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27 
28 #ifndef SILK_SIGPROC_FIX_H
29 #define SILK_SIGPROC_FIX_H
30 
31 #ifdef  __cplusplus
32 extern "C"
33 {
34 #endif
35 
36 /*#define silk_MACRO_COUNT */          /* Used to enable WMOPS counting */
37 
38 #define SILK_MAX_ORDER_LPC            16            /* max order of the LPC analysis in schur() and k2a() */
39 
40 #include <string.h>                                 /* for memset(), memcpy(), memmove() */
41 #include "typedef.h"
42 #include "resampler_structs.h"
43 #include "macros.h"
44 
45 
46 /********************************************************************/
47 /*                    SIGNAL PROCESSING FUNCTIONS                   */
48 /********************************************************************/
49 
50 /*!
51  * Initialize/reset the resampler state for a given pair of input/output sampling rates
52 */
53 opus_int silk_resampler_init(
54     silk_resampler_state_struct *S,                 /* I/O  Resampler state                                             */
55     opus_int32                  Fs_Hz_in,           /* I    Input sampling rate (Hz)                                    */
56     opus_int32                  Fs_Hz_out,          /* I    Output sampling rate (Hz)                                   */
57     opus_int                    forEnc              /* I    If 1: encoder; if 0: decoder                                */
58 );
59 
60 /*!
61  * Resampler: convert from one sampling rate to another
62  */
63 opus_int silk_resampler(
64     silk_resampler_state_struct *S,                 /* I/O  Resampler state                                             */
65     opus_int16                  out[],              /* O    Output signal                                               */
66     const opus_int16            in[],               /* I    Input signal                                                */
67     opus_int32                  inLen               /* I    Number of input samples                                     */
68 );
69 
70 /*!
71 * Downsample 2x, mediocre quality
72 */
73 void silk_resampler_down2(
74     opus_int32                  *S,                 /* I/O  State vector [ 2 ]                                          */
75     opus_int16                  *out,               /* O    Output signal [ len ]                                       */
76     const opus_int16            *in,                /* I    Input signal [ floor(len/2) ]                               */
77     opus_int32                  inLen               /* I    Number of input samples                                     */
78 );
79 
80 /*!
81  * Downsample by a factor 2/3, low quality
82 */
83 void silk_resampler_down2_3(
84     opus_int32                  *S,                 /* I/O  State vector [ 6 ]                                          */
85     opus_int16                  *out,               /* O    Output signal [ floor(2*inLen/3) ]                          */
86     const opus_int16            *in,                /* I    Input signal [ inLen ]                                      */
87     opus_int32                  inLen               /* I    Number of input samples                                     */
88 );
89 
90 /*!
91  * second order ARMA filter;
92  * slower than biquad() but uses more precise coefficients
93  * can handle (slowly) varying coefficients
94  */
95 void silk_biquad_alt(
96     const opus_int16            *in,                /* I     input signal                                               */
97     const opus_int32            *B_Q28,             /* I     MA coefficients [3]                                        */
98     const opus_int32            *A_Q28,             /* I     AR coefficients [2]                                        */
99     opus_int32                  *S,                 /* I/O   State vector [2]                                           */
100     opus_int16                  *out,               /* O     output signal                                              */
101     const opus_int32            len,                /* I     signal length (must be even)                               */
102     opus_int                    stride              /* I     Operate on interleaved signal if > 1                       */
103 );
104 
105 /* Variable order MA prediction error filter. */
106 void silk_LPC_analysis_filter(
107     opus_int16                  *out,               /* O    Output signal                                               */
108     const opus_int16            *in,                /* I    Input signal                                                */
109     const opus_int16            *B,                 /* I    MA prediction coefficients, Q12 [order]                     */
110     const opus_int32            len,                /* I    Signal length                                               */
111     const opus_int32            d                   /* I    Filter order                                                */
112 );
113 
114 /* Chirp (bandwidth expand) LP AR filter */
115 void silk_bwexpander(
116     opus_int16                  *ar,                /* I/O  AR filter to be expanded (without leading 1)                */
117     const opus_int              d,                  /* I    Length of ar                                                */
118     opus_int32                  chirp_Q16           /* I    Chirp factor (typically in the range 0 to 1)                */
119 );
120 
121 /* Chirp (bandwidth expand) LP AR filter */
122 void silk_bwexpander_32(
123     opus_int32                  *ar,                /* I/O  AR filter to be expanded (without leading 1)                */
124     const opus_int              d,                  /* I    Length of ar                                                */
125     opus_int32                  chirp_Q16           /* I    Chirp factor in Q16                                         */
