
tonality_get_info(TonalityAnalysisState * tonal,AnalysisInfo * info_out,int len)236*a58d3d2aSXin Li void tonality_get_info(TonalityAnalysisState *tonal, AnalysisInfo *info_out, int len)
237*a58d3d2aSXin Li {
238*a58d3d2aSXin Li int pos;
239*a58d3d2aSXin Li int curr_lookahead;
240*a58d3d2aSXin Li float tonality_max;
241*a58d3d2aSXin Li float tonality_avg;
242*a58d3d2aSXin Li int tonality_count;
243*a58d3d2aSXin Li int i;
244*a58d3d2aSXin Li int pos0;
245*a58d3d2aSXin Li float prob_avg;
246*a58d3d2aSXin Li float prob_count;
247*a58d3d2aSXin Li float prob_min, prob_max;
248*a58d3d2aSXin Li float vad_prob;
249*a58d3d2aSXin Li int mpos, vpos;
250*a58d3d2aSXin Li int bandwidth_span;
251*a58d3d2aSXin Li
252*a58d3d2aSXin Li pos = tonal->read_pos;
253*a58d3d2aSXin Li curr_lookahead = tonal->write_pos-tonal->read_pos;
254*a58d3d2aSXin Li if (curr_lookahead<0)
255*a58d3d2aSXin Li curr_lookahead += DETECT_SIZE;
256*a58d3d2aSXin Li
257*a58d3d2aSXin Li tonal->read_subframe += len/(tonal->Fs/400);
258*a58d3d2aSXin Li while (tonal->read_subframe>=8)
259*a58d3d2aSXin Li {
260*a58d3d2aSXin Li tonal->read_subframe -= 8;
261*a58d3d2aSXin Li tonal->read_pos++;
262*a58d3d2aSXin Li }
263*a58d3d2aSXin Li if (tonal->read_pos>=DETECT_SIZE)
264*a58d3d2aSXin Li tonal->read_pos-=DETECT_SIZE;
265*a58d3d2aSXin Li
266*a58d3d2aSXin Li /* On long frames, look at the second analysis window rather than the first. */
267*a58d3d2aSXin Li if (len > tonal->Fs/50 && pos != tonal->write_pos)
268*a58d3d2aSXin Li {
269*a58d3d2aSXin Li pos++;
270*a58d3d2aSXin Li if (pos==DETECT_SIZE)
271*a58d3d2aSXin Li pos=0;
272*a58d3d2aSXin Li }
273*a58d3d2aSXin Li if (pos == tonal->write_pos)
274*a58d3d2aSXin Li pos--;
275*a58d3d2aSXin Li if (pos<0)
276*a58d3d2aSXin Li pos = DETECT_SIZE-1;
277*a58d3d2aSXin Li pos0 = pos;
278*a58d3d2aSXin Li OPUS_COPY(info_out, &tonal->info[pos], 1);
279*a58d3d2aSXin Li if (!info_out->valid)
280*a58d3d2aSXin Li return;
281*a58d3d2aSXin Li tonality_max = tonality_avg = info_out->tonality;
282*a58d3d2aSXin Li tonality_count = 1;
283*a58d3d2aSXin Li /* Look at the neighbouring frames and pick largest bandwidth found (to be safe). */
284*a58d3d2aSXin Li bandwidth_span = 6;
285*a58d3d2aSXin Li /* If possible, look ahead for a tone to compensate for the delay in the tone detector. */
286*a58d3d2aSXin Li for (i=0;i<3;i++)
287*a58d3d2aSXin Li {
288*a58d3d2aSXin Li pos++;
289*a58d3d2aSXin Li if (pos==DETECT_SIZE)
290*a58d3d2aSXin Li pos = 0;
291*a58d3d2aSXin Li if (pos == tonal->write_pos)
292*a58d3d2aSXin Li break;
293*a58d3d2aSXin Li tonality_max = MAX32(tonality_max, tonal->info[pos].tonality);
294*a58d3d2aSXin Li tonality_avg += tonal->info[pos].tonality;
295*a58d3d2aSXin Li tonality_count++;
296*a58d3d2aSXin Li info_out->bandwidth = IMAX(info_out->bandwidth, tonal->info[pos].bandwidth);
297*a58d3d2aSXin Li bandwidth_span--;
298*a58d3d2aSXin Li }
299*a58d3d2aSXin Li pos = pos0;
300*a58d3d2aSXin Li /* Look back in time to see if any has a wider bandwidth than the current frame. */
301*a58d3d2aSXin Li for (i=0;i<bandwidth_span;i++)
302*a58d3d2aSXin Li {
303*a58d3d2aSXin Li pos--;
304*a58d3d2aSXin Li if (pos < 0)
305*a58d3d2aSXin Li pos = DETECT_SIZE-1;
306*a58d3d2aSXin Li if (pos == tonal->write_pos)
307*a58d3d2aSXin Li break;
308*a58d3d2aSXin Li info_out->bandwidth = IMAX(info_out->bandwidth, tonal->info[pos].bandwidth);
309*a58d3d2aSXin Li }
310*a58d3d2aSXin Li info_out->tonality = MAX32(tonality_avg/tonality_count, tonality_max-.2f);
311*a58d3d2aSXin Li
312*a58d3d2aSXin Li mpos = vpos = pos0;
313*a58d3d2aSXin Li /* If we have enough look-ahead, compensate for the ~5-frame delay in the music prob and
314*a58d3d2aSXin Li ~1 frame delay in the VAD prob. */
315*a58d3d2aSXin Li if (curr_lookahead > 15)
316*a58d3d2aSXin Li {
317*a58d3d2aSXin Li mpos += 5;
318*a58d3d2aSXin Li if (mpos>=DETECT_SIZE)
319*a58d3d2aSXin Li mpos -= DETECT_SIZE;
320*a58d3d2aSXin Li vpos += 1;
321*a58d3d2aSXin Li if (vpos>=DETECT_SIZE)
322*a58d3d2aSXin Li vpos -= DETECT_SIZE;
323*a58d3d2aSXin Li }
324*a58d3d2aSXin Li
325*a58d3d2aSXin Li /* The following calculations attempt to minimize a "badness function"
326*a58d3d2aSXin Li for the transition. When switching from speech to music, the badness
327*a58d3d2aSXin Li of switching at frame k is
328*a58d3d2aSXin Li b_k = S*v_k + \sum_{i=0}^{k-1} v_i*(p_i - T)
329*a58d3d2aSXin Li where
330*a58d3d2aSXin Li v_i is the activity probability (VAD) at frame i,
331*a58d3d2aSXin Li p_i is the music probability at frame i
332*a58d3d2aSXin Li T is the probability threshold for switching
333*a58d3d2aSXin Li S is the penalty for switching during active audio rather than silence
334*a58d3d2aSXin Li the current frame has index i=0
335*a58d3d2aSXin Li
336*a58d3d2aSXin Li Rather than apply badness to directly decide when to switch, what we compute
337*a58d3d2aSXin Li instead is the threshold for which the optimal switching point is now. When
338*a58d3d2aSXin Li considering whether to switch now (frame 0) or at frame k, we have:
339*a58d3d2aSXin Li S*v_0 = S*v_k + \sum_{i=0}^{k-1} v_i*(p_i - T)
340*a58d3d2aSXin Li which gives us:
341*a58d3d2aSXin Li T = ( \sum_{i=0}^{k-1} v_i*p_i + S*(v_k-v_0) ) / ( \sum_{i=0}^{k-1} v_i )
342*a58d3d2aSXin Li We take the min threshold across all positive values of k (up to the maximum
343*a58d3d2aSXin Li amount of lookahead we have) to give us the threshold for which the current
344*a58d3d2aSXin Li frame is the optimal switch point.
