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25 POSSIBILITY OF SUCH DAMAGE.
26 ***********************************************************************/
27 
28 #ifdef HAVE_CONFIG_H
29 #include "config.h"
30 #endif
31 
32 #include "main.h"
33 #include "stack_alloc.h"
34 
35 /* Silk VAD noise level estimation */
36 # if !defined(OPUS_X86_MAY_HAVE_SSE4_1)
37 static OPUS_INLINE void silk_VAD_GetNoiseLevels(
38     const opus_int32             pX[ VAD_N_BANDS ], /* I    subband energies                            */
39     silk_VAD_state              *psSilk_VAD         /* I/O  Pointer to Silk VAD state                   */
40 );
41 #endif
42 
43 /**********************************/
44 /* Initialization of the Silk VAD */
45 /**********************************/
silk_VAD_Init(silk_VAD_state * psSilk_VAD)46 opus_int silk_VAD_Init(                                         /* O    Return value, 0 if success                  */
47     silk_VAD_state              *psSilk_VAD                     /* I/O  Pointer to Silk VAD state                   */
48 )
49 {
50     opus_int b, ret = 0;
51 
52     /* reset state memory */
53     silk_memset( psSilk_VAD, 0, sizeof( silk_VAD_state ) );
54 
55     /* init noise levels */
56     /* Initialize array with approx pink noise levels (psd proportional to inverse of frequency) */
57     for( b = 0; b < VAD_N_BANDS; b++ ) {
58         psSilk_VAD->NoiseLevelBias[ b ] = silk_max_32( silk_DIV32_16( VAD_NOISE_LEVELS_BIAS, b + 1 ), 1 );
59     }
60 
61     /* Initialize state */
62     for( b = 0; b < VAD_N_BANDS; b++ ) {
63         psSilk_VAD->NL[ b ]     = silk_MUL( 100, psSilk_VAD->NoiseLevelBias[ b ] );
64         psSilk_VAD->inv_NL[ b ] = silk_DIV32( silk_int32_MAX, psSilk_VAD->NL[ b ] );
65     }
66     psSilk_VAD->counter = 15;
67 
68     /* init smoothed energy-to-noise ratio*/
69     for( b = 0; b < VAD_N_BANDS; b++ ) {
70         psSilk_VAD->NrgRatioSmth_Q8[ b ] = 100 * 256;       /* 100 * 256 --> 20 dB SNR */
71     }
72 
73     return( ret );
74 }
75 
76 /* Weighting factors for tilt measure */
77 static const opus_int32 tiltWeights[ VAD_N_BANDS ] = { 30000, 6000, -12000, -12000 };
78 
79 /***************************************/
80 /* Get the speech activity level in Q8 */
81 /***************************************/
silk_VAD_GetSA_Q8_c(silk_encoder_state * psEncC,const opus_int16 pIn[])82 opus_int silk_VAD_GetSA_Q8_c(                                   /* O    Return value, 0 if success                  */
83     silk_encoder_state          *psEncC,                        /* I/O  Encoder state                               */
84     const opus_int16            pIn[]                           /* I    PCM input                                   */
85 )
86 {
87     opus_int   SA_Q15, pSNR_dB_Q7, input_tilt;
88     opus_int   decimated_framelength1, decimated_framelength2;
89     opus_int   decimated_framelength;
90     opus_int   dec_subframe_length, dec_subframe_offset, SNR_Q7, i, b, s;
91     opus_int32 sumSquared, smooth_coef_Q16;
92     opus_int16 HPstateTmp;
93     VARDECL( opus_int16, X );
94     opus_int32 Xnrg[ VAD_N_BANDS ];
95     opus_int32 NrgToNoiseRatio_Q8[ VAD_N_BANDS ];
96     opus_int32 speech_nrg, x_tmp;
97     opus_int   X_offset[ VAD_N_BANDS ];
98     opus_int   ret = 0;
99     silk_VAD_state *psSilk_VAD = &psEncC->sVAD;
100     SAVE_STACK;
101 
102     /* Safety checks */
103     silk_assert( VAD_N_BANDS == 4 );
104     celt_assert( MAX_FRAME_LENGTH >= psEncC->frame_length );
105     celt_assert( psEncC->frame_length <= 512 );
106     celt_assert( psEncC->frame_length == 8 * silk_RSHIFT( psEncC->frame_length, 3 ) );
107 
108     /***********************/
109     /* Filter and Decimate */
110     /***********************/