126 );
127 
128 /* Compute inverse of LPC prediction gain, and                           */
129 /* test if LPC coefficients are stable (all poles within unit circle)    */
130 opus_int32 silk_LPC_inverse_pred_gain(              /* O   Returns inverse prediction gain in energy domain, Q30        */
131     const opus_int16            *A_Q12,             /* I   Prediction coefficients, Q12 [order]                         */
132     const opus_int              order               /* I   Prediction order                                             */
133 );
134 
135 /* For input in Q24 domain */
136 opus_int32 silk_LPC_inverse_pred_gain_Q24(          /* O    Returns inverse prediction gain in energy domain, Q30       */
137     const opus_int32            *A_Q24,             /* I    Prediction coefficients [order]                             */
138     const opus_int              order               /* I    Prediction order                                            */
139 );
140 
141 /* Split signal in two decimated bands using first-order allpass filters */
142 void silk_ana_filt_bank_1(
143     const opus_int16            *in,                /* I    Input signal [N]                                            */
144     opus_int32                  *S,                 /* I/O  State vector [2]                                            */
145     opus_int16                  *outL,              /* O    Low band [N/2]                                              */
146     opus_int16                  *outH,              /* O    High band [N/2]                                             */
147     const opus_int32            N                   /* I    Number of input samples                                     */
148 );
149 
150 /********************************************************************/
151 /*                        SCALAR FUNCTIONS                          */
152 /********************************************************************/
153 
154 /* Approximation of 128 * log2() (exact inverse of approx 2^() below) */
155 /* Convert input to a log scale    */
156 opus_int32 silk_lin2log(
157     const opus_int32            inLin               /* I  input in linear scale                                         */
158 );
159 
160 /* Approximation of a sigmoid function */
161 opus_int silk_sigm_Q15(
162     opus_int                    in_Q5               /* I                                                                */
163 );
164 
165 /* Approximation of 2^() (exact inverse of approx log2() above) */
166 /* Convert input to a linear scale */
167 opus_int32 silk_log2lin(
168     const opus_int32            inLog_Q7            /* I  input on log scale                                            */
169 );
170 
171 /* Compute number of bits to right shift the sum of squares of a vector    */
172 /* of int16s to make it fit in an int32                                    */
173 void silk_sum_sqr_shift(
174     opus_int32                  *energy,            /* O   Energy of x, after shifting to the right                     */
175     opus_int                    *shift,             /* O   Number of bits right shift applied to energy                 */
176     const opus_int16            *x,                 /* I   Input vector                                                 */
177     opus_int                    len                 /* I   Length of input vector                                       */
178 );
179 
180 /* Calculates the reflection coefficients from the correlation sequence    */
181 /* Faster than schur64(), but much less accurate.                          */
182 /* uses SMLAWB(), requiring armv5E and higher.                             */
183 opus_int32 silk_schur(                              /* O    Returns residual energy                                     */
184     opus_int16                  *rc_Q15,            /* O    reflection coefficients [order] Q15                         */
185     const opus_int32            *c,                 /* I    correlations [order+1]                                      */
186     const opus_int32            order               /* I    prediction order                                            */
187 );
188 
189 /* Calculates the reflection coefficients from the correlation sequence    */
190 /* Slower than schur(), but more accurate.                                 */
191 /* Uses SMULL(), available on armv4                                        */
192 opus_int32 silk_schur64(                            /* O    returns residual energy                                     */
193     opus_int32                  rc_Q16[],           /* O    Reflection coefficients [order] Q16                         */
194     const opus_int32            c[],                /* I    Correlations [order+1]                                      */
195     opus_int32                  order               /* I    Prediction order                                            */
196 );
197 
198 /* Step up function, converts reflection coefficients to prediction coefficients */
199 void silk_k2a(
200     opus_int32                  *A_Q24,             /* O    Prediction coefficients [order] Q24                         */
201     const opus_int16            *rc_Q15,            /* I    Reflection coefficients [order] Q15                         */
202     const opus_int32            order               /* I    Prediction order                                            */
203 );
204 
205 /* Step up function, converts reflection coefficients to prediction coefficients */
206 void silk_k2a_Q16(
207     opus_int32                  *A_Q24,             /* O    Prediction coefficients [order] Q24                         */
208     const opus_int32            *rc_Q16,            /* I    Reflection coefficients [order] Q16                         */
209     const opus_int32            order               /* I    Prediction order                                            */