345*a58d3d2aSXin Li
346*a58d3d2aSXin Li The last step is that we need to consider whether we want to switch at all.
347*a58d3d2aSXin Li For that we use the average of the music probability over the entire window.
348*a58d3d2aSXin Li If the threshold is higher than that average we're not going to
349*a58d3d2aSXin Li switch, so we compute a min with the average as well. The result of all these
350*a58d3d2aSXin Li min operations is music_prob_min, which gives the threshold for switching to music
351*a58d3d2aSXin Li if we're currently encoding for speech.
352*a58d3d2aSXin Li
353*a58d3d2aSXin Li We do the exact opposite to compute music_prob_max which is used for switching
354*a58d3d2aSXin Li from music to speech.
355*a58d3d2aSXin Li */
356*a58d3d2aSXin Li prob_min = 1.f;
357*a58d3d2aSXin Li prob_max = 0.f;
358*a58d3d2aSXin Li vad_prob = tonal->info[vpos].activity_probability;
359*a58d3d2aSXin Li prob_count = MAX16(.1f, vad_prob);
360*a58d3d2aSXin Li prob_avg = MAX16(.1f, vad_prob)*tonal->info[mpos].music_prob;
361*a58d3d2aSXin Li while (1)
362*a58d3d2aSXin Li {
363*a58d3d2aSXin Li float pos_vad;
364*a58d3d2aSXin Li mpos++;
365*a58d3d2aSXin Li if (mpos==DETECT_SIZE)
366*a58d3d2aSXin Li mpos = 0;
367*a58d3d2aSXin Li if (mpos == tonal->write_pos)
368*a58d3d2aSXin Li break;
369*a58d3d2aSXin Li vpos++;
370*a58d3d2aSXin Li if (vpos==DETECT_SIZE)
371*a58d3d2aSXin Li vpos = 0;
372*a58d3d2aSXin Li if (vpos == tonal->write_pos)
373*a58d3d2aSXin Li break;
374*a58d3d2aSXin Li pos_vad = tonal->info[vpos].activity_probability;
375*a58d3d2aSXin Li prob_min = MIN16((prob_avg - TRANSITION_PENALTY*(vad_prob - pos_vad))/prob_count, prob_min);
376*a58d3d2aSXin Li prob_max = MAX16((prob_avg + TRANSITION_PENALTY*(vad_prob - pos_vad))/prob_count, prob_max);
377*a58d3d2aSXin Li prob_count += MAX16(.1f, pos_vad);
378*a58d3d2aSXin Li prob_avg += MAX16(.1f, pos_vad)*tonal->info[mpos].music_prob;
379*a58d3d2aSXin Li }
380*a58d3d2aSXin Li info_out->music_prob = prob_avg/prob_count;
381*a58d3d2aSXin Li prob_min = MIN16(prob_avg/prob_count, prob_min);
382*a58d3d2aSXin Li prob_max = MAX16(prob_avg/prob_count, prob_max);
383*a58d3d2aSXin Li prob_min = MAX16(prob_min, 0.f);
384*a58d3d2aSXin Li prob_max = MIN16(prob_max, 1.f);
385*a58d3d2aSXin Li
386*a58d3d2aSXin Li /* If we don't have enough look-ahead, do our best to make a decent decision. */
387*a58d3d2aSXin Li if (curr_lookahead < 10)
388*a58d3d2aSXin Li {
389*a58d3d2aSXin Li float pmin, pmax;
390*a58d3d2aSXin Li pmin = prob_min;
391*a58d3d2aSXin Li pmax = prob_max;
392*a58d3d2aSXin Li pos = pos0;
393*a58d3d2aSXin Li /* Look for min/max in the past. */
394*a58d3d2aSXin Li for (i=0;i<IMIN(tonal->count-1, 15);i++)
395*a58d3d2aSXin Li {
396*a58d3d2aSXin Li pos--;
397*a58d3d2aSXin Li if (pos < 0)
398*a58d3d2aSXin Li pos = DETECT_SIZE-1;
399*a58d3d2aSXin Li pmin = MIN16(pmin, tonal->info[pos].music_prob);
400*a58d3d2aSXin Li pmax = MAX16(pmax, tonal->info[pos].music_prob);
401*a58d3d2aSXin Li }
402*a58d3d2aSXin Li /* Bias against switching on active audio. */
403*a58d3d2aSXin Li pmin = MAX16(0.f, pmin - .1f*vad_prob);
404*a58d3d2aSXin Li pmax = MIN16(1.f, pmax + .1f*vad_prob);
405*a58d3d2aSXin Li prob_min += (1.f-.1f*curr_lookahead)*(pmin - prob_min);
406*a58d3d2aSXin Li prob_max += (1.f-.1f*curr_lookahead)*(pmax - prob_max);
407*a58d3d2aSXin Li }
408*a58d3d2aSXin Li info_out->music_prob_min = prob_min;
409*a58d3d2aSXin Li info_out->music_prob_max = prob_max;
410*a58d3d2aSXin Li
411*a58d3d2aSXin Li /* printf("%f %f %f %f %f\n", prob_min, prob_max, prob_avg/prob_count, vad_prob, info_out->music_prob); */
412*a58d3d2aSXin Li }
413*a58d3d2aSXin Li
414*a58d3d2aSXin Li static const float std_feature_bias[9] = {
415*a58d3d2aSXin Li 5.684947f, 3.475288f, 1.770634f, 1.599784f, 3.773215f,
416*a58d3d2aSXin Li 2.163313f, 1.260756f, 1.116868f, 1.918795f
417*a58d3d2aSXin Li };
418*a58d3d2aSXin Li
419*a58d3d2aSXin Li #define LEAKAGE_OFFSET 2.5f
420*a58d3d2aSXin Li #define LEAKAGE_SLOPE 2.f
421*a58d3d2aSXin Li
422*a58d3d2aSXin Li #ifdef FIXED_POINT
423*a58d3d2aSXin Li /* For fixed-point, the input is +/-2^15 shifted up by SIG_SHIFT, so we need to
424*a58d3d2aSXin Li compensate for that in the energy. */
425*a58d3d2aSXin Li #define SCALE_COMPENS (1.f/((opus_int32)1<<(15+SIG_SHIFT)))
426*a58d3d2aSXin Li #define SCALE_ENER(e) ((SCALE_COMPENS*SCALE_COMPENS)*(e))
427*a58d3d2aSXin Li #else
428*a58d3d2aSXin Li #define SCALE_ENER(e) (e)
429*a58d3d2aSXin Li #endif
430*a58d3d2aSXin Li
431*a58d3d2aSXin Li #ifdef FIXED_POINT
