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1 /* ----------------------------------------------------------------------
2 * Copyright (C) 2010 ARM Limited. All rights reserved.
3 *
4 * $Date: 15. July 2011
5 * $Revision: V1.0.10
6 *
7 * Project: CMSIS DSP Library
8 * Title: arm_math.h
9 *
10 * Description: Public header file for CMSIS DSP Library
11 *
12 * Target Processor: Cortex-M4/Cortex-M3/Cortex-M0
13 *
14 * Version 1.0.10 2011/7/15
15 * Big Endian support added and Merged M0 and M3/M4 Source code.
16 *
17 * Version 1.0.3 2010/11/29
18 * Re-organized the CMSIS folders and updated documentation.
19 *
20 * Version 1.0.2 2010/11/11
21 * Documentation updated.
22 *
23 * Version 1.0.1 2010/10/05
24 * Production release and review comments incorporated.
25 *
26 * Version 1.0.0 2010/09/20
27 * Production release and review comments incorporated.
28 * -------------------------------------------------------------------- */
29
30 /**
31 \mainpage CMSIS DSP Software Library
32 *
33 * <b>Introduction</b>
34 *
35 * This user manual describes the CMSIS DSP software library,
36 * a suite of common signal processing functions for use on Cortex-M processor based devices.
37 *
38 * The library is divided into a number of modules each covering a specific category:
39 * - Basic math functions
40 * - Fast math functions
41 * - Complex math functions
42 * - Filters
43 * - Matrix functions
44 * - Transforms
45 * - Motor control functions
46 * - Statistical functions
47 * - Support functions
48 * - Interpolation functions
49 *
50 * The library has separate functions for operating on 8-bit integers, 16-bit integers,
51 * 32-bit integer and 32-bit floating-point values.
52 *
53 * <b>Processor Support</b>
54 *
55 * The library is completely written in C and is fully CMSIS compliant.
56 * High performance is achieved through maximum use of Cortex-M4 intrinsics.
57 *
58 * The supplied library source code also builds and runs on the Cortex-M3 and Cortex-M0 processor,
59 * with the DSP intrinsics being emulated through software.
60 *
61 *
62 * <b>Toolchain Support</b>
63 *
64 * The library has been developed and tested with MDK-ARM version 4.21.
65 * The library is being tested in GCC and IAR toolchains and updates on this activity will be made available shortly.
66 *
67 * <b>Using the Library</b>
68 *
69 * The library installer contains prebuilt versions of the libraries in the <code>Lib</code> folder.
70 * - arm_cortexM4lf_math.lib (Little endian and Floating Point Unit on Cortex-M4)
71 * - arm_cortexM4bf_math.lib (Big endian and Floating Point Unit on Cortex-M4)
72 * - arm_cortexM4l_math.lib (Little endian on Cortex-M4)
73 * - arm_cortexM4b_math.lib (Big endian on Cortex-M4)
74 * - arm_cortexM3l_math.lib (Little endian on Cortex-M3)
75 * - arm_cortexM3b_math.lib (Big endian on Cortex-M3)
76 * - arm_cortexM0l_math.lib (Little endian on Cortex-M0)
77 * - arm_cortexM0b_math.lib (Big endian on Cortex-M3)
78 *
79 * The library functions are declared in the public file <code>arm_math.h</code> which is placed in the <code>Include</code> folder.
80 * Simply include this file and link the appropriate library in the application and begin calling the library functions. The Library supports single
81 * public header file <code> arm_math.h</code> for Cortex-M4/M3/M0 with little endian and big endian. Same header file will be used for floating point unit(FPU) variants.
82 * Define the appropriate pre processor MACRO ARM_MATH_CM4 or ARM_MATH_CM3 or
83 * ARM_MATH_CM0 depending on the target processor in the application.
84 *
85 * <b>Examples</b>
86 *
87 * The library ships with a number of examples which demonstrate how to use the library functions.
88 *
89 * <b>Building the Library</b>
90 *
91 * The library installer contains project files to re build libraries on MDK Tool chain in the <code>CMSIS\DSP_Lib\Source\ARM</code> folder.
92 * - arm_cortexM0b_math.uvproj
93 * - arm_cortexM0l_math.uvproj
94 * - arm_cortexM3b_math.uvproj
95 * - arm_cortexM3l_math.uvproj
96 * - arm_cortexM4b_math.uvproj
97 * - arm_cortexM4l_math.uvproj
98 * - arm_cortexM4bf_math.uvproj
99 * - arm_cortexM4lf_math.uvproj
100 *
101 * Each library project have differant pre-processor macros.
102 *
103 * <b>ARM_MATH_CMx:</b>
104 * Define macro ARM_MATH_CM4 for building the library on Cortex-M4 target, ARM_MATH_CM3 for building library on Cortex-M3 target
105 * and ARM_MATH_CM0 for building library on cortex-M0 target.
106 *
107 * <b>ARM_MATH_BIG_ENDIAN:</b>
108 * Define macro ARM_MATH_BIG_ENDIAN to build the library for big endian targets. By default library builds for little endian targets.
109 *
110 * <b>ARM_MATH_MATRIX_CHECK:</b>
111 * Define macro for checking on the input and output sizes of matrices
112 *
113 * <b>ARM_MATH_ROUNDING:</b>
114 * Define macro for rounding on support functions
115 *
116 * <b>__FPU_PRESENT:</b>
117 * Initialize macro __FPU_PRESENT = 1 when building on FPU supported Targets. Enable this macro for M4bf and M4lf libraries
118 *
119 *
120 * The project can be built by opening the appropriate project in MDK-ARM 4.21 chain and defining the optional pre processor MACROs detailed above.
121 *
122 * <b>Copyright Notice</b>
123 *
124 * Copyright (C) 2010 ARM Limited. All rights reserved.
125 */
126
127
128 /**
129 * @defgroup groupMath Basic Math Functions
130 */
131
132 /**
133 * @defgroup groupFastMath Fast Math Functions
134 * This set of functions provides a fast approximation to sine, cosine, and square root.
135 * As compared to most of the other functions in the CMSIS math library, the fast math functions
136 * operate on individual values and not arrays.
137 * There are separate functions for Q15, Q31, and floating-point data.
138 *
139 */
140
141 /**
142 * @defgroup groupCmplxMath Complex Math Functions
143 * This set of functions operates on complex data vectors.
144 * The data in the complex arrays is stored in an interleaved fashion
145 * (real, imag, real, imag, ...).
146 * In the API functions, the number of samples in a complex array refers
147 * to the number of complex values; the array contains twice this number of
148 * real values.
149 */
150
151 /**
152 * @defgroup groupFilters Filtering Functions
153 */
154
155 /**
156 * @defgroup groupMatrix Matrix Functions
157 *
158 * This set of functions provides basic matrix math operations.
159 * The functions operate on matrix data structures. For example,
160 * the type
161 * definition for the floating-point matrix structure is shown
162 * below:
163 * <pre>
164 * typedef struct
165 * {
166 * uint16_t numRows; // number of rows of the matrix.
167 * uint16_t numCols; // number of columns of the matrix.
168 * float32_t *pData; // points to the data of the matrix.
169 * } arm_matrix_instance_f32;
170 * </pre>
171 * There are similar definitions for Q15 and Q31 data types.
172 *
173 * The structure specifies the size of the matrix and then points to
174 * an array of data. The array is of size <code>numRows X numCols</code>
175 * and the values are arranged in row order. That is, the
176 * matrix element (i, j) is stored at:
177 * <pre>
178 * pData[i*numCols + j]
179 * </pre>
180 *
181 * \par Init Functions
182 * There is an associated initialization function for each type of matrix
183 * data structure.
184 * The initialization function sets the values of the internal structure fields.
185 * Refer to the function <code>arm_mat_init_f32()</code>, <code>arm_mat_init_q31()</code>
186 * and <code>arm_mat_init_q15()</code> for floating-point, Q31 and Q15 types, respectively.
187 *
188 * \par
189 * Use of the initialization function is optional. However, if initialization function is used
190 * then the instance structure cannot be placed into a const data section.
191 * To place the instance structure in a const data
192 * section, manually initialize the data structure. For example:
193 * <pre>
194 * <code>arm_matrix_instance_f32 S = {nRows, nColumns, pData};</code>
195 * <code>arm_matrix_instance_q31 S = {nRows, nColumns, pData};</code>
196 * <code>arm_matrix_instance_q15 S = {nRows, nColumns, pData};</code>
197 * </pre>
198 * where <code>nRows</code> specifies the number of rows, <code>nColumns</code>
199 * specifies the number of columns, and <code>pData</code> points to the
200 * data array.
201 *
202 * \par Size Checking
203 * By default all of the matrix functions perform size checking on the input and
204 * output matrices. For example, the matrix addition function verifies that the
205 * two input matrices and the output matrix all have the same number of rows and
206 * columns. If the size check fails the functions return:
207 * <pre>
208 * ARM_MATH_SIZE_MISMATCH
209 * </pre>
210 * Otherwise the functions return
211 * <pre>
212 * ARM_MATH_SUCCESS
213 * </pre>
214 * There is some overhead associated with this matrix size checking.
215 * The matrix size checking is enabled via the #define
216 * <pre>
217 * ARM_MATH_MATRIX_CHECK
218 * </pre>
219 * within the library project settings. By default this macro is defined
220 * and size checking is enabled. By changing the project settings and
221 * undefining this macro size checking is eliminated and the functions
222 * run a bit faster. With size checking disabled the functions always
223 * return <code>ARM_MATH_SUCCESS</code>.
224 */
225
226 /**
227 * @defgroup groupTransforms Transform Functions
228 */
229
230 /**
231 * @defgroup groupController Controller Functions
232 */
233
234 /**
235 * @defgroup groupStats Statistics Functions
236 */
237 /**
238 * @defgroup groupSupport Support Functions
239 */
240
241 /**
242 * @defgroup groupInterpolation Interpolation Functions
243 * These functions perform 1- and 2-dimensional interpolation of data.
244 * Linear interpolation is used for 1-dimensional data and
245 * bilinear interpolation is used for 2-dimensional data.
246 */
247
248 /**
249 * @defgroup groupExamples Examples
250 */
251 #ifndef _ARM_MATH_H
252 #define _ARM_MATH_H
253
254 #define __CMSIS_GENERIC /* disable NVIC and Systick functions */
255
256 #if defined (ARM_MATH_CM4)
257 #include "core_cm4.h"
258 #elif defined (ARM_MATH_CM3)
259 #include "core_cm3.h"
260 #elif defined (ARM_MATH_CM0)
261 #include "core_cm0.h"
262 #else
263 #include "ARMCM4.h"
264 #warning "Define either ARM_MATH_CM4 OR ARM_MATH_CM3...By Default building on ARM_MATH_CM4....."
265 #endif
266
267 #undef __CMSIS_GENERIC /* enable NVIC and Systick functions */
268 #include "string.h"
269 #include "math.h"
270 #ifdef __cplusplus
271 extern "C"
272 {
273 #endif
274
275
276 /**
277 * @brief Macros required for reciprocal calculation in Normalized LMS
278 */
279
280 #define DELTA_Q31 (0x100)
281 #define DELTA_Q15 0x5
282 #define INDEX_MASK 0x0000003F
283 #define PI 3.14159265358979f
284
285 /**
286 * @brief Macros required for SINE and COSINE Fast math approximations
287 */
288
289 #define TABLE_SIZE 256
290 #define TABLE_SPACING_Q31 0x800000
291 #define TABLE_SPACING_Q15 0x80
292
293 /**
294 * @brief Macros required for SINE and COSINE Controller functions
295 */
296 /* 1.31(q31) Fixed value of 2/360 */
297 /* -1 to +1 is divided into 360 values so total spacing is (2/360) */
298 #define INPUT_SPACING 0xB60B61
299
300
301 /**
302 * @brief Error status returned by some functions in the library.
303 */
304
305 typedef enum
306 {
307 ARM_MATH_SUCCESS = 0, /**< No error */
308 ARM_MATH_ARGUMENT_ERROR = -1, /**< One or more arguments are incorrect */
309 ARM_MATH_LENGTH_ERROR = -2, /**< Length of data buffer is incorrect */
310 ARM_MATH_SIZE_MISMATCH = -3, /**< Size of matrices is not compatible with the operation. */
311 ARM_MATH_NANINF = -4, /**< Not-a-number (NaN) or infinity is generated */
312 ARM_MATH_SINGULAR = -5, /**< Generated by matrix inversion if the input matrix is singular and cannot be inverted. */
313 ARM_MATH_TEST_FAILURE = -6 /**< Test Failed */
314 } arm_status;
315
316 /**
317 * @brief 8-bit fractional data type in 1.7 format.
318 */
319 typedef int8_t q7_t;
320
321 /**
322 * @brief 16-bit fractional data type in 1.15 format.
323 */
324 typedef int16_t q15_t;
325
326 /**
327 * @brief 32-bit fractional data type in 1.31 format.
328 */
329 typedef int32_t q31_t;
330
331 /**
332 * @brief 64-bit fractional data type in 1.63 format.
333 */
334 typedef int64_t q63_t;
335
336 /**
337 * @brief 32-bit floating-point type definition.
338 */
339 typedef float float32_t;
340
341 /**
342 * @brief 64-bit floating-point type definition.
343 */
344 typedef double float64_t;
345
346 /**
347 * @brief definition to read/write two 16 bit values.
348 */
349 #define __SIMD32(addr) (*(int32_t **) & (addr))
350
351 #if defined (ARM_MATH_CM3) || defined (ARM_MATH_CM0)
352 /**
353 * @brief definition to pack two 16 bit values.
354 */
355 #define __PKHBT(ARG1, ARG2, ARG3) ( (((int32_t)(ARG1) << 0) & (int32_t)0x0000FFFF) | \
356 (((int32_t)(ARG2) << ARG3) & (int32_t)0xFFFF0000) )
357
358 #endif
359
360
361 /**
362 * @brief definition to pack four 8 bit values.
363 */
364 #ifndef ARM_MATH_BIG_ENDIAN
365
366 #define __PACKq7(v0,v1,v2,v3) ( (((int32_t)(v0) << 0) & (int32_t)0x000000FF) | \
367 (((int32_t)(v1) << 8) & (int32_t)0x0000FF00) | \
368 (((int32_t)(v2) << 16) & (int32_t)0x00FF0000) | \
369 (((int32_t)(v3) << 24) & (int32_t)0xFF000000) )
370 #else
371
372 #define __PACKq7(v0,v1,v2,v3) ( (((int32_t)(v3) << 0) & (int32_t)0x000000FF) | \
373 (((int32_t)(v2) << 8) & (int32_t)0x0000FF00) | \
374 (((int32_t)(v1) << 16) & (int32_t)0x00FF0000) | \
375 (((int32_t)(v0) << 24) & (int32_t)0xFF000000) )
376
377 #endif
378
379
380 /**
381 * @brief Clips Q63 to Q31 values.
382 */
383 static __INLINE q31_t clip_q63_to_q31(
384 q63_t x)
385 {
386 return ((q31_t) (x >> 32) != ((q31_t) x >> 31)) ?
387 ((0x7FFFFFFF ^ ((q31_t) (x >> 63)))) : (q31_t) x;
388 }
389
390 /**
391 * @brief Clips Q63 to Q15 values.
392 */
393 static __INLINE q15_t clip_q63_to_q15(
394 q63_t x)
395 {
396 return ((q31_t) (x >> 32) != ((q31_t) x >> 31)) ?
397 ((0x7FFF ^ ((q15_t) (x >> 63)))) : (q15_t) (x >> 15);
398 }
399
400 /**
401 * @brief Clips Q31 to Q7 values.
402 */
403 static __INLINE q7_t clip_q31_to_q7(
404 q31_t x)
405 {
406 return ((q31_t) (x >> 24) != ((q31_t) x >> 23)) ?
407 ((0x7F ^ ((q7_t) (x >> 31)))) : (q7_t) x;
408 }
409
410 /**
411 * @brief Clips Q31 to Q15 values.
412 */
413 static __INLINE q15_t clip_q31_to_q15(
414 q31_t x)
415 {
416 return ((q31_t) (x >> 16) != ((q31_t) x >> 15)) ?
417 ((0x7FFF ^ ((q15_t) (x >> 31)))) : (q15_t) x;
418 }
419
420 /**
421 * @brief Multiplies 32 X 64 and returns 32 bit result in 2.30 format.
422 */
423
424 static __INLINE q63_t mult32x64(
425 q63_t x,
426 q31_t y)
427 {
428 return ((((q63_t) (x & 0x00000000FFFFFFFF) * y) >> 32) +
429 (((q63_t) (x >> 32) * y)));
430 }
431
432
433 #if defined (ARM_MATH_CM0) && defined ( __CC_ARM )
434 #define __CLZ __clz
435 #endif
436
437 #if defined (ARM_MATH_CM0) && ((defined (__ICCARM__)) ||(defined (__GNUC__)) || defined (__TASKING__) )
438
439 static __INLINE uint32_t __CLZ(q31_t data);
440
441
442 static __INLINE uint32_t __CLZ(q31_t data)
443 {
444 uint32_t count = 0;
445 uint32_t mask = 0x80000000;
446
447 while((data & mask) == 0)
448 {
449 count += 1u;
450 mask = mask >> 1u;
451 }
452
453 return(count);
454
455 }
456
457 #endif
458
459 /**
460 * @brief Function to Calculates 1/in(reciprocal) value of Q31 Data type.
461 */
462
463 static __INLINE uint32_t arm_recip_q31(
464 q31_t in,
465 q31_t * dst,
466 q31_t * pRecipTable)
467 {
468
469 uint32_t out, tempVal;
470 uint32_t index, i;
471 uint32_t signBits;
472
473 if(in > 0)
474 {
475 signBits = __CLZ(in) - 1;
476 }
477 else
478 {
479 signBits = __CLZ(-in) - 1;
480 }
481
482 /* Convert input sample to 1.31 format */
483 in = in << signBits;
484
485 /* calculation of index for initial approximated Val */
486 index = (uint32_t) (in >> 24u);
487 index = (index & INDEX_MASK);
488
489 /* 1.31 with exp 1 */
490 out = pRecipTable[index];
491
492 /* calculation of reciprocal value */
493 /* running approximation for two iterations */
494 for (i = 0u; i < 2u; i++)
495 {
496 tempVal = (q31_t) (((q63_t) in * out) >> 31u);
497 tempVal = 0x7FFFFFFF - tempVal;
498 /* 1.31 with exp 1 */
499 //out = (q31_t) (((q63_t) out * tempVal) >> 30u);
500 out = (q31_t) clip_q63_to_q31(((q63_t) out * tempVal) >> 30u);
501 }
502
503 /* write output */
504 *dst = out;
505
506 /* return num of signbits of out = 1/in value */
507 return (signBits + 1u);
508
509 }
510
511 /**
512 * @brief Function to Calculates 1/in(reciprocal) value of Q15 Data type.
513 */
514 static __INLINE uint32_t arm_recip_q15(
515 q15_t in,
516 q15_t * dst,
517 q15_t * pRecipTable)
518 {
519
520 uint32_t out = 0, tempVal = 0;
521 uint32_t index = 0, i = 0;
522 uint32_t signBits = 0;
523
524 if(in > 0)
525 {
526 signBits = __CLZ(in) - 17;
527 }
528 else
529 {
530 signBits = __CLZ(-in) - 17;
531 }
532
533 /* Convert input sample to 1.15 format */
534 in = in << signBits;
535
536 /* calculation of index for initial approximated Val */
537 index = in >> 8;
538 index = (index & INDEX_MASK);
539
540 /* 1.15 with exp 1 */
541 out = pRecipTable[index];
542
543 /* calculation of reciprocal value */
544 /* running approximation for two iterations */
545 for (i = 0; i < 2; i++)
546 {
547 tempVal = (q15_t) (((q31_t) in * out) >> 15);
548 tempVal = 0x7FFF - tempVal;
549 /* 1.15 with exp 1 */
550 out = (q15_t) (((q31_t) out * tempVal) >> 14);
551 }
552
553 /* write output */
554 *dst = out;
555
556 /* return num of signbits of out = 1/in value */
557 return (signBits + 1);
558
559 }
560
561
562 /*
563 * @brief C custom defined intrinisic function for only M0 processors
564 */
565 #if defined(ARM_MATH_CM0)
566
567 static __INLINE q31_t __SSAT(
568 q31_t x,
569 uint32_t y)
570 {
571 int32_t posMax, negMin;
572 uint32_t i;
573
574 posMax = 1;
575 for (i = 0; i < (y - 1); i++)
576 {
577 posMax = posMax * 2;
578 }
579
580 if(x > 0)
581 {
582 posMax = (posMax - 1);
583
584 if(x > posMax)
585 {
586 x = posMax;
587 }
588 }
589 else
590 {
591 negMin = -posMax;
592
593 if(x < negMin)
594 {
595 x = negMin;
596 }
597 }
598 return (x);
599
600
601 }
602
603 #endif /* end of ARM_MATH_CM0 */
604
605
606
607 /*
608 * @brief C custom defined intrinsic function for M3 and M0 processors
609 */
610 #if defined (ARM_MATH_CM3) || defined (ARM_MATH_CM0)
611
612 /*
613 * @brief C custom defined QADD8 for M3 and M0 processors
614 */
615 static __INLINE q31_t __QADD8(
616 q31_t x,
617 q31_t y)
618 {
619
620 q31_t sum;
621 q7_t r, s, t, u;
622
623 r = (char) x;
624 s = (char) y;
625
626 r = __SSAT((q31_t) (r + s), 8);
627 s = __SSAT(((q31_t) (((x << 16) >> 24) + ((y << 16) >> 24))), 8);
628 t = __SSAT(((q31_t) (((x << 8) >> 24) + ((y << 8) >> 24))), 8);
629 u = __SSAT(((q31_t) ((x >> 24) + (y >> 24))), 8);
630
631 sum = (((q31_t) u << 24) & 0xFF000000) | (((q31_t) t << 16) & 0x00FF0000) |
632 (((q31_t) s << 8) & 0x0000FF00) | (r & 0x000000FF);
633
634 return sum;
635
636 }
637
638 /*
639 * @brief C custom defined QSUB8 for M3 and M0 processors
640 */
641 static __INLINE q31_t __QSUB8(
642 q31_t x,
643 q31_t y)
644 {
645
646 q31_t sum;
647 q31_t r, s, t, u;
648
649 r = (char) x;
650 s = (char) y;
651
652 r = __SSAT((r - s), 8);
653 s = __SSAT(((q31_t) (((x << 16) >> 24) - ((y << 16) >> 24))), 8) << 8;
654 t = __SSAT(((q31_t) (((x << 8) >> 24) - ((y << 8) >> 24))), 8) << 16;
655 u = __SSAT(((q31_t) ((x >> 24) - (y >> 24))), 8) << 24;
656
657 sum =
658 (u & 0xFF000000) | (t & 0x00FF0000) | (s & 0x0000FF00) | (r & 0x000000FF);
659
660 return sum;
661 }
662
663 /*
664 * @brief C custom defined QADD16 for M3 and M0 processors
665 */
666
667 /*
668 * @brief C custom defined QADD16 for M3 and M0 processors
669 */
670 static __INLINE q31_t __QADD16(
671 q31_t x,
672 q31_t y)
673 {
674
675 q31_t sum;
676 q31_t r, s;
677
678 r = (short) x;
679 s = (short) y;
680
681 r = __SSAT(r + s, 16);
682 s = __SSAT(((q31_t) ((x >> 16) + (y >> 16))), 16) << 16;
683
684 sum = (s & 0xFFFF0000) | (r & 0x0000FFFF);
685
686 return sum;
687
688 }
689
690 /*
691 * @brief C custom defined SHADD16 for M3 and M0 processors
692 */
693 static __INLINE q31_t __SHADD16(
694 q31_t x,
695 q31_t y)
696 {
697
698 q31_t sum;
699 q31_t r, s;
700
701 r = (short) x;
702 s = (short) y;
703
704 r = ((r >> 1) + (s >> 1));
705 s = ((q31_t) ((x >> 17) + (y >> 17))) << 16;
706
707 sum = (s & 0xFFFF0000) | (r & 0x0000FFFF);
708
709 return sum;
710
711 }
712
713 /*
714 * @brief C custom defined QSUB16 for M3 and M0 processors
715 */
716 static __INLINE q31_t __QSUB16(
717 q31_t x,
718 q31_t y)
719 {
720
721 q31_t sum;
722 q31_t r, s;
723
724 r = (short) x;
725 s = (short) y;
726
727 r = __SSAT(r - s, 16);
728 s = __SSAT(((q31_t) ((x >> 16) - (y >> 16))), 16) << 16;
729
730 sum = (s & 0xFFFF0000) | (r & 0x0000FFFF);
731
732 return sum;
733 }
734
735 /*
736 * @brief C custom defined SHSUB16 for M3 and M0 processors
737 */
738 static __INLINE q31_t __SHSUB16(
739 q31_t x,
740 q31_t y)
741 {
742
743 q31_t diff;
744 q31_t r, s;
745
746 r = (short) x;
747 s = (short) y;
748
749 r = ((r >> 1) - (s >> 1));
750 s = (((x >> 17) - (y >> 17)) << 16);
751
752 diff = (s & 0xFFFF0000) | (r & 0x0000FFFF);
753
754 return diff;
755 }
756
757 /*
758 * @brief C custom defined QASX for M3 and M0 processors
759 */
760 static __INLINE q31_t __QASX(
761 q31_t x,
762 q31_t y)
763 {
764
765 q31_t sum = 0;
766
767 sum = ((sum + clip_q31_to_q15((q31_t) ((short) (x >> 16) + (short) y))) << 16) +
768 clip_q31_to_q15((q31_t) ((short) x - (short) (y >> 16)));
769
770 return sum;
771 }
772
773 /*
774 * @brief C custom defined SHASX for M3 and M0 processors
775 */
776 static __INLINE q31_t __SHASX(
777 q31_t x,
778 q31_t y)
779 {
780
781 q31_t sum;
782 q31_t r, s;
783
784 r = (short) x;
785 s = (short) y;
786
787 r = ((r >> 1) - (y >> 17));
788 s = (((x >> 17) + (s >> 1)) << 16);
789
790 sum = (s & 0xFFFF0000) | (r & 0x0000FFFF);
791
792 return sum;
793 }
794
795
796 /*
797 * @brief C custom defined QSAX for M3 and M0 processors
798 */
799 static __INLINE q31_t __QSAX(
800 q31_t x,
801 q31_t y)
802 {
803
804 q31_t sum = 0;
805
806 sum = ((sum + clip_q31_to_q15((q31_t) ((short) (x >> 16) - (short) y))) << 16) +
807 clip_q31_to_q15((q31_t) ((short) x + (short) (y >> 16)));
808
809 return sum;
810 }
811
812 /*
813 * @brief C custom defined SHSAX for M3 and M0 processors
814 */
815 static __INLINE q31_t __SHSAX(
816 q31_t x,
817 q31_t y)
818 {
819
820 q31_t sum;
821 q31_t r, s;
822
823 r = (short) x;
824 s = (short) y;
825
826 r = ((r >> 1) + (y >> 17));
827 s = (((x >> 17) - (s >> 1)) << 16);
828
829 sum = (s & 0xFFFF0000) | (r & 0x0000FFFF);
830
831 return sum;
832 }
833
834 /*
835 * @brief C custom defined SMUSDX for M3 and M0 processors
836 */
837 static __INLINE q31_t __SMUSDX(
838 q31_t x,
839 q31_t y)
840 {
841
842 return ((q31_t)(((short) x * (short) (y >> 16)) -
843 ((short) (x >> 16) * (short) y)));
844 }
845
846 /*
847 * @brief C custom defined SMUADX for M3 and M0 processors
848 */
849 static __INLINE q31_t __SMUADX(
850 q31_t x,
851 q31_t y)
852 {
853
854 return ((q31_t)(((short) x * (short) (y >> 16)) +
855 ((short) (x >> 16) * (short) y)));
856 }
857
858 /*
859 * @brief C custom defined QADD for M3 and M0 processors
860 */
861 static __INLINE q31_t __QADD(
862 q31_t x,
863 q31_t y)
864 {
865 return clip_q63_to_q31((q63_t) x + y);
866 }
867
868 /*
869 * @brief C custom defined QSUB for M3 and M0 processors
870 */
871 static __INLINE q31_t __QSUB(
872 q31_t x,
873 q31_t y)
874 {
875 return clip_q63_to_q31((q63_t) x - y);
876 }
877
878 /*
879 * @brief C custom defined SMLAD for M3 and M0 processors
880 */
881 static __INLINE q31_t __SMLAD(
882 q31_t x,
883 q31_t y,
884 q31_t sum)
885 {
886
887 return (sum + ((short) (x >> 16) * (short) (y >> 16)) +
888 ((short) x * (short) y));
889 }
890
891 /*
892 * @brief C custom defined SMLADX for M3 and M0 processors
893 */
894 static __INLINE q31_t __SMLADX(
895 q31_t x,
896 q31_t y,
897 q31_t sum)
898 {
899
900 return (sum + ((short) (x >> 16) * (short) (y)) +
901 ((short) x * (short) (y >> 16)));
902 }
903
904 /*
905 * @brief C custom defined SMLSDX for M3 and M0 processors
906 */
907 static __INLINE q31_t __SMLSDX(
908 q31_t x,
909 q31_t y,
910 q31_t sum)
911 {
912
913 return (sum - ((short) (x >> 16) * (short) (y)) +
914 ((short) x * (short) (y >> 16)));
915 }
916
917 /*
918 * @brief C custom defined SMLALD for M3 and M0 processors
919 */
920 static __INLINE q63_t __SMLALD(
921 q31_t x,
922 q31_t y,
923 q63_t sum)
924 {
925
926 return (sum + ((short) (x >> 16) * (short) (y >> 16)) +
927 ((short) x * (short) y));
928 }
929
930 /*
931 * @brief C custom defined SMLALDX for M3 and M0 processors
932 */
933 static __INLINE q63_t __SMLALDX(
934 q31_t x,
935 q31_t y,
936 q63_t sum)
937 {
938
939 return (sum + ((short) (x >> 16) * (short) y)) +
940 ((short) x * (short) (y >> 16));
941 }
942
943 /*
944 * @brief C custom defined SMUAD for M3 and M0 processors
945 */
946 static __INLINE q31_t __SMUAD(
947 q31_t x,
948 q31_t y)
949 {
950
951 return (((x >> 16) * (y >> 16)) +
952 (((x << 16) >> 16) * ((y << 16) >> 16)));
953 }
954
955 /*
956 * @brief C custom defined SMUSD for M3 and M0 processors
957 */
958 static __INLINE q31_t __SMUSD(
959 q31_t x,
960 q31_t y)
961 {
962
963 return (-((x >> 16) * (y >> 16)) +
964 (((x << 16) >> 16) * ((y << 16) >> 16)));
965 }
966
967
968
969
970 #endif /* (ARM_MATH_CM3) || defined (ARM_MATH_CM0) */
971
972
973 /**
974 * @brief Instance structure for the Q7 FIR filter.
975 */
976 typedef struct
977 {
978 uint16_t numTaps; /**< number of filter coefficients in the filter. */
979 q7_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
980 q7_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
981 } arm_fir_instance_q7;
982
983 /**
984 * @brief Instance structure for the Q15 FIR filter.
985 */
986 typedef struct
987 {
988 uint16_t numTaps; /**< number of filter coefficients in the filter. */
989 q15_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
990 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
991 } arm_fir_instance_q15;
992
993 /**
994 * @brief Instance structure for the Q31 FIR filter.
995 */
996 typedef struct
997 {
998 uint16_t numTaps; /**< number of filter coefficients in the filter. */
999 q31_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
1000 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
1001 } arm_fir_instance_q31;
1002
1003 /**
1004 * @brief Instance structure for the floating-point FIR filter.
1005 */
1006 typedef struct
1007 {
1008 uint16_t numTaps; /**< number of filter coefficients in the filter. */
1009 float32_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
1010 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
1011 } arm_fir_instance_f32;
1012
1013
1014 /**
1015 * @brief Processing function for the Q7 FIR filter.
1016 * @param[in] *S points to an instance of the Q7 FIR filter structure.
1017 * @param[in] *pSrc points to the block of input data.
1018 * @param[out] *pDst points to the block of output data.
1019 * @param[in] blockSize number of samples to process.
1020 * @return none.
1021 */
1022 void arm_fir_q7(
1023 const arm_fir_instance_q7 * S,
1024 q7_t * pSrc,
1025 q7_t * pDst,
1026 uint32_t blockSize);
1027
1028
1029 /**
1030 * @brief Initialization function for the Q7 FIR filter.