111     decimated_framelength1 = silk_RSHIFT( psEncC->frame_length, 1 );
112     decimated_framelength2 = silk_RSHIFT( psEncC->frame_length, 2 );
113     decimated_framelength = silk_RSHIFT( psEncC->frame_length, 3 );
114     /* Decimate into 4 bands:
115        0       L      3L       L              3L                             5L
116                -      --       -              --                             --
117                8       8       2               4                              4
118 
119        [0-1 kHz| temp. |1-2 kHz|    2-4 kHz    |            4-8 kHz           |
120 
121        They're arranged to allow the minimal ( frame_length / 4 ) extra
122        scratch space during the downsampling process */
123     X_offset[ 0 ] = 0;
124     X_offset[ 1 ] = decimated_framelength + decimated_framelength2;
125     X_offset[ 2 ] = X_offset[ 1 ] + decimated_framelength;
126     X_offset[ 3 ] = X_offset[ 2 ] + decimated_framelength2;
127     ALLOC( X, X_offset[ 3 ] + decimated_framelength1, opus_int16 );
128 
129     /* 0-8 kHz to 0-4 kHz and 4-8 kHz */
130     silk_ana_filt_bank_1( pIn, &psSilk_VAD->AnaState[  0 ],
131         X, &X[ X_offset[ 3 ] ], psEncC->frame_length );
132 
133     /* 0-4 kHz to 0-2 kHz and 2-4 kHz */
134     silk_ana_filt_bank_1( X, &psSilk_VAD->AnaState1[ 0 ],
135         X, &X[ X_offset[ 2 ] ], decimated_framelength1 );
136 
137     /* 0-2 kHz to 0-1 kHz and 1-2 kHz */
138     silk_ana_filt_bank_1( X, &psSilk_VAD->AnaState2[ 0 ],
139         X, &X[ X_offset[ 1 ] ], decimated_framelength2 );
140 
141     /*********************************************/
142     /* HP filter on lowest band (differentiator) */
143     /*********************************************/
144     X[ decimated_framelength - 1 ] = silk_RSHIFT( X[ decimated_framelength - 1 ], 1 );
145     HPstateTmp = X[ decimated_framelength - 1 ];
146     for( i = decimated_framelength - 1; i > 0; i-- ) {
147         X[ i - 1 ]  = silk_RSHIFT( X[ i - 1 ], 1 );
148         X[ i ]     -= X[ i - 1 ];
149     }
150     X[ 0 ] -= psSilk_VAD->HPstate;
151     psSilk_VAD->HPstate = HPstateTmp;
152 
153     /*************************************/
154     /* Calculate the energy in each band */
155     /*************************************/
156     for( b = 0; b < VAD_N_BANDS; b++ ) {
157         /* Find the decimated framelength in the non-uniformly divided bands */
158         decimated_framelength = silk_RSHIFT( psEncC->frame_length, silk_min_int( VAD_N_BANDS - b, VAD_N_BANDS - 1 ) );
159 
160         /* Split length into subframe lengths */
161         dec_subframe_length = silk_RSHIFT( decimated_framelength, VAD_INTERNAL_SUBFRAMES_LOG2 );
162         dec_subframe_offset = 0;
163 
164         /* Compute energy per sub-frame */
165         /* initialize with summed energy of last subframe */
166         Xnrg[ b ] = psSilk_VAD->XnrgSubfr[ b ];
167         for( s = 0; s < VAD_INTERNAL_SUBFRAMES; s++ ) {
168             sumSquared = 0;
169             for( i = 0; i < dec_subframe_length; i++ ) {
170                 /* The energy will be less than dec_subframe_length * ( silk_int16_MIN / 8 ) ^ 2.            */
171                 /* Therefore we can accumulate with no risk of overflow (unless dec_subframe_length > 128)  */
172                 x_tmp = silk_RSHIFT(
173                     X[ X_offset[ b ] + i + dec_subframe_offset ], 3 );
174                 sumSquared = silk_SMLABB( sumSquared, x_tmp, x_tmp );
175 
176                 /* Safety check */
177                 silk_assert( sumSquared >= 0 );
178             }
179 
180             /* Add/saturate summed energy of current subframe */
181             if( s < VAD_INTERNAL_SUBFRAMES - 1 ) {
182                 Xnrg[ b ] = silk_ADD_POS_SAT32( Xnrg[ b ], sumSquared );
