Output/intermediate dir cleanup and fixes in 64-bit mode.
[opus.git] / silk / fixed / noise_shape_analysis_FIX.c
1 /***********************************************************************
2 Copyright (c) 2006-2011, Skype Limited. All rights reserved.
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27
28 #ifdef HAVE_CONFIG_H
29 #include "config.h"
30 #endif
31
32 #include "main_FIX.h"
33 #include "tuning_parameters.h"
34
35 /* Compute gain to make warped filter coefficients have a zero mean log frequency response on a   */
36 /* non-warped frequency scale. (So that it can be implemented with a minimum-phase monic filter.) */
37 /* Note: A monic filter is one with the first coefficient equal to 1.0. In Silk we omit the first */
38 /* coefficient in an array of coefficients, for monic filters.                                    */
39 static inline opus_int32 warped_gain( /* gain in Q16*/
40     const opus_int32     *coefs_Q24,
41     opus_int             lambda_Q16,
42     opus_int             order
43 ) {
44     opus_int   i;
45     opus_int32 gain_Q24;
46
47     lambda_Q16 = -lambda_Q16;
48     gain_Q24 = coefs_Q24[ order - 1 ];
49     for( i = order - 2; i >= 0; i-- ) {
50         gain_Q24 = silk_SMLAWB( coefs_Q24[ i ], gain_Q24, lambda_Q16 );
51     }
52     gain_Q24  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 24 ), gain_Q24, -lambda_Q16 );
53     return silk_INVERSE32_varQ( gain_Q24, 40 );
54 }
55
56 /* Convert warped filter coefficients to monic pseudo-warped coefficients and limit maximum     */
57 /* amplitude of monic warped coefficients by using bandwidth expansion on the true coefficients */
58 static inline void limit_warped_coefs(
59     opus_int32           *coefs_syn_Q24,
60     opus_int32           *coefs_ana_Q24,
61     opus_int             lambda_Q16,
62     opus_int32           limit_Q24,
63     opus_int             order
64 ) {
65     opus_int   i, iter, ind = 0;
66     opus_int32 tmp, maxabs_Q24, chirp_Q16, gain_syn_Q16, gain_ana_Q16;
67     opus_int32 nom_Q16, den_Q24;
68
69     /* Convert to monic coefficients */
70     lambda_Q16 = -lambda_Q16;
71     for( i = order - 1; i > 0; i-- ) {
72         coefs_syn_Q24[ i - 1 ] = silk_SMLAWB( coefs_syn_Q24[ i - 1 ], coefs_syn_Q24[ i ], lambda_Q16 );
73         coefs_ana_Q24[ i - 1 ] = silk_SMLAWB( coefs_ana_Q24[ i - 1 ], coefs_ana_Q24[ i ], lambda_Q16 );
74     }
75     lambda_Q16 = -lambda_Q16;
76     nom_Q16  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 16 ), -(opus_int32)lambda_Q16,        lambda_Q16 );
77     den_Q24  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 24 ), coefs_syn_Q24[ 0 ], lambda_Q16 );
78     gain_syn_Q16 = silk_DIV32_varQ( nom_Q16, den_Q24, 24 );
79     den_Q24  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 24 ), coefs_ana_Q24[ 0 ], lambda_Q16 );
80     gain_ana_Q16 = silk_DIV32_varQ( nom_Q16, den_Q24, 24 );
81     for( i = 0; i < order; i++ ) {
82         coefs_syn_Q24[ i ] = silk_SMULWW( gain_syn_Q16, coefs_syn_Q24[ i ] );