is_digital_silence32(const opus_val32 * pcm,int frame_size,int channels,int lsb_depth)432*a58d3d2aSXin Li static int is_digital_silence32(const opus_val32* pcm, int frame_size, int channels, int lsb_depth)
433*a58d3d2aSXin Li {
434*a58d3d2aSXin Li int silence = 0;
435*a58d3d2aSXin Li opus_val32 sample_max = 0;
436*a58d3d2aSXin Li #ifdef MLP_TRAINING
437*a58d3d2aSXin Li return 0;
438*a58d3d2aSXin Li #endif
439*a58d3d2aSXin Li sample_max = celt_maxabs32(pcm, frame_size*channels);
440*a58d3d2aSXin Li
441*a58d3d2aSXin Li silence = (sample_max == 0);
442*a58d3d2aSXin Li (void)lsb_depth;
443*a58d3d2aSXin Li return silence;
444*a58d3d2aSXin Li }
445*a58d3d2aSXin Li #else
446*a58d3d2aSXin Li #define is_digital_silence32(pcm, frame_size, channels, lsb_depth) is_digital_silence(pcm, frame_size, channels, lsb_depth)
447*a58d3d2aSXin Li #endif
448*a58d3d2aSXin Li
tonality_analysis(TonalityAnalysisState * tonal,const CELTMode * celt_mode,const void * x,int len,int offset,int c1,int c2,int C,int lsb_depth,downmix_func downmix)449*a58d3d2aSXin Li static void tonality_analysis(TonalityAnalysisState *tonal, const CELTMode *celt_mode, const void *x, int len, int offset, int c1, int c2, int C, int lsb_depth, downmix_func downmix)
450*a58d3d2aSXin Li {
451*a58d3d2aSXin Li int i, b;
452*a58d3d2aSXin Li const kiss_fft_state *kfft;
453*a58d3d2aSXin Li VARDECL(kiss_fft_cpx, in);
454*a58d3d2aSXin Li VARDECL(kiss_fft_cpx, out);
455*a58d3d2aSXin Li int N = 480, N2=240;
456*a58d3d2aSXin Li float * OPUS_RESTRICT A = tonal->angle;
457*a58d3d2aSXin Li float * OPUS_RESTRICT dA = tonal->d_angle;
458*a58d3d2aSXin Li float * OPUS_RESTRICT d2A = tonal->d2_angle;
459*a58d3d2aSXin Li VARDECL(float, tonality);
460*a58d3d2aSXin Li VARDECL(float, noisiness);
461*a58d3d2aSXin Li float band_tonality[NB_TBANDS];
462*a58d3d2aSXin Li float logE[NB_TBANDS];
463*a58d3d2aSXin Li float BFCC[8];
464*a58d3d2aSXin Li float features[25];
465*a58d3d2aSXin Li float frame_tonality;
466*a58d3d2aSXin Li float max_frame_tonality;
467*a58d3d2aSXin Li /*float tw_sum=0;*/
468*a58d3d2aSXin Li float frame_noisiness;
469*a58d3d2aSXin Li const float pi4 = (float)(M_PI*M_PI*M_PI*M_PI);
470*a58d3d2aSXin Li float slope=0;
471*a58d3d2aSXin Li float frame_stationarity;
472*a58d3d2aSXin Li float relativeE;
473*a58d3d2aSXin Li float frame_probs[2];
474*a58d3d2aSXin Li float alpha, alphaE, alphaE2;
475*a58d3d2aSXin Li float frame_loudness;
476*a58d3d2aSXin Li float bandwidth_mask;
477*a58d3d2aSXin Li int is_masked[NB_TBANDS+1];
478*a58d3d2aSXin Li int bandwidth=0;
479*a58d3d2aSXin Li float maxE = 0;
480*a58d3d2aSXin Li float noise_floor;
481*a58d3d2aSXin Li int remaining;
482*a58d3d2aSXin Li AnalysisInfo *info;
483*a58d3d2aSXin Li float hp_ener;
484*a58d3d2aSXin Li float tonality2[240];
485*a58d3d2aSXin Li float midE[8];
486*a58d3d2aSXin Li float spec_variability=0;
487*a58d3d2aSXin Li float band_log2[NB_TBANDS+1];
488*a58d3d2aSXin Li float leakage_from[NB_TBANDS+1];
489*a58d3d2aSXin Li float leakage_to[NB_TBANDS+1];
490*a58d3d2aSXin Li float layer_out[MAX_NEURONS];
491*a58d3d2aSXin Li float below_max_pitch;
492*a58d3d2aSXin Li float above_max_pitch;
493*a58d3d2aSXin Li int is_silence;
494*a58d3d2aSXin Li SAVE_STACK;
495*a58d3d2aSXin Li
496*a58d3d2aSXin Li if (!tonal->initialized)
497*a58d3d2aSXin Li {
498*a58d3d2aSXin Li tonal->mem_fill = 240;
499*a58d3d2aSXin Li tonal->initialized = 1;
500*a58d3d2aSXin Li }
501*a58d3d2aSXin Li alpha = 1.f/IMIN(10, 1+tonal->count);
502*a58d3d2aSXin Li alphaE = 1.f/IMIN(25, 1+tonal->count);
503*a58d3d2aSXin Li /* Noise floor related decay for bandwidth detection: -2.2 dB/second */
504*a58d3d2aSXin Li alphaE2 = 1.f/IMIN(100, 1+tonal->count);
505*a58d3d2aSXin Li if (tonal->count <= 1) alphaE2 = 1;
506*a58d3d2aSXin Li
507*a58d3d2aSXin Li if (tonal->Fs == 48000)
508*a58d3d2aSXin Li {
509*a58d3d2aSXin Li /* len and offset are now at 24 kHz. */
510*a58d3d2aSXin Li len/= 2;
511*a58d3d2aSXin Li offset /= 2;
512*a58d3d2aSXin Li } else if (tonal->Fs == 16000) {
513*a58d3d2aSXin Li len = 3*len/2;
514*a58d3d2aSXin Li offset = 3*offset/2;
515*a58d3d2aSXin Li }
516*a58d3d2aSXin Li
517*a58d3d2aSXin Li kfft = celt_mode->mdct.kfft[0];
518*a58d3d2aSXin Li tonal->hp_ener_accum += (float)downmix_and_resample(downmix, x,
519*a58d3d2aSXin Li &tonal->inmem[tonal->mem_fill], tonal->downmix_state,
520*a58d3d2aSXin Li IMIN(len, ANALYSIS_BUF_SIZE-tonal->mem_fill), offset, c1, c2, C, tonal->Fs);
521*a58d3d2aSXin Li if (tonal->mem_fill+len < ANALYSIS_BUF_SIZE)
522*a58d3d2aSXin Li {
523*a58d3d2aSXin Li tonal->mem_fill += len;
524*a58d3d2aSXin Li /* Don't have enough to update the analysis */
525*a58d3d2aSXin Li RESTORE_STACK;
526*a58d3d2aSXin Li return;
527*a58d3d2aSXin Li }