1031 * @param[in,out] *S points to an instance of the Q7 FIR structure.
1032 * @param[in] numTaps Number of filter coefficients in the filter.
1033 * @param[in] *pCoeffs points to the filter coefficients.
1034 * @param[in] *pState points to the state buffer.
1035 * @param[in] blockSize number of samples that are processed.
1036 * @return none
1037 */
1038 void arm_fir_init_q7(
1039 arm_fir_instance_q7 * S,
1040 uint16_t numTaps,
1041 q7_t * pCoeffs,
1042 q7_t * pState,
1043 uint32_t blockSize);
1044
1045
1046 /**
1047 * @brief Processing function for the Q15 FIR filter.
1048 * @param[in] *S points to an instance of the Q15 FIR structure.
1049 * @param[in] *pSrc points to the block of input data.
1050 * @param[out] *pDst points to the block of output data.
1051 * @param[in] blockSize number of samples to process.
1052 * @return none.
1053 */
1054 void arm_fir_q15(
1055 const arm_fir_instance_q15 * S,
1056 q15_t * pSrc,
1057 q15_t * pDst,
1058 uint32_t blockSize);
1059
1060 /**
1061 * @brief Processing function for the fast Q15 FIR filter for Cortex-M3 and Cortex-M4.
1062 * @param[in] *S points to an instance of the Q15 FIR filter structure.
1063 * @param[in] *pSrc points to the block of input data.
1064 * @param[out] *pDst points to the block of output data.
1065 * @param[in] blockSize number of samples to process.
1066 * @return none.
1067 */
1068 void arm_fir_fast_q15(
1069 const arm_fir_instance_q15 * S,
1070 q15_t * pSrc,
1071 q15_t * pDst,
1072 uint32_t blockSize);
1073
1074 /**
1075 * @brief Initialization function for the Q15 FIR filter.
1076 * @param[in,out] *S points to an instance of the Q15 FIR filter structure.
1077 * @param[in] numTaps Number of filter coefficients in the filter. Must be even and greater than or equal to 4.
1078 * @param[in] *pCoeffs points to the filter coefficients.
1079 * @param[in] *pState points to the state buffer.
1080 * @param[in] blockSize number of samples that are processed at a time.
1081 * @return The function returns ARM_MATH_SUCCESS if initialization was successful or ARM_MATH_ARGUMENT_ERROR if
1082 * <code>numTaps</code> is not a supported value.
1083 */
1084
1085 arm_status arm_fir_init_q15(
1086 arm_fir_instance_q15 * S,
1087 uint16_t numTaps,
1088 q15_t * pCoeffs,
1089 q15_t * pState,
1090 uint32_t blockSize);
1091
1092 /**
1093 * @brief Processing function for the Q31 FIR filter.
1094 * @param[in] *S points to an instance of the Q31 FIR filter structure.
1095 * @param[in] *pSrc points to the block of input data.
1096 * @param[out] *pDst points to the block of output data.
1097 * @param[in] blockSize number of samples to process.
1098 * @return none.
1099 */
1100 void arm_fir_q31(
1101 const arm_fir_instance_q31 * S,
1102 q31_t * pSrc,
1103 q31_t * pDst,
1104 uint32_t blockSize);
1105
1106 /**
1107 * @brief Processing function for the fast Q31 FIR filter for Cortex-M3 and Cortex-M4.
1108 * @param[in] *S points to an instance of the Q31 FIR structure.
1109 * @param[in] *pSrc points to the block of input data.
1110 * @param[out] *pDst points to the block of output data.
1111 * @param[in] blockSize number of samples to process.
1112 * @return none.
1113 */
1114 void arm_fir_fast_q31(
1115 const arm_fir_instance_q31 * S,
1116 q31_t * pSrc,
1117 q31_t * pDst,
1118 uint32_t blockSize);
1119
1120 /**
1121 * @brief Initialization function for the Q31 FIR filter.
1122 * @param[in,out] *S points to an instance of the Q31 FIR structure.
1123 * @param[in] numTaps Number of filter coefficients in the filter.
1124 * @param[in] *pCoeffs points to the filter coefficients.
1125 * @param[in] *pState points to the state buffer.
1126 * @param[in] blockSize number of samples that are processed at a time.
1127 * @return none.
1128 */
1129 void arm_fir_init_q31(
1130 arm_fir_instance_q31 * S,
1131 uint16_t numTaps,
1132 q31_t * pCoeffs,
1133 q31_t * pState,
1134 uint32_t blockSize);
1135
1136 /**
1137 * @brief Processing function for the floating-point FIR filter.
1138 * @param[in] *S points to an instance of the floating-point FIR structure.
1139 * @param[in] *pSrc points to the block of input data.
1140 * @param[out] *pDst points to the block of output data.
1141 * @param[in] blockSize number of samples to process.
1142 * @return none.
1143 */
1144 void arm_fir_f32(
1145 const arm_fir_instance_f32 * S,
1146 float32_t * pSrc,
1147 float32_t * pDst,
1148 uint32_t blockSize);
1149
1150 /**
1151 * @brief Initialization function for the floating-point FIR filter.
1152 * @param[in,out] *S points to an instance of the floating-point FIR filter structure.
1153 * @param[in] numTaps Number of filter coefficients in the filter.
1154 * @param[in] *pCoeffs points to the filter coefficients.
1155 * @param[in] *pState points to the state buffer.
1156 * @param[in] blockSize number of samples that are processed at a time.
1157 * @return none.
1158 */
1159 void arm_fir_init_f32(
1160 arm_fir_instance_f32 * S,
1161 uint16_t numTaps,
1162 float32_t * pCoeffs,
1163 float32_t * pState,
1164 uint32_t blockSize);
1165
1166
1167 /**
1168 * @brief Instance structure for the Q15 Biquad cascade filter.
1169 */
1170 typedef struct
1171 {
1172 int8_t numStages; /**< number of 2nd order stages in the filter. Overall order is 2*numStages. */
1173 q15_t *pState; /**< Points to the array of state coefficients. The array is of length 4*numStages. */
1174 q15_t *pCoeffs; /**< Points to the array of coefficients. The array is of length 5*numStages. */
1175 int8_t postShift; /**< Additional shift, in bits, applied to each output sample. */
1176
1177 } arm_biquad_casd_df1_inst_q15;
1178
1179
1180 /**
1181 * @brief Instance structure for the Q31 Biquad cascade filter.
1182 */
1183 typedef struct
1184 {
1185 uint32_t numStages; /**< number of 2nd order stages in the filter. Overall order is 2*numStages. */
1186 q31_t *pState; /**< Points to the array of state coefficients. The array is of length 4*numStages. */
1187 q31_t *pCoeffs; /**< Points to the array of coefficients. The array is of length 5*numStages. */
1188 uint8_t postShift; /**< Additional shift, in bits, applied to each output sample. */
1189
1190 } arm_biquad_casd_df1_inst_q31;
1191
1192 /**
1193 * @brief Instance structure for the floating-point Biquad cascade filter.
1194 */
1195 typedef struct
1196 {
1197 uint32_t numStages; /**< number of 2nd order stages in the filter. Overall order is 2*numStages. */
1198 float32_t *pState; /**< Points to the array of state coefficients. The array is of length 4*numStages. */
1199 float32_t *pCoeffs; /**< Points to the array of coefficients. The array is of length 5*numStages. */
1200
1201
1202 } arm_biquad_casd_df1_inst_f32;
1203
1204
1205
1206 /**
1207 * @brief Processing function for the Q15 Biquad cascade filter.
1208 * @param[in] *S points to an instance of the Q15 Biquad cascade structure.
1209 * @param[in] *pSrc points to the block of input data.
1210 * @param[out] *pDst points to the block of output data.
1211 * @param[in] blockSize number of samples to process.
1212 * @return none.
1213 */
1214
1215 void arm_biquad_cascade_df1_q15(
1216 const arm_biquad_casd_df1_inst_q15 * S,
1217 q15_t * pSrc,
1218 q15_t * pDst,
1219 uint32_t blockSize);
1220
1221 /**
1222 * @brief Initialization function for the Q15 Biquad cascade filter.
1223 * @param[in,out] *S points to an instance of the Q15 Biquad cascade structure.
1224 * @param[in] numStages number of 2nd order stages in the filter.
1225 * @param[in] *pCoeffs points to the filter coefficients.
1226 * @param[in] *pState points to the state buffer.
1227 * @param[in] postShift Shift to be applied to the output. Varies according to the coefficients format
1228 * @return none
1229 */
1230
1231 void arm_biquad_cascade_df1_init_q15(
1232 arm_biquad_casd_df1_inst_q15 * S,
1233 uint8_t numStages,
1234 q15_t * pCoeffs,
1235 q15_t * pState,
1236 int8_t postShift);
1237
1238
1239 /**
1240 * @brief Fast but less precise processing function for the Q15 Biquad cascade filter for Cortex-M3 and Cortex-M4.
1241 * @param[in] *S points to an instance of the Q15 Biquad cascade structure.
1242 * @param[in] *pSrc points to the block of input data.
1243 * @param[out] *pDst points to the block of output data.
1244 * @param[in] blockSize number of samples to process.
1245 * @return none.
1246 */
1247
1248 void arm_biquad_cascade_df1_fast_q15(
1249 const arm_biquad_casd_df1_inst_q15 * S,
1250 q15_t * pSrc,
1251 q15_t * pDst,
1252 uint32_t blockSize);
1253
1254
1255 /**
1256 * @brief Processing function for the Q31 Biquad cascade filter
1257 * @param[in] *S points to an instance of the Q31 Biquad cascade structure.
1258 * @param[in] *pSrc points to the block of input data.
1259 * @param[out] *pDst points to the block of output data.
1260 * @param[in] blockSize number of samples to process.
1261 * @return none.
1262 */
1263
1264 void arm_biquad_cascade_df1_q31(
1265 const arm_biquad_casd_df1_inst_q31 * S,
1266 q31_t * pSrc,
1267 q31_t * pDst,
1268 uint32_t blockSize);
1269
1270 /**
1271 * @brief Fast but less precise processing function for the Q31 Biquad cascade filter for Cortex-M3 and Cortex-M4.
1272 * @param[in] *S points to an instance of the Q31 Biquad cascade structure.
1273 * @param[in] *pSrc points to the block of input data.
1274 * @param[out] *pDst points to the block of output data.
1275 * @param[in] blockSize number of samples to process.
1276 * @return none.
1277 */
1278
1279 void arm_biquad_cascade_df1_fast_q31(
1280 const arm_biquad_casd_df1_inst_q31 * S,
1281 q31_t * pSrc,
1282 q31_t * pDst,
1283 uint32_t blockSize);
1284
1285 /**
1286 * @brief Initialization function for the Q31 Biquad cascade filter.
1287 * @param[in,out] *S points to an instance of the Q31 Biquad cascade structure.
1288 * @param[in] numStages number of 2nd order stages in the filter.
1289 * @param[in] *pCoeffs points to the filter coefficients.
1290 * @param[in] *pState points to the state buffer.
1291 * @param[in] postShift Shift to be applied to the output. Varies according to the coefficients format
1292 * @return none
1293 */
1294
1295 void arm_biquad_cascade_df1_init_q31(
1296 arm_biquad_casd_df1_inst_q31 * S,
1297 uint8_t numStages,
1298 q31_t * pCoeffs,
1299 q31_t * pState,
1300 int8_t postShift);
1301
1302 /**
1303 * @brief Processing function for the floating-point Biquad cascade filter.
1304 * @param[in] *S points to an instance of the floating-point Biquad cascade structure.
1305 * @param[in] *pSrc points to the block of input data.
1306 * @param[out] *pDst points to the block of output data.
1307 * @param[in] blockSize number of samples to process.
1308 * @return none.
1309 */
1310
1311 void arm_biquad_cascade_df1_f32(
1312 const arm_biquad_casd_df1_inst_f32 * S,
1313 float32_t * pSrc,
1314 float32_t * pDst,
1315 uint32_t blockSize);
1316
1317 /**
1318 * @brief Initialization function for the floating-point Biquad cascade filter.
1319 * @param[in,out] *S points to an instance of the floating-point Biquad cascade structure.
1320 * @param[in] numStages number of 2nd order stages in the filter.
1321 * @param[in] *pCoeffs points to the filter coefficients.
1322 * @param[in] *pState points to the state buffer.
1323 * @return none
1324 */
1325
1326 void arm_biquad_cascade_df1_init_f32(
1327 arm_biquad_casd_df1_inst_f32 * S,
1328 uint8_t numStages,
1329 float32_t * pCoeffs,
1330 float32_t * pState);
1331
1332
1333 /**
1334 * @brief Instance structure for the floating-point matrix structure.
1335 */
1336
1337 typedef struct
1338 {
1339 uint16_t numRows; /**< number of rows of the matrix. */
1340 uint16_t numCols; /**< number of columns of the matrix. */
1341 float32_t *pData; /**< points to the data of the matrix. */
1342 } arm_matrix_instance_f32;
1343
1344 /**
1345 * @brief Instance structure for the Q15 matrix structure.
1346 */
1347
1348 typedef struct
1349 {
1350 uint16_t numRows; /**< number of rows of the matrix. */
1351 uint16_t numCols; /**< number of columns of the matrix. */
1352 q15_t *pData; /**< points to the data of the matrix. */
1353
1354 } arm_matrix_instance_q15;
1355
1356 /**
1357 * @brief Instance structure for the Q31 matrix structure.
1358 */
1359
1360 typedef struct
1361 {
1362 uint16_t numRows; /**< number of rows of the matrix. */
1363 uint16_t numCols; /**< number of columns of the matrix. */
1364 q31_t *pData; /**< points to the data of the matrix. */
1365
1366 } arm_matrix_instance_q31;
1367
1368
1369
1370 /**
1371 * @brief Floating-point matrix addition.
1372 * @param[in] *pSrcA points to the first input matrix structure
1373 * @param[in] *pSrcB points to the second input matrix structure
1374 * @param[out] *pDst points to output matrix structure
1375 * @return The function returns either
1376 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1377 */
1378
1379 arm_status arm_mat_add_f32(
1380 const arm_matrix_instance_f32 * pSrcA,
1381 const arm_matrix_instance_f32 * pSrcB,
1382 arm_matrix_instance_f32 * pDst);
1383
1384 /**
1385 * @brief Q15 matrix addition.
1386 * @param[in] *pSrcA points to the first input matrix structure
1387 * @param[in] *pSrcB points to the second input matrix structure
1388 * @param[out] *pDst points to output matrix structure
1389 * @return The function returns either
1390 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1391 */
1392
1393 arm_status arm_mat_add_q15(
1394 const arm_matrix_instance_q15 * pSrcA,
1395 const arm_matrix_instance_q15 * pSrcB,
1396 arm_matrix_instance_q15 * pDst);
1397
1398 /**
1399 * @brief Q31 matrix addition.
1400 * @param[in] *pSrcA points to the first input matrix structure
1401 * @param[in] *pSrcB points to the second input matrix structure
1402 * @param[out] *pDst points to output matrix structure
1403 * @return The function returns either
1404 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1405 */
1406
1407 arm_status arm_mat_add_q31(
1408 const arm_matrix_instance_q31 * pSrcA,
1409 const arm_matrix_instance_q31 * pSrcB,
1410 arm_matrix_instance_q31 * pDst);
1411
1412
1413 /**
1414 * @brief Floating-point matrix transpose.
1415 * @param[in] *pSrc points to the input matrix
1416 * @param[out] *pDst points to the output matrix
1417 * @return The function returns either <code>ARM_MATH_SIZE_MISMATCH</code>
1418 * or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1419 */
1420
1421 arm_status arm_mat_trans_f32(
1422 const arm_matrix_instance_f32 * pSrc,
1423 arm_matrix_instance_f32 * pDst);
1424
1425
1426 /**
1427 * @brief Q15 matrix transpose.
1428 * @param[in] *pSrc points to the input matrix
1429 * @param[out] *pDst points to the output matrix
1430 * @return The function returns either <code>ARM_MATH_SIZE_MISMATCH</code>
1431 * or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1432 */
1433
1434 arm_status arm_mat_trans_q15(
1435 const arm_matrix_instance_q15 * pSrc,
1436 arm_matrix_instance_q15 * pDst);
1437
1438 /**
1439 * @brief Q31 matrix transpose.
1440 * @param[in] *pSrc points to the input matrix
1441 * @param[out] *pDst points to the output matrix
1442 * @return The function returns either <code>ARM_MATH_SIZE_MISMATCH</code>
1443 * or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1444 */
1445
1446 arm_status arm_mat_trans_q31(
1447 const arm_matrix_instance_q31 * pSrc,
1448 arm_matrix_instance_q31 * pDst);
1449
1450
1451 /**
1452 * @brief Floating-point matrix multiplication
1453 * @param[in] *pSrcA points to the first input matrix structure
1454 * @param[in] *pSrcB points to the second input matrix structure
1455 * @param[out] *pDst points to output matrix structure
1456 * @return The function returns either
1457 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1458 */
1459
1460 arm_status arm_mat_mult_f32(
1461 const arm_matrix_instance_f32 * pSrcA,
1462 const arm_matrix_instance_f32 * pSrcB,
1463 arm_matrix_instance_f32 * pDst);
1464
1465 /**
1466 * @brief Q15 matrix multiplication
1467 * @param[in] *pSrcA points to the first input matrix structure
1468 * @param[in] *pSrcB points to the second input matrix structure
1469 * @param[out] *pDst points to output matrix structure
1470 * @return The function returns either
1471 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1472 */
1473
1474 arm_status arm_mat_mult_q15(
1475 const arm_matrix_instance_q15 * pSrcA,
1476 const arm_matrix_instance_q15 * pSrcB,
1477 arm_matrix_instance_q15 * pDst,
1478 q15_t * pState);
1479
1480 /**
1481 * @brief Q15 matrix multiplication (fast variant) for Cortex-M3 and Cortex-M4
1482 * @param[in] *pSrcA points to the first input matrix structure
1483 * @param[in] *pSrcB points to the second input matrix structure
1484 * @param[out] *pDst points to output matrix structure
1485 * @param[in] *pState points to the array for storing intermediate results
1486 * @return The function returns either
1487 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1488 */
1489
1490 arm_status arm_mat_mult_fast_q15(
1491 const arm_matrix_instance_q15 * pSrcA,
1492 const arm_matrix_instance_q15 * pSrcB,
1493 arm_matrix_instance_q15 * pDst,
1494 q15_t * pState);
1495
1496 /**
1497 * @brief Q31 matrix multiplication
1498 * @param[in] *pSrcA points to the first input matrix structure
1499 * @param[in] *pSrcB points to the second input matrix structure
1500 * @param[out] *pDst points to output matrix structure
1501 * @return The function returns either
1502 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1503 */
1504
1505 arm_status arm_mat_mult_q31(
1506 const arm_matrix_instance_q31 * pSrcA,
1507 const arm_matrix_instance_q31 * pSrcB,
1508 arm_matrix_instance_q31 * pDst);
1509
1510 /**
1511 * @brief Q31 matrix multiplication (fast variant) for Cortex-M3 and Cortex-M4
1512 * @param[in] *pSrcA points to the first input matrix structure
1513 * @param[in] *pSrcB points to the second input matrix structure
1514 * @param[out] *pDst points to output matrix structure
1515 * @return The function returns either
1516 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1517 */
1518
1519 arm_status arm_mat_mult_fast_q31(
1520 const arm_matrix_instance_q31 * pSrcA,
1521 const arm_matrix_instance_q31 * pSrcB,
1522 arm_matrix_instance_q31 * pDst);
1523
1524
1525 /**
1526 * @brief Floating-point matrix subtraction
1527 * @param[in] *pSrcA points to the first input matrix structure
1528 * @param[in] *pSrcB points to the second input matrix structure
1529 * @param[out] *pDst points to output matrix structure
1530 * @return The function returns either
1531 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1532 */
1533
1534 arm_status arm_mat_sub_f32(
1535 const arm_matrix_instance_f32 * pSrcA,
1536 const arm_matrix_instance_f32 * pSrcB,
1537 arm_matrix_instance_f32 * pDst);
1538
1539 /**
1540 * @brief Q15 matrix subtraction
1541 * @param[in] *pSrcA points to the first input matrix structure
1542 * @param[in] *pSrcB points to the second input matrix structure
1543 * @param[out] *pDst points to output matrix structure
1544 * @return The function returns either
1545 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1546 */
1547
1548 arm_status arm_mat_sub_q15(
1549 const arm_matrix_instance_q15 * pSrcA,
1550 const arm_matrix_instance_q15 * pSrcB,
1551 arm_matrix_instance_q15 * pDst);
1552
1553 /**
1554 * @brief Q31 matrix subtraction
1555 * @param[in] *pSrcA points to the first input matrix structure
1556 * @param[in] *pSrcB points to the second input matrix structure
1557 * @param[out] *pDst points to output matrix structure
1558 * @return The function returns either
1559 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1560 */
1561
1562 arm_status arm_mat_sub_q31(
1563 const arm_matrix_instance_q31 * pSrcA,
1564 const arm_matrix_instance_q31 * pSrcB,
1565 arm_matrix_instance_q31 * pDst);
1566
1567 /**
1568 * @brief Floating-point matrix scaling.
1569 * @param[in] *pSrc points to the input matrix
1570 * @param[in] scale scale factor
1571 * @param[out] *pDst points to the output matrix
1572 * @return The function returns either
1573 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1574 */
1575
1576 arm_status arm_mat_scale_f32(
1577 const arm_matrix_instance_f32 * pSrc,
1578 float32_t scale,
1579 arm_matrix_instance_f32 * pDst);
1580
1581 /**
1582 * @brief Q15 matrix scaling.
1583 * @param[in] *pSrc points to input matrix
1584 * @param[in] scaleFract fractional portion of the scale factor
1585 * @param[in] shift number of bits to shift the result by
1586 * @param[out] *pDst points to output matrix
1587 * @return The function returns either
1588 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1589 */
1590
1591 arm_status arm_mat_scale_q15(
1592 const arm_matrix_instance_q15 * pSrc,
1593 q15_t scaleFract,
1594 int32_t shift,
1595 arm_matrix_instance_q15 * pDst);
1596
1597 /**
1598 * @brief Q31 matrix scaling.
1599 * @param[in] *pSrc points to input matrix
1600 * @param[in] scaleFract fractional portion of the scale factor
1601 * @param[in] shift number of bits to shift the result by
1602 * @param[out] *pDst points to output matrix structure
1603 * @return The function returns either
1604 * <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
1605 */
1606
1607 arm_status arm_mat_scale_q31(
1608 const arm_matrix_instance_q31 * pSrc,
1609 q31_t scaleFract,
1610 int32_t shift,
1611 arm_matrix_instance_q31 * pDst);
1612
1613
1614 /**
1615 * @brief Q31 matrix initialization.
1616 * @param[in,out] *S points to an instance of the floating-point matrix structure.
1617 * @param[in] nRows number of rows in the matrix.
1618 * @param[in] nColumns number of columns in the matrix.
1619 * @param[in] *pData points to the matrix data array.
1620 * @return none
1621 */
1622
1623 void arm_mat_init_q31(
1624 arm_matrix_instance_q31 * S,
1625 uint16_t nRows,
1626 uint16_t nColumns,
1627 q31_t *pData);
1628
1629 /**
1630 * @brief Q15 matrix initialization.
1631 * @param[in,out] *S points to an instance of the floating-point matrix structure.
1632 * @param[in] nRows number of rows in the matrix.
1633 * @param[in] nColumns number of columns in the matrix.
1634 * @param[in] *pData points to the matrix data array.
1635 * @return none
1636 */
1637
1638 void arm_mat_init_q15(
1639 arm_matrix_instance_q15 * S,
1640 uint16_t nRows,
1641 uint16_t nColumns,
1642 q15_t *pData);
1643
1644 /**
1645 * @brief Floating-point matrix initialization.
1646 * @param[in,out] *S points to an instance of the floating-point matrix structure.
1647 * @param[in] nRows number of rows in the matrix.
1648 * @param[in] nColumns number of columns in the matrix.
1649 * @param[in] *pData points to the matrix data array.
1650 * @return none
1651 */
1652
1653 void arm_mat_init_f32(
1654 arm_matrix_instance_f32 * S,
1655 uint16_t nRows,
1656 uint16_t nColumns,
1657 float32_t *pData);
1658
1659
1660
1661 /**
1662 * @brief Instance structure for the Q15 PID Control.
1663 */
1664 typedef struct
1665 {
1666 q15_t A0; /**< The derived gain, A0 = Kp + Ki + Kd . */
1667 #ifdef ARM_MATH_CM0
1668 q15_t A1;
1669 q15_t A2;
1670 #else
1671 q31_t A1; /**< The derived gain A1 = -Kp - 2Kd | Kd.*/
1672 #endif
1673 q15_t state[3]; /**< The state array of length 3. */
1674 q15_t Kp; /**< The proportional gain. */
1675 q15_t Ki; /**< The integral gain. */
1676 q15_t Kd; /**< The derivative gain. */
1677 } arm_pid_instance_q15;
1678
1679 /**
1680 * @brief Instance structure for the Q31 PID Control.
1681 */
1682 typedef struct
1683 {
1684 q31_t A0; /**< The derived gain, A0 = Kp + Ki + Kd . */
1685 q31_t A1; /**< The derived gain, A1 = -Kp - 2Kd. */
1686 q31_t A2; /**< The derived gain, A2 = Kd . */
1687 q31_t state[3]; /**< The state array of length 3. */
1688 q31_t Kp; /**< The proportional gain. */
1689 q31_t Ki; /**< The integral gain. */
1690 q31_t Kd; /**< The derivative gain. */
1691
1692 } arm_pid_instance_q31;
1693
1694 /**
1695 * @brief Instance structure for the floating-point PID Control.
1696 */
1697 typedef struct
1698 {
1699 float32_t A0; /**< The derived gain, A0 = Kp + Ki + Kd . */
1700 float32_t A1; /**< The derived gain, A1 = -Kp - 2Kd. */
1701 float32_t A2; /**< The derived gain, A2 = Kd . */
1702 float32_t state[3]; /**< The state array of length 3. */
1703 float32_t Kp; /**< The proportional gain. */
1704 float32_t Ki; /**< The integral gain. */
1705 float32_t Kd; /**< The derivative gain. */
1706 } arm_pid_instance_f32;
1707
1708
1709
1710 /**
1711 * @brief Initialization function for the floating-point PID Control.
1712 * @param[in,out] *S points to an instance of the PID structure.
1713 * @param[in] resetStateFlag flag to reset the state. 0 = no change in state 1 = reset the state.
1714 * @return none.
1715 */
1716 void arm_pid_init_f32(
1717 arm_pid_instance_f32 * S,
1718 int32_t resetStateFlag);
1719
1720 /**
1721 * @brief Reset function for the floating-point PID Control.
1722 * @param[in,out] *S is an instance of the floating-point PID Control structure
1723 * @return none
1724 */
1725 void arm_pid_reset_f32(
1726 arm_pid_instance_f32 * S);
1727
1728
1729 /**
1730 * @brief Initialization function for the Q31 PID Control.
1731 * @param[in,out] *S points to an instance of the Q15 PID structure.
1732 * @param[in] resetStateFlag flag to reset the state. 0 = no change in state 1 = reset the state.
1733 * @return none.
1734 */
1735 void arm_pid_init_q31(
1736 arm_pid_instance_q31 * S,
1737 int32_t resetStateFlag);
1738
1739
1740 /**
1741 * @brief Reset function for the Q31 PID Control.
1742 * @param[in,out] *S points to an instance of the Q31 PID Control structure
1743 * @return none
1744 */
1745
1746 void arm_pid_reset_q31(
1747 arm_pid_instance_q31 * S);
1748
1749 /**
1750 * @brief Initialization function for the Q15 PID Control.
1751 * @param[in,out] *S points to an instance of the Q15 PID structure.
1752 * @param[in] resetStateFlag flag to reset the state. 0 = no change in state 1 = reset the state.
1753 * @return none.
1754 */
1755 void arm_pid_init_q15(
1756 arm_pid_instance_q15 * S,
1757 int32_t resetStateFlag);
1758
1759 /**
1760 * @brief Reset function for the Q15 PID Control.
1761 * @param[in,out] *S points to an instance of the q15 PID Control structure
1762 * @return none
1763 */
1764 void arm_pid_reset_q15(
1765 arm_pid_instance_q15 * S);
1766
1767
1768 /**
1769 * @brief Instance structure for the floating-point Linear Interpolate function.
1770 */
1771 typedef struct
1772 {
1773 uint32_t nValues;
1774 float32_t x1;
1775 float32_t xSpacing;
1776 float32_t *pYData; /**< pointer to the table of Y values */
1777 } arm_linear_interp_instance_f32;
1778
1779 /**
1780 * @brief Instance structure for the floating-point bilinear interpolation function.
1781 */
1782
1783 typedef struct
1784 {
1785 uint16_t numRows; /**< number of rows in the data table. */
1786 uint16_t numCols; /**< number of columns in the data table. */
1787 float32_t *pData; /**< points to the data table. */
1788 } arm_bilinear_interp_instance_f32;
1789
1790 /**
1791 * @brief Instance structure for the Q31 bilinear interpolation function.
1792 */
1793
1794 typedef struct
1795 {
1796 uint16_t numRows; /**< number of rows in the data table. */
1797 uint16_t numCols; /**< number of columns in the data table. */
1798 q31_t *pData; /**< points to the data table. */
1799 } arm_bilinear_interp_instance_q31;
1800
1801 /**
1802 * @brief Instance structure for the Q15 bilinear interpolation function.
1803 */
1804
1805 typedef struct
1806 {
1807 uint16_t numRows; /**< number of rows in the data table. */
1808 uint16_t numCols; /**< number of columns in the data table. */
1809 q15_t *pData; /**< points to the data table. */
1810 } arm_bilinear_interp_instance_q15;
1811
1812 /**
1813 * @brief Instance structure for the Q15 bilinear interpolation function.
1814 */
1815
1816 typedef struct
1817 {
1818 uint16_t numRows; /**< number of rows in the data table. */
1819 uint16_t numCols; /**< number of columns in the data table. */
1820 q7_t *pData; /**< points to the data table. */
1821 } arm_bilinear_interp_instance_q7;
1822
1823
1824 /**
1825 * @brief Q7 vector multiplication.
1826 * @param[in] *pSrcA points to the first input vector
1827 * @param[in] *pSrcB points to the second input vector
1828 * @param[out] *pDst points to the output vector
1829 * @param[in] blockSize number of samples in each vector
1830 * @return none.
1831 */
1832
1833 void arm_mult_q7(
1834 q7_t * pSrcA,
1835 q7_t * pSrcB,
1836 q7_t * pDst,
1837 uint32_t blockSize);
1838
1839 /**
1840 * @brief Q15 vector multiplication.
1841 * @param[in] *pSrcA points to the first input vector
1842 * @param[in] *pSrcB points to the second input vector
1843 * @param[out] *pDst points to the output vector
1844 * @param[in] blockSize number of samples in each vector
1845 * @return none.
1846 */
1847
1848 void arm_mult_q15(
1849 q15_t * pSrcA,
1850 q15_t * pSrcB,
1851 q15_t * pDst,
1852 uint32_t blockSize);
1853
1854 /**
1855 * @brief Q31 vector multiplication.
1856 * @param[in] *pSrcA points to the first input vector
1857 * @param[in] *pSrcB points to the second input vector
1858 * @param[out] *pDst points to the output vector
1859 * @param[in] blockSize number of samples in each vector
1860 * @return none.
1861 */
1862
1863 void arm_mult_q31(
1864 q31_t * pSrcA,
1865 q31_t * pSrcB,
1866 q31_t * pDst,
1867 uint32_t blockSize);
1868
1869 /**
1870 * @brief Floating-point vector multiplication.
1871 * @param[in] *pSrcA points to the first input vector
1872 * @param[in] *pSrcB points to the second input vector
1873 * @param[out] *pDst points to the output vector
1874 * @param[in] blockSize number of samples in each vector
1875 * @return none.
1876 */
1877
1878 void arm_mult_f32(
1879 float32_t * pSrcA,
1880 float32_t * pSrcB,
1881 float32_t * pDst,
1882 uint32_t blockSize);
1883
1884
1885 /**
1886 * @brief Instance structure for the Q15 CFFT/CIFFT function.
