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libcm is a C development framework with an emphasis on audio signal processing applications.
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libcm/vop/cmVectOpsRIHdr.h

cmVectOpsRIHdr.h 13KB
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  1. 

  2. VECT_OP_TYPE* VECT_OP_FUNC(Col)(    VECT_OP_TYPE* m, unsigned ci, unsigned rn, unsigned cn );

  3. VECT_OP_TYPE* VECT_OP_FUNC(Row)(    VECT_OP_TYPE* m, unsigned ri, unsigned rn, unsigned cn );

  4. VECT_OP_TYPE* VECT_OP_FUNC(ElePtr)( VECT_OP_TYPE* m, unsigned ri, unsigned ci, unsigned rn, unsigned cn );

  5. VECT_OP_TYPE  VECT_OP_FUNC(Ele)(    VECT_OP_TYPE* m, unsigned ri, unsigned ci, unsigned rn, unsigned cn );

  6. void          VECT_OP_FUNC(Set)(    VECT_OP_TYPE* m, unsigned ri, unsigned ci, unsigned rn, unsigned cn, VECT_OP_TYPE v );

  7. 

  8. const VECT_OP_TYPE* VECT_OP_FUNC(CCol)(    const VECT_OP_TYPE* m, unsigned ci, unsigned rn, unsigned cn );

  9. const VECT_OP_TYPE* VECT_OP_FUNC(CRow)(    const VECT_OP_TYPE* m, unsigned ri, unsigned rn, unsigned cn );

  10. const VECT_OP_TYPE* VECT_OP_FUNC(CElePtr)( const VECT_OP_TYPE* m, unsigned ri, unsigned ci, unsigned rn, unsigned cn );

  11. VECT_OP_TYPE        VECT_OP_FUNC(CEle)(    const VECT_OP_TYPE* m, unsigned ri, unsigned ci, unsigned rn, unsigned cn );

  12. 

  13. 

  14. 

  15. /// Fill a vector with a value. If value is 0 then the function is accellerated via memset().

  16. VECT_OP_TYPE* VECT_OP_FUNC(Fill)( VECT_OP_TYPE* dbp, unsigned dn, VECT_OP_TYPE value  );

  17. 

  18. // Fill a vector with zeros

  19. VECT_OP_TYPE* VECT_OP_FUNC(Zero)( VECT_OP_TYPE* dbp, unsigned dn  );

  20. 

  21. // analogous to memmove()

  22. VECT_OP_TYPE* VECT_OP_FUNC(Move)(  VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sp );

  23. 

  24. /// Fill the vector from various sources

  25. VECT_OP_TYPE* VECT_OP_FUNC(Copy)(  VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sp );

  26. VECT_OP_TYPE* VECT_OP_FUNC(CopyN)( VECT_OP_TYPE* dbp, unsigned dn, unsigned d_stride, const VECT_OP_TYPE* sp, unsigned s_stride );

  27. VECT_OP_TYPE* VECT_OP_FUNC(CopyU)( VECT_OP_TYPE* dbp, unsigned dn, const unsigned* sp );

  28. VECT_OP_TYPE* VECT_OP_FUNC(CopyI)( VECT_OP_TYPE* dbp, unsigned dn, const int* sp );

  29. VECT_OP_TYPE* VECT_OP_FUNC(CopyF)( VECT_OP_TYPE* dbp, unsigned dn, const float* sp );

  30. VECT_OP_TYPE* VECT_OP_FUNC(CopyD)( VECT_OP_TYPE* dbp, unsigned dn, const double* sp );

  31. VECT_OP_TYPE* VECT_OP_FUNC(CopyS)( VECT_OP_TYPE* dbp, unsigned dn, const cmSample_t* sp );

  32. VECT_OP_TYPE* VECT_OP_FUNC(CopyR)( VECT_OP_TYPE* dbp, unsigned dn, const cmReal_t* sp );

  33. 

  34. // Shrink the elemetns of dbp[dn] by copying all elements past t+tn to t.