528*a58d3d2aSXin Li hp_ener = tonal->hp_ener_accum;
529*a58d3d2aSXin Li info = &tonal->info[tonal->write_pos++];
530*a58d3d2aSXin Li if (tonal->write_pos>=DETECT_SIZE)
531*a58d3d2aSXin Li tonal->write_pos-=DETECT_SIZE;
532*a58d3d2aSXin Li
533*a58d3d2aSXin Li is_silence = is_digital_silence32(tonal->inmem, ANALYSIS_BUF_SIZE, 1, lsb_depth);
534*a58d3d2aSXin Li
535*a58d3d2aSXin Li ALLOC(in, 480, kiss_fft_cpx);
536*a58d3d2aSXin Li ALLOC(out, 480, kiss_fft_cpx);
537*a58d3d2aSXin Li ALLOC(tonality, 240, float);
538*a58d3d2aSXin Li ALLOC(noisiness, 240, float);
539*a58d3d2aSXin Li for (i=0;i<N2;i++)
540*a58d3d2aSXin Li {
541*a58d3d2aSXin Li float w = analysis_window[i];
542*a58d3d2aSXin Li in[i].r = (kiss_fft_scalar)(w*tonal->inmem[i]);
543*a58d3d2aSXin Li in[i].i = (kiss_fft_scalar)(w*tonal->inmem[N2+i]);
544*a58d3d2aSXin Li in[N-i-1].r = (kiss_fft_scalar)(w*tonal->inmem[N-i-1]);
545*a58d3d2aSXin Li in[N-i-1].i = (kiss_fft_scalar)(w*tonal->inmem[N+N2-i-1]);
546*a58d3d2aSXin Li }
547*a58d3d2aSXin Li OPUS_MOVE(tonal->inmem, tonal->inmem+ANALYSIS_BUF_SIZE-240, 240);
548*a58d3d2aSXin Li remaining = len - (ANALYSIS_BUF_SIZE-tonal->mem_fill);
549*a58d3d2aSXin Li tonal->hp_ener_accum = (float)downmix_and_resample(downmix, x,
550*a58d3d2aSXin Li &tonal->inmem[240], tonal->downmix_state, remaining,
551*a58d3d2aSXin Li offset+ANALYSIS_BUF_SIZE-tonal->mem_fill, c1, c2, C, tonal->Fs);
552*a58d3d2aSXin Li tonal->mem_fill = 240 + remaining;
553*a58d3d2aSXin Li if (is_silence)
554*a58d3d2aSXin Li {
555*a58d3d2aSXin Li /* On silence, copy the previous analysis. */
556*a58d3d2aSXin Li int prev_pos = tonal->write_pos-2;
557*a58d3d2aSXin Li if (prev_pos < 0)
558*a58d3d2aSXin Li prev_pos += DETECT_SIZE;
559*a58d3d2aSXin Li OPUS_COPY(info, &tonal->info[prev_pos], 1);
560*a58d3d2aSXin Li RESTORE_STACK;
561*a58d3d2aSXin Li return;
562*a58d3d2aSXin Li }
563*a58d3d2aSXin Li opus_fft(kfft, in, out, tonal->arch);
564*a58d3d2aSXin Li #ifndef FIXED_POINT
565*a58d3d2aSXin Li /* If there's any NaN on the input, the entire output will be NaN, so we only need to check one value. */
566*a58d3d2aSXin Li if (celt_isnan(out[0].r))
567*a58d3d2aSXin Li {
568*a58d3d2aSXin Li info->valid = 0;
569*a58d3d2aSXin Li RESTORE_STACK;
570*a58d3d2aSXin Li return;
571*a58d3d2aSXin Li }
572*a58d3d2aSXin Li #endif
573*a58d3d2aSXin Li
574*a58d3d2aSXin Li for (i=1;i<N2;i++)
575*a58d3d2aSXin Li {
576*a58d3d2aSXin Li float X1r, X2r, X1i, X2i;
577*a58d3d2aSXin Li float angle, d_angle, d2_angle;
578*a58d3d2aSXin Li float angle2, d_angle2, d2_angle2;
579*a58d3d2aSXin Li float mod1, mod2, avg_mod;
580*a58d3d2aSXin Li X1r = (float)out[i].r+out[N-i].r;
581*a58d3d2aSXin Li X1i = (float)out[i].i-out[N-i].i;
582*a58d3d2aSXin Li X2r = (float)out[i].i+out[N-i].i;
583*a58d3d2aSXin Li X2i = (float)out[N-i].r-out[i].r;
584*a58d3d2aSXin Li
585*a58d3d2aSXin Li angle = (float)(.5f/M_PI)*fast_atan2f(X1i, X1r);
586*a58d3d2aSXin Li d_angle = angle - A[i];
587*a58d3d2aSXin Li d2_angle = d_angle - dA[i];
588*a58d3d2aSXin Li
589*a58d3d2aSXin Li angle2 = (float)(.5f/M_PI)*fast_atan2f(X2i, X2r);
590*a58d3d2aSXin Li d_angle2 = angle2 - angle;
591*a58d3d2aSXin Li d2_angle2 = d_angle2 - d_angle;
592*a58d3d2aSXin Li
593*a58d3d2aSXin Li mod1 = d2_angle - (float)float2int(d2_angle);
594*a58d3d2aSXin Li noisiness[i] = ABS16(mod1);
595*a58d3d2aSXin Li mod1 *= mod1;
596*a58d3d2aSXin Li mod1 *= mod1;
597*a58d3d2aSXin Li
598*a58d3d2aSXin Li mod2 = d2_angle2 - (float)float2int(d2_angle2);
599*a58d3d2aSXin Li noisiness[i] += ABS16(mod2);
600*a58d3d2aSXin Li mod2 *= mod2;
601*a58d3d2aSXin Li mod2 *= mod2;
602*a58d3d2aSXin Li
603*a58d3d2aSXin Li avg_mod = .25f*(d2A[i]+mod1+2*mod2);
604*a58d3d2aSXin Li /* This introduces an extra delay of 2 frames in the detection. */
605*a58d3d2aSXin Li tonality[i] = 1.f/(1.f+40.f*16.f*pi4*avg_mod)-.015f;
606*a58d3d2aSXin Li /* No delay on this detection, but it's less reliable. */
607*a58d3d2aSXin Li tonality2[i] = 1.f/(1.f+40.f*16.f*pi4*mod2)-.015f;
608*a58d3d2aSXin Li
609*a58d3d2aSXin Li A[i] = angle2;
610*a58d3d2aSXin Li dA[i] = d_angle2;
611*a58d3d2aSXin Li d2A[i] = mod2;
612*a58d3d2aSXin Li }
613*a58d3d2aSXin Li for (i=2;i<N2-1;i++)
614*a58d3d2aSXin Li {
615*a58d3d2aSXin Li float tt = MIN32(tonality2[i], MAX32(tonality2[i-1], tonality2[i+1]));
616*a58d3d2aSXin Li tonality[i] = .9f*MAX32(tonality[i], tt-.1f);
617*a58d3d2aSXin Li }
618*a58d3d2aSXin Li frame_tonality = 0;
619*a58d3d2aSXin Li max_frame_tonality = 0;
620*a58d3d2aSXin Li /*tw_sum = 0;*/
621*a58d3d2aSXin Li info->activity = 0;
622*a58d3d2aSXin Li frame_noisiness = 0;
623*a58d3d2aSXin Li frame_stationarity = 0;