210 );
211 
212 /* Apply sine window to signal vector.                              */
213 /* Window types:                                                    */
214 /*    1 -> sine window from 0 to pi/2                               */
215 /*    2 -> sine window from pi/2 to pi                              */
216 /* every other sample of window is linearly interpolated, for speed */
217 void silk_apply_sine_window(
218     opus_int16                  px_win[],           /* O    Pointer to windowed signal                                  */
219     const opus_int16            px[],               /* I    Pointer to input signal                                     */
220     const opus_int              win_type,           /* I    Selects a window type                                       */
221     const opus_int              length              /* I    Window length, multiple of 4                                */
222 );
223 
224 /* Compute autocorrelation */
225 void silk_autocorr(
226     opus_int32                  *results,           /* O    Result (length correlationCount)                            */
227     opus_int                    *scale,             /* O    Scaling of the correlation vector                           */
228     const opus_int16            *inputData,         /* I    Input data to correlate                                     */
229     const opus_int              inputDataSize,      /* I    Length of input                                             */
230     const opus_int              correlationCount,   /* I    Number of correlation taps to compute                       */
231     int                         arch                /* I    Run-time architecture                                       */
232 );
233 
234 void silk_decode_pitch(
235     opus_int16                  lagIndex,           /* I                                                                */
236     opus_int8                   contourIndex,       /* O                                                                */
237     opus_int                    pitch_lags[],       /* O    4 pitch values                                              */
238     const opus_int              Fs_kHz,             /* I    sampling frequency (kHz)                                    */
239     const opus_int              nb_subfr            /* I    number of sub frames                                        */
240 );
241 
242 opus_int silk_pitch_analysis_core(                  /* O    Voicing estimate: 0 voiced, 1 unvoiced                      */
243     const opus_int16            *frame,             /* I    Signal of length PE_FRAME_LENGTH_MS*Fs_kHz                  */
244     opus_int                    *pitch_out,         /* O    4 pitch lag values                                          */
245     opus_int16                  *lagIndex,          /* O    Lag Index                                                   */
246     opus_int8                   *contourIndex,      /* O    Pitch contour Index                                         */
247     opus_int                    *LTPCorr_Q15,       /* I/O  Normalized correlation; input: value from previous frame    */
248     opus_int                    prevLag,            /* I    Last lag of previous frame; set to zero is unvoiced         */
249     const opus_int32            search_thres1_Q16,  /* I    First stage threshold for lag candidates 0 - 1              */
250     const opus_int              search_thres2_Q13,  /* I    Final threshold for lag candidates 0 - 1                    */
251     const opus_int              Fs_kHz,             /* I    Sample frequency (kHz)                                      */
252     const opus_int              complexity,         /* I    Complexity setting, 0-2, where 2 is highest                 */
253     const opus_int              nb_subfr,           /* I    number of 5 ms subframes                                    */
254     int                         arch                /* I    Run-time architecture                                       */
255 );
256 
257 /* Compute Normalized Line Spectral Frequencies (NLSFs) from whitening filter coefficients      */
258 /* If not all roots are found, the a_Q16 coefficients are bandwidth expanded until convergence. */
259 void silk_A2NLSF(
260     opus_int16                  *NLSF,              /* O    Normalized Line Spectral Frequencies in Q15 (0..2^15-1) [d] */
261     opus_int32                  *a_Q16,             /* I/O  Monic whitening filter coefficients in Q16 [d]              */
262     const opus_int              d                   /* I    Filter order (must be even)                                 */
263 );
264 
265 /* compute whitening filter coefficients from normalized line spectral frequencies */
266 void silk_NLSF2A(
267     opus_int16                  *a_Q12,             /* O    monic whitening filter coefficients in Q12,  [ d ]          */
268     const opus_int16            *NLSF,              /* I    normalized line spectral frequencies in Q15, [ d ]          */
269     const opus_int              d                   /* I    filter order (should be even)                               */
270 );
271 
272 void silk_insertion_sort_increasing(
273     opus_int32                  *a,                 /* I/O   Unsorted / Sorted vector                                   */
274     opus_int                    *idx,               /* O     Index vector for the sorted elements                       */
275     const opus_int              L,                  /* I     Vector length                                              */
276     const opus_int              K                   /* I     Number of correctly sorted positions                       */
277 );
278 
279 void silk_insertion_sort_decreasing_int16(
280     opus_int16                  *a,                 /* I/O   Unsorted / Sorted vector                                   */
