libcm is a C development framework with an emphasis on audio signal processing applications.
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cmProc2.h 36KB

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  1. #ifndef cmProc2_h
  2. #define cmProc2_h
  3. #ifdef __cplusplus
  4. extern "C" {
  5. #endif
  6. //------------------------------------------------------------------------------------------------------------
  7. // cmArray is an expandable array designed to work easily with the alloc/init/final/free model
  8. // used by this library. The arrays can be safely used by using the cmArrayAllocXXX macros
  9. // with static cmArray member fields during object allocation. cmArrayResizeXXX macros are then
  10. // used during the object initialization phase to allocate the actual array data space. Notice that
  11. // when used this way there is no need to call cmArrayFinal() prior to cmArrayResizeXXX().
  12. // The data memory used by cmArray's is allocated through the cmAllocData() and cmAllocDataZ()
  13. // macros. The resulting base memory address is therefore guaranteed to be aligned to a
  14. // 16 byte address boundary.
  15. typedef struct
  16. {
  17. cmObj obj;
  18. char* ptr;
  19. unsigned allocByteCnt;
  20. unsigned eleCnt;
  21. unsigned eleByteCnt;
  22. } cmArray;
  23. enum
  24. {
  25. kZeroArrayFl = 0x01
  26. };
  27. cmArray* cmArrayAllocate( cmCtx* c, cmArray* p, unsigned eleCnt, unsigned eleByteCnt, unsigned flags );
  28. cmRC_t cmArrayFree( cmArray** pp );
  29. cmRC_t cmArrayInit( cmArray* p, unsigned eleCnt, unsigned eleByteCnt, unsigned flags );
  30. cmRC_t cmArrayFinal( cmArray* p );
  31. char* cmArrayReallocDestroy( cmArray* p, unsigned newEleCnt, unsigned newEleByteCnt, unsigned flags );
  32. void cmArrayReallocDestroyV(cmArray* p, int eleByteCnt,unsigned flags, ... );
  33. char* cmArrayReallocPreserve(cmArray* p, unsigned newEleCnt, unsigned newEleByteCnt, unsigned flags );
  34. #define cmArrayAlloc( c, p ) cmArrayAllocate(c,p,0,0,0);
  35. #define cmArrayAllocInit( c, p, eleCnt, type ) cmArrayAllocate(c,p,eleCnt,sizeof(type),0)
  36. #define cmArrayAllocInitZ( c, p, eleCnt, type ) cmArrayAllocate(c,p,eleCnt,sizeof(type),kZeroArrayFl)
  37. #define cmArrayResize( c, p, newEleCnt, type ) (type*)cmArrayReallocDestroy(c,p,newEleCnt,sizeof(type), 0 )
  38. #define cmArrayResizeZ( c, p, newEleCnt, type ) (type*)cmArrayReallocDestroy(c,p,newEleCnt,sizeof(type), kZeroArrayFl )
  39. #define cmArrayResizePreserve( c, p, newEleCnt, type ) (type*)cmArrayReallocPreserve(c,p,newEleCnt,sizeof(type), 0 )
  40. #define cmArrayResizePreserveZ(c, p, newEleCnt, type ) (type*)cmArrayReallocPreserve(c,p,newEleCnt,sizeof(type), kZeroArrayFl )
  41. #define cmArrayResizeV( c, p, type, ... ) cmArrayReallocDestroyV(c,p,sizeof(type),0,##__VA_ARGS__)
  42. #define cmArrayResizeVZ( c, p, type, ... ) cmArrayReallocDestroyV(c,p,sizeof(type),kZeroArrayFl,##__VA_ARGS__)
  43. #define cmArrayPtr( type, p ) (type*)(p)->ptr
  44. #define cmArrayCount( p ) (p)->eleCnt
  45. //------------------------------------------------------------------------------------------------------------
  46. typedef struct
  47. {
  48. cmObj obj;
  49. cmAudioFileH_t h;
  50. unsigned chCnt;
  51. unsigned curChCnt;
  52. unsigned procSmpCnt;
  53. char* fn;
  54. cmSample_t* bufV;
  55. } cmAudioFileWr;
  56. cmAudioFileWr* cmAudioFileWrAlloc( cmCtx* c, cmAudioFileWr* p, unsigned procSmpCnt, const char* fn, double srate, unsigned chCnt, unsigned bitsPerSample );
  57. cmRC_t cmAudioFileWrFree( cmAudioFileWr** pp );
  58. cmRC_t cmAudioFileWrInit( cmAudioFileWr* p, unsigned procSmpCnt, const char* fn, double srate, unsigned chCnt, unsigned bitsPerSample );
  59. cmRC_t cmAudioFileWrFinal( cmAudioFileWr* p );
  60. cmRC_t cmAudioFileWrExec( cmAudioFileWr* p, unsigned chIdx, const cmSample_t* sp, unsigned sn );
  61. void cmAudioFileWrTest();
  62. //------------------------------------------------------------------------------------------------------------
  63. typedef struct
  64. {
  65. cmObj obj;
  66. unsigned rn;
  67. unsigned cn;
  68. cmSample_t *bufPtr;
  69. } cmMatrixBuf;
  70. /// Set p to NULL to dynamically allocate the object