83         coefs_ana_Q24[ i ] = silk_SMULWW( gain_ana_Q16, coefs_ana_Q24[ i ] );
84     }
85
86     for( iter = 0; iter < 10; iter++ ) {
87         /* Find maximum absolute value */
88         maxabs_Q24 = -1;
89         for( i = 0; i < order; i++ ) {
90             tmp = silk_max( silk_abs_int32( coefs_syn_Q24[ i ] ), silk_abs_int32( coefs_ana_Q24[ i ] ) );
91             if( tmp > maxabs_Q24 ) {
92                 maxabs_Q24 = tmp;
93                 ind = i;
94             }
95         }
96         if( maxabs_Q24 <= limit_Q24 ) {
97             /* Coefficients are within range - done */
98             return;
99         }
100
101         /* Convert back to true warped coefficients */
102         for( i = 1; i < order; i++ ) {
103             coefs_syn_Q24[ i - 1 ] = silk_SMLAWB( coefs_syn_Q24[ i - 1 ], coefs_syn_Q24[ i ], lambda_Q16 );
104             coefs_ana_Q24[ i - 1 ] = silk_SMLAWB( coefs_ana_Q24[ i - 1 ], coefs_ana_Q24[ i ], lambda_Q16 );
105         }
106         gain_syn_Q16 = silk_INVERSE32_varQ( gain_syn_Q16, 32 );
107         gain_ana_Q16 = silk_INVERSE32_varQ( gain_ana_Q16, 32 );
108         for( i = 0; i < order; i++ ) {
109             coefs_syn_Q24[ i ] = silk_SMULWW( gain_syn_Q16, coefs_syn_Q24[ i ] );
110             coefs_ana_Q24[ i ] = silk_SMULWW( gain_ana_Q16, coefs_ana_Q24[ i ] );
111         }
112
113         /* Apply bandwidth expansion */
114         chirp_Q16 = SILK_FIX_CONST( 0.99, 16 ) - silk_DIV32_varQ(
115             silk_SMULWB( maxabs_Q24 - limit_Q24, silk_SMLABB( SILK_FIX_CONST( 0.8, 10 ), SILK_FIX_CONST( 0.1, 10 ), iter ) ),
116             silk_MUL( maxabs_Q24, ind + 1 ), 22 );
117         silk_bwexpander_32( coefs_syn_Q24, order, chirp_Q16 );
118         silk_bwexpander_32( coefs_ana_Q24, order, chirp_Q16 );
119
120         /* Convert to monic warped coefficients */
121         lambda_Q16 = -lambda_Q16;
122         for( i = order - 1; i > 0; i-- ) {
123             coefs_syn_Q24[ i - 1 ] = silk_SMLAWB( coefs_syn_Q24[ i - 1 ], coefs_syn_Q24[ i ], lambda_Q16 );
124             coefs_ana_Q24[ i - 1 ] = silk_SMLAWB( coefs_ana_Q24[ i - 1 ], coefs_ana_Q24[ i ], lambda_Q16 );
125         }
126         lambda_Q16 = -lambda_Q16;
127         nom_Q16  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 16 ), -(opus_int32)lambda_Q16,        lambda_Q16 );
128         den_Q24  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 24 ), coefs_syn_Q24[ 0 ], lambda_Q16 );
129         gain_syn_Q16 = silk_DIV32_varQ( nom_Q16, den_Q24, 24 );
130         den_Q24  = silk_SMLAWB( SILK_FIX_CONST( 1.0, 24 ), coefs_ana_Q24[ 0 ], lambda_Q16 );
131         gain_ana_Q16 = silk_DIV32_varQ( nom_Q16, den_Q24, 24 );
132         for( i = 0; i < order; i++ ) {
133             coefs_syn_Q24[ i ] = silk_SMULWW( gain_syn_Q16, coefs_syn_Q24[ i ] );
134             coefs_ana_Q24[ i ] = silk_SMULWW( gain_ana_Q16, coefs_ana_Q24[ i ] );
135         }
136     }
137     silk_assert( 0 );
138 }
139
140 /**************************************************************/