281     opus_int                    *idx,               /* O     Index vector for the sorted elements                       */
282     const opus_int              L,                  /* I     Vector length                                              */
283     const opus_int              K                   /* I     Number of correctly sorted positions                       */
284 );
285 
286 void silk_insertion_sort_increasing_all_values_int16(
287      opus_int16                 *a,                 /* I/O   Unsorted / Sorted vector                                   */
288      const opus_int             L                   /* I     Vector length                                              */
289 );
290 
291 /* NLSF stabilizer, for a single input data vector */
292 void silk_NLSF_stabilize(
293           opus_int16            *NLSF_Q15,          /* I/O   Unstable/stabilized normalized LSF vector in Q15 [L]       */
294     const opus_int16            *NDeltaMin_Q15,     /* I     Min distance vector, NDeltaMin_Q15[L] must be >= 1 [L+1]   */
295     const opus_int              L                   /* I     Number of NLSF parameters in the input vector              */
296 );
297 
298 /* Laroia low complexity NLSF weights */
299 void silk_NLSF_VQ_weights_laroia(
300     opus_int16                  *pNLSFW_Q_OUT,      /* O     Pointer to input vector weights [D]                        */
301     const opus_int16            *pNLSF_Q15,         /* I     Pointer to input vector         [D]                        */
302     const opus_int              D                   /* I     Input vector dimension (even)                              */
303 );
304 
305 /* Compute reflection coefficients from input signal */
306 void silk_burg_modified(
307     opus_int32                  *res_nrg,           /* O    Residual energy                                             */
308     opus_int                    *res_nrg_Q,         /* O    Residual energy Q value                                     */
309     opus_int32                  A_Q16[],            /* O    Prediction coefficients (length order)                      */
310     const opus_int16            x[],                /* I    Input signal, length: nb_subfr * ( D + subfr_length )       */
311     const opus_int32            minInvGain_Q30,     /* I    Inverse of max prediction gain                              */
312     const opus_int              subfr_length,       /* I    Input signal subframe length (incl. D preceding samples)    */
313     const opus_int              nb_subfr,           /* I    Number of subframes stacked in x                            */
314     const opus_int              D,                  /* I    Order                                                       */
315     int                         arch                /* I    Run-time architecture                                       */
316 );
317 
318 /* Copy and multiply a vector by a constant */
319 void silk_scale_copy_vector16(
320     opus_int16                  *data_out,
321     const opus_int16            *data_in,
322     opus_int32                  gain_Q16,           /* I    Gain in Q16                                                 */
323     const opus_int              dataSize            /* I    Length                                                      */
324 );
325 
326 /* Some for the LTP related function requires Q26 to work.*/
327 void silk_scale_vector32_Q26_lshift_18(
328     opus_int32                  *data1,             /* I/O  Q0/Q18                                                      */
329     opus_int32                  gain_Q26,           /* I    Q26                                                         */
330     opus_int                    dataSize            /* I    length                                                      */
331 );
332 
333 /********************************************************************/
334 /*                        INLINE ARM MATH                           */
335 /********************************************************************/
336 
337 /*    return sum( inVec1[i] * inVec2[i] ) */
338 opus_int32 silk_inner_prod_aligned(
339     const opus_int16 *const     inVec1,             /*    I input vector 1                                              */
340     const opus_int16 *const     inVec2,             /*    I input vector 2                                              */
341     const opus_int              len                 /*    I vector lengths                                              */
342 );
343 
344 opus_int32 silk_inner_prod_aligned_scale(
345     const opus_int16 *const     inVec1,             /*    I input vector 1                                              */
346     const opus_int16 *const     inVec2,             /*    I input vector 2                                              */
347     const opus_int              scale,              /*    I number of bits to shift                                     */
348     const opus_int              len                 /*    I vector lengths                                              */
349 );
350 
351 opus_int64 silk_inner_prod16_aligned_64(
352     const opus_int16            *inVec1,            /*    I input vector 1                                              */
353     const opus_int16            *inVec2,            /*    I input vector 2                                              */
354     const opus_int              len                 /*    I vector lengths                                              */
355 );
356 
357 /********************************************************************/
358 /*                                MACROS                            */
359 /********************************************************************/
360 
361 /* Rotate a32 right by 'rot' bits. Negative rot values result in rotating
362    left. Output is 32bit int.