  71. cmMatrixBuf* cmMatrixBufAllocFile(cmCtx* c, cmMatrixBuf* p, const char* fn );
  72. cmMatrixBuf* cmMatrixBufAllocCopy(cmCtx* c, cmMatrixBuf* p, unsigned rn, unsigned cn, const cmSample_t* sp );
  73. cmMatrixBuf* cmMatrixBufAlloc( cmCtx* c, cmMatrixBuf* p, unsigned rn, unsigned cn );
  74. cmRC_t cmMatrixBufFree( cmMatrixBuf**p );
  75. cmRC_t cmMatrixBufInitFile( cmMatrixBuf* p, const char* fn );
  76. cmRC_t cmMatrixBufInitCopy( cmMatrixBuf* p, unsigned rn, unsigned cn, const cmSample_t* sp );
  77. cmRC_t cmMatrixBufInit( cmMatrixBuf* p, unsigned rn, unsigned cn );
  78. cmRC_t cmMatrixBufFinal( cmMatrixBuf* p );
  79. cmSample_t* cmMatrixBufColPtr( cmMatrixBuf* p, unsigned ci );
  80. cmSample_t* cmMatrixBufRowPtr( cmMatrixBuf* p, unsigned ri );
  81. void cmMatrixBufTest();
  82. //------------------------------------------------------------------------------------------------------------
  83. enum
  84. {
  85. kInvalidWfId,
  86. kSineWfId,
  87. kCosWfId,
  88. kSquareWfId,
  89. kTriangleWfId,
  90. kSawtoothWfId,
  91. kWhiteWfId,
  92. kPinkWfId,
  93. kPulseWfId,
  94. kImpulseWfId,
  95. kSilenceWfId,
  96. kPhasorWfId,
  97. kSeqWfId, // always incrementing integer sequence (srate,frq,otCnt is ignored)
  98. } cmSigGenWaveformId;
  99. typedef struct
  100. {
  101. cmObj obj;
  102. unsigned wfId;
  103. unsigned overToneCnt;
  104. double fundFrqHz;
  105. cmSample_t* outV;
  106. unsigned outN; // outN == procSmpCnt
  107. unsigned phase;
  108. cmSample_t delaySmp;
  109. double srate;
  110. } cmSigGen;
  111. /// Set p to NULL to dynamically allocate the object
  112. /// The last three arguments are optional. Set wfId to kInvalidWfId to allocate the signal generator without initializint it.
  113. cmSigGen* cmSigGenAlloc( cmCtx* c, cmSigGen* p, unsigned procSmpCnt, double srate, unsigned wfId, double fundFrqHz, unsigned overToneCnt );
  114. cmRC_t cmSigGenFree( cmSigGen** p );
  115. cmRC_t cmSigGenInit( cmSigGen* p, unsigned procSmpCnt, double srate, unsigned wfId, double fundFrqHz, unsigned overToneCnt );
  116. cmRC_t cmSigGenFinal( cmSigGen* p );
  117. cmRC_t cmSigGenExec( cmSigGen* p );
  118. //------------------------------------------------------------------------------------------------------------
  119. typedef struct
  120. {
  121. cmObj* obj;
  122. cmSample_t* bufPtr;
  123. unsigned bufSmpCnt; // count of samples in the delay line (bufSmpCnt = procSmpCnt+delaySmpCnt)
  124. unsigned procSmpCnt; // maximum legal samples to receive in a single call to cmDelayExec()
  125. unsigned delaySmpCnt; // delay time in samples
  126. int delayInIdx; // index into bufPtr[] of next element to receive an incoming sample
  127. unsigned outCnt; // count of valid buffers in outV[]
  128. cmSample_t* outV[2]; // pointers to output buffers
  129. unsigned outN[2]; // length of output buffers (the sum of the length of both output buffers is always procSmpCnt)
  130. } cmDelay;
  131. cmDelay* cmDelayAlloc( cmCtx* c, cmDelay* p, unsigned procSmpCnt, unsigned delaySmpCnt );
  132. cmRC_t cmDelayFree( cmDelay** p );
  133. cmRC_t cmDelayInit( cmDelay* p, unsigned procSmpCnt, unsigned delaySmpCnt );
  134. cmRC_t cmDelayFinal( cmDelay* p );
  135. cmRC_t cmDelayCopyIn( cmDelay* p, const cmSample_t* sp, unsigned sn );
  136. cmRC_t cmDelayAdvance( cmDelay* p, unsigned sn );
  137. cmRC_t cmDelayExec( cmDelay* p, const cmSample_t* sp, unsigned sn, bool bypassFl );
  138. void cmDelayTest();
  139. //------------------------------------------------------------------------------------------------------------
  140. typedef struct
  141. {
  142. cmObj obj;
  143. double* coeffV; // FIR coefficient vector (impulse response)
  144. unsigned coeffCnt; // count of elements in coeffV
  145. double* delayV; // delay vector contains one less elements than the coeff array
  146. cmSample_t* outV; // output signal
  147. unsigned outN; // length of the output signal (outN == ctx.procSmpCnt)
  148. unsigned delayIdx; // current next sample to receive input in the the delay line
  149. } cmFIR;
  150. enum { kHighPassFIRFl = 0x01 };
  151. /// Set p to NULL to dynamically allocate the object.