1887 */
1888
1889 typedef struct
1890 {
1891 uint16_t fftLen; /**< length of the FFT. */
1892 uint8_t ifftFlag; /**< flag that selects forward (ifftFlag=0) or inverse (ifftFlag=1) transform. */
1893 uint8_t bitReverseFlag; /**< flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output. */
1894 q15_t *pTwiddle; /**< points to the twiddle factor table. */
1895 uint16_t *pBitRevTable; /**< points to the bit reversal table. */
1896 uint16_t twidCoefModifier; /**< twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table. */
1897 uint16_t bitRevFactor; /**< bit reversal modifier that supports different size FFTs with the same bit reversal table. */
1898 } arm_cfft_radix4_instance_q15;
1899
1900 /**
1901 * @brief Instance structure for the Q31 CFFT/CIFFT function.
1902 */
1903
1904 typedef struct
1905 {
1906 uint16_t fftLen; /**< length of the FFT. */
1907 uint8_t ifftFlag; /**< flag that selects forward (ifftFlag=0) or inverse (ifftFlag=1) transform. */
1908 uint8_t bitReverseFlag; /**< flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output. */
1909 q31_t *pTwiddle; /**< points to the twiddle factor table. */
1910 uint16_t *pBitRevTable; /**< points to the bit reversal table. */
1911 uint16_t twidCoefModifier; /**< twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table. */
1912 uint16_t bitRevFactor; /**< bit reversal modifier that supports different size FFTs with the same bit reversal table. */
1913 } arm_cfft_radix4_instance_q31;
1914
1915 /**
1916 * @brief Instance structure for the floating-point CFFT/CIFFT function.
1917 */
1918
1919 typedef struct
1920 {
1921 uint16_t fftLen; /**< length of the FFT. */
1922 uint8_t ifftFlag; /**< flag that selects forward (ifftFlag=0) or inverse (ifftFlag=1) transform. */
1923 uint8_t bitReverseFlag; /**< flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output. */
1924 float32_t *pTwiddle; /**< points to the twiddle factor table. */
1925 uint16_t *pBitRevTable; /**< points to the bit reversal table. */
1926 uint16_t twidCoefModifier; /**< twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table. */
1927 uint16_t bitRevFactor; /**< bit reversal modifier that supports different size FFTs with the same bit reversal table. */
1928 float32_t onebyfftLen; /**< value of 1/fftLen. */
1929 } arm_cfft_radix4_instance_f32;
1930
1931 /**
1932 * @brief Processing function for the Q15 CFFT/CIFFT.
1933 * @param[in] *S points to an instance of the Q15 CFFT/CIFFT structure.
1934 * @param[in, out] *pSrc points to the complex data buffer. Processing occurs in-place.
1935 * @return none.
1936 */
1937
1938 void arm_cfft_radix4_q15(
1939 const arm_cfft_radix4_instance_q15 * S,
1940 q15_t * pSrc);
1941
1942 /**
1943 * @brief Initialization function for the Q15 CFFT/CIFFT.
1944 * @param[in,out] *S points to an instance of the Q15 CFFT/CIFFT structure.
1945 * @param[in] fftLen length of the FFT.
1946 * @param[in] ifftFlag flag that selects forward (ifftFlag=0) or inverse (ifftFlag=1) transform.
1947 * @param[in] bitReverseFlag flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output.
1948 * @return arm_status function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLen</code> is not a supported value.
1949 */
1950
1951 arm_status arm_cfft_radix4_init_q15(
1952 arm_cfft_radix4_instance_q15 * S,
1953 uint16_t fftLen,
1954 uint8_t ifftFlag,
1955 uint8_t bitReverseFlag);
1956
1957 /**
1958 * @brief Processing function for the Q31 CFFT/CIFFT.
1959 * @param[in] *S points to an instance of the Q31 CFFT/CIFFT structure.
1960 * @param[in, out] *pSrc points to the complex data buffer. Processing occurs in-place.
1961 * @return none.
1962 */
1963
1964 void arm_cfft_radix4_q31(
1965 const arm_cfft_radix4_instance_q31 * S,
1966 q31_t * pSrc);
1967
1968 /**
1969 * @brief Initialization function for the Q31 CFFT/CIFFT.
1970 * @param[in,out] *S points to an instance of the Q31 CFFT/CIFFT structure.
1971 * @param[in] fftLen length of the FFT.
1972 * @param[in] ifftFlag flag that selects forward (ifftFlag=0) or inverse (ifftFlag=1) transform.
1973 * @param[in] bitReverseFlag flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output.
1974 * @return arm_status function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLen</code> is not a supported value.
1975 */
1976
1977 arm_status arm_cfft_radix4_init_q31(
1978 arm_cfft_radix4_instance_q31 * S,
1979 uint16_t fftLen,
1980 uint8_t ifftFlag,
1981 uint8_t bitReverseFlag);
1982
1983 /**
1984 * @brief Processing function for the floating-point CFFT/CIFFT.
1985 * @param[in] *S points to an instance of the floating-point CFFT/CIFFT structure.
1986 * @param[in, out] *pSrc points to the complex data buffer. Processing occurs in-place.
1987 * @return none.
1988 */
1989
1990 void arm_cfft_radix4_f32(
1991 const arm_cfft_radix4_instance_f32 * S,
1992 float32_t * pSrc);
1993
1994 /**
1995 * @brief Initialization function for the floating-point CFFT/CIFFT.
1996 * @param[in,out] *S points to an instance of the floating-point CFFT/CIFFT structure.
1997 * @param[in] fftLen length of the FFT.
1998 * @param[in] ifftFlag flag that selects forward (ifftFlag=0) or inverse (ifftFlag=1) transform.
1999 * @param[in] bitReverseFlag flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output.
2000 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLen</code> is not a supported value.
2001 */
2002
2003 arm_status arm_cfft_radix4_init_f32(
2004 arm_cfft_radix4_instance_f32 * S,
2005 uint16_t fftLen,
2006 uint8_t ifftFlag,
2007 uint8_t bitReverseFlag);
2008
2009
2010
2011 /*----------------------------------------------------------------------
2012 * Internal functions prototypes FFT function
2013 ----------------------------------------------------------------------*/
2014
2015 /**
2016 * @brief Core function for the floating-point CFFT butterfly process.
2017 * @param[in, out] *pSrc points to the in-place buffer of floating-point data type.
2018 * @param[in] fftLen length of the FFT.
2019 * @param[in] *pCoef points to the twiddle coefficient buffer.
2020 * @param[in] twidCoefModifier twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table.
2021 * @return none.
2022 */
2023
2024 void arm_radix4_butterfly_f32(
2025 float32_t * pSrc,
2026 uint16_t fftLen,
2027 float32_t * pCoef,
2028 uint16_t twidCoefModifier);
2029
2030 /**
2031 * @brief Core function for the floating-point CIFFT butterfly process.
2032 * @param[in, out] *pSrc points to the in-place buffer of floating-point data type.
2033 * @param[in] fftLen length of the FFT.
2034 * @param[in] *pCoef points to twiddle coefficient buffer.
2035 * @param[in] twidCoefModifier twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table.
2036 * @param[in] onebyfftLen value of 1/fftLen.
2037 * @return none.
2038 */
2039
2040 void arm_radix4_butterfly_inverse_f32(
2041 float32_t * pSrc,
2042 uint16_t fftLen,
2043 float32_t * pCoef,
2044 uint16_t twidCoefModifier,
2045 float32_t onebyfftLen);
2046
2047 /**
2048 * @brief In-place bit reversal function.
2049 * @param[in, out] *pSrc points to the in-place buffer of floating-point data type.
2050 * @param[in] fftSize length of the FFT.
2051 * @param[in] bitRevFactor bit reversal modifier that supports different size FFTs with the same bit reversal table.
2052 * @param[in] *pBitRevTab points to the bit reversal table.
2053 * @return none.
2054 */
2055
2056 void arm_bitreversal_f32(
2057 float32_t *pSrc,
2058 uint16_t fftSize,
2059 uint16_t bitRevFactor,
2060 uint16_t *pBitRevTab);
2061
2062 /**
2063 * @brief Core function for the Q31 CFFT butterfly process.
2064 * @param[in, out] *pSrc points to the in-place buffer of Q31 data type.
2065 * @param[in] fftLen length of the FFT.
2066 * @param[in] *pCoef points to twiddle coefficient buffer.
2067 * @param[in] twidCoefModifier twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table.
2068 * @return none.
2069 */
2070
2071 void arm_radix4_butterfly_q31(
2072 q31_t *pSrc,
2073 uint32_t fftLen,
2074 q31_t *pCoef,
2075 uint32_t twidCoefModifier);
2076
2077 /**
2078 * @brief Core function for the Q31 CIFFT butterfly process.
2079 * @param[in, out] *pSrc points to the in-place buffer of Q31 data type.
2080 * @param[in] fftLen length of the FFT.
2081 * @param[in] *pCoef points to twiddle coefficient buffer.
2082 * @param[in] twidCoefModifier twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table.
2083 * @return none.
2084 */
2085
2086 void arm_radix4_butterfly_inverse_q31(
2087 q31_t * pSrc,
2088 uint32_t fftLen,
2089 q31_t * pCoef,
2090 uint32_t twidCoefModifier);
2091
2092 /**
2093 * @brief In-place bit reversal function.
2094 * @param[in, out] *pSrc points to the in-place buffer of Q31 data type.
2095 * @param[in] fftLen length of the FFT.
2096 * @param[in] bitRevFactor bit reversal modifier that supports different size FFTs with the same bit reversal table
2097 * @param[in] *pBitRevTab points to bit reversal table.
2098 * @return none.
2099 */
2100
2101 void arm_bitreversal_q31(
2102 q31_t * pSrc,
2103 uint32_t fftLen,
2104 uint16_t bitRevFactor,
2105 uint16_t *pBitRevTab);
2106
2107 /**
2108 * @brief Core function for the Q15 CFFT butterfly process.
2109 * @param[in, out] *pSrc16 points to the in-place buffer of Q15 data type.
2110 * @param[in] fftLen length of the FFT.
2111 * @param[in] *pCoef16 points to twiddle coefficient buffer.
2112 * @param[in] twidCoefModifier twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table.
2113 * @return none.
2114 */
2115
2116 void arm_radix4_butterfly_q15(
2117 q15_t *pSrc16,
2118 uint32_t fftLen,
2119 q15_t *pCoef16,
2120 uint32_t twidCoefModifier);
2121
2122 /**
2123 * @brief Core function for the Q15 CIFFT butterfly process.
2124 * @param[in, out] *pSrc16 points to the in-place buffer of Q15 data type.
2125 * @param[in] fftLen length of the FFT.
2126 * @param[in] *pCoef16 points to twiddle coefficient buffer.
2127 * @param[in] twidCoefModifier twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table.
2128 * @return none.
2129 */
2130
2131 void arm_radix4_butterfly_inverse_q15(
2132 q15_t *pSrc16,
2133 uint32_t fftLen,
2134 q15_t *pCoef16,
2135 uint32_t twidCoefModifier);
2136
2137 /**
2138 * @brief In-place bit reversal function.
2139 * @param[in, out] *pSrc points to the in-place buffer of Q15 data type.
2140 * @param[in] fftLen length of the FFT.
2141 * @param[in] bitRevFactor bit reversal modifier that supports different size FFTs with the same bit reversal table
2142 * @param[in] *pBitRevTab points to bit reversal table.
2143 * @return none.
2144 */
2145
2146 void arm_bitreversal_q15(
2147 q15_t * pSrc,
2148 uint32_t fftLen,
2149 uint16_t bitRevFactor,
2150 uint16_t *pBitRevTab);
2151
2152 /**
2153 * @brief Instance structure for the Q15 RFFT/RIFFT function.
2154 */
2155
2156 typedef struct
2157 {
2158 uint32_t fftLenReal; /**< length of the real FFT. */
2159 uint32_t fftLenBy2; /**< length of the complex FFT. */
2160 uint8_t ifftFlagR; /**< flag that selects forward (ifftFlagR=0) or inverse (ifftFlagR=1) transform. */
2161 uint8_t bitReverseFlagR; /**< flag that enables (bitReverseFlagR=1) or disables (bitReverseFlagR=0) bit reversal of output. */
2162 uint32_t twidCoefRModifier; /**< twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table. */
2163 q15_t *pTwiddleAReal; /**< points to the real twiddle factor table. */
2164 q15_t *pTwiddleBReal; /**< points to the imag twiddle factor table. */
2165 arm_cfft_radix4_instance_q15 *pCfft; /**< points to the complex FFT instance. */
2166 } arm_rfft_instance_q15;
2167
2168 /**
2169 * @brief Instance structure for the Q31 RFFT/RIFFT function.
2170 */
2171
2172 typedef struct
2173 {
2174 uint32_t fftLenReal; /**< length of the real FFT. */
2175 uint32_t fftLenBy2; /**< length of the complex FFT. */
2176 uint8_t ifftFlagR; /**< flag that selects forward (ifftFlagR=0) or inverse (ifftFlagR=1) transform. */
2177 uint8_t bitReverseFlagR; /**< flag that enables (bitReverseFlagR=1) or disables (bitReverseFlagR=0) bit reversal of output. */
2178 uint32_t twidCoefRModifier; /**< twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table. */
2179 q31_t *pTwiddleAReal; /**< points to the real twiddle factor table. */
2180 q31_t *pTwiddleBReal; /**< points to the imag twiddle factor table. */
2181 arm_cfft_radix4_instance_q31 *pCfft; /**< points to the complex FFT instance. */
2182 } arm_rfft_instance_q31;
2183
2184 /**
2185 * @brief Instance structure for the floating-point RFFT/RIFFT function.
2186 */
2187
2188 typedef struct
2189 {
2190 uint32_t fftLenReal; /**< length of the real FFT. */
2191 uint16_t fftLenBy2; /**< length of the complex FFT. */
2192 uint8_t ifftFlagR; /**< flag that selects forward (ifftFlagR=0) or inverse (ifftFlagR=1) transform. */
2193 uint8_t bitReverseFlagR; /**< flag that enables (bitReverseFlagR=1) or disables (bitReverseFlagR=0) bit reversal of output. */
2194 uint32_t twidCoefRModifier; /**< twiddle coefficient modifier that supports different size FFTs with the same twiddle factor table. */
2195 float32_t *pTwiddleAReal; /**< points to the real twiddle factor table. */
2196 float32_t *pTwiddleBReal; /**< points to the imag twiddle factor table. */
2197 arm_cfft_radix4_instance_f32 *pCfft; /**< points to the complex FFT instance. */
2198 } arm_rfft_instance_f32;
2199
2200 /**
2201 * @brief Processing function for the Q15 RFFT/RIFFT.
2202 * @param[in] *S points to an instance of the Q15 RFFT/RIFFT structure.
2203 * @param[in] *pSrc points to the input buffer.
2204 * @param[out] *pDst points to the output buffer.
2205 * @return none.
2206 */
2207
2208 void arm_rfft_q15(
2209 const arm_rfft_instance_q15 * S,
2210 q15_t * pSrc,
2211 q15_t * pDst);
2212
2213 /**
2214 * @brief Initialization function for the Q15 RFFT/RIFFT.
2215 * @param[in, out] *S points to an instance of the Q15 RFFT/RIFFT structure.
2216 * @param[in] *S_CFFT points to an instance of the Q15 CFFT/CIFFT structure.
2217 * @param[in] fftLenReal length of the FFT.
2218 * @param[in] ifftFlagR flag that selects forward (ifftFlagR=0) or inverse (ifftFlagR=1) transform.
2219 * @param[in] bitReverseFlag flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output.
2220 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLenReal</code> is not a supported value.
2221 */
2222
2223 arm_status arm_rfft_init_q15(
2224 arm_rfft_instance_q15 * S,
2225 arm_cfft_radix4_instance_q15 * S_CFFT,
2226 uint32_t fftLenReal,
2227 uint32_t ifftFlagR,
2228 uint32_t bitReverseFlag);
2229
2230 /**
2231 * @brief Processing function for the Q31 RFFT/RIFFT.
2232 * @param[in] *S points to an instance of the Q31 RFFT/RIFFT structure.
2233 * @param[in] *pSrc points to the input buffer.
2234 * @param[out] *pDst points to the output buffer.
2235 * @return none.
2236 */
2237
2238 void arm_rfft_q31(
2239 const arm_rfft_instance_q31 * S,
2240 q31_t * pSrc,
2241 q31_t * pDst);
2242
2243 /**
2244 * @brief Initialization function for the Q31 RFFT/RIFFT.
2245 * @param[in, out] *S points to an instance of the Q31 RFFT/RIFFT structure.
2246 * @param[in, out] *S_CFFT points to an instance of the Q31 CFFT/CIFFT structure.
2247 * @param[in] fftLenReal length of the FFT.
2248 * @param[in] ifftFlagR flag that selects forward (ifftFlagR=0) or inverse (ifftFlagR=1) transform.
2249 * @param[in] bitReverseFlag flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output.
2250 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLenReal</code> is not a supported value.
2251 */
2252
2253 arm_status arm_rfft_init_q31(
2254 arm_rfft_instance_q31 * S,
2255 arm_cfft_radix4_instance_q31 * S_CFFT,
2256 uint32_t fftLenReal,
2257 uint32_t ifftFlagR,
2258 uint32_t bitReverseFlag);
2259
2260 /**
2261 * @brief Initialization function for the floating-point RFFT/RIFFT.
2262 * @param[in,out] *S points to an instance of the floating-point RFFT/RIFFT structure.
2263 * @param[in,out] *S_CFFT points to an instance of the floating-point CFFT/CIFFT structure.
2264 * @param[in] fftLenReal length of the FFT.
2265 * @param[in] ifftFlagR flag that selects forward (ifftFlagR=0) or inverse (ifftFlagR=1) transform.
2266 * @param[in] bitReverseFlag flag that enables (bitReverseFlag=1) or disables (bitReverseFlag=0) bit reversal of output.
2267 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLenReal</code> is not a supported value.
2268 */
2269
2270 arm_status arm_rfft_init_f32(
2271 arm_rfft_instance_f32 * S,
2272 arm_cfft_radix4_instance_f32 * S_CFFT,
2273 uint32_t fftLenReal,
2274 uint32_t ifftFlagR,
2275 uint32_t bitReverseFlag);
2276
2277 /**
2278 * @brief Processing function for the floating-point RFFT/RIFFT.
2279 * @param[in] *S points to an instance of the floating-point RFFT/RIFFT structure.
2280 * @param[in] *pSrc points to the input buffer.
2281 * @param[out] *pDst points to the output buffer.
2282 * @return none.
2283 */
2284
2285 void arm_rfft_f32(
2286 const arm_rfft_instance_f32 * S,
2287 float32_t * pSrc,
2288 float32_t * pDst);
2289
2290 /**
2291 * @brief Instance structure for the floating-point DCT4/IDCT4 function.
2292 */
2293
2294 typedef struct
2295 {
2296 uint16_t N; /**< length of the DCT4. */
2297 uint16_t Nby2; /**< half of the length of the DCT4. */
2298 float32_t normalize; /**< normalizing factor. */
2299 float32_t *pTwiddle; /**< points to the twiddle factor table. */
2300 float32_t *pCosFactor; /**< points to the cosFactor table. */
2301 arm_rfft_instance_f32 *pRfft; /**< points to the real FFT instance. */
2302 arm_cfft_radix4_instance_f32 *pCfft; /**< points to the complex FFT instance. */
2303 } arm_dct4_instance_f32;
2304
2305 /**
2306 * @brief Initialization function for the floating-point DCT4/IDCT4.
2307 * @param[in,out] *S points to an instance of floating-point DCT4/IDCT4 structure.
2308 * @param[in] *S_RFFT points to an instance of floating-point RFFT/RIFFT structure.
2309 * @param[in] *S_CFFT points to an instance of floating-point CFFT/CIFFT structure.
2310 * @param[in] N length of the DCT4.
2311 * @param[in] Nby2 half of the length of the DCT4.
2312 * @param[in] normalize normalizing factor.
2313 * @return arm_status function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>fftLenReal</code> is not a supported transform length.
2314 */
2315
2316 arm_status arm_dct4_init_f32(
2317 arm_dct4_instance_f32 * S,
2318 arm_rfft_instance_f32 * S_RFFT,
2319 arm_cfft_radix4_instance_f32 * S_CFFT,
2320 uint16_t N,
2321 uint16_t Nby2,
2322 float32_t normalize);
2323
2324 /**
2325 * @brief Processing function for the floating-point DCT4/IDCT4.
2326 * @param[in] *S points to an instance of the floating-point DCT4/IDCT4 structure.
2327 * @param[in] *pState points to state buffer.
2328 * @param[in,out] *pInlineBuffer points to the in-place input and output buffer.
2329 * @return none.
2330 */
2331
2332 void arm_dct4_f32(
2333 const arm_dct4_instance_f32 * S,
2334 float32_t * pState,
2335 float32_t * pInlineBuffer);
2336
2337 /**
2338 * @brief Instance structure for the Q31 DCT4/IDCT4 function.
2339 */
2340
2341 typedef struct
2342 {
2343 uint16_t N; /**< length of the DCT4. */
2344 uint16_t Nby2; /**< half of the length of the DCT4. */
2345 q31_t normalize; /**< normalizing factor. */
2346 q31_t *pTwiddle; /**< points to the twiddle factor table. */
2347 q31_t *pCosFactor; /**< points to the cosFactor table. */
2348 arm_rfft_instance_q31 *pRfft; /**< points to the real FFT instance. */
2349 arm_cfft_radix4_instance_q31 *pCfft; /**< points to the complex FFT instance. */
2350 } arm_dct4_instance_q31;
2351
2352 /**
2353 * @brief Initialization function for the Q31 DCT4/IDCT4.
2354 * @param[in,out] *S points to an instance of Q31 DCT4/IDCT4 structure.
2355 * @param[in] *S_RFFT points to an instance of Q31 RFFT/RIFFT structure
2356 * @param[in] *S_CFFT points to an instance of Q31 CFFT/CIFFT structure
2357 * @param[in] N length of the DCT4.
2358 * @param[in] Nby2 half of the length of the DCT4.
2359 * @param[in] normalize normalizing factor.
2360 * @return arm_status function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>N</code> is not a supported transform length.
2361 */
2362
2363 arm_status arm_dct4_init_q31(
2364 arm_dct4_instance_q31 * S,
2365 arm_rfft_instance_q31 * S_RFFT,
2366 arm_cfft_radix4_instance_q31 * S_CFFT,
2367 uint16_t N,
2368 uint16_t Nby2,
2369 q31_t normalize);
2370
2371 /**
2372 * @brief Processing function for the Q31 DCT4/IDCT4.
2373 * @param[in] *S points to an instance of the Q31 DCT4 structure.
2374 * @param[in] *pState points to state buffer.
2375 * @param[in,out] *pInlineBuffer points to the in-place input and output buffer.
2376 * @return none.
2377 */
2378
2379 void arm_dct4_q31(
2380 const arm_dct4_instance_q31 * S,
2381 q31_t * pState,
2382 q31_t * pInlineBuffer);
2383
2384 /**
2385 * @brief Instance structure for the Q15 DCT4/IDCT4 function.
2386 */
2387
2388 typedef struct
2389 {
2390 uint16_t N; /**< length of the DCT4. */
2391 uint16_t Nby2; /**< half of the length of the DCT4. */
2392 q15_t normalize; /**< normalizing factor. */
2393 q15_t *pTwiddle; /**< points to the twiddle factor table. */
2394 q15_t *pCosFactor; /**< points to the cosFactor table. */
2395 arm_rfft_instance_q15 *pRfft; /**< points to the real FFT instance. */
2396 arm_cfft_radix4_instance_q15 *pCfft; /**< points to the complex FFT instance. */
2397 } arm_dct4_instance_q15;
2398
2399 /**
2400 * @brief Initialization function for the Q15 DCT4/IDCT4.
2401 * @param[in,out] *S points to an instance of Q15 DCT4/IDCT4 structure.
2402 * @param[in] *S_RFFT points to an instance of Q15 RFFT/RIFFT structure.
2403 * @param[in] *S_CFFT points to an instance of Q15 CFFT/CIFFT structure.
2404 * @param[in] N length of the DCT4.
2405 * @param[in] Nby2 half of the length of the DCT4.
2406 * @param[in] normalize normalizing factor.
2407 * @return arm_status function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_ARGUMENT_ERROR if <code>N</code> is not a supported transform length.
2408 */
2409
2410 arm_status arm_dct4_init_q15(
2411 arm_dct4_instance_q15 * S,
2412 arm_rfft_instance_q15 * S_RFFT,
2413 arm_cfft_radix4_instance_q15 * S_CFFT,
2414 uint16_t N,
2415 uint16_t Nby2,
2416 q15_t normalize);
2417
2418 /**
2419 * @brief Processing function for the Q15 DCT4/IDCT4.
2420 * @param[in] *S points to an instance of the Q15 DCT4 structure.
2421 * @param[in] *pState points to state buffer.
2422 * @param[in,out] *pInlineBuffer points to the in-place input and output buffer.
2423 * @return none.
2424 */
2425
2426 void arm_dct4_q15(
2427 const arm_dct4_instance_q15 * S,
2428 q15_t * pState,
2429 q15_t * pInlineBuffer);
2430
2431 /**
2432 * @brief Floating-point vector addition.
2433 * @param[in] *pSrcA points to the first input vector
2434 * @param[in] *pSrcB points to the second input vector
2435 * @param[out] *pDst points to the output vector
2436 * @param[in] blockSize number of samples in each vector
2437 * @return none.
2438 */
2439
2440 void arm_add_f32(
2441 float32_t * pSrcA,
2442 float32_t * pSrcB,
2443 float32_t * pDst,
2444 uint32_t blockSize);
2445
2446 /**
2447 * @brief Q7 vector addition.
2448 * @param[in] *pSrcA points to the first input vector
2449 * @param[in] *pSrcB points to the second input vector
2450 * @param[out] *pDst points to the output vector
2451 * @param[in] blockSize number of samples in each vector
2452 * @return none.
2453 */
2454
2455 void arm_add_q7(
2456 q7_t * pSrcA,
2457 q7_t * pSrcB,
2458 q7_t * pDst,
2459 uint32_t blockSize);
2460
2461 /**
2462 * @brief Q15 vector addition.
2463 * @param[in] *pSrcA points to the first input vector
2464 * @param[in] *pSrcB points to the second input vector
2465 * @param[out] *pDst points to the output vector
2466 * @param[in] blockSize number of samples in each vector
2467 * @return none.
2468 */
2469
2470 void arm_add_q15(
2471 q15_t * pSrcA,
2472 q15_t * pSrcB,
2473 q15_t * pDst,
2474 uint32_t blockSize);
2475
2476 /**
2477 * @brief Q31 vector addition.
2478 * @param[in] *pSrcA points to the first input vector
2479 * @param[in] *pSrcB points to the second input vector
2480 * @param[out] *pDst points to the output vector
2481 * @param[in] blockSize number of samples in each vector
2482 * @return none.
2483 */
2484
2485 void arm_add_q31(
2486 q31_t * pSrcA,
2487 q31_t * pSrcB,
2488 q31_t * pDst,
2489 uint32_t blockSize);
2490
2491 /**
2492 * @brief Floating-point vector subtraction.
2493 * @param[in] *pSrcA points to the first input vector
2494 * @param[in] *pSrcB points to the second input vector
2495 * @param[out] *pDst points to the output vector
2496 * @param[in] blockSize number of samples in each vector
2497 * @return none.
2498 */
2499
2500 void arm_sub_f32(
2501 float32_t * pSrcA,
2502 float32_t * pSrcB,
2503 float32_t * pDst,
2504 uint32_t blockSize);
2505
2506 /**
2507 * @brief Q7 vector subtraction.
2508 * @param[in] *pSrcA points to the first input vector
2509 * @param[in] *pSrcB points to the second input vector
2510 * @param[out] *pDst points to the output vector
2511 * @param[in] blockSize number of samples in each vector
2512 * @return none.
2513 */
2514
2515 void arm_sub_q7(
2516 q7_t * pSrcA,
2517 q7_t * pSrcB,
2518 q7_t * pDst,
2519 uint32_t blockSize);
2520
2521 /**
2522 * @brief Q15 vector subtraction.
2523 * @param[in] *pSrcA points to the first input vector
2524 * @param[in] *pSrcB points to the second input vector
2525 * @param[out] *pDst points to the output vector
2526 * @param[in] blockSize number of samples in each vector
2527 * @return none.
2528 */
2529
2530 void arm_sub_q15(
2531 q15_t * pSrcA,
2532 q15_t * pSrcB,
2533 q15_t * pDst,
2534 uint32_t blockSize);
2535
2536 /**
2537 * @brief Q31 vector subtraction.
2538 * @param[in] *pSrcA points to the first input vector
2539 * @param[in] *pSrcB points to the second input vector
2540 * @param[out] *pDst points to the output vector
2541 * @param[in] blockSize number of samples in each vector
2542 * @return none.
2543 */
2544
2545 void arm_sub_q31(
2546 q31_t * pSrcA,
2547 q31_t * pSrcB,
2548 q31_t * pDst,
2549 uint32_t blockSize);
2550
2551 /**
2552 * @brief Multiplies a floating-point vector by a scalar.
2553 * @param[in] *pSrc points to the input vector
2554 * @param[in] scale scale factor to be applied
2555 * @param[out] *pDst points to the output vector
2556 * @param[in] blockSize number of samples in the vector
2557 * @return none.
2558 */
2559
2560 void arm_scale_f32(
2561 float32_t * pSrc,
2562 float32_t scale,
2563 float32_t * pDst,
2564 uint32_t blockSize);
2565
2566 /**
2567 * @brief Multiplies a Q7 vector by a scalar.
2568 * @param[in] *pSrc points to the input vector
2569 * @param[in] scaleFract fractional portion of the scale value
2570 * @param[in] shift number of bits to shift the result by
2571 * @param[out] *pDst points to the output vector
2572 * @param[in] blockSize number of samples in the vector
2573 * @return none.
2574 */
2575
2576 void arm_scale_q7(
2577 q7_t * pSrc,
2578 q7_t scaleFract,
2579 int8_t shift,
2580 q7_t * pDst,
2581 uint32_t blockSize);
2582
2583 /**
2584 * @brief Multiplies a Q15 vector by a scalar.
2585 * @param[in] *pSrc points to the input vector
2586 * @param[in] scaleFract fractional portion of the scale value
2587 * @param[in] shift number of bits to shift the result by
2588 * @param[out] *pDst points to the output vector
2589 * @param[in] blockSize number of samples in the vector
2590 * @return none.
2591 */
2592
2593 void arm_scale_q15(
2594 q15_t * pSrc,
2595 q15_t scaleFract,
2596 int8_t shift,
2597 q15_t * pDst,
2598 uint32_t blockSize);
2599
2600 /**
2601 * @brief Multiplies a Q31 vector by a scalar.
2602 * @param[in] *pSrc points to the input vector
2603 * @param[in] scaleFract fractional portion of the scale value
2604 * @param[in] shift number of bits to shift the result by
2605 * @param[out] *pDst points to the output vector
2606 * @param[in] blockSize number of samples in the vector
2607 * @return none.
2608 */
2609
2610 void arm_scale_q31(
2611 q31_t * pSrc,
2612 q31_t scaleFract,
2613 int8_t shift,
2614 q31_t * pDst,
2615 uint32_t blockSize);
2616
2617 /**
2618 * @brief Q7 vector absolute value.
2619 * @param[in] *pSrc points to the input buffer
2620 * @param[out] *pDst points to the output buffer
2621 * @param[in] blockSize number of samples in each vector
2622 * @return none.
2623 */
2624
2625 void arm_abs_q7(
2626 q7_t * pSrc,
2627 q7_t * pDst,
2628 uint32_t blockSize);
2629
2630 /**
2631 * @brief Floating-point vector absolute value.
2632 * @param[in] *pSrc points to the input buffer
2633 * @param[out] *pDst points to the output buffer
2634 * @param[in] blockSize number of samples in each vector
2635 * @return none.
2636 */
2637
2638 void arm_abs_f32(
2639 float32_t * pSrc,
2640 float32_t * pDst,
2641 uint32_t blockSize);
2642
2643 /**
2644 * @brief Q15 vector absolute value.
2645 * @param[in] *pSrc points to the input buffer
2646 * @param[out] *pDst points to the output buffer
2647 * @param[in] blockSize number of samples in each vector
2648 * @return none.
2649 */
2650
2651 void arm_abs_q15(
2652 q15_t * pSrc,
2653 q15_t * pDst,
2654 uint32_t blockSize);
2655
2656 /**
2657 * @brief Q31 vector absolute value.
2658 * @param[in] *pSrc points to the input buffer
2659 * @param[out] *pDst points to the output buffer
2660 * @param[in] blockSize number of samples in each vector
2661 * @return none.