363    Note: contemporary compilers recognize the C expression below and
364    compile it into a 'ror' instruction if available. No need for OPUS_INLINE ASM! */
silk_ROR32(opus_int32 a32,opus_int rot)365 static OPUS_INLINE opus_int32 silk_ROR32( opus_int32 a32, opus_int rot )
366 {
367     opus_uint32 x = (opus_uint32) a32;
368     opus_uint32 r = (opus_uint32) rot;
369     opus_uint32 m = (opus_uint32) -rot;
370     if( rot == 0 ) {
371         return a32;
372     } else if( rot < 0 ) {
373         return (opus_int32) ((x << m) | (x >> (32 - m)));
374     } else {
375         return (opus_int32) ((x << (32 - r)) | (x >> r));
376     }
377 }
378 
379 /* Allocate opus_int16 aligned to 4-byte memory address */
380 #if EMBEDDED_ARM
381 #define silk_DWORD_ALIGN __attribute__((aligned(4)))
382 #else
383 #define silk_DWORD_ALIGN
384 #endif
385 
386 /* Useful Macros that can be adjusted to other platforms */
387 #define silk_memcpy(dest, src, size)        memcpy((dest), (src), (size))
388 #define silk_memset(dest, src, size)        memset((dest), (src), (size))
389 #define silk_memmove(dest, src, size)       memmove((dest), (src), (size))
390 
391 /* Fixed point macros */
392 
393 /* (a32 * b32) output have to be 32bit int */
394 #define silk_MUL(a32, b32)                  ((a32) * (b32))
395 
396 /* (a32 * b32) output have to be 32bit uint */
397 #define silk_MUL_uint(a32, b32)             silk_MUL(a32, b32)
398 
399 /* a32 + (b32 * c32) output have to be 32bit int */
400 #define silk_MLA(a32, b32, c32)             silk_ADD32((a32),((b32) * (c32)))
401 
402 /* a32 + (b32 * c32) output have to be 32bit uint */
403 #define silk_MLA_uint(a32, b32, c32)        silk_MLA(a32, b32, c32)
404 
405 /* ((a32 >> 16)  * (b32 >> 16)) output have to be 32bit int */
406 #define silk_SMULTT(a32, b32)               (((a32) >> 16) * ((b32) >> 16))
407 
408 /* a32 + ((a32 >> 16)  * (b32 >> 16)) output have to be 32bit int */
409 #define silk_SMLATT(a32, b32, c32)          silk_ADD32((a32),((b32) >> 16) * ((c32) >> 16))
410 
411 #define silk_SMLALBB(a64, b16, c16)         silk_ADD64((a64),(opus_int64)((opus_int32)(b16) * (opus_int32)(c16)))
412 
413 /* (a32 * b32) */
414 #define silk_SMULL(a32, b32)                ((opus_int64)(a32) * /*(opus_int64)*/(b32))
415 
416 /* Adds two signed 32-bit values in a way that can overflow, while not relying on undefined behaviour
417    (just standard two's complement implementation-specific behaviour) */
418 #define silk_ADD32_ovflw(a, b)              ((opus_int32)((opus_uint32)(a) + (opus_uint32)(b)))
419 /* Subtractss two signed 32-bit values in a way that can overflow, while not relying on undefined behaviour
420    (just standard two's complement implementation-specific behaviour) */
421 #define silk_SUB32_ovflw(a, b)              ((opus_int32)((opus_uint32)(a) - (opus_uint32)(b)))
422 
423 /* Multiply-accumulate macros that allow overflow in the addition (ie, no asserts in debug mode) */
424 #define silk_MLA_ovflw(a32, b32, c32)       silk_ADD32_ovflw((a32), (opus_uint32)(b32) * (opus_uint32)(c32))
425 #define silk_SMLABB_ovflw(a32, b32, c32)    (silk_ADD32_ovflw((a32) , ((opus_int32)((opus_int16)(b32))) * (opus_int32)((opus_int16)(c32))))
426 
427 #define silk_DIV32_16(a32, b16)             ((opus_int32)((a32) / (b16)))
428 #define silk_DIV32(a32, b32)                ((opus_int32)((a32) / (b32)))
429 
430 /* These macros enables checking for overflow in silk_API_Debug.h*/