  152. cmFIR* cmFIRAllocKaiser(cmCtx* c, cmFIR* p, unsigned procSmpCnt, double srate, double passHz, double stopHz, double passDb, double stopDb );
  153. cmFIR* cmFIRAllocSinc( cmCtx* c, cmFIR* p, unsigned procSmpCnt, double srate, unsigned sincSmpCnt, double fcHz, unsigned flags );
  154. cmRC_t cmFIRFree( cmFIR** pp );
  155. cmRC_t cmFIRInitKaiser( cmFIR* p, unsigned procSmpCnt, double srate, double passHz, double stopHz, double passDb, double stopDb );
  156. cmRC_t cmFIRInitSinc( cmFIR* p, unsigned procSmpCnt, double srate, unsigned sincSmpCnt, double fcHz, unsigned flags );
  157. cmRC_t cmFIRFinal( cmFIR* p );
  158. cmRC_t cmFIRExec( cmFIR* p, const cmSample_t* sp, unsigned sn );
  159. void cmFIRTest();
  160. //------------------------------------------------------------------------------------------------------------
  161. // Apply a generic function to a windowed signal with a one sample hop size.
  162. typedef cmSample_t (*cmFuncFiltPtr_t)( const cmSample_t* sp, unsigned sn, void* userPtr );
  163. typedef struct
  164. {
  165. cmObj obj;
  166. cmFuncFiltPtr_t funcPtr;
  167. cmShiftBuf shiftBuf;
  168. cmSample_t* outV;
  169. unsigned outN; // outN == procSmpCnt
  170. unsigned curWndSmpCnt;
  171. unsigned wndSmpCnt;
  172. void* userPtr;
  173. } cmFuncFilter;
  174. /// Set p to NULL to dynamically allocate the object.
  175. cmFuncFilter* cmFuncFilterAlloc( cmCtx* c, cmFuncFilter* p, unsigned procSmpCnt, cmFuncFiltPtr_t funcPtr, void* userPtr, unsigned wndSmpCnt );
  176. cmRC_t cmFuncFilterFree( cmFuncFilter** pp );
  177. cmRC_t cmFuncFilterInit( cmFuncFilter* p, unsigned procSmpCnt, cmFuncFiltPtr_t funcPtr, void* userPtr, unsigned wndSmpCnt );
  178. cmRC_t cmFuncFilterFinal( cmFuncFilter* p );
  179. cmRC_t cmFuncFilterExec( cmFuncFilter* p, const cmSample_t* sp, unsigned sn );
  180. void cmFuncFilterTest();
  181. //------------------------------------------------------------------------------------------------------------
  182. typedef struct
  183. {
  184. cmObj obj;
  185. unsigned stateN; // count of states
  186. unsigned symN; // count of discrete observation symbols
  187. cmReal_t* initV; // initial state probability vector init[ stateN ]
  188. cmReal_t* transM; // transition probability matrix trans[ stateN (current), stateN (next) ]
  189. cmReal_t* stsM; // state to symbol prob. matrix stsM[ stateN, symN ]
  190. } cmDhmm;
  191. cmDhmm* cmDhmmAlloc( cmCtx* c, cmDhmm* p, unsigned stateN, unsigned symN, cmReal_t* initV, cmReal_t* transM, cmReal_t* stsM );
  192. cmRC_t cmDhmmFree( cmDhmm** pp );
  193. cmRC_t cmDhmmInit( cmDhmm* p, unsigned stateN, unsigned symN, cmReal_t* initV, cmReal_t* transM, cmReal_t* stsM );
  194. cmRC_t cmDhmmFinal( cmDhmm* p );
  195. cmRC_t cmDhmmExec( cmDhmm* p );
  196. cmRC_t cmDhmmGenObsSequence( cmDhmm* p, unsigned* dbp, unsigned dn );
  197. cmRC_t cmDhmmForwardEval( cmDhmm* p, const cmReal_t* statePrV, const unsigned* obsV, unsigned obsN, cmReal_t* alphaM, unsigned flags, cmReal_t* logProbPtr );
  198. cmRC_t cmDhmmReport( cmDhmm* p );
  199. void cmDhmmTest();
  200. //------------------------------------------------------------------------------------------------------------
  201. typedef struct
  202. {
  203. cmObj obj;
  204. cmFftSR* fft;
  205. cmIFftRS* ifft;
  206. cmComplexR_t* H;
  207. unsigned hn;
  208. cmSample_t* olaV; // olaV[hn-1];
  209. cmSample_t* outV; // outV[procSmpCnt]
  210. unsigned outN; // outN == procSmpCnt
  211. } cmConvolve;
  212. // After cmConvolveExec() outV[outN] contains the first outN samples
  213. // which are complete and can be used by the application.