141 /* Compute noise shaping coefficients and initial gain values */
142 /**************************************************************/
143 void silk_noise_shape_analysis_FIX(
144     silk_encoder_state_FIX          *psEnc,                                 /* I/O  Encoder state FIX                                                           */
145     silk_encoder_control_FIX        *psEncCtrl,                             /* I/O  Encoder control FIX                                                         */
146     const opus_int16                *pitch_res,                             /* I    LPC residual from pitch analysis                                            */
147     const opus_int16                *x                                      /* I    Input signal [ frame_length + la_shape ]                                    */
148 )
149 {
150     silk_shape_state_FIX *psShapeSt = &psEnc->sShape;
151     opus_int     k, i, nSamples, Qnrg, b_Q14, warping_Q16, scale = 0;
152     opus_int32   SNR_adj_dB_Q7, HarmBoost_Q16, HarmShapeGain_Q16, Tilt_Q16, tmp32;
153     opus_int32   nrg, pre_nrg_Q30, log_energy_Q7, log_energy_prev_Q7, energy_variation_Q7;
154     opus_int32   delta_Q16, BWExp1_Q16, BWExp2_Q16, gain_mult_Q16, gain_add_Q16, strength_Q16, b_Q8;
155     opus_int32   auto_corr[     MAX_SHAPE_LPC_ORDER + 1 ];
156     opus_int32   refl_coef_Q16[ MAX_SHAPE_LPC_ORDER ];
157     opus_int32   AR1_Q24[       MAX_SHAPE_LPC_ORDER ];
158     opus_int32   AR2_Q24[       MAX_SHAPE_LPC_ORDER ];
159     opus_int16   x_windowed[    SHAPE_LPC_WIN_MAX ];
160     const opus_int16 *x_ptr, *pitch_res_ptr;
161
162     /* Point to start of first LPC analysis block */
163     x_ptr = x - psEnc->sCmn.la_shape;
164
165     /****************/
166     /* GAIN CONTROL */
167     /****************/
168     SNR_adj_dB_Q7 = psEnc->sCmn.SNR_dB_Q7;
169
170     /* Input quality is the average of the quality in the lowest two VAD bands */
171     psEncCtrl->input_quality_Q14 = ( opus_int )silk_RSHIFT( (opus_int32)psEnc->sCmn.input_quality_bands_Q15[ 0 ]
172         + psEnc->sCmn.input_quality_bands_Q15[ 1 ], 2 );
173
174     /* Coding quality level, between 0.0_Q0 and 1.0_Q0, but in Q14 */
175     psEncCtrl->coding_quality_Q14 = silk_RSHIFT( silk_sigm_Q15( silk_RSHIFT_ROUND( SNR_adj_dB_Q7 -
176         SILK_FIX_CONST( 20.0, 7 ), 4 ) ), 1 );
177
178     /* Reduce coding SNR during low speech activity */
179     if( psEnc->sCmn.useCBR == 0 ) {
180         b_Q8 = SILK_FIX_CONST( 1.0, 8 ) - psEnc->sCmn.speech_activity_Q8;
181         b_Q8 = silk_SMULWB( silk_LSHIFT( b_Q8, 8 ), b_Q8 );
182         SNR_adj_dB_Q7 = silk_SMLAWB( SNR_adj_dB_Q7,
183             silk_SMULBB( SILK_FIX_CONST( -BG_SNR_DECR_dB, 7 ) >> ( 4 + 1 ), b_Q8 ),                                       /* Q11*/
184             silk_SMULWB( SILK_FIX_CONST( 1.0, 14 ) + psEncCtrl->input_quality_Q14, psEncCtrl->coding_quality_Q14 ) );     /* Q12*/
185     }
186
187     if( psEnc->sCmn.indices.signalType == TYPE_VOICED ) {