431 #define silk_ADD16(a, b)                    ((a) + (b))
432 #define silk_ADD32(a, b)                    ((a) + (b))
433 #define silk_ADD64(a, b)                    ((a) + (b))
434 
435 #define silk_SUB16(a, b)                    ((a) - (b))
436 #define silk_SUB32(a, b)                    ((a) - (b))
437 #define silk_SUB64(a, b)                    ((a) - (b))
438 
439 #define silk_SAT8(a)                        ((a) > silk_int8_MAX ? silk_int8_MAX  :       \
440                                             ((a) < silk_int8_MIN ? silk_int8_MIN  : (a)))
441 #define silk_SAT16(a)                       ((a) > silk_int16_MAX ? silk_int16_MAX :      \
442                                             ((a) < silk_int16_MIN ? silk_int16_MIN : (a)))
443 #define silk_SAT32(a)                       ((a) > silk_int32_MAX ? silk_int32_MAX :      \
444                                             ((a) < silk_int32_MIN ? silk_int32_MIN : (a)))
445 
446 #define silk_CHECK_FIT8(a)                  (a)
447 #define silk_CHECK_FIT16(a)                 (a)
448 #define silk_CHECK_FIT32(a)                 (a)
449 
450 #define silk_ADD_SAT16(a, b)                (opus_int16)silk_SAT16( silk_ADD32( (opus_int32)(a), (b) ) )
451 #define silk_ADD_SAT64(a, b)                ((((a) + (b)) & 0x8000000000000000LL) == 0 ?                            \
452                                             ((((a) & (b)) & 0x8000000000000000LL) != 0 ? silk_int64_MIN : (a)+(b)) : \
453                                             ((((a) | (b)) & 0x8000000000000000LL) == 0 ? silk_int64_MAX : (a)+(b)) )
454 
455 #define silk_SUB_SAT16(a, b)                (opus_int16)silk_SAT16( silk_SUB32( (opus_int32)(a), (b) ) )
456 #define silk_SUB_SAT64(a, b)                ((((a)-(b)) & 0x8000000000000000LL) == 0 ?                                               \
457                                             (( (a) & ((b)^0x8000000000000000LL) & 0x8000000000000000LL) ? silk_int64_MIN : (a)-(b)) : \
458                                             ((((a)^0x8000000000000000LL) & (b)  & 0x8000000000000000LL) ? silk_int64_MAX : (a)-(b)) )
459 
460 /* Saturation for positive input values */
461 #define silk_POS_SAT32(a)                   ((a) > silk_int32_MAX ? silk_int32_MAX : (a))
462 
463 /* Add with saturation for positive input values */
464 #define silk_ADD_POS_SAT8(a, b)             ((((a)+(b)) & 0x80)                 ? silk_int8_MAX  : ((a)+(b)))
465 #define silk_ADD_POS_SAT16(a, b)            ((((a)+(b)) & 0x8000)               ? silk_int16_MAX : ((a)+(b)))
466 #define silk_ADD_POS_SAT32(a, b)            ((((a)+(b)) & 0x80000000)           ? silk_int32_MAX : ((a)+(b)))
467 #define silk_ADD_POS_SAT64(a, b)            ((((a)+(b)) & 0x8000000000000000LL) ? silk_int64_MAX : ((a)+(b)))
468 
469 #define silk_LSHIFT8(a, shift)              ((opus_int8)((opus_uint8)(a)<<(shift)))         /* shift >= 0, shift < 8  */
470 #define silk_LSHIFT16(a, shift)             ((opus_int16)((opus_uint16)(a)<<(shift)))       /* shift >= 0, shift < 16 */
471 #define silk_LSHIFT32(a, shift)             ((opus_int32)((opus_uint32)(a)<<(shift)))       /* shift >= 0, shift < 32 */
472 #define silk_LSHIFT64(a, shift)             ((opus_int64)((opus_uint64)(a)<<(shift)))       /* shift >= 0, shift < 64 */
473 #define silk_LSHIFT(a, shift)               silk_LSHIFT32(a, shift)                         /* shift >= 0, shift < 32 */
474 