  214. // The tail of the convolution is held in olaV[hn-1] and will
  215. // be automatically summed with the beginning of the next convolution
  216. // frame.
  217. // BUG BUG BUG
  218. // This code seems to have a problem when hn != procSmpCnt (or maybe hn > procSmpCnt ???).
  219. // See mas/main.c convolve() where procSmpCnt must be set to wndSmpCnt size or
  220. // only the first half of the window is emitted.
  221. // h[hn] is the impulse response to convolve with
  222. cmConvolve* cmConvolveAlloc( cmCtx* c, cmConvolve* p, const cmSample_t* h, unsigned hn, unsigned procSmpCnt );
  223. cmRC_t cmConvolveFree( cmConvolve** pp );
  224. cmRC_t cmConvolveInit( cmConvolve* p, const cmSample_t* h, unsigned hn, unsigned procSmpCnt );
  225. cmRC_t cmConvolveFinal( cmConvolve* p );
  226. // xn must be <= procSmpCnt
  227. cmRC_t cmConvolveExec( cmConvolve* p, const cmSample_t* x, unsigned xn );
  228. cmRC_t cmConvolveSignal( cmCtx* c, const cmSample_t* h, unsigned hn, const cmSample_t* x, unsigned xn, cmSample_t* y, unsigned yn );
  229. cmRC_t cmConvolveTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
  230. //------------------------------------------------------------------------------------------------------------
  231. typedef struct
  232. {
  233. cmObj obj;
  234. cmReal_t* dctMtx; // dctMtx[ binCnt, bandCnt ]
  235. cmReal_t* filtMask; // filtMask[ bandCnt, bandCnt ]
  236. unsigned binCnt; // bin cnt of input magnitude spectrum
  237. unsigned bandCnt; // must be <= kDefaultBarkBandCnt
  238. cmReal_t* outV; // outV[binCnt]
  239. } cmBfcc;
  240. cmBfcc* cmBfccAlloc( cmCtx* ctx, cmBfcc* p, unsigned bandCnt, unsigned binCnt, double binHz );
  241. cmRC_t cmBfccFree( cmBfcc** pp );
  242. cmRC_t cmBfccInit( cmBfcc* p, unsigned bandCnt, unsigned binCnt, double binHz );
  243. cmRC_t cmBfccFinal( cmBfcc* p );
  244. cmRC_t cmBfccExec( cmBfcc* p, const cmReal_t* magV, unsigned binCnt );
  245. void cmBfccTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
  246. //------------------------------------------------------------------------------------------------------------
  247. typedef struct
  248. {
  249. cmObj obj;
  250. //cmIFftRR ft;
  251. unsigned dct_cn; // (binCnt-1)*2
  252. cmReal_t* dctM; // dctM[ outN, dct_cn ]
  253. unsigned binCnt; // bin cnt of input magnitude spectrum
  254. unsigned outN; // count of cepstral coeff's
  255. cmReal_t* outV; // outV[outN]
  256. } cmCeps;
  257. // outN is the number of cepstral coeff's in the output vector
  258. cmCeps* cmCepsAlloc( cmCtx* ctx, cmCeps* p, unsigned binCnt, unsigned outN );
  259. cmRC_t cmCepsFree( cmCeps** pp );
  260. cmRC_t cmCepsInit( cmCeps* p, unsigned binCnt, unsigned outN );
  261. cmRC_t cmCepsFinal( cmCeps* p );
  262. cmRC_t cmCepsExec( cmCeps* p, const cmReal_t* magV, const cmReal_t* phsV, unsigned binCnt );
  263. //------------------------------------------------------------------------------------------------------------
  264. typedef struct
  265. {
  266. cmObj obj;
  267. cmWndFunc wf;
  268. unsigned wndSmpCnt;
  269. unsigned hopSmpCnt;
  270. unsigned procSmpCnt;
  271. cmSample_t* bufV; // bufV[wndSmpCnt] overlap add buffer
  272. cmSample_t* outV; // outV[hopSmpCnt] output vector
  273. cmSample_t* outPtr; // outPtr[procSmpCnt] output vector
  274. unsigned idx; // idx of next val in bufV[] to be moved to outV[]
  275. } cmOla;
  276. // hopSmpCnt must be <= wndSmpCnt.