183             } else {
184                 /* Look-ahead subframe */
185                 Xnrg[ b ] = silk_ADD_POS_SAT32( Xnrg[ b ], silk_RSHIFT( sumSquared, 1 ) );
186             }
187 
188             dec_subframe_offset += dec_subframe_length;
189         }
190         psSilk_VAD->XnrgSubfr[ b ] = sumSquared;
191     }
192 
193     /********************/
194     /* Noise estimation */
195     /********************/
196     silk_VAD_GetNoiseLevels( &Xnrg[ 0 ], psSilk_VAD );
197 
198     /***********************************************/
199     /* Signal-plus-noise to noise ratio estimation */
200     /***********************************************/
201     sumSquared = 0;
202     input_tilt = 0;
203     for( b = 0; b < VAD_N_BANDS; b++ ) {
204         speech_nrg = Xnrg[ b ] - psSilk_VAD->NL[ b ];
205         if( speech_nrg > 0 ) {
206             /* Divide, with sufficient resolution */
207             if( ( Xnrg[ b ] & 0xFF800000 ) == 0 ) {
208                 NrgToNoiseRatio_Q8[ b ] = silk_DIV32( silk_LSHIFT( Xnrg[ b ], 8 ), psSilk_VAD->NL[ b ] + 1 );
209             } else {
210                 NrgToNoiseRatio_Q8[ b ] = silk_DIV32( Xnrg[ b ], silk_RSHIFT( psSilk_VAD->NL[ b ], 8 ) + 1 );
211             }
212 
213             /* Convert to log domain */
214             SNR_Q7 = silk_lin2log( NrgToNoiseRatio_Q8[ b ] ) - 8 * 128;
215 
216             /* Sum-of-squares */
217             sumSquared = silk_SMLABB( sumSquared, SNR_Q7, SNR_Q7 );          /* Q14 */
218 
219             /* Tilt measure */
220             if( speech_nrg < ( (opus_int32)1 << 20 ) ) {
221                 /* Scale down SNR value for small subband speech energies */
222                 SNR_Q7 = silk_SMULWB( silk_LSHIFT( silk_SQRT_APPROX( speech_nrg ), 6 ), SNR_Q7 );
223             }
224             input_tilt = silk_SMLAWB( input_tilt, tiltWeights[ b ], SNR_Q7 );
225         } else {
226             NrgToNoiseRatio_Q8[ b ] = 256;
227         }
228     }
229 
230     /* Mean-of-squares */
231     sumSquared = silk_DIV32_16( sumSquared, VAD_N_BANDS ); /* Q14 */
232 
233     /* Root-mean-square approximation, scale to dBs, and write to output pointer */
234     pSNR_dB_Q7 = (opus_int16)( 3 * silk_SQRT_APPROX( sumSquared ) ); /* Q7 */
235 
236     /*********************************/
237     /* Speech Probability Estimation */
238     /*********************************/
239     SA_Q15 = silk_sigm_Q15( silk_SMULWB( VAD_SNR_FACTOR_Q16, pSNR_dB_Q7 ) - VAD_NEGATIVE_OFFSET_Q5 );
240 
241     /**************************/
242     /* Frequency Tilt Measure */
243     /**************************/
244     psEncC->input_tilt_Q15 = silk_LSHIFT( silk_sigm_Q15( input_tilt ) - 16384, 1 );
245 
246     /**************************************************/
247     /* Scale the sigmoid output based on power levels */
248     /**************************************************/
249     speech_nrg = 0;
250     for( b = 0; b < VAD_N_BANDS; b++ ) {
251         /* Accumulate signal-without-noise energies, higher frequency bands have more weight */
252         speech_nrg += ( b + 1 ) * silk_RSHIFT( Xnrg[ b ] - psSilk_VAD->NL[ b ], 4 );
253     }
254 
255     if( psEncC->frame_length == 20 * psEncC->fs_kHz ) {
256         speech_nrg = silk_RSHIFT32( speech_nrg, 1 );
257     }
258     /* Power scaling */
259     if( speech_nrg <= 0 ) {
260         SA_Q15 = silk_RSHIFT( SA_Q15, 1 );
261     } else if( speech_nrg < 16384 ) {
262         speech_nrg = silk_LSHIFT32( speech_nrg, 16 );
263 
264         /* square-root */
265         speech_nrg = silk_SQRT_APPROX( speech_nrg );
266         SA_Q15 = silk_SMULWB( 32768 + speech_nrg, SA_Q15 );
267     }
268 
269     /* Copy the resulting speech activity in Q8 */