475 #define silk_RSHIFT8(a, shift)              ((a)>>(shift))                                  /* shift >= 0, shift < 8  */
476 #define silk_RSHIFT16(a, shift)             ((a)>>(shift))                                  /* shift >= 0, shift < 16 */
477 #define silk_RSHIFT32(a, shift)             ((a)>>(shift))                                  /* shift >= 0, shift < 32 */
478 #define silk_RSHIFT64(a, shift)             ((a)>>(shift))                                  /* shift >= 0, shift < 64 */
479 #define silk_RSHIFT(a, shift)               silk_RSHIFT32(a, shift)                         /* shift >= 0, shift < 32 */
480 
481 /* saturates before shifting */
482 #define silk_LSHIFT_SAT32(a, shift)         (silk_LSHIFT32( silk_LIMIT( (a), silk_RSHIFT32( silk_int32_MIN, (shift) ), \
483                                                     silk_RSHIFT32( silk_int32_MAX, (shift) ) ), (shift) ))
484 
485 #define silk_LSHIFT_ovflw(a, shift)         ((opus_int32)((opus_uint32)(a) << (shift)))     /* shift >= 0, allowed to overflow */
486 #define silk_LSHIFT_uint(a, shift)          ((a) << (shift))                                /* shift >= 0 */
487 #define silk_RSHIFT_uint(a, shift)          ((a) >> (shift))                                /* shift >= 0 */
488 
489 #define silk_ADD_LSHIFT(a, b, shift)        ((a) + silk_LSHIFT((b), (shift)))               /* shift >= 0 */
490 #define silk_ADD_LSHIFT32(a, b, shift)      silk_ADD32((a), silk_LSHIFT32((b), (shift)))    /* shift >= 0 */
491 #define silk_ADD_LSHIFT_uint(a, b, shift)   ((a) + silk_LSHIFT_uint((b), (shift)))          /* shift >= 0 */
492 #define silk_ADD_RSHIFT(a, b, shift)        ((a) + silk_RSHIFT((b), (shift)))               /* shift >= 0 */
493 #define silk_ADD_RSHIFT32(a, b, shift)      silk_ADD32((a), silk_RSHIFT32((b), (shift)))    /* shift >= 0 */
494 #define silk_ADD_RSHIFT_uint(a, b, shift)   ((a) + silk_RSHIFT_uint((b), (shift)))          /* shift >= 0 */
495 #define silk_SUB_LSHIFT32(a, b, shift)      silk_SUB32((a), silk_LSHIFT32((b), (shift)))    /* shift >= 0 */
496 #define silk_SUB_RSHIFT32(a, b, shift)      silk_SUB32((a), silk_RSHIFT32((b), (shift)))    /* shift >= 0 */
497 
498 /* Requires that shift > 0 */
499 #define silk_RSHIFT_ROUND(a, shift)         ((shift) == 1 ? ((a) >> 1) + ((a) & 1) : (((a) >> ((shift) - 1)) + 1) >> 1)
500 #define silk_RSHIFT_ROUND64(a, shift)       ((shift) == 1 ? ((a) >> 1) + ((a) & 1) : (((a) >> ((shift) - 1)) + 1) >> 1)
501 
502 /* Number of rightshift required to fit the multiplication */
503 #define silk_NSHIFT_MUL_32_32(a, b)         ( -(31- (32-silk_CLZ32(silk_abs(a)) + (32-silk_CLZ32(silk_abs(b))))) )
504 #define silk_NSHIFT_MUL_16_16(a, b)         ( -(15- (16-silk_CLZ16(silk_abs(a)) + (16-silk_CLZ16(silk_abs(b))))) )
505 
506 
507 #define silk_min(a, b)                      (((a) < (b)) ? (a) : (b))
508 #define silk_max(a, b)                      (((a) > (b)) ? (a) : (b))
509 
510 /* Macro to convert floating-point constants to fixed-point */
511 #define SILK_FIX_CONST( C, Q )              ((opus_int32)((C) * ((opus_int64)1 << (Q)) + 0.5))
512 
513 /* silk_min() versions with typecast in the function call */
silk_min_int(opus_int a,opus_int b)514 static OPUS_INLINE opus_int silk_min_int(opus_int a, opus_int b)
515 {
516     return (((a) < (b)) ? (a) : (b));
517 }
silk_min_16(opus_int16 a,opus_int16 b)518 static OPUS_INLINE opus_int16 silk_min_16(opus_int16 a, opus_int16 b)
519 {
520     return (((a) < (b)) ? (a) : (b));
521 }