  277. // hopSmpCnt must be an even multiple of procSmpCnt.
  278. // Call cmOlaExecR() or cmOlaExecS() at the spectral frame rate.
  279. // Call cmOlaExecOut() at the time domain audio frame rate.
  280. // Set wndTypeId to one of the cmWndFuncXXX enumerated widnow type id's.
  281. cmOla* cmOlaAlloc( cmCtx* ctx, cmOla* p, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned procSmpCnt, unsigned wndTypeId );
  282. cmRC_t cmOlaFree( cmOla** pp );
  283. cmRC_t cmOlaInit( cmOla* p, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned procSmpCnt, unsigned wndTypeId );
  284. cmRC_t cmOlaFinal( cmOla* p );
  285. cmRC_t cmOlaExecS( cmOla* p, const cmSample_t* xV, unsigned xN );
  286. cmRC_t cmOlaExecR( cmOla* p, const cmReal_t* xV, unsigned xN );
  287. const cmSample_t* cmOlaExecOut(cmOla* p );
  288. //------------------------------------------------------------------------------------------------------------
  289. typedef struct
  290. {
  291. cmObj obj;
  292. cmReal_t* hzV; // hzV[binCnt] output vector - frequency in Hertz
  293. cmReal_t* phsV; // phsV[binCnt]
  294. cmReal_t* wV; // bin freq in rads/hop
  295. double srate;
  296. unsigned hopSmpCnt;
  297. unsigned binCnt;
  298. } cmPhsToFrq;
  299. cmPhsToFrq* cmPhsToFrqAlloc( cmCtx* c, cmPhsToFrq* p, double srate, unsigned binCnt, unsigned hopSmpCnt );
  300. cmRC_t cmPhsToFrqFree( cmPhsToFrq** p );
  301. cmRC_t cmPhsToFrqInit( cmPhsToFrq* p, double srate, unsigned binCnt, unsigned hopSmpCnt );
  302. cmRC_t cmPhsToFrqFinal(cmPhsToFrq* p );
  303. cmRC_t cmPhsToFrqExec( cmPhsToFrq* p, const cmReal_t* phsV );
  304. //------------------------------------------------------------------------------------------------------------
  305. enum
  306. {
  307. kNoCalcHzPvaFl = 0x00,
  308. kCalcHzPvaFl = 0x01
  309. };
  310. typedef struct
  311. {
  312. cmObj obj;
  313. cmShiftBuf sb;
  314. cmFftSR ft;
  315. cmWndFunc wf;
  316. cmPhsToFrq pf;
  317. unsigned flags;
  318. unsigned procSmpCnt;
  319. double srate;
  320. unsigned wndSmpCnt;
  321. unsigned hopSmpCnt;
  322. unsigned binCnt;
  323. const cmReal_t* magV; // amplitude NOT power
  324. const cmReal_t* phsV;
  325. const cmReal_t* hzV;
  326. } cmPvAnl;
  327. cmPvAnl* cmPvAnlAlloc( cmCtx* ctx, cmPvAnl* p, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned flags );
  328. cmRC_t cmPvAnlFree( cmPvAnl** pp );
  329. cmRC_t cmPvAnlInit( cmPvAnl* p, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned flags );
  330. cmRC_t cmPvAnlFinal(cmPvAnl* p );
  331. // Returns true when a new spectrum has been computed
  332. bool cmPvAnlExec( cmPvAnl* p, const cmSample_t* x, unsigned xN );
  333. //------------------------------------------------------------------------------------------------------------
  334. typedef struct
  335. {
  336. cmObj obj;
  337. cmIFftRS ft;
  338. cmWndFunc wf;
  339. cmOla ola;
  340. cmReal_t* minRphV;
  341. cmReal_t* maxRphV;
  342. cmReal_t* itrV;
  343. cmReal_t* phs0V;
  344. cmReal_t* mag0V;
  345. cmReal_t* phsV;
  346. cmReal_t* magV;
  347. double outSrate;
  348. unsigned procSmpCnt;
  349. unsigned wndSmpCnt;
  350. unsigned hopSmpCnt;
  351. unsigned binCnt;
  352. } cmPvSyn;
  353. cmPvSyn* cmPvSynAlloc( cmCtx* ctx, cmPvSyn* p, unsigned procSmpCnt, double outSrate, unsigned wndSmpCnt, unsigned hopSmpCnt,unsigned wndTypeId );
  354. cmRC_t cmPvSynFree( cmPvSyn** pp );