2662 */
2663
2664 void arm_abs_q31(
2665 q31_t * pSrc,
2666 q31_t * pDst,
2667 uint32_t blockSize);
2668
2669 /**
2670 * @brief Dot product of floating-point vectors.
2671 * @param[in] *pSrcA points to the first input vector
2672 * @param[in] *pSrcB points to the second input vector
2673 * @param[in] blockSize number of samples in each vector
2674 * @param[out] *result output result returned here
2675 * @return none.
2676 */
2677
2678 void arm_dot_prod_f32(
2679 float32_t * pSrcA,
2680 float32_t * pSrcB,
2681 uint32_t blockSize,
2682 float32_t * result);
2683
2684 /**
2685 * @brief Dot product of Q7 vectors.
2686 * @param[in] *pSrcA points to the first input vector
2687 * @param[in] *pSrcB points to the second input vector
2688 * @param[in] blockSize number of samples in each vector
2689 * @param[out] *result output result returned here
2690 * @return none.
2691 */
2692
2693 void arm_dot_prod_q7(
2694 q7_t * pSrcA,
2695 q7_t * pSrcB,
2696 uint32_t blockSize,
2697 q31_t * result);
2698
2699 /**
2700 * @brief Dot product of Q15 vectors.
2701 * @param[in] *pSrcA points to the first input vector
2702 * @param[in] *pSrcB points to the second input vector
2703 * @param[in] blockSize number of samples in each vector
2704 * @param[out] *result output result returned here
2705 * @return none.
2706 */
2707
2708 void arm_dot_prod_q15(
2709 q15_t * pSrcA,
2710 q15_t * pSrcB,
2711 uint32_t blockSize,
2712 q63_t * result);
2713
2714 /**
2715 * @brief Dot product of Q31 vectors.
2716 * @param[in] *pSrcA points to the first input vector
2717 * @param[in] *pSrcB points to the second input vector
2718 * @param[in] blockSize number of samples in each vector
2719 * @param[out] *result output result returned here
2720 * @return none.
2721 */
2722
2723 void arm_dot_prod_q31(
2724 q31_t * pSrcA,
2725 q31_t * pSrcB,
2726 uint32_t blockSize,
2727 q63_t * result);
2728
2729 /**
2730 * @brief Shifts the elements of a Q7 vector a specified number of bits.
2731 * @param[in] *pSrc points to the input vector
2732 * @param[in] shiftBits number of bits to shift. A positive value shifts left; a negative value shifts right.
2733 * @param[out] *pDst points to the output vector
2734 * @param[in] blockSize number of samples in the vector
2735 * @return none.
2736 */
2737
2738 void arm_shift_q7(
2739 q7_t * pSrc,
2740 int8_t shiftBits,
2741 q7_t * pDst,
2742 uint32_t blockSize);
2743
2744 /**
2745 * @brief Shifts the elements of a Q15 vector a specified number of bits.
2746 * @param[in] *pSrc points to the input vector
2747 * @param[in] shiftBits number of bits to shift. A positive value shifts left; a negative value shifts right.
2748 * @param[out] *pDst points to the output vector
2749 * @param[in] blockSize number of samples in the vector
2750 * @return none.
2751 */
2752
2753 void arm_shift_q15(
2754 q15_t * pSrc,
2755 int8_t shiftBits,
2756 q15_t * pDst,
2757 uint32_t blockSize);
2758
2759 /**
2760 * @brief Shifts the elements of a Q31 vector a specified number of bits.
2761 * @param[in] *pSrc points to the input vector
2762 * @param[in] shiftBits number of bits to shift. A positive value shifts left; a negative value shifts right.
2763 * @param[out] *pDst points to the output vector
2764 * @param[in] blockSize number of samples in the vector
2765 * @return none.
2766 */
2767
2768 void arm_shift_q31(
2769 q31_t * pSrc,
2770 int8_t shiftBits,
2771 q31_t * pDst,
2772 uint32_t blockSize);
2773
2774 /**
2775 * @brief Adds a constant offset to a floating-point vector.
2776 * @param[in] *pSrc points to the input vector
2777 * @param[in] offset is the offset to be added
2778 * @param[out] *pDst points to the output vector
2779 * @param[in] blockSize number of samples in the vector
2780 * @return none.
2781 */
2782
2783 void arm_offset_f32(
2784 float32_t * pSrc,
2785 float32_t offset,
2786 float32_t * pDst,
2787 uint32_t blockSize);
2788
2789 /**
2790 * @brief Adds a constant offset to a Q7 vector.
2791 * @param[in] *pSrc points to the input vector
2792 * @param[in] offset is the offset to be added
2793 * @param[out] *pDst points to the output vector
2794 * @param[in] blockSize number of samples in the vector
2795 * @return none.
2796 */
2797
2798 void arm_offset_q7(
2799 q7_t * pSrc,
2800 q7_t offset,
2801 q7_t * pDst,
2802 uint32_t blockSize);
2803
2804 /**
2805 * @brief Adds a constant offset to a Q15 vector.
2806 * @param[in] *pSrc points to the input vector
2807 * @param[in] offset is the offset to be added
2808 * @param[out] *pDst points to the output vector
2809 * @param[in] blockSize number of samples in the vector
2810 * @return none.
2811 */
2812
2813 void arm_offset_q15(
2814 q15_t * pSrc,
2815 q15_t offset,
2816 q15_t * pDst,
2817 uint32_t blockSize);
2818
2819 /**
2820 * @brief Adds a constant offset to a Q31 vector.
2821 * @param[in] *pSrc points to the input vector
2822 * @param[in] offset is the offset to be added
2823 * @param[out] *pDst points to the output vector
2824 * @param[in] blockSize number of samples in the vector
2825 * @return none.
2826 */
2827
2828 void arm_offset_q31(
2829 q31_t * pSrc,
2830 q31_t offset,
2831 q31_t * pDst,
2832 uint32_t blockSize);
2833
2834 /**
2835 * @brief Negates the elements of a floating-point vector.
2836 * @param[in] *pSrc points to the input vector
2837 * @param[out] *pDst points to the output vector
2838 * @param[in] blockSize number of samples in the vector
2839 * @return none.
2840 */
2841
2842 void arm_negate_f32(
2843 float32_t * pSrc,
2844 float32_t * pDst,
2845 uint32_t blockSize);
2846
2847 /**
2848 * @brief Negates the elements of a Q7 vector.
2849 * @param[in] *pSrc points to the input vector
2850 * @param[out] *pDst points to the output vector
2851 * @param[in] blockSize number of samples in the vector
2852 * @return none.
2853 */
2854
2855 void arm_negate_q7(
2856 q7_t * pSrc,
2857 q7_t * pDst,
2858 uint32_t blockSize);
2859
2860 /**
2861 * @brief Negates the elements of a Q15 vector.
2862 * @param[in] *pSrc points to the input vector
2863 * @param[out] *pDst points to the output vector
2864 * @param[in] blockSize number of samples in the vector
2865 * @return none.
2866 */
2867
2868 void arm_negate_q15(
2869 q15_t * pSrc,
2870 q15_t * pDst,
2871 uint32_t blockSize);
2872
2873 /**
2874 * @brief Negates the elements of a Q31 vector.
2875 * @param[in] *pSrc points to the input vector
2876 * @param[out] *pDst points to the output vector
2877 * @param[in] blockSize number of samples in the vector
2878 * @return none.
2879 */
2880
2881 void arm_negate_q31(
2882 q31_t * pSrc,
2883 q31_t * pDst,
2884 uint32_t blockSize);
2885 /**
2886 * @brief Copies the elements of a floating-point vector.
2887 * @param[in] *pSrc input pointer
2888 * @param[out] *pDst output pointer
2889 * @param[in] blockSize number of samples to process
2890 * @return none.
2891 */
2892 void arm_copy_f32(
2893 float32_t * pSrc,
2894 float32_t * pDst,
2895 uint32_t blockSize);
2896
2897 /**
2898 * @brief Copies the elements of a Q7 vector.
2899 * @param[in] *pSrc input pointer
2900 * @param[out] *pDst output pointer
2901 * @param[in] blockSize number of samples to process
2902 * @return none.
2903 */
2904 void arm_copy_q7(
2905 q7_t * pSrc,
2906 q7_t * pDst,
2907 uint32_t blockSize);
2908
2909 /**
2910 * @brief Copies the elements of a Q15 vector.
2911 * @param[in] *pSrc input pointer
2912 * @param[out] *pDst output pointer
2913 * @param[in] blockSize number of samples to process
2914 * @return none.
2915 */
2916 void arm_copy_q15(
2917 q15_t * pSrc,
2918 q15_t * pDst,
2919 uint32_t blockSize);
2920
2921 /**
2922 * @brief Copies the elements of a Q31 vector.
2923 * @param[in] *pSrc input pointer
2924 * @param[out] *pDst output pointer
2925 * @param[in] blockSize number of samples to process
2926 * @return none.
2927 */
2928 void arm_copy_q31(
2929 q31_t * pSrc,
2930 q31_t * pDst,
2931 uint32_t blockSize);
2932 /**
2933 * @brief Fills a constant value into a floating-point vector.
2934 * @param[in] value input value to be filled
2935 * @param[out] *pDst output pointer
2936 * @param[in] blockSize number of samples to process
2937 * @return none.
2938 */
2939 void arm_fill_f32(
2940 float32_t value,
2941 float32_t * pDst,
2942 uint32_t blockSize);
2943
2944 /**
2945 * @brief Fills a constant value into a Q7 vector.
2946 * @param[in] value input value to be filled
2947 * @param[out] *pDst output pointer
2948 * @param[in] blockSize number of samples to process
2949 * @return none.
2950 */
2951 void arm_fill_q7(
2952 q7_t value,
2953 q7_t * pDst,
2954 uint32_t blockSize);
2955
2956 /**
2957 * @brief Fills a constant value into a Q15 vector.
2958 * @param[in] value input value to be filled
2959 * @param[out] *pDst output pointer
2960 * @param[in] blockSize number of samples to process
2961 * @return none.
2962 */
2963 void arm_fill_q15(
2964 q15_t value,
2965 q15_t * pDst,
2966 uint32_t blockSize);
2967
2968 /**
2969 * @brief Fills a constant value into a Q31 vector.
2970 * @param[in] value input value to be filled
2971 * @param[out] *pDst output pointer
2972 * @param[in] blockSize number of samples to process
2973 * @return none.
2974 */
2975 void arm_fill_q31(
2976 q31_t value,
2977 q31_t * pDst,
2978 uint32_t blockSize);
2979
2980 /**
2981 * @brief Convolution of floating-point sequences.
2982 * @param[in] *pSrcA points to the first input sequence.
2983 * @param[in] srcALen length of the first input sequence.
2984 * @param[in] *pSrcB points to the second input sequence.
2985 * @param[in] srcBLen length of the second input sequence.
2986 * @param[out] *pDst points to the location where the output result is written. Length srcALen+srcBLen-1.
2987 * @return none.
2988 */
2989
2990 void arm_conv_f32(
2991 float32_t * pSrcA,
2992 uint32_t srcALen,
2993 float32_t * pSrcB,
2994 uint32_t srcBLen,
2995 float32_t * pDst);
2996
2997 /**
2998 * @brief Convolution of Q15 sequences.
2999 * @param[in] *pSrcA points to the first input sequence.
3000 * @param[in] srcALen length of the first input sequence.
3001 * @param[in] *pSrcB points to the second input sequence.
3002 * @param[in] srcBLen length of the second input sequence.
3003 * @param[out] *pDst points to the location where the output result is written. Length srcALen+srcBLen-1.
3004 * @return none.
3005 */
3006
3007 void arm_conv_q15(
3008 q15_t * pSrcA,
3009 uint32_t srcALen,
3010 q15_t * pSrcB,
3011 uint32_t srcBLen,
3012 q15_t * pDst);
3013
3014 /**
3015 * @brief Convolution of Q15 sequences (fast version) for Cortex-M3 and Cortex-M4
3016 * @param[in] *pSrcA points to the first input sequence.
3017 * @param[in] srcALen length of the first input sequence.
3018 * @param[in] *pSrcB points to the second input sequence.
3019 * @param[in] srcBLen length of the second input sequence.
3020 * @param[out] *pDst points to the block of output data Length srcALen+srcBLen-1.
3021 * @return none.
3022 */
3023
3024 void arm_conv_fast_q15(
3025 q15_t * pSrcA,
3026 uint32_t srcALen,
3027 q15_t * pSrcB,
3028 uint32_t srcBLen,
3029 q15_t * pDst);
3030
3031 /**
3032 * @brief Convolution of Q31 sequences.
3033 * @param[in] *pSrcA points to the first input sequence.
3034 * @param[in] srcALen length of the first input sequence.
3035 * @param[in] *pSrcB points to the second input sequence.
3036 * @param[in] srcBLen length of the second input sequence.
3037 * @param[out] *pDst points to the block of output data Length srcALen+srcBLen-1.
3038 * @return none.
3039 */
3040
3041 void arm_conv_q31(
3042 q31_t * pSrcA,
3043 uint32_t srcALen,
3044 q31_t * pSrcB,
3045 uint32_t srcBLen,
3046 q31_t * pDst);
3047
3048 /**
3049 * @brief Convolution of Q31 sequences (fast version) for Cortex-M3 and Cortex-M4
3050 * @param[in] *pSrcA points to the first input sequence.
3051 * @param[in] srcALen length of the first input sequence.
3052 * @param[in] *pSrcB points to the second input sequence.
3053 * @param[in] srcBLen length of the second input sequence.
3054 * @param[out] *pDst points to the block of output data Length srcALen+srcBLen-1.
3055 * @return none.
3056 */
3057
3058 void arm_conv_fast_q31(
3059 q31_t * pSrcA,
3060 uint32_t srcALen,
3061 q31_t * pSrcB,
3062 uint32_t srcBLen,
3063 q31_t * pDst);
3064
3065 /**
3066 * @brief Convolution of Q7 sequences.
3067 * @param[in] *pSrcA points to the first input sequence.
3068 * @param[in] srcALen length of the first input sequence.
3069 * @param[in] *pSrcB points to the second input sequence.
3070 * @param[in] srcBLen length of the second input sequence.
3071 * @param[out] *pDst points to the block of output data Length srcALen+srcBLen-1.
3072 * @return none.
3073 */
3074
3075 void arm_conv_q7(
3076 q7_t * pSrcA,
3077 uint32_t srcALen,
3078 q7_t * pSrcB,
3079 uint32_t srcBLen,
3080 q7_t * pDst);
3081
3082 /**
3083 * @brief Partial convolution of floating-point sequences.
3084 * @param[in] *pSrcA points to the first input sequence.
3085 * @param[in] srcALen length of the first input sequence.
3086 * @param[in] *pSrcB points to the second input sequence.
3087 * @param[in] srcBLen length of the second input sequence.
3088 * @param[out] *pDst points to the block of output data
3089 * @param[in] firstIndex is the first output sample to start with.
3090 * @param[in] numPoints is the number of output points to be computed.
3091 * @return Returns either ARM_MATH_SUCCESS if the function completed correctly or ARM_MATH_ARGUMENT_ERROR if the requested subset is not in the range [0 srcALen+srcBLen-2].
3092 */
3093
3094 arm_status arm_conv_partial_f32(
3095 float32_t * pSrcA,
3096 uint32_t srcALen,
3097 float32_t * pSrcB,
3098 uint32_t srcBLen,
3099 float32_t * pDst,
3100 uint32_t firstIndex,
3101 uint32_t numPoints);
3102
3103 /**
3104 * @brief Partial convolution of Q15 sequences.
3105 * @param[in] *pSrcA points to the first input sequence.
3106 * @param[in] srcALen length of the first input sequence.
3107 * @param[in] *pSrcB points to the second input sequence.
3108 * @param[in] srcBLen length of the second input sequence.
3109 * @param[out] *pDst points to the block of output data
3110 * @param[in] firstIndex is the first output sample to start with.
3111 * @param[in] numPoints is the number of output points to be computed.
3112 * @return Returns either ARM_MATH_SUCCESS if the function completed correctly or ARM_MATH_ARGUMENT_ERROR if the requested subset is not in the range [0 srcALen+srcBLen-2].
3113 */
3114
3115 arm_status arm_conv_partial_q15(
3116 q15_t * pSrcA,
3117 uint32_t srcALen,
3118 q15_t * pSrcB,
3119 uint32_t srcBLen,
3120 q15_t * pDst,
3121 uint32_t firstIndex,
3122 uint32_t numPoints);
3123
3124 /**
3125 * @brief Partial convolution of Q15 sequences (fast version) for Cortex-M3 and Cortex-M4
3126 * @param[in] *pSrcA points to the first input sequence.
3127 * @param[in] srcALen length of the first input sequence.
3128 * @param[in] *pSrcB points to the second input sequence.
3129 * @param[in] srcBLen length of the second input sequence.
3130 * @param[out] *pDst points to the block of output data
3131 * @param[in] firstIndex is the first output sample to start with.
3132 * @param[in] numPoints is the number of output points to be computed.
3133 * @return Returns either ARM_MATH_SUCCESS if the function completed correctly or ARM_MATH_ARGUMENT_ERROR if the requested subset is not in the range [0 srcALen+srcBLen-2].
3134 */
3135
3136 arm_status arm_conv_partial_fast_q15(
3137 q15_t * pSrcA,
3138 uint32_t srcALen,
3139 q15_t * pSrcB,
3140 uint32_t srcBLen,
3141 q15_t * pDst,
3142 uint32_t firstIndex,
3143 uint32_t numPoints);
3144
3145 /**
3146 * @brief Partial convolution of Q31 sequences.
3147 * @param[in] *pSrcA points to the first input sequence.
3148 * @param[in] srcALen length of the first input sequence.
3149 * @param[in] *pSrcB points to the second input sequence.
3150 * @param[in] srcBLen length of the second input sequence.
3151 * @param[out] *pDst points to the block of output data
3152 * @param[in] firstIndex is the first output sample to start with.
3153 * @param[in] numPoints is the number of output points to be computed.
3154 * @return Returns either ARM_MATH_SUCCESS if the function completed correctly or ARM_MATH_ARGUMENT_ERROR if the requested subset is not in the range [0 srcALen+srcBLen-2].
3155 */
3156
3157 arm_status arm_conv_partial_q31(
3158 q31_t * pSrcA,
3159 uint32_t srcALen,
3160 q31_t * pSrcB,
3161 uint32_t srcBLen,
3162 q31_t * pDst,
3163 uint32_t firstIndex,
3164 uint32_t numPoints);
3165
3166
3167 /**
3168 * @brief Partial convolution of Q31 sequences (fast version) for Cortex-M3 and Cortex-M4
3169 * @param[in] *pSrcA points to the first input sequence.
3170 * @param[in] srcALen length of the first input sequence.
3171 * @param[in] *pSrcB points to the second input sequence.
3172 * @param[in] srcBLen length of the second input sequence.
3173 * @param[out] *pDst points to the block of output data
3174 * @param[in] firstIndex is the first output sample to start with.
3175 * @param[in] numPoints is the number of output points to be computed.
3176 * @return Returns either ARM_MATH_SUCCESS if the function completed correctly or ARM_MATH_ARGUMENT_ERROR if the requested subset is not in the range [0 srcALen+srcBLen-2].
3177 */
3178
3179 arm_status arm_conv_partial_fast_q31(
3180 q31_t * pSrcA,
3181 uint32_t srcALen,
3182 q31_t * pSrcB,
3183 uint32_t srcBLen,
3184 q31_t * pDst,
3185 uint32_t firstIndex,
3186 uint32_t numPoints);
3187
3188 /**
3189 * @brief Partial convolution of Q7 sequences.
3190 * @param[in] *pSrcA points to the first input sequence.
3191 * @param[in] srcALen length of the first input sequence.
3192 * @param[in] *pSrcB points to the second input sequence.
3193 * @param[in] srcBLen length of the second input sequence.
3194 * @param[out] *pDst points to the block of output data
3195 * @param[in] firstIndex is the first output sample to start with.
3196 * @param[in] numPoints is the number of output points to be computed.
3197 * @return Returns either ARM_MATH_SUCCESS if the function completed correctly or ARM_MATH_ARGUMENT_ERROR if the requested subset is not in the range [0 srcALen+srcBLen-2].
3198 */
3199
3200 arm_status arm_conv_partial_q7(
3201 q7_t * pSrcA,
3202 uint32_t srcALen,
3203 q7_t * pSrcB,
3204 uint32_t srcBLen,
3205 q7_t * pDst,
3206 uint32_t firstIndex,
3207 uint32_t numPoints);
3208
3209
3210 /**
3211 * @brief Instance structure for the Q15 FIR decimator.
3212 */
3213
3214 typedef struct
3215 {
3216 uint8_t M; /**< decimation factor. */
3217 uint16_t numTaps; /**< number of coefficients in the filter. */
3218 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
3219 q15_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
3220 } arm_fir_decimate_instance_q15;
3221
3222 /**
3223 * @brief Instance structure for the Q31 FIR decimator.
3224 */
3225
3226 typedef struct
3227 {
3228 uint8_t M; /**< decimation factor. */
3229 uint16_t numTaps; /**< number of coefficients in the filter. */
3230 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
3231 q31_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
3232
3233 } arm_fir_decimate_instance_q31;
3234
3235 /**
3236 * @brief Instance structure for the floating-point FIR decimator.
3237 */
3238
3239 typedef struct
3240 {
3241 uint8_t M; /**< decimation factor. */
3242 uint16_t numTaps; /**< number of coefficients in the filter. */
3243 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
3244 float32_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
3245
3246 } arm_fir_decimate_instance_f32;
3247
3248
3249
3250 /**
3251 * @brief Processing function for the floating-point FIR decimator.
3252 * @param[in] *S points to an instance of the floating-point FIR decimator structure.
3253 * @param[in] *pSrc points to the block of input data.
3254 * @param[out] *pDst points to the block of output data
3255 * @param[in] blockSize number of input samples to process per call.
3256 * @return none
3257 */
3258
3259 void arm_fir_decimate_f32(
3260 const arm_fir_decimate_instance_f32 * S,
3261 float32_t * pSrc,
3262 float32_t * pDst,
3263 uint32_t blockSize);
3264
3265
3266 /**
3267 * @brief Initialization function for the floating-point FIR decimator.
3268 * @param[in,out] *S points to an instance of the floating-point FIR decimator structure.
3269 * @param[in] numTaps number of coefficients in the filter.
3270 * @param[in] M decimation factor.
3271 * @param[in] *pCoeffs points to the filter coefficients.
3272 * @param[in] *pState points to the state buffer.
3273 * @param[in] blockSize number of input samples to process per call.
3274 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_LENGTH_ERROR if
3275 * <code>blockSize</code> is not a multiple of <code>M</code>.
3276 */
3277
3278 arm_status arm_fir_decimate_init_f32(
3279 arm_fir_decimate_instance_f32 * S,
3280 uint16_t numTaps,
3281 uint8_t M,
3282 float32_t * pCoeffs,
3283 float32_t * pState,
3284 uint32_t blockSize);
3285
3286 /**
3287 * @brief Processing function for the Q15 FIR decimator.
3288 * @param[in] *S points to an instance of the Q15 FIR decimator structure.
3289 * @param[in] *pSrc points to the block of input data.
3290 * @param[out] *pDst points to the block of output data
3291 * @param[in] blockSize number of input samples to process per call.
3292 * @return none
3293 */
3294
3295 void arm_fir_decimate_q15(
3296 const arm_fir_decimate_instance_q15 * S,
3297 q15_t * pSrc,
3298 q15_t * pDst,
3299 uint32_t blockSize);
3300
3301 /**
3302 * @brief Processing function for the Q15 FIR decimator (fast variant) for Cortex-M3 and Cortex-M4.
3303 * @param[in] *S points to an instance of the Q15 FIR decimator structure.
3304 * @param[in] *pSrc points to the block of input data.
3305 * @param[out] *pDst points to the block of output data
3306 * @param[in] blockSize number of input samples to process per call.
3307 * @return none
3308 */
3309
3310 void arm_fir_decimate_fast_q15(
3311 const arm_fir_decimate_instance_q15 * S,
3312 q15_t * pSrc,
3313 q15_t * pDst,
3314 uint32_t blockSize);
3315
3316
3317
3318 /**
3319 * @brief Initialization function for the Q15 FIR decimator.
3320 * @param[in,out] *S points to an instance of the Q15 FIR decimator structure.
3321 * @param[in] numTaps number of coefficients in the filter.
3322 * @param[in] M decimation factor.
3323 * @param[in] *pCoeffs points to the filter coefficients.
3324 * @param[in] *pState points to the state buffer.
3325 * @param[in] blockSize number of input samples to process per call.
3326 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_LENGTH_ERROR if
3327 * <code>blockSize</code> is not a multiple of <code>M</code>.
3328 */
3329
3330 arm_status arm_fir_decimate_init_q15(
3331 arm_fir_decimate_instance_q15 * S,
3332 uint16_t numTaps,
3333 uint8_t M,
3334 q15_t * pCoeffs,
3335 q15_t * pState,
3336 uint32_t blockSize);
3337
3338 /**
3339 * @brief Processing function for the Q31 FIR decimator.
3340 * @param[in] *S points to an instance of the Q31 FIR decimator structure.
3341 * @param[in] *pSrc points to the block of input data.
3342 * @param[out] *pDst points to the block of output data
3343 * @param[in] blockSize number of input samples to process per call.
3344 * @return none
3345 */
3346
3347 void arm_fir_decimate_q31(
3348 const arm_fir_decimate_instance_q31 * S,
3349 q31_t * pSrc,
3350 q31_t * pDst,
3351 uint32_t blockSize);
3352
3353 /**
3354 * @brief Processing function for the Q31 FIR decimator (fast variant) for Cortex-M3 and Cortex-M4.
3355 * @param[in] *S points to an instance of the Q31 FIR decimator structure.
3356 * @param[in] *pSrc points to the block of input data.
3357 * @param[out] *pDst points to the block of output data
3358 * @param[in] blockSize number of input samples to process per call.
3359 * @return none
3360 */
3361
3362 void arm_fir_decimate_fast_q31(
3363 arm_fir_decimate_instance_q31 * S,
3364 q31_t * pSrc,
3365 q31_t * pDst,
3366 uint32_t blockSize);
3367
3368
3369 /**
3370 * @brief Initialization function for the Q31 FIR decimator.
3371 * @param[in,out] *S points to an instance of the Q31 FIR decimator structure.
3372 * @param[in] numTaps number of coefficients in the filter.
3373 * @param[in] M decimation factor.
3374 * @param[in] *pCoeffs points to the filter coefficients.
3375 * @param[in] *pState points to the state buffer.
3376 * @param[in] blockSize number of input samples to process per call.
3377 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_LENGTH_ERROR if
3378 * <code>blockSize</code> is not a multiple of <code>M</code>.
3379 */
3380
3381 arm_status arm_fir_decimate_init_q31(
3382 arm_fir_decimate_instance_q31 * S,
3383 uint16_t numTaps,
3384 uint8_t M,
3385 q31_t * pCoeffs,
3386 q31_t * pState,
3387 uint32_t blockSize);
3388
3389
3390
3391 /**
3392 * @brief Instance structure for the Q15 FIR interpolator.
3393 */
3394
3395 typedef struct
3396 {
3397 uint8_t L; /**< upsample factor. */
3398 uint16_t phaseLength; /**< length of each polyphase filter component. */
3399 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length L*phaseLength. */
3400 q15_t *pState; /**< points to the state variable array. The array is of length blockSize+phaseLength-1. */
3401 } arm_fir_interpolate_instance_q15;
3402
3403 /**
3404 * @brief Instance structure for the Q31 FIR interpolator.
3405 */
3406
3407 typedef struct
3408 {
3409 uint8_t L; /**< upsample factor. */
3410 uint16_t phaseLength; /**< length of each polyphase filter component. */
3411 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length L*phaseLength. */
3412 q31_t *pState; /**< points to the state variable array. The array is of length blockSize+phaseLength-1. */
3413 } arm_fir_interpolate_instance_q31;
3414
3415 /**
3416 * @brief Instance structure for the floating-point FIR interpolator.
3417 */
3418
3419 typedef struct
3420 {
3421 uint8_t L; /**< upsample factor. */
3422 uint16_t phaseLength; /**< length of each polyphase filter component. */
3423 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length L*phaseLength. */
3424 float32_t *pState; /**< points to the state variable array. The array is of length phaseLength+numTaps-1. */
3425 } arm_fir_interpolate_instance_f32;
3426
3427
3428 /**
3429 * @brief Processing function for the Q15 FIR interpolator.
3430 * @param[in] *S points to an instance of the Q15 FIR interpolator structure.
3431 * @param[in] *pSrc points to the block of input data.
3432 * @param[out] *pDst points to the block of output data.
3433 * @param[in] blockSize number of input samples to process per call.
3434 * @return none.
3435 */
3436
3437 void arm_fir_interpolate_q15(
3438 const arm_fir_interpolate_instance_q15 * S,
3439 q15_t * pSrc,
3440 q15_t * pDst,
3441 uint32_t blockSize);
3442
3443
3444 /**
3445 * @brief Initialization function for the Q15 FIR interpolator.
3446 * @param[in,out] *S points to an instance of the Q15 FIR interpolator structure.
3447 * @param[in] L upsample factor.
3448 * @param[in] numTaps number of filter coefficients in the filter.
3449 * @param[in] *pCoeffs points to the filter coefficient buffer.
3450 * @param[in] *pState points to the state buffer.
3451 * @param[in] blockSize number of input samples to process per call.
3452 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_LENGTH_ERROR if
3453 * the filter length <code>numTaps</code> is not a multiple of the interpolation factor <code>L</code>.
3454 */
3455
3456 arm_status arm_fir_interpolate_init_q15(
3457 arm_fir_interpolate_instance_q15 * S,
3458 uint8_t L,
3459 uint16_t numTaps,
3460 q15_t * pCoeffs,
3461 q15_t * pState,
3462 uint32_t blockSize);
3463
3464 /**
3465 * @brief Processing function for the Q31 FIR interpolator.
3466 * @param[in] *S points to an instance of the Q15 FIR interpolator structure.
3467 * @param[in] *pSrc points to the block of input data.
3468 * @param[out] *pDst points to the block of output data.
3469 * @param[in] blockSize number of input samples to process per call.
3470 * @return none.
3471 */
3472
3473 void arm_fir_interpolate_q31(
3474 const arm_fir_interpolate_instance_q31 * S,
3475 q31_t * pSrc,
3476 q31_t * pDst,
3477 uint32_t blockSize);
3478
3479 /**
3480 * @brief Initialization function for the Q31 FIR interpolator.
3481 * @param[in,out] *S points to an instance of the Q31 FIR interpolator structure.
3482 * @param[in] L upsample factor.
3483 * @param[in] numTaps number of filter coefficients in the filter.
3484 * @param[in] *pCoeffs points to the filter coefficient buffer.
3485 * @param[in] *pState points to the state buffer.
3486 * @param[in] blockSize number of input samples to process per call.
3487 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_LENGTH_ERROR if
3488 * the filter length <code>numTaps</code> is not a multiple of the interpolation factor <code>L</code>.
3489 */
3490
3491 arm_status arm_fir_interpolate_init_q31(
3492 arm_fir_interpolate_instance_q31 * S,
3493 uint8_t L,
3494 uint16_t numTaps,
3495 q31_t * pCoeffs,
3496 q31_t * pState,
3497 uint32_t blockSize);
3498
3499
3500 /**
3501 * @brief Processing function for the floating-point FIR interpolator.
3502 * @param[in] *S points to an instance of the floating-point FIR interpolator structure.
3503 * @param[in] *pSrc points to the block of input data.
3504 * @param[out] *pDst points to the block of output data.
3505 * @param[in] blockSize number of input samples to process per call.
3506 * @return none.
3507 */
3508
3509 void arm_fir_interpolate_f32(
3510 const arm_fir_interpolate_instance_f32 * S,
3511 float32_t * pSrc,
3512 float32_t * pDst,
3513 uint32_t blockSize);
3514
3515 /**
3516 * @brief Initialization function for the floating-point FIR interpolator.
3517 * @param[in,out] *S points to an instance of the floating-point FIR interpolator structure.
3518 * @param[in] L upsample factor.
3519 * @param[in] numTaps number of filter coefficients in the filter.
3520 * @param[in] *pCoeffs points to the filter coefficient buffer.
3521 * @param[in] *pState points to the state buffer.
3522 * @param[in] blockSize number of input samples to process per call.