  35. // This operation results in overwriting the elements in the range t[tn].

  36. // t[tn] must be entirely inside dbp[dn].

  37. VECT_OP_TYPE* VECT_OP_FUNC(Shrink)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* t, unsigned tn );

  38. 

  39. // Expand dbp[[dn] by shifting all elements past t to t+tn.

  40. // This produces a set of empty elements in t[tn].

  41. // t must be inside or at the end of dbp[dn].

  42. // This results in a reallocation of dbp[]. Be sure to call cmMemFree(dbp)

  43. // to release the returned pointer.

  44. VECT_OP_TYPE* VECT_OP_FUNC(Expand)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* t, unsigned tn );                                                            

  45. 

  46. // Replace the elements t[tn] with the elements in u[un]. 

  47. // t must be inside or at the end of dbp[dn].

  48. // This operation may result in a reallocation of dbp[]. Be sure to call cmMemFree(dbp)

  49. // to release the returned pointer.

  50. // IF dbp==NULL and tn==0 then the dbp[un] is allocated and returned 

  51. // with the contents of u[un].

  52. VECT_OP_TYPE* VECT_OP_FUNC(Replace)(VECT_OP_TYPE* dbp, unsigned* dn, const VECT_OP_TYPE* t, unsigned tn, const VECT_OP_TYPE* u, unsigned un );

  53. 

  54. /// Fill the the destination vector from a source vector where the source vector contains

  55. /// srcStride interleaved elements to be ignored. 

  56. VECT_OP_TYPE* VECT_OP_FUNC(CopyStride)(  VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sp, unsigned srcStride );

  57. 

  58. 

  59. /// Assuming a row vector positive shiftCnt rotates right, negative shiftCnt rotates left.

  60. VECT_OP_TYPE* VECT_OP_FUNC(Rotate)( VECT_OP_TYPE* dbp, unsigned dn, int shiftCnt );

  61. 

  62. /// Equivalent to Matlab circshift().

  63. VECT_OP_TYPE* VECT_OP_FUNC(RotateM)( VECT_OP_TYPE* dbp, unsigned drn, unsigned dcn, const VECT_OP_TYPE* sbp, int rShift, int cShift  );

  64. 

  65. /// Assuming a row vector positive shiftCnt shifts right, negative shiftCnt shifts left.

  66. VECT_OP_TYPE* VECT_OP_FUNC(Shift)( VECT_OP_TYPE* dbp, unsigned dn, int shiftCnt, VECT_OP_TYPE fill );

  67. 

  68. /// Reverse the contents of the vector.

  69. VECT_OP_TYPE* VECT_OP_FUNC(Flip)(  VECT_OP_TYPE* dbp, unsigned dn);

  70. 

  71. 

  72. 

  73. VECT_OP_TYPE* VECT_OP_FUNC(SubVS)(  VECT_OP_TYPE* dp, unsigned dn, VECT_OP_TYPE v );

  74. VECT_OP_TYPE* VECT_OP_FUNC(SubVV)(  VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* v );

  75. VECT_OP_TYPE* VECT_OP_FUNC(SubVVS)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* v, VECT_OP_TYPE s );

  76. VECT_OP_TYPE* VECT_OP_FUNC(SubVVNN)(VECT_OP_TYPE* dp, unsigned dn, unsigned dnn, const VECT_OP_TYPE* sp, unsigned snn );

  77. VECT_OP_TYPE* VECT_OP_FUNC(SubVVV)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* sb0p, const VECT_OP_TYPE* sb1p );

  78. VECT_OP_TYPE* VECT_OP_FUNC(SubVSV)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE  s0, const VECT_OP_TYPE* sb1p );

  79. 