  355. cmRC_t cmPvSynInit( cmPvSyn* p, unsigned procSmpCnt, double outSrate, unsigned wndSmpCnt, unsigned hopSmpCnt,unsigned wndTypeId );
  356. cmRC_t cmPvSynFinal(cmPvSyn* p );
  357. cmRC_t cmPvSynExec( cmPvSyn* p, const cmReal_t* magV, const cmReal_t* phsV );
  358. const cmSample_t* cmPvSynExecOut(cmPvSyn* p );
  359. //------------------------------------------------------------------------------------------------------------
  360. // callback selector values
  361. enum
  362. {
  363. kAttackMsId,
  364. kReleaseMsId,
  365. kDspMsId // return 0 if the voice is no longer active
  366. };
  367. // voice flags
  368. enum
  369. {
  370. kActiveMsFl = 0x01, // set if the voice is active
  371. kKeyGateMsFl = 0x02, // set if the key is down for this note
  372. };
  373. struct cmMidiSynth_str;
  374. struct cmMidiSynthCh_str;
  375. struct cmMidiVoice_str;
  376. // voice update callback - use voicePtr->pgm.cbDataPtr to get voice specific data
  377. typedef int (*cmMidiSynthCb_t)( struct cmMidiVoice_str* voicePtr, unsigned sel, cmSample_t* outChArray[], unsigned outChCnt );
  378. typedef struct
  379. {
  380. cmMidiByte_t pgm; // MIDI pgm number
  381. cmMidiSynthCb_t cbPtr; // voice update callback
  382. void* cbDataPtr; // user data pointer
  383. } cmMidiSynthPgm;
  384. typedef struct cmMidiVoice_str
  385. {
  386. unsigned index; // voice index
  387. unsigned flags; // see kXXXMsFl above
  388. cmMidiByte_t pitch; // note-on pitch
  389. cmMidiByte_t velocity; // note-on/off veloctiy
  390. cmMidiSynthPgm pgm; // pgm associated with this voice
  391. struct cmMidiSynthCh_str* chPtr; // pointer to owning ch
  392. struct cmMidiVoice_str* link; // link to next active/avail voice in chain
  393. } cmMidiVoice;
  394. typedef struct cmMidiSynthCh_str
  395. {
  396. cmMidiByte_t midiCtl[ kMidiCtlCnt ]; // current ctl values
  397. short pitchBend; // current pitch bend value
  398. cmMidiByte_t pgm; // last pgm received
  399. cmMidiVoice* active; // first active voice on this channel
  400. struct cmMidiSynth_str* synthPtr; // owning synth
  401. } cmMidiSynthCh;
  402. typedef struct cmMidiSynth_str
  403. {
  404. cmObj obj;
  405. cmMidiSynthCh chArray[ kMidiChCnt ]; // midi channel array
  406. unsigned voiceCnt; // count of voice records
  407. cmMidiVoice* avail; // avail voice chain
  408. unsigned activeVoiceCnt; // current count of active voices
  409. unsigned voiceStealCnt; // count of times voice stealing was required
  410. cmMidiVoice* voiceArray; // array of voice records
  411. cmMidiSynthPgm pgmArray[ kMidiPgmCnt ]; // array of pgm records
  412. unsigned procSmpCnt; // samples per DSP cycle
  413. unsigned outChCnt; // count of output channels
  414. cmSample_t* outM; // outM[ procSmpCnt, outChCnt ] output buffer
  415. cmSample_t** outChArray; // buffer of pointers to each output channel
  416. cmReal_t srate; // output signal sample rate
  417. } cmMidiSynth;
  418. cmMidiSynth* cmMidiSynthAlloc( cmCtx* ctx, cmMidiSynth* p, const cmMidiSynthPgm* pgmArray, unsigned pgmCnt, unsigned voiceCnt, unsigned procSmpCnt, unsigned outChCnt, cmReal_t srate );
  419. cmRC_t cmMidiSynthFree( cmMidiSynth** pp );
  420. cmRC_t cmMidiSynthInit( cmMidiSynth* p, const cmMidiSynthPgm* pgmArray, unsigned pgmCnt, unsigned voiceCnt, unsigned procSmpCnt, unsigned outChCnt, cmReal_t srate );
  421. cmRC_t cmMidiSynthFinal( cmMidiSynth* p );
  422. cmRC_t cmMidiSynthOnMidi(cmMidiSynth* p, const cmMidiPacket_t* pktArray, unsigned pktCnt );