3523 * @return The function returns ARM_MATH_SUCCESS if initialization is successful or ARM_MATH_LENGTH_ERROR if
3524 * the filter length <code>numTaps</code> is not a multiple of the interpolation factor <code>L</code>.
3525 */
3526
3527 arm_status arm_fir_interpolate_init_f32(
3528 arm_fir_interpolate_instance_f32 * S,
3529 uint8_t L,
3530 uint16_t numTaps,
3531 float32_t * pCoeffs,
3532 float32_t * pState,
3533 uint32_t blockSize);
3534
3535 /**
3536 * @brief Instance structure for the high precision Q31 Biquad cascade filter.
3537 */
3538
3539 typedef struct
3540 {
3541 uint8_t numStages; /**< number of 2nd order stages in the filter. Overall order is 2*numStages. */
3542 q63_t *pState; /**< points to the array of state coefficients. The array is of length 4*numStages. */
3543 q31_t *pCoeffs; /**< points to the array of coefficients. The array is of length 5*numStages. */
3544 uint8_t postShift; /**< additional shift, in bits, applied to each output sample. */
3545
3546 } arm_biquad_cas_df1_32x64_ins_q31;
3547
3548
3549 /**
3550 * @param[in] *S points to an instance of the high precision Q31 Biquad cascade filter structure.
3551 * @param[in] *pSrc points to the block of input data.
3552 * @param[out] *pDst points to the block of output data
3553 * @param[in] blockSize number of samples to process.
3554 * @return none.
3555 */
3556
3557 void arm_biquad_cas_df1_32x64_q31(
3558 const arm_biquad_cas_df1_32x64_ins_q31 * S,
3559 q31_t * pSrc,
3560 q31_t * pDst,
3561 uint32_t blockSize);
3562
3563
3564 /**
3565 * @param[in,out] *S points to an instance of the high precision Q31 Biquad cascade filter structure.
3566 * @param[in] numStages number of 2nd order stages in the filter.
3567 * @param[in] *pCoeffs points to the filter coefficients.
3568 * @param[in] *pState points to the state buffer.
3569 * @param[in] postShift shift to be applied to the output. Varies according to the coefficients format
3570 * @return none
3571 */
3572
3573 void arm_biquad_cas_df1_32x64_init_q31(
3574 arm_biquad_cas_df1_32x64_ins_q31 * S,
3575 uint8_t numStages,
3576 q31_t * pCoeffs,
3577 q63_t * pState,
3578 uint8_t postShift);
3579
3580
3581
3582 /**
3583 * @brief Instance structure for the floating-point transposed direct form II Biquad cascade filter.
3584 */
3585
3586 typedef struct
3587 {
3588 uint8_t numStages; /**< number of 2nd order stages in the filter. Overall order is 2*numStages. */
3589 float32_t *pState; /**< points to the array of state coefficients. The array is of length 2*numStages. */
3590 float32_t *pCoeffs; /**< points to the array of coefficients. The array is of length 5*numStages. */
3591 } arm_biquad_cascade_df2T_instance_f32;
3592
3593
3594 /**
3595 * @brief Processing function for the floating-point transposed direct form II Biquad cascade filter.
3596 * @param[in] *S points to an instance of the filter data structure.
3597 * @param[in] *pSrc points to the block of input data.
3598 * @param[out] *pDst points to the block of output data
3599 * @param[in] blockSize number of samples to process.
3600 * @return none.
3601 */
3602
3603 void arm_biquad_cascade_df2T_f32(
3604 const arm_biquad_cascade_df2T_instance_f32 * S,
3605 float32_t * pSrc,
3606 float32_t * pDst,
3607 uint32_t blockSize);
3608
3609
3610 /**
3611 * @brief Initialization function for the floating-point transposed direct form II Biquad cascade filter.
3612 * @param[in,out] *S points to an instance of the filter data structure.
3613 * @param[in] numStages number of 2nd order stages in the filter.
3614 * @param[in] *pCoeffs points to the filter coefficients.
3615 * @param[in] *pState points to the state buffer.
3616 * @return none
3617 */
3618
3619 void arm_biquad_cascade_df2T_init_f32(
3620 arm_biquad_cascade_df2T_instance_f32 * S,
3621 uint8_t numStages,
3622 float32_t * pCoeffs,
3623 float32_t * pState);
3624
3625
3626
3627 /**
3628 * @brief Instance structure for the Q15 FIR lattice filter.
3629 */
3630
3631 typedef struct
3632 {
3633 uint16_t numStages; /**< number of filter stages. */
3634 q15_t *pState; /**< points to the state variable array. The array is of length numStages. */
3635 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length numStages. */
3636 } arm_fir_lattice_instance_q15;
3637
3638 /**
3639 * @brief Instance structure for the Q31 FIR lattice filter.
3640 */
3641
3642 typedef struct
3643 {
3644 uint16_t numStages; /**< number of filter stages. */
3645 q31_t *pState; /**< points to the state variable array. The array is of length numStages. */
3646 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length numStages. */
3647 } arm_fir_lattice_instance_q31;
3648
3649 /**
3650 * @brief Instance structure for the floating-point FIR lattice filter.
3651 */
3652
3653 typedef struct
3654 {
3655 uint16_t numStages; /**< number of filter stages. */
3656 float32_t *pState; /**< points to the state variable array. The array is of length numStages. */
3657 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length numStages. */
3658 } arm_fir_lattice_instance_f32;
3659
3660 /**
3661 * @brief Initialization function for the Q15 FIR lattice filter.
3662 * @param[in] *S points to an instance of the Q15 FIR lattice structure.
3663 * @param[in] numStages number of filter stages.
3664 * @param[in] *pCoeffs points to the coefficient buffer. The array is of length numStages.
3665 * @param[in] *pState points to the state buffer. The array is of length numStages.
3666 * @return none.
3667 */
3668
3669 void arm_fir_lattice_init_q15(
3670 arm_fir_lattice_instance_q15 * S,
3671 uint16_t numStages,
3672 q15_t * pCoeffs,
3673 q15_t * pState);
3674
3675
3676 /**
3677 * @brief Processing function for the Q15 FIR lattice filter.
3678 * @param[in] *S points to an instance of the Q15 FIR lattice structure.
3679 * @param[in] *pSrc points to the block of input data.
3680 * @param[out] *pDst points to the block of output data.
3681 * @param[in] blockSize number of samples to process.
3682 * @return none.
3683 */
3684 void arm_fir_lattice_q15(
3685 const arm_fir_lattice_instance_q15 * S,
3686 q15_t * pSrc,
3687 q15_t * pDst,
3688 uint32_t blockSize);
3689
3690 /**
3691 * @brief Initialization function for the Q31 FIR lattice filter.
3692 * @param[in] *S points to an instance of the Q31 FIR lattice structure.
3693 * @param[in] numStages number of filter stages.
3694 * @param[in] *pCoeffs points to the coefficient buffer. The array is of length numStages.
3695 * @param[in] *pState points to the state buffer. The array is of length numStages.
3696 * @return none.
3697 */
3698
3699 void arm_fir_lattice_init_q31(
3700 arm_fir_lattice_instance_q31 * S,
3701 uint16_t numStages,
3702 q31_t * pCoeffs,
3703 q31_t * pState);
3704
3705
3706 /**
3707 * @brief Processing function for the Q31 FIR lattice filter.
3708 * @param[in] *S points to an instance of the Q31 FIR lattice structure.
3709 * @param[in] *pSrc points to the block of input data.
3710 * @param[out] *pDst points to the block of output data
3711 * @param[in] blockSize number of samples to process.
3712 * @return none.
3713 */
3714
3715 void arm_fir_lattice_q31(
3716 const arm_fir_lattice_instance_q31 * S,
3717 q31_t * pSrc,
3718 q31_t * pDst,
3719 uint32_t blockSize);
3720
3721 /**
3722 * @brief Initialization function for the floating-point FIR lattice filter.
3723 * @param[in] *S points to an instance of the floating-point FIR lattice structure.
3724 * @param[in] numStages number of filter stages.
3725 * @param[in] *pCoeffs points to the coefficient buffer. The array is of length numStages.
3726 * @param[in] *pState points to the state buffer. The array is of length numStages.
3727 * @return none.
3728 */
3729
3730 void arm_fir_lattice_init_f32(
3731 arm_fir_lattice_instance_f32 * S,
3732 uint16_t numStages,
3733 float32_t * pCoeffs,
3734 float32_t * pState);
3735
3736 /**
3737 * @brief Processing function for the floating-point FIR lattice filter.
3738 * @param[in] *S points to an instance of the floating-point FIR lattice structure.
3739 * @param[in] *pSrc points to the block of input data.
3740 * @param[out] *pDst points to the block of output data
3741 * @param[in] blockSize number of samples to process.
3742 * @return none.
3743 */
3744
3745 void arm_fir_lattice_f32(
3746 const arm_fir_lattice_instance_f32 * S,
3747 float32_t * pSrc,
3748 float32_t * pDst,
3749 uint32_t blockSize);
3750
3751 /**
3752 * @brief Instance structure for the Q15 IIR lattice filter.
3753 */
3754 typedef struct
3755 {
3756 uint16_t numStages; /**< number of stages in the filter. */
3757 q15_t *pState; /**< points to the state variable array. The array is of length numStages+blockSize. */
3758 q15_t *pkCoeffs; /**< points to the reflection coefficient array. The array is of length numStages. */
3759 q15_t *pvCoeffs; /**< points to the ladder coefficient array. The array is of length numStages+1. */
3760 } arm_iir_lattice_instance_q15;
3761
3762 /**
3763 * @brief Instance structure for the Q31 IIR lattice filter.
3764 */
3765 typedef struct
3766 {
3767 uint16_t numStages; /**< number of stages in the filter. */
3768 q31_t *pState; /**< points to the state variable array. The array is of length numStages+blockSize. */
3769 q31_t *pkCoeffs; /**< points to the reflection coefficient array. The array is of length numStages. */
3770 q31_t *pvCoeffs; /**< points to the ladder coefficient array. The array is of length numStages+1. */
3771 } arm_iir_lattice_instance_q31;
3772
3773 /**
3774 * @brief Instance structure for the floating-point IIR lattice filter.
3775 */
3776 typedef struct
3777 {
3778 uint16_t numStages; /**< number of stages in the filter. */
3779 float32_t *pState; /**< points to the state variable array. The array is of length numStages+blockSize. */
3780 float32_t *pkCoeffs; /**< points to the reflection coefficient array. The array is of length numStages. */
3781 float32_t *pvCoeffs; /**< points to the ladder coefficient array. The array is of length numStages+1. */
3782 } arm_iir_lattice_instance_f32;
3783
3784 /**
3785 * @brief Processing function for the floating-point IIR lattice filter.
3786 * @param[in] *S points to an instance of the floating-point IIR lattice structure.
3787 * @param[in] *pSrc points to the block of input data.
3788 * @param[out] *pDst points to the block of output data.
3789 * @param[in] blockSize number of samples to process.
3790 * @return none.
3791 */
3792
3793 void arm_iir_lattice_f32(
3794 const arm_iir_lattice_instance_f32 * S,
3795 float32_t * pSrc,
3796 float32_t * pDst,
3797 uint32_t blockSize);
3798
3799 /**
3800 * @brief Initialization function for the floating-point IIR lattice filter.
3801 * @param[in] *S points to an instance of the floating-point IIR lattice structure.
3802 * @param[in] numStages number of stages in the filter.
3803 * @param[in] *pkCoeffs points to the reflection coefficient buffer. The array is of length numStages.
3804 * @param[in] *pvCoeffs points to the ladder coefficient buffer. The array is of length numStages+1.
3805 * @param[in] *pState points to the state buffer. The array is of length numStages+blockSize-1.
3806 * @param[in] blockSize number of samples to process.
3807 * @return none.
3808 */
3809
3810 void arm_iir_lattice_init_f32(
3811 arm_iir_lattice_instance_f32 * S,
3812 uint16_t numStages,
3813 float32_t *pkCoeffs,
3814 float32_t *pvCoeffs,
3815 float32_t *pState,
3816 uint32_t blockSize);
3817
3818
3819 /**
3820 * @brief Processing function for the Q31 IIR lattice filter.
3821 * @param[in] *S points to an instance of the Q31 IIR lattice structure.
3822 * @param[in] *pSrc points to the block of input data.
3823 * @param[out] *pDst points to the block of output data.
3824 * @param[in] blockSize number of samples to process.
3825 * @return none.
3826 */
3827
3828 void arm_iir_lattice_q31(
3829 const arm_iir_lattice_instance_q31 * S,
3830 q31_t * pSrc,
3831 q31_t * pDst,
3832 uint32_t blockSize);
3833
3834
3835 /**
3836 * @brief Initialization function for the Q31 IIR lattice filter.
3837 * @param[in] *S points to an instance of the Q31 IIR lattice structure.
3838 * @param[in] numStages number of stages in the filter.
3839 * @param[in] *pkCoeffs points to the reflection coefficient buffer. The array is of length numStages.
3840 * @param[in] *pvCoeffs points to the ladder coefficient buffer. The array is of length numStages+1.
3841 * @param[in] *pState points to the state buffer. The array is of length numStages+blockSize.
3842 * @param[in] blockSize number of samples to process.
3843 * @return none.
3844 */
3845
3846 void arm_iir_lattice_init_q31(
3847 arm_iir_lattice_instance_q31 * S,
3848 uint16_t numStages,
3849 q31_t *pkCoeffs,
3850 q31_t *pvCoeffs,
3851 q31_t *pState,
3852 uint32_t blockSize);
3853
3854
3855 /**
3856 * @brief Processing function for the Q15 IIR lattice filter.
3857 * @param[in] *S points to an instance of the Q15 IIR lattice structure.
3858 * @param[in] *pSrc points to the block of input data.
3859 * @param[out] *pDst points to the block of output data.
3860 * @param[in] blockSize number of samples to process.
3861 * @return none.
3862 */
3863
3864 void arm_iir_lattice_q15(
3865 const arm_iir_lattice_instance_q15 * S,
3866 q15_t * pSrc,
3867 q15_t * pDst,
3868 uint32_t blockSize);
3869
3870
3871 /**
3872 * @brief Initialization function for the Q15 IIR lattice filter.
3873 * @param[in] *S points to an instance of the fixed-point Q15 IIR lattice structure.
3874 * @param[in] numStages number of stages in the filter.
3875 * @param[in] *pkCoeffs points to reflection coefficient buffer. The array is of length numStages.
3876 * @param[in] *pvCoeffs points to ladder coefficient buffer. The array is of length numStages+1.
3877 * @param[in] *pState points to state buffer. The array is of length numStages+blockSize.
3878 * @param[in] blockSize number of samples to process per call.
3879 * @return none.
3880 */
3881
3882 void arm_iir_lattice_init_q15(
3883 arm_iir_lattice_instance_q15 * S,
3884 uint16_t numStages,
3885 q15_t *pkCoeffs,
3886 q15_t *pvCoeffs,
3887 q15_t *pState,
3888 uint32_t blockSize);
3889
3890 /**
3891 * @brief Instance structure for the floating-point LMS filter.
3892 */
3893
3894 typedef struct
3895 {
3896 uint16_t numTaps; /**< number of coefficients in the filter. */
3897 float32_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
3898 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
3899 float32_t mu; /**< step size that controls filter coefficient updates. */
3900 } arm_lms_instance_f32;
3901
3902 /**
3903 * @brief Processing function for floating-point LMS filter.
3904 * @param[in] *S points to an instance of the floating-point LMS filter structure.
3905 * @param[in] *pSrc points to the block of input data.
3906 * @param[in] *pRef points to the block of reference data.
3907 * @param[out] *pOut points to the block of output data.
3908 * @param[out] *pErr points to the block of error data.
3909 * @param[in] blockSize number of samples to process.
3910 * @return none.
3911 */
3912
3913 void arm_lms_f32(
3914 const arm_lms_instance_f32 * S,
3915 float32_t * pSrc,
3916 float32_t * pRef,
3917 float32_t * pOut,
3918 float32_t * pErr,
3919 uint32_t blockSize);
3920
3921 /**
3922 * @brief Initialization function for floating-point LMS filter.
3923 * @param[in] *S points to an instance of the floating-point LMS filter structure.
3924 * @param[in] numTaps number of filter coefficients.
3925 * @param[in] *pCoeffs points to the coefficient buffer.
3926 * @param[in] *pState points to state buffer.
3927 * @param[in] mu step size that controls filter coefficient updates.
3928 * @param[in] blockSize number of samples to process.
3929 * @return none.
3930 */
3931
3932 void arm_lms_init_f32(
3933 arm_lms_instance_f32 * S,
3934 uint16_t numTaps,
3935 float32_t * pCoeffs,
3936 float32_t * pState,
3937 float32_t mu,
3938 uint32_t blockSize);
3939
3940 /**
3941 * @brief Instance structure for the Q15 LMS filter.
3942 */
3943
3944 typedef struct
3945 {
3946 uint16_t numTaps; /**< number of coefficients in the filter. */
3947 q15_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
3948 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
3949 q15_t mu; /**< step size that controls filter coefficient updates. */
3950 uint32_t postShift; /**< bit shift applied to coefficients. */
3951 } arm_lms_instance_q15;
3952
3953
3954 /**
3955 * @brief Initialization function for the Q15 LMS filter.
3956 * @param[in] *S points to an instance of the Q15 LMS filter structure.
3957 * @param[in] numTaps number of filter coefficients.
3958 * @param[in] *pCoeffs points to the coefficient buffer.
3959 * @param[in] *pState points to the state buffer.
3960 * @param[in] mu step size that controls filter coefficient updates.
3961 * @param[in] blockSize number of samples to process.
3962 * @param[in] postShift bit shift applied to coefficients.
3963 * @return none.
3964 */
3965
3966 void arm_lms_init_q15(
3967 arm_lms_instance_q15 * S,
3968 uint16_t numTaps,
3969 q15_t * pCoeffs,
3970 q15_t * pState,
3971 q15_t mu,
3972 uint32_t blockSize,
3973 uint32_t postShift);
3974
3975 /**
3976 * @brief Processing function for Q15 LMS filter.
3977 * @param[in] *S points to an instance of the Q15 LMS filter structure.
3978 * @param[in] *pSrc points to the block of input data.
3979 * @param[in] *pRef points to the block of reference data.
3980 * @param[out] *pOut points to the block of output data.
3981 * @param[out] *pErr points to the block of error data.
3982 * @param[in] blockSize number of samples to process.
3983 * @return none.
3984 */
3985
3986 void arm_lms_q15(
3987 const arm_lms_instance_q15 * S,
3988 q15_t * pSrc,
3989 q15_t * pRef,
3990 q15_t * pOut,
3991 q15_t * pErr,
3992 uint32_t blockSize);
3993
3994
3995 /**
3996 * @brief Instance structure for the Q31 LMS filter.
3997 */
3998
3999 typedef struct
4000 {
4001 uint16_t numTaps; /**< number of coefficients in the filter. */
4002 q31_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
4003 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
4004 q31_t mu; /**< step size that controls filter coefficient updates. */
4005 uint32_t postShift; /**< bit shift applied to coefficients. */
4006
4007 } arm_lms_instance_q31;
4008
4009 /**
4010 * @brief Processing function for Q31 LMS filter.
4011 * @param[in] *S points to an instance of the Q15 LMS filter structure.
4012 * @param[in] *pSrc points to the block of input data.
4013 * @param[in] *pRef points to the block of reference data.
4014 * @param[out] *pOut points to the block of output data.
4015 * @param[out] *pErr points to the block of error data.
4016 * @param[in] blockSize number of samples to process.
4017 * @return none.
4018 */
4019
4020 void arm_lms_q31(
4021 const arm_lms_instance_q31 * S,
4022 q31_t * pSrc,
4023 q31_t * pRef,
4024 q31_t * pOut,
4025 q31_t * pErr,
4026 uint32_t blockSize);
4027
4028 /**
4029 * @brief Initialization function for Q31 LMS filter.
4030 * @param[in] *S points to an instance of the Q31 LMS filter structure.
4031 * @param[in] numTaps number of filter coefficients.
4032 * @param[in] *pCoeffs points to coefficient buffer.
4033 * @param[in] *pState points to state buffer.
4034 * @param[in] mu step size that controls filter coefficient updates.
4035 * @param[in] blockSize number of samples to process.
4036 * @param[in] postShift bit shift applied to coefficients.
4037 * @return none.
4038 */
4039
4040 void arm_lms_init_q31(
4041 arm_lms_instance_q31 * S,
4042 uint16_t numTaps,
4043 q31_t *pCoeffs,
4044 q31_t *pState,
4045 q31_t mu,
4046 uint32_t blockSize,
4047 uint32_t postShift);
4048
4049 /**
4050 * @brief Instance structure for the floating-point normalized LMS filter.
4051 */
4052
4053 typedef struct
4054 {
4055 uint16_t numTaps; /**< number of coefficients in the filter. */
4056 float32_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
4057 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
4058 float32_t mu; /**< step size that control filter coefficient updates. */
4059 float32_t energy; /**< saves previous frame energy. */
4060 float32_t x0; /**< saves previous input sample. */
4061 } arm_lms_norm_instance_f32;
4062
4063 /**
4064 * @brief Processing function for floating-point normalized LMS filter.
4065 * @param[in] *S points to an instance of the floating-point normalized LMS filter structure.
4066 * @param[in] *pSrc points to the block of input data.
4067 * @param[in] *pRef points to the block of reference data.
4068 * @param[out] *pOut points to the block of output data.
4069 * @param[out] *pErr points to the block of error data.
4070 * @param[in] blockSize number of samples to process.
4071 * @return none.
4072 */
4073
4074 void arm_lms_norm_f32(
4075 arm_lms_norm_instance_f32 * S,
4076 float32_t * pSrc,
4077 float32_t * pRef,
4078 float32_t * pOut,
4079 float32_t * pErr,
4080 uint32_t blockSize);
4081
4082 /**
4083 * @brief Initialization function for floating-point normalized LMS filter.
4084 * @param[in] *S points to an instance of the floating-point LMS filter structure.
4085 * @param[in] numTaps number of filter coefficients.
4086 * @param[in] *pCoeffs points to coefficient buffer.
4087 * @param[in] *pState points to state buffer.
4088 * @param[in] mu step size that controls filter coefficient updates.
4089 * @param[in] blockSize number of samples to process.
4090 * @return none.
4091 */
4092
4093 void arm_lms_norm_init_f32(
4094 arm_lms_norm_instance_f32 * S,
4095 uint16_t numTaps,
4096 float32_t * pCoeffs,
4097 float32_t * pState,
4098 float32_t mu,
4099 uint32_t blockSize);
4100
4101
4102 /**
4103 * @brief Instance structure for the Q31 normalized LMS filter.
4104 */
4105 typedef struct
4106 {
4107 uint16_t numTaps; /**< number of coefficients in the filter. */
4108 q31_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
4109 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
4110 q31_t mu; /**< step size that controls filter coefficient updates. */
4111 uint8_t postShift; /**< bit shift applied to coefficients. */
4112 q31_t *recipTable; /**< points to the reciprocal initial value table. */
4113 q31_t energy; /**< saves previous frame energy. */
4114 q31_t x0; /**< saves previous input sample. */
4115 } arm_lms_norm_instance_q31;
4116
4117 /**
4118 * @brief Processing function for Q31 normalized LMS filter.
4119 * @param[in] *S points to an instance of the Q31 normalized LMS filter structure.
4120 * @param[in] *pSrc points to the block of input data.
4121 * @param[in] *pRef points to the block of reference data.
4122 * @param[out] *pOut points to the block of output data.
4123 * @param[out] *pErr points to the block of error data.
4124 * @param[in] blockSize number of samples to process.
4125 * @return none.
4126 */
4127
4128 void arm_lms_norm_q31(
4129 arm_lms_norm_instance_q31 * S,
4130 q31_t * pSrc,
4131 q31_t * pRef,
4132 q31_t * pOut,
4133 q31_t * pErr,
4134 uint32_t blockSize);
4135
4136 /**
4137 * @brief Initialization function for Q31 normalized LMS filter.
4138 * @param[in] *S points to an instance of the Q31 normalized LMS filter structure.
4139 * @param[in] numTaps number of filter coefficients.
4140 * @param[in] *pCoeffs points to coefficient buffer.
4141 * @param[in] *pState points to state buffer.
4142 * @param[in] mu step size that controls filter coefficient updates.
4143 * @param[in] blockSize number of samples to process.
4144 * @param[in] postShift bit shift applied to coefficients.
4145 * @return none.
4146 */
4147
4148 void arm_lms_norm_init_q31(
4149 arm_lms_norm_instance_q31 * S,
4150 uint16_t numTaps,
4151 q31_t * pCoeffs,
4152 q31_t * pState,
4153 q31_t mu,
4154 uint32_t blockSize,
4155 uint8_t postShift);
4156
4157 /**
4158 * @brief Instance structure for the Q15 normalized LMS filter.
4159 */
4160
4161 typedef struct
4162 {
4163 uint16_t numTaps; /**< Number of coefficients in the filter. */
4164 q15_t *pState; /**< points to the state variable array. The array is of length numTaps+blockSize-1. */
4165 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps. */
4166 q15_t mu; /**< step size that controls filter coefficient updates. */
4167 uint8_t postShift; /**< bit shift applied to coefficients. */
4168 q15_t *recipTable; /**< Points to the reciprocal initial value table. */
4169 q15_t energy; /**< saves previous frame energy. */
4170 q15_t x0; /**< saves previous input sample. */
4171 } arm_lms_norm_instance_q15;
4172
4173 /**
4174 * @brief Processing function for Q15 normalized LMS filter.
4175 * @param[in] *S points to an instance of the Q15 normalized LMS filter structure.
4176 * @param[in] *pSrc points to the block of input data.
4177 * @param[in] *pRef points to the block of reference data.
4178 * @param[out] *pOut points to the block of output data.
4179 * @param[out] *pErr points to the block of error data.
4180 * @param[in] blockSize number of samples to process.
4181 * @return none.
4182 */
4183
4184 void arm_lms_norm_q15(
4185 arm_lms_norm_instance_q15 * S,
4186 q15_t * pSrc,
4187 q15_t * pRef,
4188 q15_t * pOut,
4189 q15_t * pErr,
4190 uint32_t blockSize);
4191
4192
4193 /**
4194 * @brief Initialization function for Q15 normalized LMS filter.
4195 * @param[in] *S points to an instance of the Q15 normalized LMS filter structure.
4196 * @param[in] numTaps number of filter coefficients.
4197 * @param[in] *pCoeffs points to coefficient buffer.
4198 * @param[in] *pState points to state buffer.
4199 * @param[in] mu step size that controls filter coefficient updates.
4200 * @param[in] blockSize number of samples to process.
4201 * @param[in] postShift bit shift applied to coefficients.
4202 * @return none.
4203 */
4204
4205 void arm_lms_norm_init_q15(
4206 arm_lms_norm_instance_q15 * S,
4207 uint16_t numTaps,
4208 q15_t * pCoeffs,
4209 q15_t * pState,
4210 q15_t mu,
4211 uint32_t blockSize,
4212 uint8_t postShift);
4213
4214 /**
4215 * @brief Correlation of floating-point sequences.
4216 * @param[in] *pSrcA points to the first input sequence.
4217 * @param[in] srcALen length of the first input sequence.
4218 * @param[in] *pSrcB points to the second input sequence.
4219 * @param[in] srcBLen length of the second input sequence.
4220 * @param[out] *pDst points to the block of output data Length 2 * max(srcALen, srcBLen) - 1.
4221 * @return none.
4222 */
4223
4224 void arm_correlate_f32(
4225 float32_t * pSrcA,
4226 uint32_t srcALen,
4227 float32_t * pSrcB,
4228 uint32_t srcBLen,
4229 float32_t * pDst);
4230
4231 /**
4232 * @brief Correlation of Q15 sequences.
4233 * @param[in] *pSrcA points to the first input sequence.
4234 * @param[in] srcALen length of the first input sequence.
4235 * @param[in] *pSrcB points to the second input sequence.
4236 * @param[in] srcBLen length of the second input sequence.
4237 * @param[out] *pDst points to the block of output data Length 2 * max(srcALen, srcBLen) - 1.
4238 * @return none.
4239 */
4240
4241 void arm_correlate_q15(
4242 q15_t * pSrcA,
4243 uint32_t srcALen,
4244 q15_t * pSrcB,
4245 uint32_t srcBLen,
4246 q15_t * pDst);
4247
4248 /**
4249 * @brief Correlation of Q15 sequences (fast version) for Cortex-M3 and Cortex-M4.
4250 * @param[in] *pSrcA points to the first input sequence.
4251 * @param[in] srcALen length of the first input sequence.
4252 * @param[in] *pSrcB points to the second input sequence.
4253 * @param[in] srcBLen length of the second input sequence.
4254 * @param[out] *pDst points to the block of output data Length 2 * max(srcALen, srcBLen) - 1.
4255 * @return none.
4256 */
4257
4258 void arm_correlate_fast_q15(
4259 q15_t * pSrcA,
4260 uint32_t srcALen,
4261 q15_t * pSrcB,
4262 uint32_t srcBLen,
4263 q15_t * pDst);
4264
4265 /**
4266 * @brief Correlation of Q31 sequences.
4267 * @param[in] *pSrcA points to the first input sequence.
4268 * @param[in] srcALen length of the first input sequence.
4269 * @param[in] *pSrcB points to the second input sequence.
4270 * @param[in] srcBLen length of the second input sequence.
4271 * @param[out] *pDst points to the block of output data Length 2 * max(srcALen, srcBLen) - 1.
4272 * @return none.
4273 */
4274
4275 void arm_correlate_q31(
4276 q31_t * pSrcA,
4277 uint32_t srcALen,
4278 q31_t * pSrcB,
4279 uint32_t srcBLen,
4280 q31_t * pDst);
4281
4282 /**
4283 * @brief Correlation of Q31 sequences (fast version) for Cortex-M3 and Cortex-M4
4284 * @param[in] *pSrcA points to the first input sequence.
4285 * @param[in] srcALen length of the first input sequence.
4286 * @param[in] *pSrcB points to the second input sequence.
4287 * @param[in] srcBLen length of the second input sequence.
4288 * @param[out] *pDst points to the block of output data Length 2 * max(srcALen, srcBLen) - 1.
4289 * @return none.
4290 */
4291
4292 void arm_correlate_fast_q31(
4293 q31_t * pSrcA,
4294 uint32_t srcALen,
4295 q31_t * pSrcB,
4296 uint32_t srcBLen,
4297 q31_t * pDst);
4298
4299 /**
4300 * @brief Correlation of Q7 sequences.
4301 * @param[in] *pSrcA points to the first input sequence.
4302 * @param[in] srcALen length of the first input sequence.
4303 * @param[in] *pSrcB points to the second input sequence.
4304 * @param[in] srcBLen length of the second input sequence.
4305 * @param[out] *pDst points to the block of output data Length 2 * max(srcALen, srcBLen) - 1.
4306 * @return none.
4307 */
4308
4309 void arm_correlate_q7(
4310 q7_t * pSrcA,
4311 uint32_t srcALen,
4312 q7_t * pSrcB,
4313 uint32_t srcBLen,
4314 q7_t * pDst);
4315
4316 /**
4317 * @brief Instance structure for the floating-point sparse FIR filter.
4318 */
4319 typedef struct
4320 {
4321 uint16_t numTaps; /**< number of coefficients in the filter. */
4322 uint16_t stateIndex; /**< state buffer index. Points to the oldest sample in the state buffer. */
4323 float32_t *pState; /**< points to the state buffer array. The array is of length maxDelay+blockSize-1. */
4324 float32_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
4325 uint16_t maxDelay; /**< maximum offset specified by the pTapDelay array. */
4326 int32_t *pTapDelay; /**< points to the array of delay values. The array is of length numTaps. */
4327 } arm_fir_sparse_instance_f32;
4328
4329 /**
4330 * @brief Instance structure for the Q31 sparse FIR filter.
4331 */
4332
4333 typedef struct
4334 {
4335 uint16_t numTaps; /**< number of coefficients in the filter. */
4336 uint16_t stateIndex; /**< state buffer index. Points to the oldest sample in the state buffer. */
4337 q31_t *pState; /**< points to the state buffer array. The array is of length maxDelay+blockSize-1. */
4338 q31_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
4339 uint16_t maxDelay; /**< maximum offset specified by the pTapDelay array. */
4340 int32_t *pTapDelay; /**< points to the array of delay values. The array is of length numTaps. */
4341 } arm_fir_sparse_instance_q31;
4342
4343 /**
4344 * @brief Instance structure for the Q15 sparse FIR filter.