624*a58d3d2aSXin Li if (!tonal->count)
625*a58d3d2aSXin Li {
626*a58d3d2aSXin Li for (b=0;b<NB_TBANDS;b++)
627*a58d3d2aSXin Li {
628*a58d3d2aSXin Li tonal->lowE[b] = 1e10;
629*a58d3d2aSXin Li tonal->highE[b] = -1e10;
630*a58d3d2aSXin Li }
631*a58d3d2aSXin Li }
632*a58d3d2aSXin Li relativeE = 0;
633*a58d3d2aSXin Li frame_loudness = 0;
634*a58d3d2aSXin Li /* The energy of the very first band is special because of DC. */
635*a58d3d2aSXin Li {
636*a58d3d2aSXin Li float E = 0;
637*a58d3d2aSXin Li float X1r, X2r;
638*a58d3d2aSXin Li X1r = 2*(float)out[0].r;
639*a58d3d2aSXin Li X2r = 2*(float)out[0].i;
640*a58d3d2aSXin Li E = X1r*X1r + X2r*X2r;
641*a58d3d2aSXin Li for (i=1;i<4;i++)
642*a58d3d2aSXin Li {
643*a58d3d2aSXin Li float binE = out[i].r*(float)out[i].r + out[N-i].r*(float)out[N-i].r
644*a58d3d2aSXin Li + out[i].i*(float)out[i].i + out[N-i].i*(float)out[N-i].i;
645*a58d3d2aSXin Li E += binE;
646*a58d3d2aSXin Li }
647*a58d3d2aSXin Li E = SCALE_ENER(E);
648*a58d3d2aSXin Li band_log2[0] = .5f*1.442695f*(float)log(E+1e-10f);
649*a58d3d2aSXin Li }
650*a58d3d2aSXin Li for (b=0;b<NB_TBANDS;b++)
651*a58d3d2aSXin Li {
652*a58d3d2aSXin Li float E=0, tE=0, nE=0;
653*a58d3d2aSXin Li float L1, L2;
654*a58d3d2aSXin Li float stationarity;
655*a58d3d2aSXin Li for (i=tbands[b];i<tbands[b+1];i++)
656*a58d3d2aSXin Li {
657*a58d3d2aSXin Li float binE = out[i].r*(float)out[i].r + out[N-i].r*(float)out[N-i].r
658*a58d3d2aSXin Li + out[i].i*(float)out[i].i + out[N-i].i*(float)out[N-i].i;
659*a58d3d2aSXin Li binE = SCALE_ENER(binE);
660*a58d3d2aSXin Li E += binE;
661*a58d3d2aSXin Li tE += binE*MAX32(0, tonality[i]);
662*a58d3d2aSXin Li nE += binE*2.f*(.5f-noisiness[i]);
663*a58d3d2aSXin Li }
664*a58d3d2aSXin Li #ifndef FIXED_POINT
665*a58d3d2aSXin Li /* Check for extreme band energies that could cause NaNs later. */
666*a58d3d2aSXin Li if (!(E<1e9f) || celt_isnan(E))
667*a58d3d2aSXin Li {
668*a58d3d2aSXin Li info->valid = 0;
669*a58d3d2aSXin Li RESTORE_STACK;
670*a58d3d2aSXin Li return;
671*a58d3d2aSXin Li }
672*a58d3d2aSXin Li #endif
673*a58d3d2aSXin Li
674*a58d3d2aSXin Li tonal->E[tonal->E_count][b] = E;
675*a58d3d2aSXin Li frame_noisiness += nE/(1e-15f+E);
676*a58d3d2aSXin Li
677*a58d3d2aSXin Li frame_loudness += (float)sqrt(E+1e-10f);
678*a58d3d2aSXin Li logE[b] = (float)log(E+1e-10f);
679*a58d3d2aSXin Li band_log2[b+1] = .5f*1.442695f*(float)log(E+1e-10f);
680*a58d3d2aSXin Li tonal->logE[tonal->E_count][b] = logE[b];
681*a58d3d2aSXin Li if (tonal->count==0)
682*a58d3d2aSXin Li tonal->highE[b] = tonal->lowE[b] = logE[b];
683*a58d3d2aSXin Li if (tonal->highE[b] > tonal->lowE[b] + 7.5)
684*a58d3d2aSXin Li {
685*a58d3d2aSXin Li if (tonal->highE[b] - logE[b] > logE[b] - tonal->lowE[b])
686*a58d3d2aSXin Li tonal->highE[b] -= .01f;
687*a58d3d2aSXin Li else
688*a58d3d2aSXin Li tonal->lowE[b] += .01f;
689*a58d3d2aSXin Li }
690*a58d3d2aSXin Li if (logE[b] > tonal->highE[b])
691*a58d3d2aSXin Li {
692*a58d3d2aSXin Li tonal->highE[b] = logE[b];
693*a58d3d2aSXin Li tonal->lowE[b] = MAX32(tonal->highE[b]-15, tonal->lowE[b]);
694*a58d3d2aSXin Li } else if (logE[b] < tonal->lowE[b])
695*a58d3d2aSXin Li {
696*a58d3d2aSXin Li tonal->lowE[b] = logE[b];
697*a58d3d2aSXin Li tonal->highE[b] = MIN32(tonal->lowE[b]+15, tonal->highE[b]);
698*a58d3d2aSXin Li }
699*a58d3d2aSXin Li relativeE += (logE[b]-tonal->lowE[b])/(1e-5f + (tonal->highE[b]-tonal->lowE[b]));
700*a58d3d2aSXin Li
701*a58d3d2aSXin Li L1=L2=0;
702*a58d3d2aSXin Li for (i=0;i<NB_FRAMES;i++)
703*a58d3d2aSXin Li {
704*a58d3d2aSXin Li L1 += (float)sqrt(tonal->E[i][b]);
705*a58d3d2aSXin Li L2 += tonal->E[i][b];
706*a58d3d2aSXin Li }
707*a58d3d2aSXin Li
708*a58d3d2aSXin Li stationarity = MIN16(0.99f,L1/(float)sqrt(1e-15+NB_FRAMES*L2));
709*a58d3d2aSXin Li stationarity *= stationarity;
710*a58d3d2aSXin Li stationarity *= stationarity;
711*a58d3d2aSXin Li frame_stationarity += stationarity;
712*a58d3d2aSXin Li /*band_tonality[b] = tE/(1e-15+E)*/;
713*a58d3d2aSXin Li band_tonality[b] = MAX16(tE/(1e-15f+E), stationarity*tonal->prev_band_tonality[b]);
714*a58d3d2aSXin Li #if 0
715*a58d3d2aSXin Li if (b>=NB_TONAL_SKIP_BANDS)
716*a58d3d2aSXin Li {
717*a58d3d2aSXin Li frame_tonality += tweight[b]*band_tonality[b];
718*a58d3d2aSXin Li tw_sum += tweight[b];
719*a58d3d2aSXin Li }
720*a58d3d2aSXin Li #else
721*a58d3d2aSXin Li frame_tonality += band_tonality[b];
722*a58d3d2aSXin Li if (b>=NB_TBANDS-NB_TONAL_SKIP_BANDS)
723*a58d3d2aSXin Li frame_tonality -= band_tonality[b-NB_TBANDS+NB_TONAL_SKIP_BANDS];
724*a58d3d2aSXin Li #endif
725*a58d3d2aSXin Li max_frame_tonality = MAX16(max_frame_tonality, (1.f+.03f*(b-NB_TBANDS))*frame_tonality);