188         /* Reduce gains for periodic signals */
189         SNR_adj_dB_Q7 = silk_SMLAWB( SNR_adj_dB_Q7, SILK_FIX_CONST( HARM_SNR_INCR_dB, 8 ), psEnc->LTPCorr_Q15 );
190     } else {
191         /* For unvoiced signals and low-quality input, adjust the quality slower than SNR_dB setting */
192         SNR_adj_dB_Q7 = silk_SMLAWB( SNR_adj_dB_Q7,
193             silk_SMLAWB( SILK_FIX_CONST( 6.0, 9 ), -SILK_FIX_CONST( 0.4, 18 ), psEnc->sCmn.SNR_dB_Q7 ),
194             SILK_FIX_CONST( 1.0, 14 ) - psEncCtrl->input_quality_Q14 );
195     }
196
197     /*************************/
198     /* SPARSENESS PROCESSING */
199     /*************************/
200     /* Set quantizer offset */
201     if( psEnc->sCmn.indices.signalType == TYPE_VOICED ) {
202         /* Initally set to 0; may be overruled in process_gains(..) */
203         psEnc->sCmn.indices.quantOffsetType = 0;
204         psEncCtrl->sparseness_Q8 = 0;
205     } else {
206         /* Sparseness measure, based on relative fluctuations of energy per 2 milliseconds */
207         nSamples = silk_LSHIFT( psEnc->sCmn.fs_kHz, 1 );
208         energy_variation_Q7 = 0;
209         log_energy_prev_Q7  = 0;
210         pitch_res_ptr = pitch_res;
211         for( k = 0; k < silk_SMULBB( SUB_FRAME_LENGTH_MS, psEnc->sCmn.nb_subfr ) / 2; k++ ) {
212             silk_sum_sqr_shift( &nrg, &scale, pitch_res_ptr, nSamples );
213             nrg += silk_RSHIFT( nSamples, scale );           /* Q(-scale)*/
214
215             log_energy_Q7 = silk_lin2log( nrg );
216             if( k > 0 ) {
217                 energy_variation_Q7 += silk_abs( log_energy_Q7 - log_energy_prev_Q7 );
218             }
219             log_energy_prev_Q7 = log_energy_Q7;
220             pitch_res_ptr += nSamples;
221         }
222
223         psEncCtrl->sparseness_Q8 = silk_RSHIFT( silk_sigm_Q15( silk_SMULWB( energy_variation_Q7 -
224             SILK_FIX_CONST( 5.0, 7 ), SILK_FIX_CONST( 0.1, 16 ) ) ), 7 );
225
226         /* Set quantization offset depending on sparseness measure */
227         if( psEncCtrl->sparseness_Q8 > SILK_FIX_CONST( SPARSENESS_THRESHOLD_QNT_OFFSET, 8 ) ) {
228             psEnc->sCmn.indices.quantOffsetType = 0;
229         } else {
230             psEnc->sCmn.indices.quantOffsetType = 1;
231         }
232
233         /* Increase coding SNR for sparse signals */
234         SNR_adj_dB_Q7 = silk_SMLAWB( SNR_adj_dB_Q7, SILK_FIX_CONST( SPARSE_SNR_INCR_dB, 15 ), psEncCtrl->sparseness_Q8 - SILK_FIX_CONST( 0.5, 8 ) );
235     }
236
237     /*******************************/
238     /* Control bandwidth expansion */
239     /*******************************/
240     /* More BWE for signals with high prediction gain */
241     strength_Q16 = silk_SMULWB( psEncCtrl->predGain_Q16, SILK_FIX_CONST( FIND_PITCH_WHITE_NOISE_FRACTION, 16 ) );
242     BWExp1_Q16 = BWExp2_Q16 = silk_DIV32_varQ( SILK_FIX_CONST( BANDWIDTH_EXPANSION, 16 ),
243         silk_SMLAWW( SILK_FIX_CONST( 1.0, 16 ), strength_Q16, strength_Q16 ), 16 );