  423. cmRC_t cmMidiSynthExec( cmMidiSynth* p, cmSample_t** outChArray, unsigned outChCnt );
  424. //------------------------------------------------------------------------------------------------------------
  425. // state id's
  426. enum
  427. {
  428. kOffWtId,
  429. kAtkWtId,
  430. kDcyWtId,
  431. kSusWtId,
  432. kRlsWtId
  433. };
  434. typedef struct
  435. {
  436. cmObj obj;
  437. cmReal_t hz; // current frq in Hz
  438. cmReal_t level; // current gain (0.0 to 1.0)
  439. cmReal_t phase; // osc phase (radians)
  440. unsigned durSmpCnt; // count of samples generated so far
  441. unsigned state; // osc state - see kXXXWtId above
  442. cmSample_t* outV; // signal output vector
  443. unsigned outN; // samples in outV[]
  444. } cmWtVoice;
  445. cmWtVoice* cmWtVoiceAlloc( cmCtx* ctx, cmWtVoice* p, unsigned procSmpCnt, cmReal_t hz );
  446. cmRC_t cmWtVoiceFree( cmWtVoice** pp );
  447. cmRC_t cmWtVoiceInit( cmWtVoice* p, unsigned procSmpCnt, cmReal_t hz );
  448. cmRC_t cmWtVoiceFinal( cmWtVoice* p );
  449. // 'sel' values are cmMidiSynthExec (kXXXMsId) values
  450. // Set outChArray[] to NULL to use internal audio buffer.
  451. int cmWtVoiceExec( cmWtVoice* p, struct cmMidiVoice_str* voicePtr, unsigned sel, cmSample_t* outChArray[], unsigned outChCnt );
  452. //------------------------------------------------------------------------------------------------------------
  453. typedef struct
  454. {
  455. cmObj obj;
  456. cmWtVoice** voiceArray; // osc state array
  457. unsigned voiceCnt;
  458. cmSample_t* buf;
  459. cmSample_t** chArray;
  460. unsigned chCnt;
  461. unsigned procSmpCnt; // count of samples in each chArray[i] sample vector
  462. double srate; // synth sample rate
  463. } cmWtVoiceBank;
  464. cmWtVoiceBank* cmWtVoiceBankAlloc( cmCtx* ctx, cmWtVoiceBank* p, double srate, unsigned procSmpCnt, unsigned voiceCnt, unsigned chCnt );
  465. cmRC_t cmWtVoiceBankFree( cmWtVoiceBank** pp );
  466. cmRC_t cmWtVoiceBankInit( cmWtVoiceBank* p, double srate, unsigned procSmpCnt, unsigned voiceCnt, unsigned chCnt );
  467. cmRC_t cmWtVoiceBankFinal( cmWtVoiceBank* p );
  468. // 'sel' values are cmMidiSynthExec (kXXXMsId) values
  469. // Set outChArray[] to NULL to use internal audio buffer.
  470. // Return 0 if the voice has gone inactive otherwise return 1.
  471. int cmWtVoiceBankExec( cmWtVoiceBank* p, struct cmMidiVoice_str* voicePtr, unsigned sel, cmSample_t* chArray[], unsigned chCnt );
  472. //------------------------------------------------------------------------------------------------------------
  473. typedef struct
  474. {
  475. cmObj obj;
  476. cmSample_t* bufV; // bufV[ bufN ]
  477. unsigned bufN;
  478. cmAudioFileInfo_t info;
  479. unsigned begSmpIdx;
  480. unsigned chIdx;
  481. char* fn;
  482. } cmAudioFileBuf;
  483. // set 'durSmpCnt' to cmInvalidCnt to include all samples to the end of the file
  484. cmAudioFileBuf* cmAudioFileBufAlloc( cmCtx* ctx, cmAudioFileBuf* p, unsigned procSmpCnt, const char* fn, unsigned chIdx, unsigned begSmpIdx, unsigned durSmpCnt );
  485. cmRC_t cmAudioFileBufFree( cmAudioFileBuf** pp );
  486. cmRC_t cmAudioFileBufInit( cmAudioFileBuf* p, unsigned procSmpCnt, const char* fn, unsigned chIdx, unsigned begSmpIdx, unsigned durSmpCnt );
  487. cmRC_t cmAudioFileBufFinal(cmAudioFileBuf* p );
  488. // Returns the count of samples copied into outV or 0 if smpIdx >= p->bufN.