726*a58d3d2aSXin Li slope += band_tonality[b]*(b-8);
727*a58d3d2aSXin Li /*printf("%f %f ", band_tonality[b], stationarity);*/
728*a58d3d2aSXin Li tonal->prev_band_tonality[b] = band_tonality[b];
729*a58d3d2aSXin Li }
730*a58d3d2aSXin Li
731*a58d3d2aSXin Li leakage_from[0] = band_log2[0];
732*a58d3d2aSXin Li leakage_to[0] = band_log2[0] - LEAKAGE_OFFSET;
733*a58d3d2aSXin Li for (b=1;b<NB_TBANDS+1;b++)
734*a58d3d2aSXin Li {
735*a58d3d2aSXin Li float leak_slope = LEAKAGE_SLOPE*(tbands[b]-tbands[b-1])/4;
736*a58d3d2aSXin Li leakage_from[b] = MIN16(leakage_from[b-1]+leak_slope, band_log2[b]);
737*a58d3d2aSXin Li leakage_to[b] = MAX16(leakage_to[b-1]-leak_slope, band_log2[b]-LEAKAGE_OFFSET);
738*a58d3d2aSXin Li }
739*a58d3d2aSXin Li for (b=NB_TBANDS-2;b>=0;b--)
740*a58d3d2aSXin Li {
741*a58d3d2aSXin Li float leak_slope = LEAKAGE_SLOPE*(tbands[b+1]-tbands[b])/4;
742*a58d3d2aSXin Li leakage_from[b] = MIN16(leakage_from[b+1]+leak_slope, leakage_from[b]);
743*a58d3d2aSXin Li leakage_to[b] = MAX16(leakage_to[b+1]-leak_slope, leakage_to[b]);
744*a58d3d2aSXin Li }
745*a58d3d2aSXin Li celt_assert(NB_TBANDS+1 <= LEAK_BANDS);
746*a58d3d2aSXin Li for (b=0;b<NB_TBANDS+1;b++)
747*a58d3d2aSXin Li {
748*a58d3d2aSXin Li /* leak_boost[] is made up of two terms. The first, based on leakage_to[],
749*a58d3d2aSXin Li represents the boost needed to overcome the amount of analysis leakage
750*a58d3d2aSXin Li cause in a weaker band b by louder neighbouring bands.
751*a58d3d2aSXin Li The second, based on leakage_from[], applies to a loud band b for
752*a58d3d2aSXin Li which the quantization noise causes synthesis leakage to the weaker
753*a58d3d2aSXin Li neighbouring bands. */
754*a58d3d2aSXin Li float boost = MAX16(0, leakage_to[b] - band_log2[b]) +
755*a58d3d2aSXin Li MAX16(0, band_log2[b] - (leakage_from[b]+LEAKAGE_OFFSET));
756*a58d3d2aSXin Li info->leak_boost[b] = IMIN(255, (int)floor(.5 + 64.f*boost));
757*a58d3d2aSXin Li }
758*a58d3d2aSXin Li for (;b<LEAK_BANDS;b++) info->leak_boost[b] = 0;
759*a58d3d2aSXin Li
760*a58d3d2aSXin Li for (i=0;i<NB_FRAMES;i++)
761*a58d3d2aSXin Li {
762*a58d3d2aSXin Li int j;
763*a58d3d2aSXin Li float mindist = 1e15f;
764*a58d3d2aSXin Li for (j=0;j<NB_FRAMES;j++)
765*a58d3d2aSXin Li {
766*a58d3d2aSXin Li int k;
767*a58d3d2aSXin Li float dist=0;
768*a58d3d2aSXin Li for (k=0;k<NB_TBANDS;k++)
769*a58d3d2aSXin Li {
770*a58d3d2aSXin Li float tmp;
771*a58d3d2aSXin Li tmp = tonal->logE[i][k] - tonal->logE[j][k];
772*a58d3d2aSXin Li dist += tmp*tmp;
773*a58d3d2aSXin Li }
774*a58d3d2aSXin Li if (j!=i)
775*a58d3d2aSXin Li mindist = MIN32(mindist, dist);
776*a58d3d2aSXin Li }
777*a58d3d2aSXin Li spec_variability += mindist;
778*a58d3d2aSXin Li }
779*a58d3d2aSXin Li spec_variability = (float)sqrt(spec_variability/NB_FRAMES/NB_TBANDS);
780*a58d3d2aSXin Li bandwidth_mask = 0;
781*a58d3d2aSXin Li bandwidth = 0;
782*a58d3d2aSXin Li maxE = 0;
783*a58d3d2aSXin Li noise_floor = 5.7e-4f/(1<<(IMAX(0,lsb_depth-8)));
784*a58d3d2aSXin Li noise_floor *= noise_floor;
785*a58d3d2aSXin Li below_max_pitch=0;
786*a58d3d2aSXin Li above_max_pitch=0;
787*a58d3d2aSXin Li for (b=0;b<NB_TBANDS;b++)
788*a58d3d2aSXin Li {
789*a58d3d2aSXin Li float E=0;
790*a58d3d2aSXin Li float Em;
791*a58d3d2aSXin Li int band_start, band_end;
792*a58d3d2aSXin Li /* Keep a margin of 300 Hz for aliasing */
793*a58d3d2aSXin Li band_start = tbands[b];
794*a58d3d2aSXin Li band_end = tbands[b+1];
795*a58d3d2aSXin Li for (i=band_start;i<band_end;i++)
796*a58d3d2aSXin Li {
797*a58d3d2aSXin Li float binE = out[i].r*(float)out[i].r + out[N-i].r*(float)out[N-i].r
798*a58d3d2aSXin Li + out[i].i*(float)out[i].i + out[N-i].i*(float)out[N-i].i;
799*a58d3d2aSXin Li E += binE;
800*a58d3d2aSXin Li }
801*a58d3d2aSXin Li E = SCALE_ENER(E);
802*a58d3d2aSXin Li maxE = MAX32(maxE, E);
803*a58d3d2aSXin Li if (band_start < 64)
804*a58d3d2aSXin Li {
805*a58d3d2aSXin Li below_max_pitch += E;
806*a58d3d2aSXin Li } else {
807*a58d3d2aSXin Li above_max_pitch += E;
808*a58d3d2aSXin Li }
809*a58d3d2aSXin Li tonal->meanE[b] = MAX32((1-alphaE2)*tonal->meanE[b], E);
810*a58d3d2aSXin Li Em = MAX32(E, tonal->meanE[b]);
811*a58d3d2aSXin Li /* Consider the band "active" only if all these conditions are met:
812*a58d3d2aSXin Li 1) less than 90 dB below the peak band (maximal masking possible considering
813*a58d3d2aSXin Li both the ATH and the loudness-dependent slope of the spreading function)
814*a58d3d2aSXin Li 2) above the PCM quantization noise floor
815*a58d3d2aSXin Li We use b+1 because the first CELT band isn't included in tbands[]
816*a58d3d2aSXin Li */