270     psEncC->speech_activity_Q8 = silk_min_int( silk_RSHIFT( SA_Q15, 7 ), silk_uint8_MAX );
271 
272     /***********************************/
273     /* Energy Level and SNR estimation */
274     /***********************************/
275     /* Smoothing coefficient */
276     smooth_coef_Q16 = silk_SMULWB( VAD_SNR_SMOOTH_COEF_Q18, silk_SMULWB( (opus_int32)SA_Q15, SA_Q15 ) );
277 
278     if( psEncC->frame_length == 10 * psEncC->fs_kHz ) {
279         smooth_coef_Q16 >>= 1;
280     }
281 
282     for( b = 0; b < VAD_N_BANDS; b++ ) {
283         /* compute smoothed energy-to-noise ratio per band */
284         psSilk_VAD->NrgRatioSmth_Q8[ b ] = silk_SMLAWB( psSilk_VAD->NrgRatioSmth_Q8[ b ],
285             NrgToNoiseRatio_Q8[ b ] - psSilk_VAD->NrgRatioSmth_Q8[ b ], smooth_coef_Q16 );
286 
287         /* signal to noise ratio in dB per band */
288         SNR_Q7 = 3 * ( silk_lin2log( psSilk_VAD->NrgRatioSmth_Q8[b] ) - 8 * 128 );
289         /* quality = sigmoid( 0.25 * ( SNR_dB - 16 ) ); */
290         psEncC->input_quality_bands_Q15[ b ] = silk_sigm_Q15( silk_RSHIFT( SNR_Q7 - 16 * 128, 4 ) );
291     }
292 
293     RESTORE_STACK;
294     return( ret );
295 }
296 
297 /**************************/
298 /* Noise level estimation */
299 /**************************/
300 # if  !defined(OPUS_X86_MAY_HAVE_SSE4_1)
301 static OPUS_INLINE
302 #endif
silk_VAD_GetNoiseLevels(const opus_int32 pX[VAD_N_BANDS],silk_VAD_state * psSilk_VAD)303 void silk_VAD_GetNoiseLevels(
304     const opus_int32            pX[ VAD_N_BANDS ],  /* I    subband energies                            */
305     silk_VAD_state              *psSilk_VAD         /* I/O  Pointer to Silk VAD state                   */
306 )
307 {
308     opus_int   k;
309     opus_int32 nl, nrg, inv_nrg;
310     opus_int   coef, min_coef;
311 
312     /* Initially faster smoothing */
313     if( psSilk_VAD->counter < 1000 ) { /* 1000 = 20 sec */
314         min_coef = silk_DIV32_16( silk_int16_MAX, silk_RSHIFT( psSilk_VAD->counter, 4 ) + 1 );
315         /* Increment frame counter */
316         psSilk_VAD->counter++;
317     } else {
318         min_coef = 0;
319     }
320 
321     for( k = 0; k < VAD_N_BANDS; k++ ) {
322         /* Get old noise level estimate for current band */
323         nl = psSilk_VAD->NL[ k ];
324         silk_assert( nl >= 0 );
325 
326         /* Add bias */
327         nrg = silk_ADD_POS_SAT32( pX[ k ], psSilk_VAD->NoiseLevelBias[ k ] );
328         silk_assert( nrg > 0 );
329 
330         /* Invert energies */
331         inv_nrg = silk_DIV32( silk_int32_MAX, nrg );
332         silk_assert( inv_nrg >= 0 );
333 
334         /* Less update when subband energy is high */
335         if( nrg > silk_LSHIFT( nl, 3 ) ) {
336             coef = VAD_NOISE_LEVEL_SMOOTH_COEF_Q16 >> 3;
337         } else if( nrg < nl ) {
338             coef = VAD_NOISE_LEVEL_SMOOTH_COEF_Q16;
339         } else {
340             coef = silk_SMULWB( silk_SMULWW( inv_nrg, nl ), VAD_NOISE_LEVEL_SMOOTH_COEF_Q16 << 1 );
341         }
342 
343         /* Initially faster smoothing */
344         coef = silk_max_int( coef, min_coef );
345 
346         /* Smooth inverse energies */
347         psSilk_VAD->inv_NL[ k ] = silk_SMLAWB( psSilk_VAD->inv_NL[ k ], inv_nrg - psSilk_VAD->inv_NL[ k ], coef );
348         silk_assert( psSilk_VAD->inv_NL[ k ] >= 0 );
349 
350         /* Compute noise level by inverting again */
351         nl = silk_DIV32( silk_int32_MAX, psSilk_VAD->inv_NL[ k ] );
352         silk_assert( nl >= 0 );
353 
354         /* Limit noise levels (guarantee 7 bits of head room) */
355         nl = silk_min( nl, 0x00FFFFFF );
356 
357         /* Store as part of state */
358         psSilk_VAD->NL[ k ] = nl;
359     }
360 }
361