4345 */
4346
4347 typedef struct
4348 {
4349 uint16_t numTaps; /**< number of coefficients in the filter. */
4350 uint16_t stateIndex; /**< state buffer index. Points to the oldest sample in the state buffer. */
4351 q15_t *pState; /**< points to the state buffer array. The array is of length maxDelay+blockSize-1. */
4352 q15_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
4353 uint16_t maxDelay; /**< maximum offset specified by the pTapDelay array. */
4354 int32_t *pTapDelay; /**< points to the array of delay values. The array is of length numTaps. */
4355 } arm_fir_sparse_instance_q15;
4356
4357 /**
4358 * @brief Instance structure for the Q7 sparse FIR filter.
4359 */
4360
4361 typedef struct
4362 {
4363 uint16_t numTaps; /**< number of coefficients in the filter. */
4364 uint16_t stateIndex; /**< state buffer index. Points to the oldest sample in the state buffer. */
4365 q7_t *pState; /**< points to the state buffer array. The array is of length maxDelay+blockSize-1. */
4366 q7_t *pCoeffs; /**< points to the coefficient array. The array is of length numTaps.*/
4367 uint16_t maxDelay; /**< maximum offset specified by the pTapDelay array. */
4368 int32_t *pTapDelay; /**< points to the array of delay values. The array is of length numTaps. */
4369 } arm_fir_sparse_instance_q7;
4370
4371 /**
4372 * @brief Processing function for the floating-point sparse FIR filter.
4373 * @param[in] *S points to an instance of the floating-point sparse FIR structure.
4374 * @param[in] *pSrc points to the block of input data.
4375 * @param[out] *pDst points to the block of output data
4376 * @param[in] *pScratchIn points to a temporary buffer of size blockSize.
4377 * @param[in] blockSize number of input samples to process per call.
4378 * @return none.
4379 */
4380
4381 void arm_fir_sparse_f32(
4382 arm_fir_sparse_instance_f32 * S,
4383 float32_t * pSrc,
4384 float32_t * pDst,
4385 float32_t * pScratchIn,
4386 uint32_t blockSize);
4387
4388 /**
4389 * @brief Initialization function for the floating-point sparse FIR filter.
4390 * @param[in,out] *S points to an instance of the floating-point sparse FIR structure.
4391 * @param[in] numTaps number of nonzero coefficients in the filter.
4392 * @param[in] *pCoeffs points to the array of filter coefficients.
4393 * @param[in] *pState points to the state buffer.
4394 * @param[in] *pTapDelay points to the array of offset times.
4395 * @param[in] maxDelay maximum offset time supported.
4396 * @param[in] blockSize number of samples that will be processed per block.
4397 * @return none
4398 */
4399
4400 void arm_fir_sparse_init_f32(
4401 arm_fir_sparse_instance_f32 * S,
4402 uint16_t numTaps,
4403 float32_t * pCoeffs,
4404 float32_t * pState,
4405 int32_t * pTapDelay,
4406 uint16_t maxDelay,
4407 uint32_t blockSize);
4408
4409 /**
4410 * @brief Processing function for the Q31 sparse FIR filter.
4411 * @param[in] *S points to an instance of the Q31 sparse FIR structure.
4412 * @param[in] *pSrc points to the block of input data.
4413 * @param[out] *pDst points to the block of output data
4414 * @param[in] *pScratchIn points to a temporary buffer of size blockSize.
4415 * @param[in] blockSize number of input samples to process per call.
4416 * @return none.
4417 */
4418
4419 void arm_fir_sparse_q31(
4420 arm_fir_sparse_instance_q31 * S,
4421 q31_t * pSrc,
4422 q31_t * pDst,
4423 q31_t * pScratchIn,
4424 uint32_t blockSize);
4425
4426 /**
4427 * @brief Initialization function for the Q31 sparse FIR filter.
4428 * @param[in,out] *S points to an instance of the Q31 sparse FIR structure.
4429 * @param[in] numTaps number of nonzero coefficients in the filter.
4430 * @param[in] *pCoeffs points to the array of filter coefficients.
4431 * @param[in] *pState points to the state buffer.
4432 * @param[in] *pTapDelay points to the array of offset times.
4433 * @param[in] maxDelay maximum offset time supported.
4434 * @param[in] blockSize number of samples that will be processed per block.
4435 * @return none
4436 */
4437
4438 void arm_fir_sparse_init_q31(
4439 arm_fir_sparse_instance_q31 * S,
4440 uint16_t numTaps,
4441 q31_t * pCoeffs,
4442 q31_t * pState,
4443 int32_t * pTapDelay,
4444 uint16_t maxDelay,
4445 uint32_t blockSize);
4446
4447 /**
4448 * @brief Processing function for the Q15 sparse FIR filter.
4449 * @param[in] *S points to an instance of the Q15 sparse FIR structure.
4450 * @param[in] *pSrc points to the block of input data.
4451 * @param[out] *pDst points to the block of output data
4452 * @param[in] *pScratchIn points to a temporary buffer of size blockSize.
4453 * @param[in] *pScratchOut points to a temporary buffer of size blockSize.
4454 * @param[in] blockSize number of input samples to process per call.
4455 * @return none.
4456 */
4457
4458 void arm_fir_sparse_q15(
4459 arm_fir_sparse_instance_q15 * S,
4460 q15_t * pSrc,
4461 q15_t * pDst,
4462 q15_t * pScratchIn,
4463 q31_t * pScratchOut,
4464 uint32_t blockSize);
4465
4466
4467 /**
4468 * @brief Initialization function for the Q15 sparse FIR filter.
4469 * @param[in,out] *S points to an instance of the Q15 sparse FIR structure.
4470 * @param[in] numTaps number of nonzero coefficients in the filter.
4471 * @param[in] *pCoeffs points to the array of filter coefficients.
4472 * @param[in] *pState points to the state buffer.
4473 * @param[in] *pTapDelay points to the array of offset times.
4474 * @param[in] maxDelay maximum offset time supported.
4475 * @param[in] blockSize number of samples that will be processed per block.
4476 * @return none
4477 */
4478
4479 void arm_fir_sparse_init_q15(
4480 arm_fir_sparse_instance_q15 * S,
4481 uint16_t numTaps,
4482 q15_t * pCoeffs,
4483 q15_t * pState,
4484 int32_t * pTapDelay,
4485 uint16_t maxDelay,
4486 uint32_t blockSize);
4487
4488 /**
4489 * @brief Processing function for the Q7 sparse FIR filter.
4490 * @param[in] *S points to an instance of the Q7 sparse FIR structure.
4491 * @param[in] *pSrc points to the block of input data.
4492 * @param[out] *pDst points to the block of output data
4493 * @param[in] *pScratchIn points to a temporary buffer of size blockSize.
4494 * @param[in] *pScratchOut points to a temporary buffer of size blockSize.
4495 * @param[in] blockSize number of input samples to process per call.
4496 * @return none.
4497 */
4498
4499 void arm_fir_sparse_q7(
4500 arm_fir_sparse_instance_q7 * S,
4501 q7_t * pSrc,
4502 q7_t * pDst,
4503 q7_t * pScratchIn,
4504 q31_t * pScratchOut,
4505 uint32_t blockSize);
4506
4507 /**
4508 * @brief Initialization function for the Q7 sparse FIR filter.
4509 * @param[in,out] *S points to an instance of the Q7 sparse FIR structure.
4510 * @param[in] numTaps number of nonzero coefficients in the filter.
4511 * @param[in] *pCoeffs points to the array of filter coefficients.
4512 * @param[in] *pState points to the state buffer.
4513 * @param[in] *pTapDelay points to the array of offset times.
4514 * @param[in] maxDelay maximum offset time supported.
4515 * @param[in] blockSize number of samples that will be processed per block.
4516 * @return none
4517 */
4518
4519 void arm_fir_sparse_init_q7(
4520 arm_fir_sparse_instance_q7 * S,
4521 uint16_t numTaps,
4522 q7_t * pCoeffs,
4523 q7_t * pState,
4524 int32_t *pTapDelay,
4525 uint16_t maxDelay,
4526 uint32_t blockSize);
4527
4528
4529 /*
4530 * @brief Floating-point sin_cos function.
4531 * @param[in] theta input value in degrees
4532 * @param[out] *pSinVal points to the processed sine output.
4533 * @param[out] *pCosVal points to the processed cos output.
4534 * @return none.
4535 */
4536
4537 void arm_sin_cos_f32(
4538 float32_t theta,
4539 float32_t *pSinVal,
4540 float32_t *pCcosVal);
4541
4542 /*
4543 * @brief Q31 sin_cos function.
4544 * @param[in] theta scaled input value in degrees
4545 * @param[out] *pSinVal points to the processed sine output.
4546 * @param[out] *pCosVal points to the processed cosine output.
4547 * @return none.
4548 */
4549
4550 void arm_sin_cos_q31(
4551 q31_t theta,
4552 q31_t *pSinVal,
4553 q31_t *pCosVal);
4554
4555
4556 /**
4557 * @brief Floating-point complex conjugate.
4558 * @param[in] *pSrc points to the input vector
4559 * @param[out] *pDst points to the output vector
4560 * @param[in] numSamples number of complex samples in each vector
4561 * @return none.
4562 */
4563
4564 void arm_cmplx_conj_f32(
4565 float32_t * pSrc,
4566 float32_t * pDst,
4567 uint32_t numSamples);
4568
4569 /**
4570 * @brief Q31 complex conjugate.
4571 * @param[in] *pSrc points to the input vector
4572 * @param[out] *pDst points to the output vector
4573 * @param[in] numSamples number of complex samples in each vector
4574 * @return none.
4575 */
4576
4577 void arm_cmplx_conj_q31(
4578 q31_t * pSrc,
4579 q31_t * pDst,
4580 uint32_t numSamples);
4581
4582 /**
4583 * @brief Q15 complex conjugate.
4584 * @param[in] *pSrc points to the input vector
4585 * @param[out] *pDst points to the output vector
4586 * @param[in] numSamples number of complex samples in each vector
4587 * @return none.
4588 */
4589
4590 void arm_cmplx_conj_q15(
4591 q15_t * pSrc,
4592 q15_t * pDst,
4593 uint32_t numSamples);
4594
4595
4596
4597 /**
4598 * @brief Floating-point complex magnitude squared
4599 * @param[in] *pSrc points to the complex input vector
4600 * @param[out] *pDst points to the real output vector
4601 * @param[in] numSamples number of complex samples in the input vector
4602 * @return none.
4603 */
4604
4605 void arm_cmplx_mag_squared_f32(
4606 float32_t * pSrc,
4607 float32_t * pDst,
4608 uint32_t numSamples);
4609
4610 /**
4611 * @brief Q31 complex magnitude squared
4612 * @param[in] *pSrc points to the complex input vector
4613 * @param[out] *pDst points to the real output vector
4614 * @param[in] numSamples number of complex samples in the input vector
4615 * @return none.
4616 */
4617
4618 void arm_cmplx_mag_squared_q31(
4619 q31_t * pSrc,
4620 q31_t * pDst,
4621 uint32_t numSamples);
4622
4623 /**
4624 * @brief Q15 complex magnitude squared
4625 * @param[in] *pSrc points to the complex input vector
4626 * @param[out] *pDst points to the real output vector
4627 * @param[in] numSamples number of complex samples in the input vector
4628 * @return none.
4629 */
4630
4631 void arm_cmplx_mag_squared_q15(
4632 q15_t * pSrc,
4633 q15_t * pDst,
4634 uint32_t numSamples);
4635
4636
4637 /**
4638 * @ingroup groupController
4639 */
4640
4641 /**
4642 * @defgroup PID PID Motor Control
4643 *
4644 * A Proportional Integral Derivative (PID) controller is a generic feedback control
4645 * loop mechanism widely used in industrial control systems.
4646 * A PID controller is the most commonly used type of feedback controller.
4647 *
4648 * This set of functions implements (PID) controllers
4649 * for Q15, Q31, and floating-point data types. The functions operate on a single sample
4650 * of data and each call to the function returns a single processed value.
4651 * <code>S</code> points to an instance of the PID control data structure. <code>in</code>
4652 * is the input sample value. The functions return the output value.
4653 *
4654 * \par Algorithm:
4655 * <pre>
4656 * y[n] = y[n-1] + A0 * x[n] + A1 * x[n-1] + A2 * x[n-2]
4657 * A0 = Kp + Ki + Kd
4658 * A1 = (-Kp ) - (2 * Kd )
4659 * A2 = Kd </pre>
4660 *
4661 * \par
4662 * where \c Kp is proportional constant, \c Ki is Integral constant and \c Kd is Derivative constant
4663 *
4664 * \par
4665 * \image html PID.gif "Proportional Integral Derivative Controller"
4666 *
4667 * \par
4668 * The PID controller calculates an "error" value as the difference between
4669 * the measured output and the reference input.
4670 * The controller attempts to minimize the error by adjusting the process control inputs.
4671 * The proportional value determines the reaction to the current error,
4672 * the integral value determines the reaction based on the sum of recent errors,
4673 * and the derivative value determines the reaction based on the rate at which the error has been changing.
4674 *
4675 * \par Instance Structure
4676 * The Gains A0, A1, A2 and state variables for a PID controller are stored together in an instance data structure.
4677 * A separate instance structure must be defined for each PID Controller.
4678 * There are separate instance structure declarations for each of the 3 supported data types.
4679 *
4680 * \par Reset Functions
4681 * There is also an associated reset function for each data type which clears the state array.
4682 *
4683 * \par Initialization Functions
4684 * There is also an associated initialization function for each data type.
4685 * The initialization function performs the following operations:
4686 * - Initializes the Gains A0, A1, A2 from Kp,Ki, Kd gains.
4687 * - Zeros out the values in the state buffer.
4688 *
4689 * \par
4690 * Instance structure cannot be placed into a const data section and it is recommended to use the initialization function.
4691 *
4692 * \par Fixed-Point Behavior
4693 * Care must be taken when using the fixed-point versions of the PID Controller functions.
4694 * In particular, the overflow and saturation behavior of the accumulator used in each function must be considered.
4695 * Refer to the function specific documentation below for usage guidelines.
4696 */
4697
4698 /**
4699 * @addtogroup PID
4700 * @{
4701 */
4702
4703 /**
4704 * @brief Process function for the floating-point PID Control.
4705 * @param[in,out] *S is an instance of the floating-point PID Control structure
4706 * @param[in] in input sample to process
4707 * @return out processed output sample.
4708 */
4709
4710
4711 static __INLINE float32_t arm_pid_f32(
4712 arm_pid_instance_f32 * S,
4713 float32_t in)
4714 {
4715 float32_t out;
4716
4717 /* y[n] = y[n-1] + A0 * x[n] + A1 * x[n-1] + A2 * x[n-2] */
4718 out = (S->A0 * in) +
4719 (S->A1 * S->state[0]) + (S->A2 * S->state[1]) + (S->state[2]);
4720
4721 /* Update state */
4722 S->state[1] = S->state[0];
4723 S->state[0] = in;
4724 S->state[2] = out;
4725
4726 /* return to application */
4727 return (out);
4728
4729 }
4730
4731 /**
4732 * @brief Process function for the Q31 PID Control.
4733 * @param[in,out] *S points to an instance of the Q31 PID Control structure
4734 * @param[in] in input sample to process
4735 * @return out processed output sample.
4736 *
4737 * <b>Scaling and Overflow Behavior:</b>
4738 * \par
4739 * The function is implemented using an internal 64-bit accumulator.
4740 * The accumulator has a 2.62 format and maintains full precision of the intermediate multiplication results but provides only a single guard bit.
4741 * Thus, if the accumulator result overflows it wraps around rather than clip.
4742 * In order to avoid overflows completely the input signal must be scaled down by 2 bits as there are four additions.
4743 * After all multiply-accumulates are performed, the 2.62 accumulator is truncated to 1.32 format and then saturated to 1.31 format.
4744 */
4745
4746 static __INLINE q31_t arm_pid_q31(
4747 arm_pid_instance_q31 * S,
4748 q31_t in)
4749 {
4750 q63_t acc;
4751 q31_t out;
4752
4753 /* acc = A0 * x[n] */
4754 acc = (q63_t) S->A0 * in;
4755
4756 /* acc += A1 * x[n-1] */
4757 acc += (q63_t) S->A1 * S->state[0];
4758
4759 /* acc += A2 * x[n-2] */
4760 acc += (q63_t) S->A2 * S->state[1];
4761
4762 /* convert output to 1.31 format to add y[n-1] */
4763 out = (q31_t) (acc >> 31u);
4764
4765 /* out += y[n-1] */
4766 out += S->state[2];
4767
4768 /* Update state */
4769 S->state[1] = S->state[0];
4770 S->state[0] = in;
4771 S->state[2] = out;
4772
4773 /* return to application */
4774 return (out);
4775
4776 }
4777
4778 /**
4779 * @brief Process function for the Q15 PID Control.
4780 * @param[in,out] *S points to an instance of the Q15 PID Control structure
4781 * @param[in] in input sample to process
4782 * @return out processed output sample.
4783 *
4784 * <b>Scaling and Overflow Behavior:</b>
4785 * \par
4786 * The function is implemented using a 64-bit internal accumulator.
4787 * Both Gains and state variables are represented in 1.15 format and multiplications yield a 2.30 result.
4788 * The 2.30 intermediate results are accumulated in a 64-bit accumulator in 34.30 format.
4789 * There is no risk of internal overflow with this approach and the full precision of intermediate multiplications is preserved.
4790 * After all additions have been performed, the accumulator is truncated to 34.15 format by discarding low 15 bits.
4791 * Lastly, the accumulator is saturated to yield a result in 1.15 format.
4792 */
4793
4794 static __INLINE q15_t arm_pid_q15(
4795 arm_pid_instance_q15 * S,
4796 q15_t in)
4797 {
4798 q63_t acc;
4799 q15_t out;
4800
4801 /* Implementation of PID controller */
4802
4803 #ifdef ARM_MATH_CM0
4804
4805 /* acc = A0 * x[n] */
4806 acc = ((q31_t) S->A0 )* in ;
4807
4808 #else
4809
4810 /* acc = A0 * x[n] */
4811 acc = (q31_t) __SMUAD(S->A0, in);
4812
4813 #endif
4814
4815 #ifdef ARM_MATH_CM0
4816
4817 /* acc += A1 * x[n-1] + A2 * x[n-2] */
4818 acc += (q31_t) S->A1 * S->state[0] ;
4819 acc += (q31_t) S->A2 * S->state[1] ;
4820
4821 #else
4822
4823 /* acc += A1 * x[n-1] + A2 * x[n-2] */
4824 acc = __SMLALD(S->A1, (q31_t)__SIMD32(S->state), acc);
4825
4826 #endif
4827
4828 /* acc += y[n-1] */
4829 acc += (q31_t) S->state[2] << 15;
4830
4831 /* saturate the output */
4832 out = (q15_t) (__SSAT((acc >> 15), 16));
4833
4834 /* Update state */
4835 S->state[1] = S->state[0];
4836 S->state[0] = in;
4837 S->state[2] = out;
4838
4839 /* return to application */
4840 return (out);
4841
4842 }
4843
4844 /**
4845 * @} end of PID group
4846 */
4847
4848
4849 /**
4850 * @brief Floating-point matrix inverse.
4851 * @param[in] *src points to the instance of the input floating-point matrix structure.
4852 * @param[out] *dst points to the instance of the output floating-point matrix structure.
4853 * @return The function returns ARM_MATH_SIZE_MISMATCH, if the dimensions do not match.
4854 * If the input matrix is singular (does not have an inverse), then the algorithm terminates and returns error status ARM_MATH_SINGULAR.
4855 */
4856
4857 arm_status arm_mat_inverse_f32(
4858 const arm_matrix_instance_f32 * src,
4859 arm_matrix_instance_f32 * dst);
4860
4861
4862
4863 /**
4864 * @ingroup groupController
4865 */
4866
4867
4868 /**
4869 * @defgroup clarke Vector Clarke Transform
4870 * Forward Clarke transform converts the instantaneous stator phases into a two-coordinate time invariant vector.
4871 * Generally the Clarke transform uses three-phase currents <code>Ia, Ib and Ic</code> to calculate currents
4872 * in the two-phase orthogonal stator axis <code>Ialpha</code> and <code>Ibeta</code>.
4873 * When <code>Ialpha</code> is superposed with <code>Ia</code> as shown in the figure below
4874 * \image html clarke.gif Stator current space vector and its components in (a,b).
4875 * and <code>Ia + Ib + Ic = 0</code>, in this condition <code>Ialpha</code> and <code>Ibeta</code>
4876 * can be calculated using only <code>Ia</code> and <code>Ib</code>.
4877 *
4878 * The function operates on a single sample of data and each call to the function returns the processed output.
4879 * The library provides separate functions for Q31 and floating-point data types.
4880 * \par Algorithm
4881 * \image html clarkeFormula.gif
4882 * where <code>Ia</code> and <code>Ib</code> are the instantaneous stator phases and
4883 * <code>pIalpha</code> and <code>pIbeta</code> are the two coordinates of time invariant vector.
4884 * \par Fixed-Point Behavior
4885 * Care must be taken when using the Q31 version of the Clarke transform.
4886 * In particular, the overflow and saturation behavior of the accumulator used must be considered.
4887 * Refer to the function specific documentation below for usage guidelines.
4888 */
4889
4890 /**
4891 * @addtogroup clarke
4892 * @{
4893 */
4894
4895 /**
4896 *
4897 * @brief Floating-point Clarke transform
4898 * @param[in] Ia input three-phase coordinate <code>a</code>
4899 * @param[in] Ib input three-phase coordinate <code>b</code>
4900 * @param[out] *pIalpha points to output two-phase orthogonal vector axis alpha
4901 * @param[out] *pIbeta points to output two-phase orthogonal vector axis beta
4902 * @return none.
4903 */
4904
4905 static __INLINE void arm_clarke_f32(
4906 float32_t Ia,
4907 float32_t Ib,
4908 float32_t * pIalpha,
4909 float32_t * pIbeta)
4910 {
4911 /* Calculate pIalpha using the equation, pIalpha = Ia */
4912 *pIalpha = Ia;
4913
4914 /* Calculate pIbeta using the equation, pIbeta = (1/sqrt(3)) * Ia + (2/sqrt(3)) * Ib */
4915 *pIbeta = ((float32_t) 0.57735026919 * Ia + (float32_t) 1.15470053838 * Ib);
4916
4917 }
4918
4919 /**
4920 * @brief Clarke transform for Q31 version
4921 * @param[in] Ia input three-phase coordinate <code>a</code>
4922 * @param[in] Ib input three-phase coordinate <code>b</code>
4923 * @param[out] *pIalpha points to output two-phase orthogonal vector axis alpha
4924 * @param[out] *pIbeta points to output two-phase orthogonal vector axis beta
4925 * @return none.
4926 *
4927 * <b>Scaling and Overflow Behavior:</b>
4928 * \par
4929 * The function is implemented using an internal 32-bit accumulator.
4930 * The accumulator maintains 1.31 format by truncating lower 31 bits of the intermediate multiplication in 2.62 format.
4931 * There is saturation on the addition, hence there is no risk of overflow.
4932 */
4933
4934 static __INLINE void arm_clarke_q31(
4935 q31_t Ia,
4936 q31_t Ib,
4937 q31_t * pIalpha,
4938 q31_t * pIbeta)
4939 {
4940 q31_t product1, product2; /* Temporary variables used to store intermediate results */
4941
4942 /* Calculating pIalpha from Ia by equation pIalpha = Ia */
4943 *pIalpha = Ia;
4944
4945 /* Intermediate product is calculated by (1/(sqrt(3)) * Ia) */
4946 product1 = (q31_t) (((q63_t) Ia * 0x24F34E8B) >> 30);
4947
4948 /* Intermediate product is calculated by (2/sqrt(3) * Ib) */
4949 product2 = (q31_t) (((q63_t) Ib * 0x49E69D16) >> 30);
4950
4951 /* pIbeta is calculated by adding the intermediate products */
4952 *pIbeta = __QADD(product1, product2);
4953 }
4954
4955 /**
4956 * @} end of clarke group
4957 */
4958
4959 /**
4960 * @brief Converts the elements of the Q7 vector to Q31 vector.
4961 * @param[in] *pSrc input pointer
4962 * @param[out] *pDst output pointer
4963 * @param[in] blockSize number of samples to process
4964 * @return none.
4965 */
4966 void arm_q7_to_q31(
4967 q7_t * pSrc,
4968 q31_t * pDst,
4969 uint32_t blockSize);
4970
4971
4972
4973
4974 /**
4975 * @ingroup groupController
4976 */
4977
4978 /**
4979 * @defgroup inv_clarke Vector Inverse Clarke Transform
4980 * Inverse Clarke transform converts the two-coordinate time invariant vector into instantaneous stator phases.
4981 *
4982 * The function operates on a single sample of data and each call to the function returns the processed output.
4983 * The library provides separate functions for Q31 and floating-point data types.
4984 * \par Algorithm
4985 * \image html clarkeInvFormula.gif
4986 * where <code>pIa</code> and <code>pIb</code> are the instantaneous stator phases and
4987 * <code>Ialpha</code> and <code>Ibeta</code> are the two coordinates of time invariant vector.
4988 * \par Fixed-Point Behavior
4989 * Care must be taken when using the Q31 version of the Clarke transform.
4990 * In particular, the overflow and saturation behavior of the accumulator used must be considered.
4991 * Refer to the function specific documentation below for usage guidelines.
4992 */
4993
4994 /**
4995 * @addtogroup inv_clarke
4996 * @{
4997 */
4998
4999 /**
5000 * @brief Floating-point Inverse Clarke transform
5001 * @param[in] Ialpha input two-phase orthogonal vector axis alpha
5002 * @param[in] Ibeta input two-phase orthogonal vector axis beta
5003 * @param[out] *pIa points to output three-phase coordinate <code>a</code>
5004 * @param[out] *pIb points to output three-phase coordinate <code>b</code>
5005 * @return none.
5006 */
5007
5008
5009 static __INLINE void arm_inv_clarke_f32(
5010 float32_t Ialpha,
5011 float32_t Ibeta,
5012 float32_t * pIa,
5013 float32_t * pIb)
5014 {
5015 /* Calculating pIa from Ialpha by equation pIa = Ialpha */
5016 *pIa = Ialpha;
5017
5018 /* Calculating pIb from Ialpha and Ibeta by equation pIb = -(1/2) * Ialpha + (sqrt(3)/2) * Ibeta */
5019 *pIb = -0.5 * Ialpha + (float32_t) 0.8660254039 *Ibeta;
5020
5021 }
5022
5023 /**
5024 * @brief Inverse Clarke transform for Q31 version
5025 * @param[in] Ialpha input two-phase orthogonal vector axis alpha
5026 * @param[in] Ibeta input two-phase orthogonal vector axis beta
5027 * @param[out] *pIa points to output three-phase coordinate <code>a</code>
5028 * @param[out] *pIb points to output three-phase coordinate <code>b</code>
5029 * @return none.
5030 *
5031 * <b>Scaling and Overflow Behavior:</b>
5032 * \par
5033 * The function is implemented using an internal 32-bit accumulator.
5034 * The accumulator maintains 1.31 format by truncating lower 31 bits of the intermediate multiplication in 2.62 format.
5035 * There is saturation on the subtraction, hence there is no risk of overflow.
5036 */
5037
5038 static __INLINE void arm_inv_clarke_q31(
5039 q31_t Ialpha,
5040 q31_t Ibeta,
5041 q31_t * pIa,
5042 q31_t * pIb)
5043 {
5044 q31_t product1, product2; /* Temporary variables used to store intermediate results */
5045
5046 /* Calculating pIa from Ialpha by equation pIa = Ialpha */
5047 *pIa = Ialpha;
5048
5049 /* Intermediate product is calculated by (1/(2*sqrt(3)) * Ia) */
5050 product1 = (q31_t) (((q63_t) (Ialpha) * (0x40000000)) >> 31);
5051
5052 /* Intermediate product is calculated by (1/sqrt(3) * pIb) */
5053 product2 = (q31_t) (((q63_t) (Ibeta) * (0x6ED9EBA1)) >> 31);
5054
5055 /* pIb is calculated by subtracting the products */
5056 *pIb = __QSUB(product2, product1);
5057
5058 }
5059
5060 /**
5061 * @} end of inv_clarke group
5062 */
5063
5064 /**
5065 * @brief Converts the elements of the Q7 vector to Q15 vector.
5066 * @param[in] *pSrc input pointer
5067 * @param[out] *pDst output pointer
5068 * @param[in] blockSize number of samples to process
5069 * @return none.
5070 */
5071 void arm_q7_to_q15(
5072 q7_t * pSrc,
5073 q15_t * pDst,
5074 uint32_t blockSize);
5075
5076
5077
5078 /**
5079 * @ingroup groupController
5080 */
5081
5082 /**
5083 * @defgroup park Vector Park Transform
5084 *
5085 * Forward Park transform converts the input two-coordinate vector to flux and torque components.
5086 * The Park transform can be used to realize the transformation of the <code>Ialpha</code> and the <code>Ibeta</code> currents
5087 * from the stationary to the moving reference frame and control the spatial relationship between
5088 * the stator vector current and rotor flux vector.
5089 * If we consider the d axis aligned with the rotor flux, the diagram below shows the
5090 * current vector and the relationship from the two reference frames:
5091 * \image html park.gif "Stator current space vector and its component in (a,b) and in the d,q rotating reference frame"
5092 *
5093 * The function operates on a single sample of data and each call to the function returns the processed output.
5094 * The library provides separate functions for Q31 and floating-point data types.
5095 * \par Algorithm
5096 * \image html parkFormula.gif
5097 * where <code>Ialpha</code> and <code>Ibeta</code> are the stator vector components,
5098 * <code>pId</code> and <code>pIq</code> are rotor vector components and <code>cosVal</code> and <code>sinVal</code> are the
5099 * cosine and sine values of theta (rotor flux position).
5100 * \par Fixed-Point Behavior
5101 * Care must be taken when using the Q31 version of the Park transform.
5102 * In particular, the overflow and saturation behavior of the accumulator used must be considered.
5103 * Refer to the function specific documentation below for usage guidelines.
5104 */
5105
5106 /**
5107 * @addtogroup park
5108 * @{
5109 */
5110
5111 /**
5112 * @brief Floating-point Park transform
5113 * @param[in] Ialpha input two-phase vector coordinate alpha
5114 * @param[in] Ibeta input two-phase vector coordinate beta
5115 * @param[out] *pId points to output rotor reference frame d
5116 * @param[out] *pIq points to output rotor reference frame q
5117 * @param[in] sinVal sine value of rotation angle theta
5118 * @param[in] cosVal cosine value of rotation angle theta
5119 * @return none.
5120 *
5121 * The function implements the forward Park transform.
5122 *
5123 */
5124
5125 static __INLINE void arm_park_f32(
5126 float32_t Ialpha,
5127 float32_t Ibeta,
5128 float32_t * pId,
5129 float32_t * pIq,
5130 float32_t sinVal,
5131 float32_t cosVal)
5132 {
5133 /* Calculate pId using the equation, pId = Ialpha * cosVal + Ibeta * sinVal */
5134 *pId = Ialpha * cosVal + Ibeta * sinVal;
5135
5136 /* Calculate pIq using the equation, pIq = - Ialpha * sinVal + Ibeta * cosVal */
5137 *pIq = -Ialpha * sinVal + Ibeta * cosVal;
5138
5139 }
5140
5141 /**
5142 * @brief Park transform for Q31 version
5143 * @param[in] Ialpha input two-phase vector coordinate alpha
5144 * @param[in] Ibeta input two-phase vector coordinate beta
5145 * @param[out] *pId points to output rotor reference frame d
5146 * @param[out] *pIq points to output rotor reference frame q
5147 * @param[in] sinVal sine value of rotation angle theta
5148 * @param[in] cosVal cosine value of rotation angle theta
5149 * @return none.
5150 *
5151 * <b>Scaling and Overflow Behavior:</b>
5152 * \par
5153 * The function is implemented using an internal 32-bit accumulator.
5154 * The accumulator maintains 1.31 format by truncating lower 31 bits of the intermediate multiplication in 2.62 format.
5155 * There is saturation on the addition and subtraction, hence there is no risk of overflow.