  80. VECT_OP_TYPE* VECT_OP_FUNC(AddVS)(  VECT_OP_TYPE* dp, unsigned dn, VECT_OP_TYPE v );

  81. VECT_OP_TYPE* VECT_OP_FUNC(AddVV)(  VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* v );

  82. VECT_OP_TYPE* VECT_OP_FUNC(AddVVS)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* v, VECT_OP_TYPE s );

  83. VECT_OP_TYPE* VECT_OP_FUNC(AddVVNN)(VECT_OP_TYPE* dp, unsigned dn, unsigned dnn, const VECT_OP_TYPE* sp, unsigned snn );

  84. VECT_OP_TYPE* VECT_OP_FUNC(AddVVV)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* sb0p, const VECT_OP_TYPE* sb1p );

  85. 

  86. VECT_OP_TYPE* VECT_OP_FUNC(MultVVV)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sb0p, const VECT_OP_TYPE* sb1p );

  87. VECT_OP_TYPE* VECT_OP_FUNC(MultVV)(  VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sbp );

  88. VECT_OP_TYPE* VECT_OP_FUNC(MultVVNN)(VECT_OP_TYPE* dp,  unsigned dn, unsigned dnn, const VECT_OP_TYPE* sp, unsigned snn );

  89. VECT_OP_TYPE* VECT_OP_FUNC(MultVS)(  VECT_OP_TYPE* dbp, unsigned dn, VECT_OP_TYPE s );

  90. VECT_OP_TYPE* VECT_OP_FUNC(MultVVS)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sbp, VECT_OP_TYPE s );

  91. VECT_OP_TYPE* VECT_OP_FUNC(MultVaVS)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sbp, VECT_OP_TYPE s );

  92. VECT_OP_TYPE* VECT_OP_FUNC(MultSumVVS)(VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sbp, VECT_OP_TYPE s );

  93. 

  94. VECT_OP_TYPE* VECT_OP_FUNC(DivVVS)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sb0p, VECT_OP_TYPE sb1 );

  95. VECT_OP_TYPE* VECT_OP_FUNC(DivVVV)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sb0p, const VECT_OP_TYPE* sb1p );

  96. VECT_OP_TYPE* VECT_OP_FUNC(DivVV)(  VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sb0p );

  97. VECT_OP_TYPE* VECT_OP_FUNC(DivVVNN)(VECT_OP_TYPE* dp,  unsigned dn, unsigned dnn, const VECT_OP_TYPE* sp, unsigned snn );

  98. VECT_OP_TYPE* VECT_OP_FUNC(DivVS)(  VECT_OP_TYPE* dbp, unsigned dn, VECT_OP_TYPE s );

  99. VECT_OP_TYPE* VECT_OP_FUNC(DivVSV)( VECT_OP_TYPE* dp,  unsigned dn, const VECT_OP_TYPE  s0, const VECT_OP_TYPE* sb1p );

  100. 

  101. // Set dest to 0 if denominator is 0.

  102. VECT_OP_TYPE* VECT_OP_FUNC(DivVVVZ)( VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sb0p, const VECT_OP_TYPE* sb1p );

  103. VECT_OP_TYPE* VECT_OP_FUNC(DivVVZ)(  VECT_OP_TYPE* dbp, unsigned dn, const VECT_OP_TYPE* sb0p );

  104. 

  105. // Divide columns of dp[:,i] by each value in the source vector sp[i]. 

  106. VECT_OP_TYPE*  VECT_OP_FUNC(DivMS)(    VECT_OP_TYPE* dp, unsigned drn, unsigned dcn, const VECT_OP_TYPE* sp ); 

  107. 

  108. 

  109. VECT_OP_TYPE  VECT_OP_FUNC(Sum)(      const VECT_OP_TYPE* sp, unsigned sn );

  110. VECT_OP_TYPE  VECT_OP_FUNC(SumN)(     const VECT_OP_TYPE* sp, unsigned sn, unsigned stride );

  111. 

  112. // Sum the columns of sp[srn,scn] into dp[scn]. 

  113. // dp[] is zeroed prior to computing the sum.

  114. VECT_OP_TYPE*  VECT_OP_FUNC(SumM)(     const VECT_OP_TYPE* sp, unsigned srn, unsigned scn, VECT_OP_TYPE* dp );

  115. 