244     delta_Q16  = silk_SMULWB( SILK_FIX_CONST( 1.0, 16 ) - silk_SMULBB( 3, psEncCtrl->coding_quality_Q14 ),
245         SILK_FIX_CONST( LOW_RATE_BANDWIDTH_EXPANSION_DELTA, 16 ) );
246     BWExp1_Q16 = silk_SUB32( BWExp1_Q16, delta_Q16 );
247     BWExp2_Q16 = silk_ADD32( BWExp2_Q16, delta_Q16 );
248     /* BWExp1 will be applied after BWExp2, so make it relative */
249     BWExp1_Q16 = silk_DIV32_16( silk_LSHIFT( BWExp1_Q16, 14 ), silk_RSHIFT( BWExp2_Q16, 2 ) );
250
251     if( psEnc->sCmn.warping_Q16 > 0 ) {
252         /* Slightly more warping in analysis will move quantization noise up in frequency, where it's better masked */
253         warping_Q16 = silk_SMLAWB( psEnc->sCmn.warping_Q16, (opus_int32)psEncCtrl->coding_quality_Q14, SILK_FIX_CONST( 0.01, 18 ) );
254     } else {
255         warping_Q16 = 0;
256     }
257
258     /********************************************/
259     /* Compute noise shaping AR coefs and gains */
260     /********************************************/
261     for( k = 0; k < psEnc->sCmn.nb_subfr; k++ ) {
262         /* Apply window: sine slope followed by flat part followed by cosine slope */
263         opus_int shift, slope_part, flat_part;
264         flat_part = psEnc->sCmn.fs_kHz * 3;
265         slope_part = silk_RSHIFT( psEnc->sCmn.shapeWinLength - flat_part, 1 );
266
267         silk_apply_sine_window( x_windowed, x_ptr, 1, slope_part );
268         shift = slope_part;
269         silk_memcpy( x_windowed + shift, x_ptr + shift, flat_part * sizeof(opus_int16) );
270         shift += flat_part;
271         silk_apply_sine_window( x_windowed + shift, x_ptr + shift, 2, slope_part );
272
273         /* Update pointer: next LPC analysis block */
274         x_ptr += psEnc->sCmn.subfr_length;
275
276         if( psEnc->sCmn.warping_Q16 > 0 ) {
277             /* Calculate warped auto correlation */
278             silk_warped_autocorrelation_FIX( auto_corr, &scale, x_windowed, warping_Q16, psEnc->sCmn.shapeWinLength, psEnc->sCmn.shapingLPCOrder );
279         } else {
280             /* Calculate regular auto correlation */
281             silk_autocorr( auto_corr, &scale, x_windowed, psEnc->sCmn.shapeWinLength, psEnc->sCmn.shapingLPCOrder + 1 );
282         }
283
284         /* Add white noise, as a fraction of energy */
285         auto_corr[0] = silk_ADD32( auto_corr[0], silk_max_32( silk_SMULWB( silk_RSHIFT( auto_corr[ 0 ], 4 ),
286             SILK_FIX_CONST( SHAPE_WHITE_NOISE_FRACTION, 20 ) ), 1 ) );
287
288         /* Calculate the reflection coefficients using schur */
289         nrg = silk_schur64( refl_coef_Q16, auto_corr, psEnc->sCmn.shapingLPCOrder );
290         silk_assert( nrg >= 0 );
291
292         /* Convert reflection coefficients to prediction coefficients */
293         silk_k2a_Q16( AR2_Q24, refl_coef_Q16, psEnc->sCmn.shapingLPCOrder );
294
295         Qnrg = -scale;          /* range: -12...30*/
296         silk_assert( Qnrg >= -12 );
297         silk_assert( Qnrg <=  30 );
298
299         /* Make sure that Qnrg is an even number */