817*a58d3d2aSXin Li if (E*1e9f > maxE && (Em > 3*noise_floor*(band_end-band_start) || E > noise_floor*(band_end-band_start)))
818*a58d3d2aSXin Li bandwidth = b+1;
819*a58d3d2aSXin Li /* Check if the band is masked (see below). */
820*a58d3d2aSXin Li is_masked[b] = E < (tonal->prev_bandwidth >= b+1 ? .01f : .05f)*bandwidth_mask;
821*a58d3d2aSXin Li /* Use a simple follower with 13 dB/Bark slope for spreading function. */
822*a58d3d2aSXin Li bandwidth_mask = MAX32(.05f*bandwidth_mask, E);
823*a58d3d2aSXin Li }
824*a58d3d2aSXin Li /* Special case for the last two bands, for which we don't have spectrum but only
825*a58d3d2aSXin Li the energy above 12 kHz. The difficulty here is that the high-pass we use
826*a58d3d2aSXin Li leaks some LF energy, so we need to increase the threshold without accidentally cutting
827*a58d3d2aSXin Li off the band. */
828*a58d3d2aSXin Li if (tonal->Fs == 48000) {
829*a58d3d2aSXin Li float noise_ratio;
830*a58d3d2aSXin Li float Em;
831*a58d3d2aSXin Li float E = hp_ener*(1.f/(60*60));
832*a58d3d2aSXin Li noise_ratio = tonal->prev_bandwidth==20 ? 10.f : 30.f;
833*a58d3d2aSXin Li
834*a58d3d2aSXin Li #ifdef FIXED_POINT
835*a58d3d2aSXin Li /* silk_resampler_down2_hp() shifted right by an extra 8 bits. */
836*a58d3d2aSXin Li E *= 256.f*(1.f/Q15ONE)*(1.f/Q15ONE);
837*a58d3d2aSXin Li #endif
838*a58d3d2aSXin Li above_max_pitch += E;
839*a58d3d2aSXin Li tonal->meanE[b] = MAX32((1-alphaE2)*tonal->meanE[b], E);
840*a58d3d2aSXin Li Em = MAX32(E, tonal->meanE[b]);
841*a58d3d2aSXin Li if (Em > 3*noise_ratio*noise_floor*160 || E > noise_ratio*noise_floor*160)
842*a58d3d2aSXin Li bandwidth = 20;
843*a58d3d2aSXin Li /* Check if the band is masked (see below). */
844*a58d3d2aSXin Li is_masked[b] = E < (tonal->prev_bandwidth == 20 ? .01f : .05f)*bandwidth_mask;
845*a58d3d2aSXin Li }
846*a58d3d2aSXin Li if (above_max_pitch > below_max_pitch)
847*a58d3d2aSXin Li info->max_pitch_ratio = below_max_pitch/above_max_pitch;
848*a58d3d2aSXin Li else
849*a58d3d2aSXin Li info->max_pitch_ratio = 1;
850*a58d3d2aSXin Li /* In some cases, resampling aliasing can create a small amount of energy in the first band
851*a58d3d2aSXin Li being cut. So if the last band is masked, we don't include it. */
852*a58d3d2aSXin Li if (bandwidth == 20 && is_masked[NB_TBANDS])
853*a58d3d2aSXin Li bandwidth-=2;
854*a58d3d2aSXin Li else if (bandwidth > 0 && bandwidth <= NB_TBANDS && is_masked[bandwidth-1])
855*a58d3d2aSXin Li bandwidth--;
856*a58d3d2aSXin Li if (tonal->count<=2)
857*a58d3d2aSXin Li bandwidth = 20;
858*a58d3d2aSXin Li frame_loudness = 20*(float)log10(frame_loudness);
859*a58d3d2aSXin Li tonal->Etracker = MAX32(tonal->Etracker-.003f, frame_loudness);
860*a58d3d2aSXin Li tonal->lowECount *= (1-alphaE);
861*a58d3d2aSXin Li if (frame_loudness < tonal->Etracker-30)
862*a58d3d2aSXin Li tonal->lowECount += alphaE;
863*a58d3d2aSXin Li
864*a58d3d2aSXin Li for (i=0;i<8;i++)
865*a58d3d2aSXin Li {
866*a58d3d2aSXin Li float sum=0;
867*a58d3d2aSXin Li for (b=0;b<16;b++)
868*a58d3d2aSXin Li sum += dct_table[i*16+b]*logE[b];
869*a58d3d2aSXin Li BFCC[i] = sum;
870*a58d3d2aSXin Li }
871*a58d3d2aSXin Li for (i=0;i<8;i++)
872*a58d3d2aSXin Li {
873*a58d3d2aSXin Li float sum=0;
874*a58d3d2aSXin Li for (b=0;b<16;b++)
875*a58d3d2aSXin Li sum += dct_table[i*16+b]*.5f*(tonal->highE[b]+tonal->lowE[b]);
876*a58d3d2aSXin Li midE[i] = sum;
877*a58d3d2aSXin Li }
878*a58d3d2aSXin Li
879*a58d3d2aSXin Li frame_stationarity /= NB_TBANDS;
880*a58d3d2aSXin Li relativeE /= NB_TBANDS;
881*a58d3d2aSXin Li if (tonal->count<10)
882*a58d3d2aSXin Li relativeE = .5f;
883*a58d3d2aSXin Li frame_noisiness /= NB_TBANDS;
884*a58d3d2aSXin Li #if 1
885*a58d3d2aSXin Li info->activity = frame_noisiness + (1-frame_noisiness)*relativeE;
886*a58d3d2aSXin Li #else
887*a58d3d2aSXin Li info->activity = .5*(1+frame_noisiness-frame_stationarity);
888*a58d3d2aSXin Li #endif
889*a58d3d2aSXin Li frame_tonality = (max_frame_tonality/(NB_TBANDS-NB_TONAL_SKIP_BANDS));
890*a58d3d2aSXin Li frame_tonality = MAX16(frame_tonality, tonal->prev_tonality*.8f);
891*a58d3d2aSXin Li tonal->prev_tonality = frame_tonality;
892*a58d3d2aSXin Li
893*a58d3d2aSXin Li slope /= 8*8;
894*a58d3d2aSXin Li info->tonality_slope = slope;
895*a58d3d2aSXin Li
896*a58d3d2aSXin Li tonal->E_count = (tonal->E_count+1)%NB_FRAMES;
897*a58d3d2aSXin Li tonal->count = IMIN(tonal->count+1, ANALYSIS_COUNT_MAX);
898*a58d3d2aSXin Li info->tonality = frame_tonality;
899*a58d3d2aSXin Li
900*a58d3d2aSXin Li for (i=0;i<4;i++)
901*a58d3d2aSXin Li features[i] = -0.12299f*(BFCC[i]+tonal->mem[i+24]) + 0.49195f*(tonal->mem[i]+tonal->mem[i+16]) + 0.69693f*tonal->mem[i+8] - 1.4349f*tonal->cmean[i];