  116. // Sum the rows of sp[srn,scn] into dp[srn]

  117. // dp[] is zeroed prior to computing the sum.

  118. VECT_OP_TYPE*  VECT_OP_FUNC(SumMN)(    const VECT_OP_TYPE* sp, unsigned srn, unsigned scn, VECT_OP_TYPE* dp );

  119. 

  120. VECT_OP_TYPE*   VECT_OP_FUNC(Abs)(   VECT_OP_TYPE* dbp, unsigned dn );

  121. 

  122. 

  123. VECT_OP_TYPE  VECT_OP_FUNC(Median)(   const VECT_OP_TYPE* sp, unsigned sn );

  124. unsigned      VECT_OP_FUNC(MinIndex)( const VECT_OP_TYPE* sp, unsigned sn, unsigned stride );

  125. unsigned      VECT_OP_FUNC(MaxIndex)( const VECT_OP_TYPE* sp, unsigned sn, unsigned stride );

  126. VECT_OP_TYPE  VECT_OP_FUNC(Min)(      const VECT_OP_TYPE* sp, unsigned sn, unsigned stride );

  127. VECT_OP_TYPE  VECT_OP_FUNC(Max)(      const VECT_OP_TYPE* sp, unsigned sn, unsigned stride );

  128. 

  129. VECT_OP_TYPE*  VECT_OP_FUNC(MinVV)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* sp );

  130. VECT_OP_TYPE*  VECT_OP_FUNC(MaxVV)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* sp );

  131. 

  132. 

  133. /// Return index of max/min value into dp[scn] of each column of sp[srn,scn]

  134. unsigned*  VECT_OP_FUNC(MinIndexM)( unsigned* dp, const VECT_OP_TYPE* sp, unsigned srn, unsigned scn );

  135. unsigned*  VECT_OP_FUNC(MaxIndexM)( unsigned* dp, const VECT_OP_TYPE* sp, unsigned srn, unsigned scn );

  136. 

  137. /// Return true if s0p[sn] is equal to s1p[sn]

  138. bool       VECT_OP_FUNC(IsEqual)( const VECT_OP_TYPE* s0p, const VECT_OP_TYPE* s1p, unsigned sn );

  139. 

  140. /// Return true if all elements of s0p[sn] are within 'eps' of s1p[sn].

  141. /// This function is based on cmMath.h:cmIsCloseX()

  142. bool VECT_OP_FUNC(IsClose)( const VECT_OP_TYPE* s0p, const VECT_OP_TYPE* s1p, unsigned sn, double eps );

  143. 

  144. /// Return the most frequently occuring element in sp.

  145. VECT_OP_TYPE  VECT_OP_FUNC(Mode)(     const VECT_OP_TYPE* sp, unsigned sn );

  146. 

  147. /// Replace all values <= lteKeyVal with replaceVal.  sp==dp is legal.

  148. VECT_OP_TYPE* VECT_OP_FUNC(ReplaceLte)( VECT_OP_TYPE* dp, unsigned dn, const VECT_OP_TYPE* sp, VECT_OP_TYPE lteKeyVal, VECT_OP_TYPE replaceVal );

  149. 

  150. /// Return the index of 'key' in sp[sn] or cmInvalidIdx if 'key' does not exist.

  151. unsigned VECT_OP_FUNC(Find)( const VECT_OP_TYPE* sp, unsigned sn, VECT_OP_TYPE key );

  152. 

  153. /// Count the number of times 'key' occurs in sp[sn].

  154. unsigned VECT_OP_FUNC(Count)(const VECT_OP_TYPE* sp, unsigned sn, VECT_OP_TYPE key );

  155. 

  156. /// Set only the diagonal of a square mtx to sbp.

  157. VECT_OP_TYPE* VECT_OP_FUNC(Diag)( VECT_OP_TYPE* dbp, unsigned n, const VECT_OP_TYPE* sbp );

  158. 