5156 */
5157
5158
5159 static __INLINE void arm_park_q31(
5160 q31_t Ialpha,
5161 q31_t Ibeta,
5162 q31_t * pId,
5163 q31_t * pIq,
5164 q31_t sinVal,
5165 q31_t cosVal)
5166 {
5167 q31_t product1, product2; /* Temporary variables used to store intermediate results */
5168 q31_t product3, product4; /* Temporary variables used to store intermediate results */
5169
5170 /* Intermediate product is calculated by (Ialpha * cosVal) */
5171 product1 = (q31_t) (((q63_t) (Ialpha) * (cosVal)) >> 31);
5172
5173 /* Intermediate product is calculated by (Ibeta * sinVal) */
5174 product2 = (q31_t) (((q63_t) (Ibeta) * (sinVal)) >> 31);
5175
5176
5177 /* Intermediate product is calculated by (Ialpha * sinVal) */
5178 product3 = (q31_t) (((q63_t) (Ialpha) * (sinVal)) >> 31);
5179
5180 /* Intermediate product is calculated by (Ibeta * cosVal) */
5181 product4 = (q31_t) (((q63_t) (Ibeta) * (cosVal)) >> 31);
5182
5183 /* Calculate pId by adding the two intermediate products 1 and 2 */
5184 *pId = __QADD(product1, product2);
5185
5186 /* Calculate pIq by subtracting the two intermediate products 3 from 4 */
5187 *pIq = __QSUB(product4, product3);
5188 }
5189
5190 /**
5191 * @} end of park group
5192 */
5193
5194 /**
5195 * @brief Converts the elements of the Q7 vector to floating-point vector.
5196 * @param[in] *pSrc is input pointer
5197 * @param[out] *pDst is output pointer
5198 * @param[in] blockSize is the number of samples to process
5199 * @return none.
5200 */
5201 void arm_q7_to_float(
5202 q7_t * pSrc,
5203 float32_t * pDst,
5204 uint32_t blockSize);
5205
5206
5207 /**
5208 * @ingroup groupController
5209 */
5210
5211 /**
5212 * @defgroup inv_park Vector Inverse Park transform
5213 * Inverse Park transform converts the input flux and torque components to two-coordinate vector.
5214 *
5215 * The function operates on a single sample of data and each call to the function returns the processed output.
5216 * The library provides separate functions for Q31 and floating-point data types.
5217 * \par Algorithm
5218 * \image html parkInvFormula.gif
5219 * where <code>pIalpha</code> and <code>pIbeta</code> are the stator vector components,
5220 * <code>Id</code> and <code>Iq</code> are rotor vector components and <code>cosVal</code> and <code>sinVal</code> are the
5221 * cosine and sine values of theta (rotor flux position).
5222 * \par Fixed-Point Behavior
5223 * Care must be taken when using the Q31 version of the Park transform.
5224 * In particular, the overflow and saturation behavior of the accumulator used must be considered.
5225 * Refer to the function specific documentation below for usage guidelines.
5226 */
5227
5228 /**
5229 * @addtogroup inv_park
5230 * @{
5231 */
5232
5233 /**
5234 * @brief Floating-point Inverse Park transform
5235 * @param[in] Id input coordinate of rotor reference frame d
5236 * @param[in] Iq input coordinate of rotor reference frame q
5237 * @param[out] *pIalpha points to output two-phase orthogonal vector axis alpha
5238 * @param[out] *pIbeta points to output two-phase orthogonal vector axis beta
5239 * @param[in] sinVal sine value of rotation angle theta
5240 * @param[in] cosVal cosine value of rotation angle theta
5241 * @return none.
5242 */
5243
5244 static __INLINE void arm_inv_park_f32(
5245 float32_t Id,
5246 float32_t Iq,
5247 float32_t * pIalpha,
5248 float32_t * pIbeta,
5249 float32_t sinVal,
5250 float32_t cosVal)
5251 {
5252 /* Calculate pIalpha using the equation, pIalpha = Id * cosVal - Iq * sinVal */
5253 *pIalpha = Id * cosVal - Iq * sinVal;
5254
5255 /* Calculate pIbeta using the equation, pIbeta = Id * sinVal + Iq * cosVal */
5256 *pIbeta = Id * sinVal + Iq * cosVal;
5257
5258 }
5259
5260
5261 /**
5262 * @brief Inverse Park transform for Q31 version
5263 * @param[in] Id input coordinate of rotor reference frame d
5264 * @param[in] Iq input coordinate of rotor reference frame q
5265 * @param[out] *pIalpha points to output two-phase orthogonal vector axis alpha
5266 * @param[out] *pIbeta points to output two-phase orthogonal vector axis beta
5267 * @param[in] sinVal sine value of rotation angle theta
5268 * @param[in] cosVal cosine value of rotation angle theta
5269 * @return none.
5270 *
5271 * <b>Scaling and Overflow Behavior:</b>
5272 * \par
5273 * The function is implemented using an internal 32-bit accumulator.
5274 * The accumulator maintains 1.31 format by truncating lower 31 bits of the intermediate multiplication in 2.62 format.
5275 * There is saturation on the addition, hence there is no risk of overflow.
5276 */
5277
5278
5279 static __INLINE void arm_inv_park_q31(
5280 q31_t Id,
5281 q31_t Iq,
5282 q31_t * pIalpha,
5283 q31_t * pIbeta,
5284 q31_t sinVal,
5285 q31_t cosVal)
5286 {
5287 q31_t product1, product2; /* Temporary variables used to store intermediate results */
5288 q31_t product3, product4; /* Temporary variables used to store intermediate results */
5289
5290 /* Intermediate product is calculated by (Id * cosVal) */
5291 product1 = (q31_t) (((q63_t) (Id) * (cosVal)) >> 31);
5292
5293 /* Intermediate product is calculated by (Iq * sinVal) */
5294 product2 = (q31_t) (((q63_t) (Iq) * (sinVal)) >> 31);
5295
5296
5297 /* Intermediate product is calculated by (Id * sinVal) */
5298 product3 = (q31_t) (((q63_t) (Id) * (sinVal)) >> 31);
5299
5300 /* Intermediate product is calculated by (Iq * cosVal) */
5301 product4 = (q31_t) (((q63_t) (Iq) * (cosVal)) >> 31);
5302
5303 /* Calculate pIalpha by using the two intermediate products 1 and 2 */
5304 *pIalpha = __QSUB(product1, product2);
5305
5306 /* Calculate pIbeta by using the two intermediate products 3 and 4 */
5307 *pIbeta = __QADD(product4, product3);
5308
5309 }
5310
5311 /**
5312 * @} end of Inverse park group
5313 */
5314
5315
5316 /**
5317 * @brief Converts the elements of the Q31 vector to floating-point vector.
5318 * @param[in] *pSrc is input pointer
5319 * @param[out] *pDst is output pointer
5320 * @param[in] blockSize is the number of samples to process
5321 * @return none.
5322 */
5323 void arm_q31_to_float(
5324 q31_t * pSrc,
5325 float32_t * pDst,
5326 uint32_t blockSize);
5327
5328 /**
5329 * @ingroup groupInterpolation
5330 */
5331
5332 /**
5333 * @defgroup LinearInterpolate Linear Interpolation
5334 *
5335 * Linear interpolation is a method of curve fitting using linear polynomials.
5336 * Linear interpolation works by effectively drawing a straight line between two neighboring samples and returning the appropriate point along that line
5337 *
5338 * \par
5339 * \image html LinearInterp.gif "Linear interpolation"
5340 *
5341 * \par
5342 * A Linear Interpolate function calculates an output value(y), for the input(x)
5343 * using linear interpolation of the input values x0, x1( nearest input values) and the output values y0 and y1(nearest output values)
5344 *
5345 * \par Algorithm:
5346 * <pre>
5347 * y = y0 + (x - x0) * ((y1 - y0)/(x1-x0))
5348 * where x0, x1 are nearest values of input x
5349 * y0, y1 are nearest values to output y
5350 * </pre>
5351 *
5352 * \par
5353 * This set of functions implements Linear interpolation process
5354 * for Q7, Q15, Q31, and floating-point data types. The functions operate on a single
5355 * sample of data and each call to the function returns a single processed value.
5356 * <code>S</code> points to an instance of the Linear Interpolate function data structure.
5357 * <code>x</code> is the input sample value. The functions returns the output value.
5358 *
5359 * \par
5360 * if x is outside of the table boundary, Linear interpolation returns first value of the table
5361 * if x is below input range and returns last value of table if x is above range.
5362 */
5363
5364 /**
5365 * @addtogroup LinearInterpolate
5366 * @{
5367 */
5368
5369 /**
5370 * @brief Process function for the floating-point Linear Interpolation Function.
5371 * @param[in,out] *S is an instance of the floating-point Linear Interpolation structure
5372 * @param[in] x input sample to process
5373 * @return y processed output sample.
5374 *
5375 */
5376
5377 static __INLINE float32_t arm_linear_interp_f32(
5378 arm_linear_interp_instance_f32 * S,
5379 float32_t x)
5380 {
5381
5382 float32_t y;
5383 float32_t x0, x1; /* Nearest input values */
5384 float32_t y0, y1; /* Nearest output values */
5385 float32_t xSpacing = S->xSpacing; /* spacing between input values */
5386 int32_t i; /* Index variable */
5387 float32_t *pYData = S->pYData; /* pointer to output table */
5388
5389 /* Calculation of index */
5390 i = (x - S->x1) / xSpacing;
5391
5392 if(i < 0)
5393 {
5394 /* Iniatilize output for below specified range as least output value of table */
5395 y = pYData[0];
5396 }
5397 else if(i >= S->nValues)
5398 {
5399 /* Iniatilize output for above specified range as last output value of table */
5400 y = pYData[S->nValues-1];
5401 }
5402 else
5403 {
5404 /* Calculation of nearest input values */
5405 x0 = S->x1 + i * xSpacing;
5406 x1 = S->x1 + (i +1) * xSpacing;
5407
5408 /* Read of nearest output values */
5409 y0 = pYData[i];
5410 y1 = pYData[i + 1];
5411
5412 /* Calculation of output */
5413 y = y0 + (x - x0) * ((y1 - y0)/(x1-x0));
5414
5415 }
5416
5417 /* returns output value */
5418 return (y);
5419 }
5420
5421 /**
5422 *
5423 * @brief Process function for the Q31 Linear Interpolation Function.
5424 * @param[in] *pYData pointer to Q31 Linear Interpolation table
5425 * @param[in] x input sample to process
5426 * @param[in] nValues number of table values
5427 * @return y processed output sample.
5428 *
5429 * \par
5430 * Input sample <code>x</code> is in 12.20 format which contains 12 bits for table index and 20 bits for fractional part.
5431 * This function can support maximum of table size 2^12.
5432 *
5433 */
5434
5435
5436 static __INLINE q31_t arm_linear_interp_q31(q31_t *pYData,
5437 q31_t x, uint32_t nValues)
5438 {
5439 q31_t y; /* output */
5440 q31_t y0, y1; /* Nearest output values */
5441 q31_t fract; /* fractional part */
5442 int32_t index; /* Index to read nearest output values */
5443
5444 /* Input is in 12.20 format */
5445 /* 12 bits for the table index */
5446 /* Index value calculation */
5447 index = ((x & 0xFFF00000) >> 20);
5448
5449 if(index >= (nValues - 1))
5450 {
5451 return(pYData[nValues - 1]);
5452 }
5453 else if(index < 0)
5454 {
5455 return(pYData[0]);
5456 }
5457 else
5458 {
5459
5460 /* 20 bits for the fractional part */
5461 /* shift left by 11 to keep fract in 1.31 format */
5462 fract = (x & 0x000FFFFF) << 11;
5463
5464 /* Read two nearest output values from the index in 1.31(q31) format */
5465 y0 = pYData[index];
5466 y1 = pYData[index + 1u];
5467
5468 /* Calculation of y0 * (1-fract) and y is in 2.30 format */
5469 y = ((q31_t) ((q63_t) y0 * (0x7FFFFFFF - fract) >> 32));
5470
5471 /* Calculation of y0 * (1-fract) + y1 *fract and y is in 2.30 format */
5472 y += ((q31_t) (((q63_t) y1 * fract) >> 32));
5473
5474 /* Convert y to 1.31 format */
5475 return (y << 1u);
5476
5477 }
5478
5479 }
5480
5481 /**
5482 *
5483 * @brief Process function for the Q15 Linear Interpolation Function.
5484 * @param[in] *pYData pointer to Q15 Linear Interpolation table
5485 * @param[in] x input sample to process
5486 * @param[in] nValues number of table values
5487 * @return y processed output sample.
5488 *
5489 * \par
5490 * Input sample <code>x</code> is in 12.20 format which contains 12 bits for table index and 20 bits for fractional part.
5491 * This function can support maximum of table size 2^12.
5492 *
5493 */
5494
5495
5496 static __INLINE q15_t arm_linear_interp_q15(q15_t *pYData, q31_t x, uint32_t nValues)
5497 {
5498 q63_t y; /* output */
5499 q15_t y0, y1; /* Nearest output values */
5500 q31_t fract; /* fractional part */
5501 int32_t index; /* Index to read nearest output values */
5502
5503 /* Input is in 12.20 format */
5504 /* 12 bits for the table index */
5505 /* Index value calculation */
5506 index = ((x & 0xFFF00000) >> 20u);
5507
5508 if(index >= (nValues - 1))
5509 {
5510 return(pYData[nValues - 1]);
5511 }
5512 else if(index < 0)
5513 {
5514 return(pYData[0]);
5515 }
5516 else
5517 {
5518 /* 20 bits for the fractional part */
5519 /* fract is in 12.20 format */
5520 fract = (x & 0x000FFFFF);
5521
5522 /* Read two nearest output values from the index */
5523 y0 = pYData[index];
5524 y1 = pYData[index + 1u];
5525
5526 /* Calculation of y0 * (1-fract) and y is in 13.35 format */
5527 y = ((q63_t) y0 * (0xFFFFF - fract));
5528
5529 /* Calculation of (y0 * (1-fract) + y1 * fract) and y is in 13.35 format */
5530 y += ((q63_t) y1 * (fract));
5531
5532 /* convert y to 1.15 format */
5533 return (y >> 20);
5534 }
5535
5536
5537 }
5538
5539 /**
5540 *
5541 * @brief Process function for the Q7 Linear Interpolation Function.
5542 * @param[in] *pYData pointer to Q7 Linear Interpolation table
5543 * @param[in] x input sample to process
5544 * @param[in] nValues number of table values
5545 * @return y processed output sample.
5546 *
5547 * \par
5548 * Input sample <code>x</code> is in 12.20 format which contains 12 bits for table index and 20 bits for fractional part.
5549 * This function can support maximum of table size 2^12.
5550 */
5551
5552
5553 static __INLINE q7_t arm_linear_interp_q7(q7_t *pYData, q31_t x, uint32_t nValues)
5554 {
5555 q31_t y; /* output */
5556 q7_t y0, y1; /* Nearest output values */
5557 q31_t fract; /* fractional part */
5558 int32_t index; /* Index to read nearest output values */
5559
5560 /* Input is in 12.20 format */
5561 /* 12 bits for the table index */
5562 /* Index value calculation */
5563 index = ((x & 0xFFF00000) >> 20u);
5564
5565
5566 if(index >= (nValues - 1))
5567 {
5568 return(pYData[nValues - 1]);
5569 }
5570 else if(index < 0)
5571 {
5572 return(pYData[0]);
5573 }
5574 else
5575 {
5576
5577 /* 20 bits for the fractional part */
5578 /* fract is in 12.20 format */
5579 fract = (x & 0x000FFFFF);
5580
5581 /* Read two nearest output values from the index and are in 1.7(q7) format */
5582 y0 = pYData[index];
5583 y1 = pYData[index + 1u];
5584
5585 /* Calculation of y0 * (1-fract ) and y is in 13.27(q27) format */
5586 y = ((y0 * (0xFFFFF - fract)));
5587
5588 /* Calculation of y1 * fract + y0 * (1-fract) and y is in 13.27(q27) format */
5589 y += (y1 * fract);
5590
5591 /* convert y to 1.7(q7) format */
5592 return (y >> 20u);
5593
5594 }
5595
5596 }
5597 /**
5598 * @} end of LinearInterpolate group
5599 */
5600
5601 /**
5602 * @brief Fast approximation to the trigonometric sine function for floating-point data.
5603 * @param[in] x input value in radians.
5604 * @return sin(x).
5605 */
5606
5607 float32_t arm_sin_f32(
5608 float32_t x);
5609
5610 /**
5611 * @brief Fast approximation to the trigonometric sine function for Q31 data.
5612 * @param[in] x Scaled input value in radians.
5613 * @return sin(x).
5614 */
5615
5616 q31_t arm_sin_q31(
5617 q31_t x);
5618
5619 /**
5620 * @brief Fast approximation to the trigonometric sine function for Q15 data.
5621 * @param[in] x Scaled input value in radians.
5622 * @return sin(x).
5623 */
5624
5625 q15_t arm_sin_q15(
5626 q15_t x);
5627
5628 /**
5629 * @brief Fast approximation to the trigonometric cosine function for floating-point data.
5630 * @param[in] x input value in radians.
5631 * @return cos(x).
5632 */
5633
5634 float32_t arm_cos_f32(
5635 float32_t x);
5636
5637 /**
5638 * @brief Fast approximation to the trigonometric cosine function for Q31 data.
5639 * @param[in] x Scaled input value in radians.
5640 * @return cos(x).
5641 */
5642
5643 q31_t arm_cos_q31(
5644 q31_t x);
5645
5646 /**
5647 * @brief Fast approximation to the trigonometric cosine function for Q15 data.
5648 * @param[in] x Scaled input value in radians.
5649 * @return cos(x).
5650 */
5651
5652 q15_t arm_cos_q15(
5653 q15_t x);
5654
5655
5656 /**
5657 * @ingroup groupFastMath
5658 */
5659
5660
5661 /**
5662 * @defgroup SQRT Square Root
5663 *
5664 * Computes the square root of a number.
5665 * There are separate functions for Q15, Q31, and floating-point data types.
5666 * The square root function is computed using the Newton-Raphson algorithm.
5667 * This is an iterative algorithm of the form:
5668 * <pre>
5669 * x1 = x0 - f(x0)/f'(x0)
5670 * </pre>
5671 * where <code>x1</code> is the current estimate,
5672 * <code>x0</code> is the previous estimate and
5673 * <code>f'(x0)</code> is the derivative of <code>f()</code> evaluated at <code>x0</code>.
5674 * For the square root function, the algorithm reduces to:
5675 * <pre>
5676 * x0 = in/2 [initial guess]
5677 * x1 = 1/2 * ( x0 + in / x0) [each iteration]
5678 * </pre>
5679 */
5680
5681
5682 /**
5683 * @addtogroup SQRT
5684 * @{
5685 */
5686
5687 /**
5688 * @brief Floating-point square root function.
5689 * @param[in] in input value.
5690 * @param[out] *pOut square root of input value.
5691 * @return The function returns ARM_MATH_SUCCESS if input value is positive value or ARM_MATH_ARGUMENT_ERROR if
5692 * <code>in</code> is negative value and returns zero output for negative values.
5693 */
5694
5695 static __INLINE arm_status arm_sqrt_f32(
5696 float32_t in, float32_t *pOut)
5697 {
5698 if(in > 0)
5699 {
5700
5701 // #if __FPU_USED
5702 #if (__FPU_USED == 1) && defined ( __CC_ARM )
5703 *pOut = __sqrtf(in);
5704 #else
5705 *pOut = sqrtf(in);
5706 #endif
5707
5708 return (ARM_MATH_SUCCESS);
5709 }
5710 else
5711 {
5712 *pOut = 0.0f;
5713 return (ARM_MATH_ARGUMENT_ERROR);
5714 }
5715
5716 }
5717
5718
5719 /**
5720 * @brief Q31 square root function.
5721 * @param[in] in input value. The range of the input value is [0 +1) or 0x00000000 to 0x7FFFFFFF.
5722 * @param[out] *pOut square root of input value.
5723 * @return The function returns ARM_MATH_SUCCESS if input value is positive value or ARM_MATH_ARGUMENT_ERROR if
5724 * <code>in</code> is negative value and returns zero output for negative values.
5725 */
5726 arm_status arm_sqrt_q31(
5727 q31_t in, q31_t *pOut);
5728
5729 /**
5730 * @brief Q15 square root function.
5731 * @param[in] in input value. The range of the input value is [0 +1) or 0x0000 to 0x7FFF.
5732 * @param[out] *pOut square root of input value.
5733 * @return The function returns ARM_MATH_SUCCESS if input value is positive value or ARM_MATH_ARGUMENT_ERROR if
5734 * <code>in</code> is negative value and returns zero output for negative values.
5735 */
5736 arm_status arm_sqrt_q15(
5737 q15_t in, q15_t *pOut);
5738
5739 /**
5740 * @} end of SQRT group
5741 */
5742
5743
5744
5745
5746
5747
5748 /**
5749 * @brief floating-point Circular write function.
5750 */
5751
5752 static __INLINE void arm_circularWrite_f32(
5753 int32_t * circBuffer,
5754 int32_t L,
5755 uint16_t * writeOffset,
5756 int32_t bufferInc,
5757 const int32_t * src,
5758 int32_t srcInc,
5759 uint32_t blockSize)
5760 {
5761 uint32_t i = 0u;
5762 int32_t wOffset;
5763
5764 /* Copy the value of Index pointer that points
5765 * to the current location where the input samples to be copied */
5766 wOffset = *writeOffset;
5767
5768 /* Loop over the blockSize */
5769 i = blockSize;
5770
5771 while(i > 0u)
5772 {
5773 /* copy the input sample to the circular buffer */
5774 circBuffer[wOffset] = *src;
5775
5776 /* Update the input pointer */
5777 src += srcInc;
5778
5779 /* Circularly update wOffset. Watch out for positive and negative value */
5780 wOffset += bufferInc;
5781 if(wOffset >= L)
5782 wOffset -= L;
5783
5784 /* Decrement the loop counter */
5785 i--;
5786 }
5787
5788 /* Update the index pointer */
5789 *writeOffset = wOffset;
5790 }
5791
5792
5793
5794 /**
5795 * @brief floating-point Circular Read function.
5796 */
5797 static __INLINE void arm_circularRead_f32(
5798 int32_t * circBuffer,
5799 int32_t L,
5800 int32_t * readOffset,
5801 int32_t bufferInc,
5802 int32_t * dst,
5803 int32_t * dst_base,
5804 int32_t dst_length,
5805 int32_t dstInc,
5806 uint32_t blockSize)
5807 {
5808 uint32_t i = 0u;
5809 int32_t rOffset, dst_end;
5810
5811 /* Copy the value of Index pointer that points
5812 * to the current location from where the input samples to be read */
5813 rOffset = *readOffset;
5814 dst_end = (int32_t) (dst_base + dst_length);
5815
5816 /* Loop over the blockSize */
5817 i = blockSize;
5818
5819 while(i > 0u)
5820 {
5821 /* copy the sample from the circular buffer to the destination buffer */
5822 *dst = circBuffer[rOffset];
5823
5824 /* Update the input pointer */
5825 dst += dstInc;
5826
5827 if(dst == (int32_t *) dst_end)
5828 {
5829 dst = dst_base;
5830 }
5831
5832 /* Circularly update rOffset. Watch out for positive and negative value */
5833 rOffset += bufferInc;
5834
5835 if(rOffset >= L)
5836 {
5837 rOffset -= L;
5838 }
5839
5840 /* Decrement the loop counter */
5841 i--;
5842 }
5843
5844 /* Update the index pointer */
5845 *readOffset = rOffset;
5846 }
5847
5848 /**
5849 * @brief Q15 Circular write function.
5850 */
5851
5852 static __INLINE void arm_circularWrite_q15(
5853 q15_t * circBuffer,
5854 int32_t L,
5855 uint16_t * writeOffset,
5856 int32_t bufferInc,
5857 const q15_t * src,
5858 int32_t srcInc,
5859 uint32_t blockSize)
5860 {
5861 uint32_t i = 0u;
5862 int32_t wOffset;
5863
5864 /* Copy the value of Index pointer that points
5865 * to the current location where the input samples to be copied */
5866 wOffset = *writeOffset;
5867
5868 /* Loop over the blockSize */
5869 i = blockSize;
5870
5871 while(i > 0u)
5872 {
5873 /* copy the input sample to the circular buffer */
5874 circBuffer[wOffset] = *src;
5875
5876 /* Update the input pointer */
5877 src += srcInc;
5878
5879 /* Circularly update wOffset. Watch out for positive and negative value */
5880 wOffset += bufferInc;
5881 if(wOffset >= L)
5882 wOffset -= L;
5883
5884 /* Decrement the loop counter */
5885 i--;
5886 }
5887
5888 /* Update the index pointer */
5889 *writeOffset = wOffset;
5890 }
5891
5892
5893
5894 /**
5895 * @brief Q15 Circular Read function.
5896 */
5897 static __INLINE void arm_circularRead_q15(
5898 q15_t * circBuffer,
5899 int32_t L,
5900 int32_t * readOffset,
5901 int32_t bufferInc,
5902 q15_t * dst,
5903 q15_t * dst_base,
5904 int32_t dst_length,
5905 int32_t dstInc,
5906 uint32_t blockSize)
5907 {
5908 uint32_t i = 0;
5909 int32_t rOffset, dst_end;
5910
5911 /* Copy the value of Index pointer that points
5912 * to the current location from where the input samples to be read */
5913 rOffset = *readOffset;
5914
5915 dst_end = (int32_t) (dst_base + dst_length);
5916
5917 /* Loop over the blockSize */
5918 i = blockSize;
5919
5920 while(i > 0u)
5921 {
5922 /* copy the sample from the circular buffer to the destination buffer */
5923 *dst = circBuffer[rOffset];
5924
5925 /* Update the input pointer */
5926 dst += dstInc;
5927
5928 if(dst == (q15_t *) dst_end)
5929 {
5930 dst = dst_base;
5931 }
5932
5933 /* Circularly update wOffset. Watch out for positive and negative value */
5934 rOffset += bufferInc;
5935
5936 if(rOffset >= L)
5937 {
5938 rOffset -= L;
5939 }
5940
5941 /* Decrement the loop counter */
5942 i--;
5943 }
5944
5945 /* Update the index pointer */
5946 *readOffset = rOffset;
5947 }
5948
5949
5950 /**
5951 * @brief Q7 Circular write function.
5952 */
5953
5954 static __INLINE void arm_circularWrite_q7(
5955 q7_t * circBuffer,
5956 int32_t L,
5957 uint16_t * writeOffset,
5958 int32_t bufferInc,
5959 const q7_t * src,
5960 int32_t srcInc,
5961 uint32_t blockSize)
5962 {
5963 uint32_t i = 0u;
5964 int32_t wOffset;
5965
5966 /* Copy the value of Index pointer that points
5967 * to the current location where the input samples to be copied */
5968 wOffset = *writeOffset;
5969
5970 /* Loop over the blockSize */
5971 i = blockSize;
5972
5973 while(i > 0u)
5974 {
5975 /* copy the input sample to the circular buffer */
5976 circBuffer[wOffset] = *src;
5977
5978 /* Update the input pointer */
5979 src += srcInc;
5980
5981 /* Circularly update wOffset. Watch out for positive and negative value */
5982 wOffset += bufferInc;
5983 if(wOffset >= L)
5984 wOffset -= L;
5985
5986 /* Decrement the loop counter */
5987 i--;
5988 }
5989
5990 /* Update the index pointer */
5991 *writeOffset = wOffset;
5992 }
5993
5994
5995
5996 /**
5997 * @brief Q7 Circular Read function.
5998 */
5999 static __INLINE void arm_circularRead_q7(
6000 q7_t * circBuffer,
6001 int32_t L,
6002 int32_t * readOffset,
6003 int32_t bufferInc,
6004 q7_t * dst,
6005 q7_t * dst_base,
6006 int32_t dst_length,
6007 int32_t dstInc,
6008 uint32_t blockSize)
6009 {
6010 uint32_t i = 0;
6011 int32_t rOffset, dst_end;
6012
6013 /* Copy the value of Index pointer that points
6014 * to the current location from where the input samples to be read */
6015 rOffset = *readOffset;
6016
6017 dst_end = (int32_t) (dst_base + dst_length);
6018
6019 /* Loop over the blockSize */
6020 i = blockSize;
6021
6022 while(i > 0u)
6023 {
6024 /* copy the sample from the circular buffer to the destination buffer */
6025 *dst = circBuffer[rOffset];
6026
6027 /* Update the input pointer */
6028 dst += dstInc;
6029
6030 if(dst == (q7_t *) dst_end)
6031 {
6032 dst = dst_base;
6033 }
6034
6035 /* Circularly update rOffset. Watch out for positive and negative value */
6036 rOffset += bufferInc;
6037
6038 if(rOffset >= L)
6039 {
6040 rOffset -= L;
6041 }
6042
6043 /* Decrement the loop counter */
6044 i--;
6045 }
6046
6047 /* Update the index pointer */
6048 *readOffset = rOffset;
6049 }
6050
6051
6052 /**
6053 * @brief Sum of the squares of the elements of a Q31 vector.
6054 * @param[in] *pSrc is input pointer
6055 * @param[in] blockSize is the number of samples to process
6056 * @param[out] *pResult is output value.
6057 * @return none.
6058 */
6059
6060 void arm_power_q31(
6061 q31_t * pSrc,
6062 uint32_t blockSize,
6063 q63_t * pResult);
6064
6065 /**
6066 * @brief Sum of the squares of the elements of a floating-point vector.
6067 * @param[in] *pSrc is input pointer
6068 * @param[in] blockSize is the number of samples to process
6069 * @param[out] *pResult is output value.
6070 * @return none.
6071 */
6072
6073 void arm_power_f32(
6074 float32_t * pSrc,
6075 uint32_t blockSize,
6076 float32_t * pResult);
6077
6078 /**
6079 * @brief Sum of the squares of the elements of a Q15 vector.
6080 * @param[in] *pSrc is input pointer
6081 * @param[in] blockSize is the number of samples to process
6082 * @param[out] *pResult is output value.
6083 * @return none.
6084 */
6085
6086 void arm_power_q15(
6087 q15_t * pSrc,
6088 uint32_t blockSize,
6089 q63_t * pResult);
6090
6091 /**
6092 * @brief Sum of the squares of the elements of a Q7 vector.
6093 * @param[in] *pSrc is input pointer
6094 * @param[in] blockSize is the number of samples to process
6095 * @param[out] *pResult is output value.
6096 * @return none.
6097 */
6098
6099 void arm_power_q7(
6100 q7_t * pSrc,
6101 uint32_t blockSize,
6102 q31_t * pResult);
6103
6104 /**
6105 * @brief Mean value of a Q7 vector.
6106 * @param[in] *pSrc is input pointer
6107 * @param[in] blockSize is the number of samples to process
6108 * @param[out] *pResult is output value.
6109 * @return none.
6110 */
6111
6112 void arm_mean_q7(
6113 q7_t * pSrc,
6114 uint32_t blockSize,
6115 q7_t * pResult);
6116
6117 /**
6118 * @brief Mean value of a Q15 vector.
6119 * @param[in] *pSrc is input pointer
6120 * @param[in] blockSize is the number of samples to process
6121 * @param[out] *pResult is output value.
6122 * @return none.
6123 */
6124 void arm_mean_q15(
6125 q15_t * pSrc,
6126 uint32_t blockSize,
6127 q15_t * pResult);
6128
6129 /**
6130 * @brief Mean value of a Q31 vector.
6131 * @param[in] *pSrc is input pointer
6132 * @param[in] blockSize is the number of samples to process
6133 * @param[out] *pResult is output value.
6134 * @return none.
6135 */
6136 void arm_mean_q31(
6137 q31_t * pSrc,
6138 uint32_t blockSize,
6139 q31_t * pResult);
6140
6141 /**
6142 * @brief Mean value of a floating-point vector.
6143 * @param[in] *pSrc is input pointer
6144 * @param[in] blockSize is the number of samples to process
6145 * @param[out] *pResult is output value.
6146 * @return none.
6147 */
6148 void arm_mean_f32(
6149 float32_t * pSrc,
6150 uint32_t blockSize,
6151 float32_t * pResult);
6152
6153 /**
6154 * @brief Variance of the elements of a floating-point vector.
6155 * @param[in] *pSrc is input pointer
6156 * @param[in] blockSize is the number of samples to process
6157 * @param[out] *pResult is output value.
6158 * @return none.
6159 */
6160
6161 void arm_var_f32(
6162 float32_t * pSrc,
6163 uint32_t blockSize,
6164 float32_t * pResult);
6165
6166 /**
6167 * @brief Variance of the elements of a Q31 vector.
6168 * @param[in] *pSrc is input pointer
6169 * @param[in] blockSize is the number of samples to process
6170 * @param[out] *pResult is output value.