902*a58d3d2aSXin Li
903*a58d3d2aSXin Li for (i=0;i<4;i++)
904*a58d3d2aSXin Li tonal->cmean[i] = (1-alpha)*tonal->cmean[i] + alpha*BFCC[i];
905*a58d3d2aSXin Li
906*a58d3d2aSXin Li for (i=0;i<4;i++)
907*a58d3d2aSXin Li features[4+i] = 0.63246f*(BFCC[i]-tonal->mem[i+24]) + 0.31623f*(tonal->mem[i]-tonal->mem[i+16]);
908*a58d3d2aSXin Li for (i=0;i<3;i++)
909*a58d3d2aSXin Li features[8+i] = 0.53452f*(BFCC[i]+tonal->mem[i+24]) - 0.26726f*(tonal->mem[i]+tonal->mem[i+16]) -0.53452f*tonal->mem[i+8];
910*a58d3d2aSXin Li
911*a58d3d2aSXin Li if (tonal->count > 5)
912*a58d3d2aSXin Li {
913*a58d3d2aSXin Li for (i=0;i<9;i++)
914*a58d3d2aSXin Li tonal->std[i] = (1-alpha)*tonal->std[i] + alpha*features[i]*features[i];
915*a58d3d2aSXin Li }
916*a58d3d2aSXin Li for (i=0;i<4;i++)
917*a58d3d2aSXin Li features[i] = BFCC[i]-midE[i];
918*a58d3d2aSXin Li
919*a58d3d2aSXin Li for (i=0;i<8;i++)
920*a58d3d2aSXin Li {
921*a58d3d2aSXin Li tonal->mem[i+24] = tonal->mem[i+16];
922*a58d3d2aSXin Li tonal->mem[i+16] = tonal->mem[i+8];
923*a58d3d2aSXin Li tonal->mem[i+8] = tonal->mem[i];
924*a58d3d2aSXin Li tonal->mem[i] = BFCC[i];
925*a58d3d2aSXin Li }
926*a58d3d2aSXin Li for (i=0;i<9;i++)
927*a58d3d2aSXin Li features[11+i] = (float)sqrt(tonal->std[i]) - std_feature_bias[i];
928*a58d3d2aSXin Li features[18] = spec_variability - 0.78f;
929*a58d3d2aSXin Li features[20] = info->tonality - 0.154723f;
930*a58d3d2aSXin Li features[21] = info->activity - 0.724643f;
931*a58d3d2aSXin Li features[22] = frame_stationarity - 0.743717f;
932*a58d3d2aSXin Li features[23] = info->tonality_slope + 0.069216f;
933*a58d3d2aSXin Li features[24] = tonal->lowECount - 0.067930f;
934*a58d3d2aSXin Li
935*a58d3d2aSXin Li analysis_compute_dense(&layer0, layer_out, features);
936*a58d3d2aSXin Li analysis_compute_gru(&layer1, tonal->rnn_state, layer_out);
937*a58d3d2aSXin Li analysis_compute_dense(&layer2, frame_probs, tonal->rnn_state);
938*a58d3d2aSXin Li
939*a58d3d2aSXin Li /* Probability of speech or music vs noise */
940*a58d3d2aSXin Li info->activity_probability = frame_probs[1];
941*a58d3d2aSXin Li info->music_prob = frame_probs[0];
942*a58d3d2aSXin Li
943*a58d3d2aSXin Li /*printf("%f %f %f\n", frame_probs[0], frame_probs[1], info->music_prob);*/
944*a58d3d2aSXin Li #ifdef MLP_TRAINING
945*a58d3d2aSXin Li for (i=0;i<25;i++)
946*a58d3d2aSXin Li printf("%f ", features[i]);
947*a58d3d2aSXin Li printf("\n");
948*a58d3d2aSXin Li #endif
949*a58d3d2aSXin Li
950*a58d3d2aSXin Li info->bandwidth = bandwidth;
951*a58d3d2aSXin Li tonal->prev_bandwidth = bandwidth;
952*a58d3d2aSXin Li /*printf("%d %d\n", info->bandwidth, info->opus_bandwidth);*/
953*a58d3d2aSXin Li info->noisiness = frame_noisiness;
954*a58d3d2aSXin Li info->valid = 1;
955*a58d3d2aSXin Li RESTORE_STACK;
956*a58d3d2aSXin Li }
957*a58d3d2aSXin Li
run_analysis(TonalityAnalysisState * analysis,const CELTMode * celt_mode,const void * analysis_pcm,int analysis_frame_size,int frame_size,int c1,int c2,int C,opus_int32 Fs,int lsb_depth,downmix_func downmix,AnalysisInfo * analysis_info)958*a58d3d2aSXin Li void run_analysis(TonalityAnalysisState *analysis, const CELTMode *celt_mode, const void *analysis_pcm,
959*a58d3d2aSXin Li int analysis_frame_size, int frame_size, int c1, int c2, int C, opus_int32 Fs,
960*a58d3d2aSXin Li int lsb_depth, downmix_func downmix, AnalysisInfo *analysis_info)
961*a58d3d2aSXin Li {
962*a58d3d2aSXin Li int offset;
963*a58d3d2aSXin Li int pcm_len;
964*a58d3d2aSXin Li
965*a58d3d2aSXin Li analysis_frame_size -= analysis_frame_size&1;
966*a58d3d2aSXin Li if (analysis_pcm != NULL)
967*a58d3d2aSXin Li {
968*a58d3d2aSXin Li /* Avoid overflow/wrap-around of the analysis buffer */
969*a58d3d2aSXin Li analysis_frame_size = IMIN((DETECT_SIZE-5)*Fs/50, analysis_frame_size);
970*a58d3d2aSXin Li
971*a58d3d2aSXin Li pcm_len = analysis_frame_size - analysis->analysis_offset;
972*a58d3d2aSXin Li offset = analysis->analysis_offset;
973*a58d3d2aSXin Li while (pcm_len>0) {
974*a58d3d2aSXin Li tonality_analysis(analysis, celt_mode, analysis_pcm, IMIN(Fs/50, pcm_len), offset, c1, c2, C, lsb_depth, downmix);
975*a58d3d2aSXin Li offset += Fs/50;
976*a58d3d2aSXin Li pcm_len -= Fs/50;
977*a58d3d2aSXin Li }
978*a58d3d2aSXin Li analysis->analysis_offset = analysis_frame_size;
979*a58d3d2aSXin Li
980*a58d3d2aSXin Li analysis->analysis_offset -= frame_size;
981*a58d3d2aSXin Li }
982*a58d3d2aSXin Li
983*a58d3d2aSXin Li tonality_get_info(analysis, analysis_info, frame_size);
984*a58d3d2aSXin Li }
985*a58d3d2aSXin Li
986*a58d3d2aSXin Li #endif /* DISABLE_FLOAT_API */
987