silk_min_32(opus_int32 a,opus_int32 b)522 static OPUS_INLINE opus_int32 silk_min_32(opus_int32 a, opus_int32 b)
523 {
524     return (((a) < (b)) ? (a) : (b));
525 }
silk_min_64(opus_int64 a,opus_int64 b)526 static OPUS_INLINE opus_int64 silk_min_64(opus_int64 a, opus_int64 b)
527 {
528     return (((a) < (b)) ? (a) : (b));
529 }
530 
531 /* silk_min() versions with typecast in the function call */
silk_max_int(opus_int a,opus_int b)532 static OPUS_INLINE opus_int silk_max_int(opus_int a, opus_int b)
533 {
534     return (((a) > (b)) ? (a) : (b));
535 }
silk_max_16(opus_int16 a,opus_int16 b)536 static OPUS_INLINE opus_int16 silk_max_16(opus_int16 a, opus_int16 b)
537 {
538     return (((a) > (b)) ? (a) : (b));
539 }
silk_max_32(opus_int32 a,opus_int32 b)540 static OPUS_INLINE opus_int32 silk_max_32(opus_int32 a, opus_int32 b)
541 {
542     return (((a) > (b)) ? (a) : (b));
543 }
silk_max_64(opus_int64 a,opus_int64 b)544 static OPUS_INLINE opus_int64 silk_max_64(opus_int64 a, opus_int64 b)
545 {
546     return (((a) > (b)) ? (a) : (b));
547 }
548 
549 #define silk_LIMIT( a, limit1, limit2)      ((limit1) > (limit2) ? ((a) > (limit1) ? (limit1) : ((a) < (limit2) ? (limit2) : (a))) \
550                                                                  : ((a) > (limit2) ? (limit2) : ((a) < (limit1) ? (limit1) : (a))))
551 
552 #define silk_LIMIT_int                      silk_LIMIT
553 #define silk_LIMIT_16                       silk_LIMIT
554 #define silk_LIMIT_32                       silk_LIMIT
555 
556 #define silk_abs(a)                         (((a) >  0)  ? (a) : -(a))            /* Be careful, silk_abs returns wrong when input equals to silk_intXX_MIN */
557 #define silk_abs_int(a)                     (((a) ^ ((a) >> (8 * sizeof(a) - 1))) - ((a) >> (8 * sizeof(a) - 1)))
558 #define silk_abs_int32(a)                   (((a) ^ ((a) >> 31)) - ((a) >> 31))
559 #define silk_abs_int64(a)                   (((a) >  0)  ? (a) : -(a))
560 
561 #define silk_sign(a)                        ((a) > 0 ? 1 : ( (a) < 0 ? -1 : 0 ))
562 
563 /* PSEUDO-RANDOM GENERATOR                                                          */
564 /* Make sure to store the result as the seed for the next call (also in between     */
565 /* frames), otherwise result won't be random at all. When only using some of the    */
566 /* bits, take the most significant bits by right-shifting.                          */
567 #define silk_RAND(seed)                     (silk_MLA_ovflw(907633515, (seed), 196314165))
568 
569 /*  Add some multiplication functions that can be easily mapped to ARM. */
570 
571 /*    silk_SMMUL: Signed top word multiply.
572           ARMv6        2 instruction cycles.
573           ARMv3M+      3 instruction cycles. use SMULL and ignore LSB registers.(except xM)*/
574 /*#define silk_SMMUL(a32, b32)                (opus_int32)silk_RSHIFT(silk_SMLAL(silk_SMULWB((a32), (b32)), (a32), silk_RSHIFT_ROUND((b32), 16)), 16)*/
575 /* the following seems faster on x86 */
576 #define silk_SMMUL(a32, b32)                (opus_int32)silk_RSHIFT64(silk_SMULL((a32), (b32)), 32)
577 
578 #include "Inlines.h"
579 #include "MacroCount.h"
580 #include "MacroDebug.h"
581 
582 #ifdef OPUS_ARM_INLINE_ASM
583 #include "arm/SigProc_FIX_armv4.h"
584 #endif
585 
586 #ifdef OPUS_ARM_INLINE_EDSP
587 #include "arm/SigProc_FIX_armv5e.h"
588 #endif
589 
590 #ifdef  __cplusplus
591 }
592 #endif
593 
594 #endif /* SILK_SIGPROC_FIX_H */
595