6171 * @return none.
6172 */
6173
6174 void arm_var_q31(
6175 q31_t * pSrc,
6176 uint32_t blockSize,
6177 q63_t * pResult);
6178
6179 /**
6180 * @brief Variance of the elements of a Q15 vector.
6181 * @param[in] *pSrc is input pointer
6182 * @param[in] blockSize is the number of samples to process
6183 * @param[out] *pResult is output value.
6184 * @return none.
6185 */
6186
6187 void arm_var_q15(
6188 q15_t * pSrc,
6189 uint32_t blockSize,
6190 q31_t * pResult);
6191
6192 /**
6193 * @brief Root Mean Square of the elements of a floating-point vector.
6194 * @param[in] *pSrc is input pointer
6195 * @param[in] blockSize is the number of samples to process
6196 * @param[out] *pResult is output value.
6197 * @return none.
6198 */
6199
6200 void arm_rms_f32(
6201 float32_t * pSrc,
6202 uint32_t blockSize,
6203 float32_t * pResult);
6204
6205 /**
6206 * @brief Root Mean Square of the elements of a Q31 vector.
6207 * @param[in] *pSrc is input pointer
6208 * @param[in] blockSize is the number of samples to process
6209 * @param[out] *pResult is output value.
6210 * @return none.
6211 */
6212
6213 void arm_rms_q31(
6214 q31_t * pSrc,
6215 uint32_t blockSize,
6216 q31_t * pResult);
6217
6218 /**
6219 * @brief Root Mean Square of the elements of a Q15 vector.
6220 * @param[in] *pSrc is input pointer
6221 * @param[in] blockSize is the number of samples to process
6222 * @param[out] *pResult is output value.
6223 * @return none.
6224 */
6225
6226 void arm_rms_q15(
6227 q15_t * pSrc,
6228 uint32_t blockSize,
6229 q15_t * pResult);
6230
6231 /**
6232 * @brief Standard deviation of the elements of a floating-point vector.
6233 * @param[in] *pSrc is input pointer
6234 * @param[in] blockSize is the number of samples to process
6235 * @param[out] *pResult is output value.
6236 * @return none.
6237 */
6238
6239 void arm_std_f32(
6240 float32_t * pSrc,
6241 uint32_t blockSize,
6242 float32_t * pResult);
6243
6244 /**
6245 * @brief Standard deviation of the elements of a Q31 vector.
6246 * @param[in] *pSrc is input pointer
6247 * @param[in] blockSize is the number of samples to process
6248 * @param[out] *pResult is output value.
6249 * @return none.
6250 */
6251
6252 void arm_std_q31(
6253 q31_t * pSrc,
6254 uint32_t blockSize,
6255 q31_t * pResult);
6256
6257 /**
6258 * @brief Standard deviation of the elements of a Q15 vector.
6259 * @param[in] *pSrc is input pointer
6260 * @param[in] blockSize is the number of samples to process
6261 * @param[out] *pResult is output value.
6262 * @return none.
6263 */
6264
6265 void arm_std_q15(
6266 q15_t * pSrc,
6267 uint32_t blockSize,
6268 q15_t * pResult);
6269
6270 /**
6271 * @brief Floating-point complex magnitude
6272 * @param[in] *pSrc points to the complex input vector
6273 * @param[out] *pDst points to the real output vector
6274 * @param[in] numSamples number of complex samples in the input vector
6275 * @return none.
6276 */
6277
6278 void arm_cmplx_mag_f32(
6279 float32_t * pSrc,
6280 float32_t * pDst,
6281 uint32_t numSamples);
6282
6283 /**
6284 * @brief Q31 complex magnitude
6285 * @param[in] *pSrc points to the complex input vector
6286 * @param[out] *pDst points to the real output vector
6287 * @param[in] numSamples number of complex samples in the input vector
6288 * @return none.
6289 */
6290
6291 void arm_cmplx_mag_q31(
6292 q31_t * pSrc,
6293 q31_t * pDst,
6294 uint32_t numSamples);
6295
6296 /**
6297 * @brief Q15 complex magnitude
6298 * @param[in] *pSrc points to the complex input vector
6299 * @param[out] *pDst points to the real output vector
6300 * @param[in] numSamples number of complex samples in the input vector
6301 * @return none.
6302 */
6303
6304 void arm_cmplx_mag_q15(
6305 q15_t * pSrc,
6306 q15_t * pDst,
6307 uint32_t numSamples);
6308
6309 /**
6310 * @brief Q15 complex dot product
6311 * @param[in] *pSrcA points to the first input vector
6312 * @param[in] *pSrcB points to the second input vector
6313 * @param[in] numSamples number of complex samples in each vector
6314 * @param[out] *realResult real part of the result returned here
6315 * @param[out] *imagResult imaginary part of the result returned here
6316 * @return none.
6317 */
6318
6319 void arm_cmplx_dot_prod_q15(
6320 q15_t * pSrcA,
6321 q15_t * pSrcB,
6322 uint32_t numSamples,
6323 q31_t * realResult,
6324 q31_t * imagResult);
6325
6326 /**
6327 * @brief Q31 complex dot product
6328 * @param[in] *pSrcA points to the first input vector
6329 * @param[in] *pSrcB points to the second input vector
6330 * @param[in] numSamples number of complex samples in each vector
6331 * @param[out] *realResult real part of the result returned here
6332 * @param[out] *imagResult imaginary part of the result returned here
6333 * @return none.
6334 */
6335
6336 void arm_cmplx_dot_prod_q31(
6337 q31_t * pSrcA,
6338 q31_t * pSrcB,
6339 uint32_t numSamples,
6340 q63_t * realResult,
6341 q63_t * imagResult);
6342
6343 /**
6344 * @brief Floating-point complex dot product
6345 * @param[in] *pSrcA points to the first input vector
6346 * @param[in] *pSrcB points to the second input vector
6347 * @param[in] numSamples number of complex samples in each vector
6348 * @param[out] *realResult real part of the result returned here
6349 * @param[out] *imagResult imaginary part of the result returned here
6350 * @return none.
6351 */
6352
6353 void arm_cmplx_dot_prod_f32(
6354 float32_t * pSrcA,
6355 float32_t * pSrcB,
6356 uint32_t numSamples,
6357 float32_t * realResult,
6358 float32_t * imagResult);
6359
6360 /**
6361 * @brief Q15 complex-by-real multiplication
6362 * @param[in] *pSrcCmplx points to the complex input vector
6363 * @param[in] *pSrcReal points to the real input vector
6364 * @param[out] *pCmplxDst points to the complex output vector
6365 * @param[in] numSamples number of samples in each vector
6366 * @return none.
6367 */
6368
6369 void arm_cmplx_mult_real_q15(
6370 q15_t * pSrcCmplx,
6371 q15_t * pSrcReal,
6372 q15_t * pCmplxDst,
6373 uint32_t numSamples);
6374
6375 /**
6376 * @brief Q31 complex-by-real multiplication
6377 * @param[in] *pSrcCmplx points to the complex input vector
6378 * @param[in] *pSrcReal points to the real input vector
6379 * @param[out] *pCmplxDst points to the complex output vector
6380 * @param[in] numSamples number of samples in each vector
6381 * @return none.
6382 */
6383
6384 void arm_cmplx_mult_real_q31(
6385 q31_t * pSrcCmplx,
6386 q31_t * pSrcReal,
6387 q31_t * pCmplxDst,
6388 uint32_t numSamples);
6389
6390 /**
6391 * @brief Floating-point complex-by-real multiplication
6392 * @param[in] *pSrcCmplx points to the complex input vector
6393 * @param[in] *pSrcReal points to the real input vector
6394 * @param[out] *pCmplxDst points to the complex output vector
6395 * @param[in] numSamples number of samples in each vector
6396 * @return none.
6397 */
6398
6399 void arm_cmplx_mult_real_f32(
6400 float32_t * pSrcCmplx,
6401 float32_t * pSrcReal,
6402 float32_t * pCmplxDst,
6403 uint32_t numSamples);
6404
6405 /**
6406 * @brief Minimum value of a Q7 vector.
6407 * @param[in] *pSrc is input pointer
6408 * @param[in] blockSize is the number of samples to process
6409 * @param[out] *result is output pointer
6410 * @param[in] index is the array index of the minimum value in the input buffer.
6411 * @return none.
6412 */
6413
6414 void arm_min_q7(
6415 q7_t * pSrc,
6416 uint32_t blockSize,
6417 q7_t * result,
6418 uint32_t * index);
6419
6420 /**
6421 * @brief Minimum value of a Q15 vector.
6422 * @param[in] *pSrc is input pointer
6423 * @param[in] blockSize is the number of samples to process
6424 * @param[out] *pResult is output pointer
6425 * @param[in] *pIndex is the array index of the minimum value in the input buffer.
6426 * @return none.
6427 */
6428
6429 void arm_min_q15(
6430 q15_t * pSrc,
6431 uint32_t blockSize,
6432 q15_t * pResult,
6433 uint32_t * pIndex);
6434
6435 /**
6436 * @brief Minimum value of a Q31 vector.
6437 * @param[in] *pSrc is input pointer
6438 * @param[in] blockSize is the number of samples to process
6439 * @param[out] *pResult is output pointer
6440 * @param[out] *pIndex is the array index of the minimum value in the input buffer.
6441 * @return none.
6442 */
6443 void arm_min_q31(
6444 q31_t * pSrc,
6445 uint32_t blockSize,
6446 q31_t * pResult,
6447 uint32_t * pIndex);
6448
6449 /**
6450 * @brief Minimum value of a floating-point vector.
6451 * @param[in] *pSrc is input pointer
6452 * @param[in] blockSize is the number of samples to process
6453 * @param[out] *pResult is output pointer
6454 * @param[out] *pIndex is the array index of the minimum value in the input buffer.
6455 * @return none.
6456 */
6457
6458 void arm_min_f32(
6459 float32_t * pSrc,
6460 uint32_t blockSize,
6461 float32_t * pResult,
6462 uint32_t * pIndex);
6463
6464 /**
6465 * @brief Maximum value of a Q7 vector.
6466 * @param[in] *pSrc points to the input buffer
6467 * @param[in] blockSize length of the input vector
6468 * @param[out] *pResult maximum value returned here
6469 * @param[out] *pIndex index of maximum value returned here
6470 * @return none.
6471 */
6472
6473 void arm_max_q7(
6474 q7_t * pSrc,
6475 uint32_t blockSize,
6476 q7_t * pResult,
6477 uint32_t * pIndex);
6478
6479 /**
6480 * @brief Maximum value of a Q15 vector.
6481 * @param[in] *pSrc points to the input buffer
6482 * @param[in] blockSize length of the input vector
6483 * @param[out] *pResult maximum value returned here
6484 * @param[out] *pIndex index of maximum value returned here
6485 * @return none.
6486 */
6487
6488 void arm_max_q15(
6489 q15_t * pSrc,
6490 uint32_t blockSize,
6491 q15_t * pResult,
6492 uint32_t * pIndex);
6493
6494 /**
6495 * @brief Maximum value of a Q31 vector.
6496 * @param[in] *pSrc points to the input buffer
6497 * @param[in] blockSize length of the input vector
6498 * @param[out] *pResult maximum value returned here
6499 * @param[out] *pIndex index of maximum value returned here
6500 * @return none.
6501 */
6502
6503 void arm_max_q31(
6504 q31_t * pSrc,
6505 uint32_t blockSize,
6506 q31_t * pResult,
6507 uint32_t * pIndex);
6508
6509 /**
6510 * @brief Maximum value of a floating-point vector.
6511 * @param[in] *pSrc points to the input buffer
6512 * @param[in] blockSize length of the input vector
6513 * @param[out] *pResult maximum value returned here
6514 * @param[out] *pIndex index of maximum value returned here
6515 * @return none.
6516 */
6517
6518 void arm_max_f32(
6519 float32_t * pSrc,
6520 uint32_t blockSize,
6521 float32_t * pResult,
6522 uint32_t * pIndex);
6523
6524 /**
6525 * @brief Q15 complex-by-complex multiplication
6526 * @param[in] *pSrcA points to the first input vector
6527 * @param[in] *pSrcB points to the second input vector
6528 * @param[out] *pDst points to the output vector
6529 * @param[in] numSamples number of complex samples in each vector
6530 * @return none.
6531 */
6532
6533 void arm_cmplx_mult_cmplx_q15(
6534 q15_t * pSrcA,
6535 q15_t * pSrcB,
6536 q15_t * pDst,
6537 uint32_t numSamples);
6538
6539 /**
6540 * @brief Q31 complex-by-complex multiplication
6541 * @param[in] *pSrcA points to the first input vector
6542 * @param[in] *pSrcB points to the second input vector
6543 * @param[out] *pDst points to the output vector
6544 * @param[in] numSamples number of complex samples in each vector
6545 * @return none.
6546 */
6547
6548 void arm_cmplx_mult_cmplx_q31(
6549 q31_t * pSrcA,
6550 q31_t * pSrcB,
6551 q31_t * pDst,
6552 uint32_t numSamples);
6553
6554 /**
6555 * @brief Floating-point complex-by-complex multiplication
6556 * @param[in] *pSrcA points to the first input vector
6557 * @param[in] *pSrcB points to the second input vector
6558 * @param[out] *pDst points to the output vector
6559 * @param[in] numSamples number of complex samples in each vector
6560 * @return none.
6561 */
6562
6563 void arm_cmplx_mult_cmplx_f32(
6564 float32_t * pSrcA,
6565 float32_t * pSrcB,
6566 float32_t * pDst,
6567 uint32_t numSamples);
6568
6569 /**
6570 * @brief Converts the elements of the floating-point vector to Q31 vector.
6571 * @param[in] *pSrc points to the floating-point input vector
6572 * @param[out] *pDst points to the Q31 output vector
6573 * @param[in] blockSize length of the input vector
6574 * @return none.
6575 */
6576 void arm_float_to_q31(
6577 float32_t * pSrc,
6578 q31_t * pDst,
6579 uint32_t blockSize);
6580
6581 /**
6582 * @brief Converts the elements of the floating-point vector to Q15 vector.
6583 * @param[in] *pSrc points to the floating-point input vector
6584 * @param[out] *pDst points to the Q15 output vector
6585 * @param[in] blockSize length of the input vector
6586 * @return none
6587 */
6588 void arm_float_to_q15(
6589 float32_t * pSrc,
6590 q15_t * pDst,
6591 uint32_t blockSize);
6592
6593 /**
6594 * @brief Converts the elements of the floating-point vector to Q7 vector.
6595 * @param[in] *pSrc points to the floating-point input vector
6596 * @param[out] *pDst points to the Q7 output vector
6597 * @param[in] blockSize length of the input vector
6598 * @return none
6599 */
6600 void arm_float_to_q7(
6601 float32_t * pSrc,
6602 q7_t * pDst,
6603 uint32_t blockSize);
6604
6605
6606 /**
6607 * @brief Converts the elements of the Q31 vector to Q15 vector.
6608 * @param[in] *pSrc is input pointer
6609 * @param[out] *pDst is output pointer
6610 * @param[in] blockSize is the number of samples to process
6611 * @return none.
6612 */
6613 void arm_q31_to_q15(
6614 q31_t * pSrc,
6615 q15_t * pDst,
6616 uint32_t blockSize);
6617
6618 /**
6619 * @brief Converts the elements of the Q31 vector to Q7 vector.
6620 * @param[in] *pSrc is input pointer
6621 * @param[out] *pDst is output pointer
6622 * @param[in] blockSize is the number of samples to process
6623 * @return none.
6624 */
6625 void arm_q31_to_q7(
6626 q31_t * pSrc,
6627 q7_t * pDst,
6628 uint32_t blockSize);
6629
6630 /**
6631 * @brief Converts the elements of the Q15 vector to floating-point vector.
6632 * @param[in] *pSrc is input pointer
6633 * @param[out] *pDst is output pointer
6634 * @param[in] blockSize is the number of samples to process
6635 * @return none.
6636 */
6637 void arm_q15_to_float(
6638 q15_t * pSrc,
6639 float32_t * pDst,
6640 uint32_t blockSize);
6641
6642
6643 /**
6644 * @brief Converts the elements of the Q15 vector to Q31 vector.
6645 * @param[in] *pSrc is input pointer
6646 * @param[out] *pDst is output pointer
6647 * @param[in] blockSize is the number of samples to process
6648 * @return none.
6649 */
6650 void arm_q15_to_q31(
6651 q15_t * pSrc,
6652 q31_t * pDst,
6653 uint32_t blockSize);
6654
6655
6656 /**
6657 * @brief Converts the elements of the Q15 vector to Q7 vector.
6658 * @param[in] *pSrc is input pointer
6659 * @param[out] *pDst is output pointer
6660 * @param[in] blockSize is the number of samples to process
6661 * @return none.
6662 */
6663 void arm_q15_to_q7(
6664 q15_t * pSrc,
6665 q7_t * pDst,
6666 uint32_t blockSize);
6667
6668
6669 /**
6670 * @ingroup groupInterpolation
6671 */
6672
6673 /**
6674 * @defgroup BilinearInterpolate Bilinear Interpolation
6675 *
6676 * Bilinear interpolation is an extension of linear interpolation applied to a two dimensional grid.
6677 * The underlying function <code>f(x, y)</code> is sampled on a regular grid and the interpolation process
6678 * determines values between the grid points.
6679 * Bilinear interpolation is equivalent to two step linear interpolation, first in the x-dimension and then in the y-dimension.
6680 * Bilinear interpolation is often used in image processing to rescale images.
6681 * The CMSIS DSP library provides bilinear interpolation functions for Q7, Q15, Q31, and floating-point data types.
6682 *
6683 * <b>Algorithm</b>
6684 * \par
6685 * The instance structure used by the bilinear interpolation functions describes a two dimensional data table.
6686 * For floating-point, the instance structure is defined as:
6687 * <pre>
6688 * typedef struct
6689 * {
6690 * uint16_t numRows;
6691 * uint16_t numCols;
6692 * float32_t *pData;
6693 * } arm_bilinear_interp_instance_f32;
6694 * </pre>
6695 *
6696 * \par
6697 * where <code>numRows</code> specifies the number of rows in the table;
6698 * <code>numCols</code> specifies the number of columns in the table;
6699 * and <code>pData</code> points to an array of size <code>numRows*numCols</code> values.
6700 * The data table <code>pTable</code> is organized in row order and the supplied data values fall on integer indexes.
6701 * That is, table element (x,y) is located at <code>pTable[x + y*numCols]</code> where x and y are integers.
6702 *
6703 * \par
6704 * Let <code>(x, y)</code> specify the desired interpolation point. Then define:
6705 * <pre>
6706 * XF = floor(x)
6707 * YF = floor(y)
6708 * </pre>
6709 * \par
6710 * The interpolated output point is computed as:
6711 * <pre>
6712 * f(x, y) = f(XF, YF) * (1-(x-XF)) * (1-(y-YF))
6713 * + f(XF+1, YF) * (x-XF)*(1-(y-YF))
6714 * + f(XF, YF+1) * (1-(x-XF))*(y-YF)
6715 * + f(XF+1, YF+1) * (x-XF)*(y-YF)
6716 * </pre>
6717 * Note that the coordinates (x, y) contain integer and fractional components.
6718 * The integer components specify which portion of the table to use while the
6719 * fractional components control the interpolation processor.
6720 *
6721 * \par
6722 * if (x,y) are outside of the table boundary, Bilinear interpolation returns zero output.
6723 */
6724
6725 /**
6726 * @addtogroup BilinearInterpolate
6727 * @{
6728 */
6729
6730 /**
6731 *
6732 * @brief Floating-point bilinear interpolation.
6733 * @param[in,out] *S points to an instance of the interpolation structure.
6734 * @param[in] X interpolation coordinate.
6735 * @param[in] Y interpolation coordinate.
6736 * @return out interpolated value.
6737 */
6738
6739
6740 static __INLINE float32_t arm_bilinear_interp_f32(
6741 const arm_bilinear_interp_instance_f32 * S,
6742 float32_t X,
6743 float32_t Y)
6744 {
6745 float32_t out;
6746 float32_t f00, f01, f10, f11;
6747 float32_t *pData = S->pData;
6748 int32_t xIndex, yIndex, index;
6749 float32_t xdiff, ydiff;
6750 float32_t b1, b2, b3, b4;
6751
6752 xIndex = (int32_t) X;
6753 yIndex = (int32_t) Y;
6754
6755 /* Care taken for table outside boundary */
6756 /* Returns zero output when values are outside table boundary */
6757 if(xIndex < 0 || xIndex > (S->numRows-1) || yIndex < 0 || yIndex > ( S->numCols-1))
6758 {
6759 return(0);
6760 }
6761
6762 /* Calculation of index for two nearest points in X-direction */
6763 index = (xIndex - 1) + (yIndex-1) * S->numCols ;
6764
6765
6766 /* Read two nearest points in X-direction */
6767 f00 = pData[index];
6768 f01 = pData[index + 1];
6769
6770 /* Calculation of index for two nearest points in Y-direction */
6771 index = (xIndex-1) + (yIndex) * S->numCols;
6772
6773
6774 /* Read two nearest points in Y-direction */
6775 f10 = pData[index];
6776 f11 = pData[index + 1];
6777
6778 /* Calculation of intermediate values */
6779 b1 = f00;
6780 b2 = f01 - f00;
6781 b3 = f10 - f00;
6782 b4 = f00 - f01 - f10 + f11;
6783
6784 /* Calculation of fractional part in X */
6785 xdiff = X - xIndex;
6786
6787 /* Calculation of fractional part in Y */
6788 ydiff = Y - yIndex;
6789
6790 /* Calculation of bi-linear interpolated output */
6791 out = b1 + b2 * xdiff + b3 * ydiff + b4 * xdiff * ydiff;
6792
6793 /* return to application */
6794 return (out);
6795
6796 }
6797
6798 /**
6799 *
6800 * @brief Q31 bilinear interpolation.
6801 * @param[in,out] *S points to an instance of the interpolation structure.
6802 * @param[in] X interpolation coordinate in 12.20 format.
6803 * @param[in] Y interpolation coordinate in 12.20 format.
6804 * @return out interpolated value.
6805 */
6806
6807 static __INLINE q31_t arm_bilinear_interp_q31(
6808 arm_bilinear_interp_instance_q31 * S,
6809 q31_t X,
6810 q31_t Y)
6811 {
6812 q31_t out; /* Temporary output */
6813 q31_t acc = 0; /* output */
6814 q31_t xfract, yfract; /* X, Y fractional parts */
6815 q31_t x1, x2, y1, y2; /* Nearest output values */
6816 int32_t rI, cI; /* Row and column indices */
6817 q31_t *pYData = S->pData; /* pointer to output table values */
6818 uint32_t nCols = S->numCols; /* num of rows */
6819
6820
6821 /* Input is in 12.20 format */
6822 /* 12 bits for the table index */
6823 /* Index value calculation */
6824 rI = ((X & 0xFFF00000) >> 20u);
6825
6826 /* Input is in 12.20 format */
6827 /* 12 bits for the table index */
6828 /* Index value calculation */
6829 cI = ((Y & 0xFFF00000) >> 20u);
6830
6831 /* Care taken for table outside boundary */
6832 /* Returns zero output when values are outside table boundary */
6833 if(rI < 0 || rI > (S->numRows-1) || cI < 0 || cI > ( S->numCols-1))
6834 {
6835 return(0);
6836 }
6837
6838 /* 20 bits for the fractional part */
6839 /* shift left xfract by 11 to keep 1.31 format */
6840 xfract = (X & 0x000FFFFF) << 11u;
6841
6842 /* Read two nearest output values from the index */
6843 x1 = pYData[(rI) + nCols * (cI)];
6844 x2 = pYData[(rI) + nCols * (cI) + 1u];
6845
6846 /* 20 bits for the fractional part */
6847 /* shift left yfract by 11 to keep 1.31 format */
6848 yfract = (Y & 0x000FFFFF) << 11u;
6849
6850 /* Read two nearest output values from the index */
6851 y1 = pYData[(rI) + nCols * (cI + 1)];
6852 y2 = pYData[(rI) + nCols * (cI + 1) + 1u];
6853
6854 /* Calculation of x1 * (1-xfract ) * (1-yfract) and acc is in 3.29(q29) format */
6855 out = ((q31_t) (((q63_t) x1 * (0x7FFFFFFF - xfract)) >> 32));
6856 acc = ((q31_t) (((q63_t) out * (0x7FFFFFFF - yfract)) >> 32));
6857
6858 /* x2 * (xfract) * (1-yfract) in 3.29(q29) and adding to acc */
6859 out = ((q31_t) ((q63_t) x2 * (0x7FFFFFFF - yfract) >> 32));
6860 acc += ((q31_t) ((q63_t) out * (xfract) >> 32));
6861
6862 /* y1 * (1 - xfract) * (yfract) in 3.29(q29) and adding to acc */
6863 out = ((q31_t) ((q63_t) y1 * (0x7FFFFFFF - xfract) >> 32));
6864 acc += ((q31_t) ((q63_t) out * (yfract) >> 32));
6865
6866 /* y2 * (xfract) * (yfract) in 3.29(q29) and adding to acc */
6867 out = ((q31_t) ((q63_t) y2 * (xfract) >> 32));
6868 acc += ((q31_t) ((q63_t) out * (yfract) >> 32));
6869
6870 /* Convert acc to 1.31(q31) format */
6871 return (acc << 2u);
6872
6873 }
6874
6875 /**
6876 * @brief Q15 bilinear interpolation.
6877 * @param[in,out] *S points to an instance of the interpolation structure.
6878 * @param[in] X interpolation coordinate in 12.20 format.
6879 * @param[in] Y interpolation coordinate in 12.20 format.
6880 * @return out interpolated value.
6881 */
6882
6883 static __INLINE q15_t arm_bilinear_interp_q15(
6884 arm_bilinear_interp_instance_q15 * S,
6885 q31_t X,
6886 q31_t Y)
6887 {
6888 q63_t acc = 0; /* output */
6889 q31_t out; /* Temporary output */
6890 q15_t x1, x2, y1, y2; /* Nearest output values */
6891 q31_t xfract, yfract; /* X, Y fractional parts */
6892 int32_t rI, cI; /* Row and column indices */
6893 q15_t *pYData = S->pData; /* pointer to output table values */
6894 uint32_t nCols = S->numCols; /* num of rows */
6895
6896 /* Input is in 12.20 format */
6897 /* 12 bits for the table index */
6898 /* Index value calculation */
6899 rI = ((X & 0xFFF00000) >> 20);
6900
6901 /* Input is in 12.20 format */
6902 /* 12 bits for the table index */
6903 /* Index value calculation */
6904 cI = ((Y & 0xFFF00000) >> 20);
6905
6906 /* Care taken for table outside boundary */
6907 /* Returns zero output when values are outside table boundary */
6908 if(rI < 0 || rI > (S->numRows-1) || cI < 0 || cI > ( S->numCols-1))
6909 {
6910 return(0);
6911 }
6912
6913 /* 20 bits for the fractional part */
6914 /* xfract should be in 12.20 format */
6915 xfract = (X & 0x000FFFFF);
6916
6917 /* Read two nearest output values from the index */
6918 x1 = pYData[(rI) + nCols * (cI)];
6919 x2 = pYData[(rI) + nCols * (cI) + 1u];
6920
6921
6922 /* 20 bits for the fractional part */
6923 /* yfract should be in 12.20 format */
6924 yfract = (Y & 0x000FFFFF);
6925
6926 /* Read two nearest output values from the index */
6927 y1 = pYData[(rI) + nCols * (cI + 1)];
6928 y2 = pYData[(rI) + nCols * (cI + 1) + 1u];
6929
6930 /* Calculation of x1 * (1-xfract ) * (1-yfract) and acc is in 13.51 format */
6931
6932 /* x1 is in 1.15(q15), xfract in 12.20 format and out is in 13.35 format */
6933 /* convert 13.35 to 13.31 by right shifting and out is in 1.31 */
6934 out = (q31_t) (((q63_t) x1 * (0xFFFFF - xfract)) >> 4u);
6935 acc = ((q63_t) out * (0xFFFFF - yfract));
6936
6937 /* x2 * (xfract) * (1-yfract) in 1.51 and adding to acc */
6938 out = (q31_t) (((q63_t) x2 * (0xFFFFF - yfract)) >> 4u);
6939 acc += ((q63_t) out * (xfract));
6940
6941 /* y1 * (1 - xfract) * (yfract) in 1.51 and adding to acc */
6942 out = (q31_t) (((q63_t) y1 * (0xFFFFF - xfract)) >> 4u);
6943 acc += ((q63_t) out * (yfract));
6944
6945 /* y2 * (xfract) * (yfract) in 1.51 and adding to acc */
6946 out = (q31_t) (((q63_t) y2 * (xfract)) >> 4u);
6947 acc += ((q63_t) out * (yfract));
6948
6949 /* acc is in 13.51 format and down shift acc by 36 times */
6950 /* Convert out to 1.15 format */
6951 return (acc >> 36);
6952
6953 }
6954
6955 /**
6956 * @brief Q7 bilinear interpolation.
6957 * @param[in,out] *S points to an instance of the interpolation structure.
6958 * @param[in] X interpolation coordinate in 12.20 format.
6959 * @param[in] Y interpolation coordinate in 12.20 format.
6960 * @return out interpolated value.
6961 */
6962
6963 static __INLINE q7_t arm_bilinear_interp_q7(
6964 arm_bilinear_interp_instance_q7 * S,
6965 q31_t X,
6966 q31_t Y)
6967 {
6968 q63_t acc = 0; /* output */
6969 q31_t out; /* Temporary output */
6970 q31_t xfract, yfract; /* X, Y fractional parts */
6971 q7_t x1, x2, y1, y2; /* Nearest output values */
6972 int32_t rI, cI; /* Row and column indices */
6973 q7_t *pYData = S->pData; /* pointer to output table values */
6974 uint32_t nCols = S->numCols; /* num of rows */
6975
6976 /* Input is in 12.20 format */
6977 /* 12 bits for the table index */
6978 /* Index value calculation */
6979 rI = ((X & 0xFFF00000) >> 20);
6980
6981 /* Input is in 12.20 format */
6982 /* 12 bits for the table index */
6983 /* Index value calculation */
6984 cI = ((Y & 0xFFF00000) >> 20);
6985
6986 /* Care taken for table outside boundary */
6987 /* Returns zero output when values are outside table boundary */
6988 if(rI < 0 || rI > (S->numRows-1) || cI < 0 || cI > ( S->numCols-1))
6989 {
6990 return(0);
6991 }
6992
6993 /* 20 bits for the fractional part */
6994 /* xfract should be in 12.20 format */
6995 xfract = (X & 0x000FFFFF);
6996
6997 /* Read two nearest output values from the index */
6998 x1 = pYData[(rI) + nCols * (cI)];
6999 x2 = pYData[(rI) + nCols * (cI) + 1u];
7000
7001
7002 /* 20 bits for the fractional part */
7003 /* yfract should be in 12.20 format */
7004 yfract = (Y & 0x000FFFFF);
7005
7006 /* Read two nearest output values from the index */
7007 y1 = pYData[(rI) + nCols * (cI + 1)];
7008 y2 = pYData[(rI) + nCols * (cI + 1) + 1u];
7009
7010 /* Calculation of x1 * (1-xfract ) * (1-yfract) and acc is in 16.47 format */
7011 out = ((x1 * (0xFFFFF - xfract)));
7012 acc = (((q63_t) out * (0xFFFFF - yfract)));
7013
7014 /* x2 * (xfract) * (1-yfract) in 2.22 and adding to acc */
7015 out = ((x2 * (0xFFFFF - yfract)));
7016 acc += (((q63_t) out * (xfract)));
7017
7018 /* y1 * (1 - xfract) * (yfract) in 2.22 and adding to acc */
7019 out = ((y1 * (0xFFFFF - xfract)));
7020 acc += (((q63_t) out * (yfract)));
7021
7022 /* y2 * (xfract) * (yfract) in 2.22 and adding to acc */
7023 out = ((y2 * (yfract)));
7024 acc += (((q63_t) out * (xfract)));
7025
7026 /* acc in 16.47 format and down shift by 40 to convert to 1.7 format */
7027 return (acc >> 40);
7028
7029 }
7030
7031 /**
7032 * @} end of BilinearInterpolate group
7033 */
7034
7035
7036
7037
7038
7039
7040 #ifdef __cplusplus
7041 }
7042 #endif
7043
7044
7045 #endif /* _ARM_MATH_H */
7046
7047
7048 /**
7049 *
7050 * End of file.
7051 */