  159. /// Set the diagonal of a square mtx to db to sbp and set all other values to zero.

  160. VECT_OP_TYPE* VECT_OP_FUNC(DiagZ)( VECT_OP_TYPE* dbp, unsigned n, const VECT_OP_TYPE* sbp ); 

  161. 

  162. /// Create an identity matrix (only sets 1's not zeros).

  163. VECT_OP_TYPE* VECT_OP_FUNC(Identity)(  VECT_OP_TYPE* dbp, unsigned rn, unsigned cn );

  164. 

  165. /// Zero the matrix and then fill it as an identity matrix.

  166. VECT_OP_TYPE* VECT_OP_FUNC(IdentityZ)( VECT_OP_TYPE* dbp, unsigned rn, unsigned cn );

  167. 

  168. /// Transpose the matrix sbp[srn,scn] into dbp[scn,srn]

  169. VECT_OP_TYPE* VECT_OP_FUNC(Transpose)(  VECT_OP_TYPE* dbp, const VECT_OP_TYPE* sbp, unsigned srn, unsigned scn );

  170. 

  171. /// Fill dbp[] with a sequence of values. Returns next value. 

  172. VECT_OP_TYPE  VECT_OP_FUNC(Seq)( VECT_OP_TYPE* dbp, unsigned dn, VECT_OP_TYPE beg, VECT_OP_TYPE incr );

  173. 

  174. 

  175. /// Apply a median or other filter of order wndN to xV[xN] and store the result in yV[xN].

  176. /// When the window goes off either side of the vector the window is shortened.

  177. /// This algorithm produces the same result as the fn_thresh function in MATLAB fv codebase.

  178. void VECT_OP_FUNC(FnThresh)( const VECT_OP_TYPE* xV, unsigned xN, unsigned wndN, VECT_OP_TYPE* yV, unsigned yStride, VECT_OP_TYPE (*fnPtr)(const VECT_OP_TYPE*, unsigned) );

  179. 

  180. 

  181. /// Apply a median filter of order wndN  to xV[xN] and store the result in yV[xN].

  182. /// When the window goes off either side of the vector the missing elements are considered

  183. /// to be 0.

  184. /// This algorithm produces the same result as the MATLAB medfilt1() function.

  185. void VECT_OP_FUNC(MedianFilt)( const VECT_OP_TYPE* xV, unsigned xN, unsigned wndN, VECT_OP_TYPE* yV, unsigned yStride );

  186. 

  187. 

  188. 

  189. /// Allocate and initialize a matrix for use by LevEditDist().

  190. /// This matrix can be released with a call to cmMemFree().

  191. unsigned* VECT_OP_FUNC(LevEditDistAllocMtx)(unsigned mtxMaxN);

  192. 

  193. /// Return the Levenshtein edit distance between two vectors.

  194. /// m must point to a matrix pre-allocated by VECT_OP_FUNC(InitiLevEditDistMtx)(maxN).

  195. double  VECT_OP_FUNC(LevEditDist)(unsigned mtxMaxN, unsigned* m, const VECT_OP_TYPE* s0, int n0, const VECT_OP_TYPE* s1, int n1, unsigned maxN );

  196. 

  197. /// Return the Levenshtein edit distance between two vectors.

  198. /// Edit distance with a max cost threshold. This version of the algorithm

  199. /// will run faster than LevEditDist() because it will stop execution as soon

  200. /// as the distance exceeds 'maxCost'.

  201. /// 'maxCost' must be between 0.0 and 1.0 or it is forced into this range.

  202. /// The maximum distance returned will be 'maxCost'.

  203. /// m must point to a matrix pre-allocated by VECT_OP_FUNC(InitiLevEditDistMtx)(maxN).

  204. double VECT_OP_FUNC(LevEditDistWithCostThresh)( int mtxMaxN, unsigned* m, const VECT_OP_TYPE* s0, int n0, const VECT_OP_TYPE* s1, int n1, double maxCost, unsigned maxN );