300         if( Qnrg & 1 ) {
301             Qnrg -= 1;
302             nrg >>= 1;
303         }
304
305         tmp32 = silk_SQRT_APPROX( nrg );
306         Qnrg >>= 1;             /* range: -6...15*/
307
308         psEncCtrl->Gains_Q16[ k ] = silk_LSHIFT_SAT32( tmp32, 16 - Qnrg );
309
310         if( psEnc->sCmn.warping_Q16 > 0 ) {
311             /* Adjust gain for warping */
312             gain_mult_Q16 = warped_gain( AR2_Q24, warping_Q16, psEnc->sCmn.shapingLPCOrder );
313             silk_assert( psEncCtrl->Gains_Q16[ k ] >= 0 );
314             if ( silk_SMULWW( silk_RSHIFT_ROUND( psEncCtrl->Gains_Q16[ k ], 1 ), gain_mult_Q16 ) >= ( silk_int32_MAX >> 1 ) ) {
315                psEncCtrl->Gains_Q16[ k ] = silk_int32_MAX;
316             } else {
317                psEncCtrl->Gains_Q16[ k ] = silk_SMULWW( psEncCtrl->Gains_Q16[ k ], gain_mult_Q16 );
318             }
319         }
320
321         /* Bandwidth expansion for synthesis filter shaping */
322         silk_bwexpander_32( AR2_Q24, psEnc->sCmn.shapingLPCOrder, BWExp2_Q16 );
323
324         /* Compute noise shaping filter coefficients */
325         silk_memcpy( AR1_Q24, AR2_Q24, psEnc->sCmn.shapingLPCOrder * sizeof( opus_int32 ) );
326
327         /* Bandwidth expansion for analysis filter shaping */
328         silk_assert( BWExp1_Q16 <= SILK_FIX_CONST( 1.0, 16 ) );
329         silk_bwexpander_32( AR1_Q24, psEnc->sCmn.shapingLPCOrder, BWExp1_Q16 );
330
331         /* Ratio of prediction gains, in energy domain */
332         pre_nrg_Q30 = silk_LPC_inverse_pred_gain_Q24( AR2_Q24, psEnc->sCmn.shapingLPCOrder );
333         nrg         = silk_LPC_inverse_pred_gain_Q24( AR1_Q24, psEnc->sCmn.shapingLPCOrder );
334
335         /*psEncCtrl->GainsPre[ k ] = 1.0f - 0.7f * ( 1.0f - pre_nrg / nrg ) = 0.3f + 0.7f * pre_nrg / nrg;*/
336         pre_nrg_Q30 = silk_LSHIFT32( silk_SMULWB( pre_nrg_Q30, SILK_FIX_CONST( 0.7, 15 ) ), 1 );
337         psEncCtrl->GainsPre_Q14[ k ] = ( opus_int ) SILK_FIX_CONST( 0.3, 14 ) + silk_DIV32_varQ( pre_nrg_Q30, nrg, 14 );
338
339         /* Convert to monic warped prediction coefficients and limit absolute values */
340         limit_warped_coefs( AR2_Q24, AR1_Q24, warping_Q16, SILK_FIX_CONST( 3.999, 24 ), psEnc->sCmn.shapingLPCOrder );
341
342         /* Convert from Q24 to Q13 and store in int16 */
343         for( i = 0; i < psEnc->sCmn.shapingLPCOrder; i++ ) {
344             psEncCtrl->AR1_Q13[ k * MAX_SHAPE_LPC_ORDER + i ] = (opus_int16)silk_SAT16( silk_RSHIFT_ROUND( AR1_Q24[ i ], 11 ) );
345             psEncCtrl->AR2_Q13[ k * MAX_SHAPE_LPC_ORDER + i ] = (opus_int16)silk_SAT16( silk_RSHIFT_ROUND( AR2_Q24[ i ], 11 ) );
346         }
347     }
348
349     /*****************/
350     /* Gain tweaking */
351     /*****************/
352     /* Increase gains during low speech activity and put lower limit on gains */
353     gain_mult_Q16 = silk_log2lin( -silk_SMLAWB( -SILK_FIX_CONST( 16.0, 7 ), SNR_adj_dB_Q7, SILK_FIX_CONST( 0.16, 16 ) ) );
354     gain_add_Q16  = silk_log2lin(  silk_SMLAWB(  SILK_FIX_CONST( 16.0, 7 ), SILK_FIX_CONST( MIN_QGAIN_DB, 7 ), SILK_FIX_CONST( 0.16, 16 ) ) );
355     silk_assert( gain_mult_Q16 > 0 );
356     for( k = 0; k < psEnc->sCmn.nb_subfr; k++ ) {
357         psEncCtrl->Gains_Q16[ k ] = silk_SMULWW( psEncCtrl->Gains_Q16[ k ], gain_mult_Q16 );
358         silk_assert( psEncCtrl->Gains_Q16[ k ] >= 0 );
359         psEncCtrl->Gains_Q16[ k ] = silk_ADD_POS_SAT32( psEncCtrl->Gains_Q16[ k ], gain_add_Q16 );
360     }
361
362     gain_mult_Q16 = SILK_FIX_CONST( 1.0, 16 ) + silk_RSHIFT_ROUND( silk_MLA( SILK_FIX_CONST( INPUT_TILT, 26 ),
363         psEncCtrl->coding_quality_Q14, SILK_FIX_CONST( HIGH_RATE_INPUT_TILT, 12 ) ), 10 );
364     for( k = 0; k < psEnc->sCmn.nb_subfr; k++ ) {
365         psEncCtrl->GainsPre_Q14[ k ] = silk_SMULWB( gain_mult_Q16, psEncCtrl->GainsPre_Q14[ k ] );
366     }
367
368     /************************************************/
369     /* Control low-frequency shaping and noise tilt */
370     /************************************************/
371     /* Less low frequency shaping for noisy inputs */
372     strength_Q16 = silk_MUL( SILK_FIX_CONST( LOW_FREQ_SHAPING, 4 ), silk_SMLAWB( SILK_FIX_CONST( 1.0, 12 ),
373         SILK_FIX_CONST( LOW_QUALITY_LOW_FREQ_SHAPING_DECR, 13 ), psEnc->sCmn.input_quality_bands_Q15[ 0 ] - SILK_FIX_CONST( 1.0, 15 ) ) );
374     strength_Q16 = silk_RSHIFT( silk_MUL( strength_Q16, psEnc->sCmn.speech_activity_Q8 ), 8 );
375     if( psEnc->sCmn.indices.signalType == TYPE_VOICED ) {
376         /* Reduce low frequencies quantization noise for periodic signals, depending on pitch lag */
377         /*f = 400; freqz([1, -0.98 + 2e-4 * f], [1, -0.97 + 7e-4 * f], 2^12, Fs); axis([0, 1000, -10, 1])*/
378         opus_int fs_kHz_inv = silk_DIV32_16( SILK_FIX_CONST( 0.2, 14 ), psEnc->sCmn.fs_kHz );
379         for( k = 0; k < psEnc->sCmn.nb_subfr; k++ ) {
380             b_Q14 = fs_kHz_inv + silk_DIV32_16( SILK_FIX_CONST( 3.0, 14 ), psEncCtrl->pitchL[ k ] );
381             /* Pack two coefficients in one int32 */
382             psEncCtrl->LF_shp_Q14[ k ]  = silk_LSHIFT( SILK_FIX_CONST( 1.0, 14 ) - b_Q14 - silk_SMULWB( strength_Q16, b_Q14 ), 16 );
383             psEncCtrl->LF_shp_Q14[ k ] |= (opus_uint16)( b_Q14 - SILK_FIX_CONST( 1.0, 14 ) );
384         }
385         silk_assert( SILK_FIX_CONST( HARM_HP_NOISE_COEF, 24 ) < SILK_FIX_CONST( 0.5, 24 ) ); /* Guarantees that second argument to SMULWB() is within range of an opus_int16*/
386         Tilt_Q16 = - SILK_FIX_CONST( HP_NOISE_COEF, 16 ) -
387             silk_SMULWB( SILK_FIX_CONST( 1.0, 16 ) - SILK_FIX_CONST( HP_NOISE_COEF, 16 ),
388                 silk_SMULWB( SILK_FIX_CONST( HARM_HP_NOISE_COEF, 24 ), psEnc->sCmn.speech_activity_Q8 ) );
389     } else {
390         b_Q14 = silk_DIV32_16( 21299, psEnc->sCmn.fs_kHz ); /* 1.3_Q0 = 21299_Q14*/
391         /* Pack two coefficients in one int32 */
392         psEncCtrl->LF_shp_Q14[ 0 ]  = silk_LSHIFT( SILK_FIX_CONST( 1.0, 14 ) - b_Q14 -
393             silk_SMULWB( strength_Q16, silk_SMULWB( SILK_FIX_CONST( 0.6, 16 ), b_Q14 ) ), 16 );
394         psEncCtrl->LF_shp_Q14[ 0 ] |= (opus_uint16)( b_Q14 - SILK_FIX_CONST( 1.0, 14 ) );
395         for( k = 1; k < psEnc->sCmn.nb_subfr; k++ ) {
396             psEncCtrl->LF_shp_Q14[ k ] = psEncCtrl->LF_shp_Q14[ 0 ];
397         }
398         Tilt_Q16 = -SILK_FIX_CONST( HP_NOISE_COEF, 16 );
399     }
400
401     /****************************/
402     /* HARMONIC SHAPING CONTROL */
403     /****************************/
404     /* Control boosting of harmonic frequencies */
405     HarmBoost_Q16 = silk_SMULWB( silk_SMULWB( SILK_FIX_CONST( 1.0, 17 ) - silk_LSHIFT( psEncCtrl->coding_quality_Q14, 3 ),
406         psEnc->LTPCorr_Q15 ), SILK_FIX_CONST( LOW_RATE_HARMONIC_BOOST, 16 ) );
407
408     /* More harmonic boost for noisy input signals */
409     HarmBoost_Q16 = silk_SMLAWB( HarmBoost_Q16,
410         SILK_FIX_CONST( 1.0, 16 ) - silk_LSHIFT( psEncCtrl->input_quality_Q14, 2 ), SILK_FIX_CONST( LOW_INPUT_QUALITY_HARMONIC_BOOST, 16 ) );
411
412     if( USE_HARM_SHAPING && psEnc->sCmn.indices.signalType == TYPE_VOICED ) {
413         /* More harmonic noise shaping for high bitrates or noisy input */
414         HarmShapeGain_Q16 = silk_SMLAWB( SILK_FIX_CONST( HARMONIC_SHAPING, 16 ),
415                 SILK_FIX_CONST( 1.0, 16 ) - silk_SMULWB( SILK_FIX_CONST( 1.0, 18 ) - silk_LSHIFT( psEncCtrl->coding_quality_Q14, 4 ),
416                 psEncCtrl->input_quality_Q14 ), SILK_FIX_CONST( HIGH_RATE_OR_LOW_QUALITY_HARMONIC_SHAPING, 16 ) );
417
418         /* Less harmonic noise shaping for less periodic signals */
419         HarmShapeGain_Q16 = silk_SMULWB( silk_LSHIFT( HarmShapeGain_Q16, 1 ),
420             silk_SQRT_APPROX( silk_LSHIFT( psEnc->LTPCorr_Q15, 15 ) ) );
421     } else {
422         HarmShapeGain_Q16 = 0;
423     }
424
425     /*************************/
426     /* Smooth over subframes */
427     /*************************/
428     for( k = 0; k < MAX_NB_SUBFR; k++ ) {
429         psShapeSt->HarmBoost_smth_Q16 =
430             silk_SMLAWB( psShapeSt->HarmBoost_smth_Q16,     HarmBoost_Q16     - psShapeSt->HarmBoost_smth_Q16,     SILK_FIX_CONST( SUBFR_SMTH_COEF, 16 ) );
431         psShapeSt->HarmShapeGain_smth_Q16 =
432             silk_SMLAWB( psShapeSt->HarmShapeGain_smth_Q16, HarmShapeGain_Q16 - psShapeSt->HarmShapeGain_smth_Q16, SILK_FIX_CONST( SUBFR_SMTH_COEF, 16 ) );
433         psShapeSt->Tilt_smth_Q16 =
434             silk_SMLAWB( psShapeSt->Tilt_smth_Q16,          Tilt_Q16          - psShapeSt->Tilt_smth_Q16,          SILK_FIX_CONST( SUBFR_SMTH_COEF, 16 ) );
435
436         psEncCtrl->HarmBoost_Q14[ k ]     = ( opus_int )silk_RSHIFT_ROUND( psShapeSt->HarmBoost_smth_Q16,     2 );
437         psEncCtrl->HarmShapeGain_Q14[ k ] = ( opus_int )silk_RSHIFT_ROUND( psShapeSt->HarmShapeGain_smth_Q16, 2 );
438         psEncCtrl->Tilt_Q14[ k ]          = ( opus_int )silk_RSHIFT_ROUND( psShapeSt->Tilt_smth_Q16,          2 );
439     }
440 }