  489. // If less than outN samples are available then the remaining samples are set to 0.
  490. unsigned cmAudioFileBufExec( cmAudioFileBuf* p, unsigned smpIdx, cmSample_t* outV, unsigned outN, bool sumIntoOutFl );
  491. //------------------------------------------------------------------------------------------------------------
  492. // Multi-delay. Each of the taps of this delay operates as a independent delay with feedback.
  493. // Delay line specification.
  494. typedef struct
  495. {
  496. cmReal_t delayGain; // delay gain
  497. cmReal_t delayMs; // delay time in milliseconds
  498. cmReal_t delaySmpFrac; // delay time in samples (next fractional delay index = inIdx - delaySmpFrac)
  499. cmSample_t* delayBuf; // delayBuf[delayBufSmpCnt] delay line memory
  500. int delayBufSmpCnt; // delay buffer length in samples
  501. int inIdx; // next delay input index
  502. } cmMDelayHead;
  503. typedef struct
  504. {
  505. cmObj obj;
  506. unsigned delayCnt; // count of taps
  507. cmMDelayHead* delayArray; // tap specs
  508. cmSample_t* outV; // outV[outN] output buffer
  509. unsigned outN; // procSmpCnt
  510. cmReal_t fbCoeff; // feedback coeff.
  511. cmReal_t srate; // system sample rate
  512. } cmMDelay;
  513. cmMDelay* cmMDelayAlloc( cmCtx* ctx, cmMDelay* p, unsigned procSmpCnt, cmReal_t srate, cmReal_t fbCoeff, unsigned delayCnt, const cmReal_t* delayMsArray, const cmReal_t* delayGainArray );
  514. cmRC_t cmMDelayFree( cmMDelay** pp );
  515. cmRC_t cmMDelayInit( cmMDelay* p, unsigned procSmpCnt, cmReal_t srate, cmReal_t fbCoeff, unsigned delayCnt, const cmReal_t* delayMsArray, const cmReal_t* delayGainArray );
  516. cmRC_t cmMDelayFinal( cmMDelay* p );
  517. cmRC_t cmMDelayExec( cmMDelay* p, const cmSample_t* sigV, cmSample_t* outV, unsigned sigN, bool bypassFl );
  518. void cmMDelaySetTapMs( cmMDelay* p, unsigned tapIdx, cmReal_t ms );
  519. void cmMDelaySetTapGain(cmMDelay* p, unsigned tapIdx, cmReal_t gain );
  520. void cmMDelayReport( cmMDelay* p, cmRpt_t* rpt );
  521. //------------------------------------------------------------------------------------------------------------
  522. enum
  523. {
  524. kEnableAspFl = 0x01,
  525. kDelAspFl = 0x02
  526. };
  527. typedef struct cmAudioSeg_str
  528. {
  529. cmAudioFileBuf* bufPtr; // pointer to the audio file buffer this segment is contained in
  530. unsigned id; // id (unique amoung segments)
  531. unsigned smpIdx; // offset into audioBuf[] of first sample
  532. unsigned smpCnt; // total count of samples to play
  533. unsigned outChIdx; // output buffer channel
  534. unsigned outSmpIdx; // outSmpIdx + smpIdx == next sample to play
  535. unsigned flags; // see kXXXAspFl
  536. } cmAudioSeg;
  537. typedef struct
  538. {
  539. cmObj obj;
  540. unsigned segCnt;
  541. cmAudioSeg* segArray;
  542. unsigned procSmpCnt;
  543. cmSample_t** outChArray;
  544. unsigned outChCnt;
  545. cmSample_t* outM;
  546. } cmAudioSegPlayer;
  547. cmAudioSegPlayer* cmAudioSegPlayerAlloc( cmCtx* ctx, cmAudioSegPlayer* p, unsigned procSmpCnt, unsigned outChCnt );
  548. cmRC_t cmAudioSegPlayerFree( cmAudioSegPlayer** pp );
  549. cmRC_t cmAudioSegPlayerInit( cmAudioSegPlayer* p, unsigned procSmpCnt, unsigned outChCnt );
  550. cmRC_t cmAudioSegPlayerFinal( cmAudioSegPlayer* p );
  551. cmRC_t cmAudioSegPlayerInsert( cmAudioSegPlayer* p, unsigned id, cmAudioFileBuf* bufPtr, unsigned smpIdx, unsigned smpCnt, unsigned outChIdx );
  552. cmRC_t cmAudioSegPlayerEdit( cmAudioSegPlayer* p, unsigned id, cmAudioFileBuf* bufPtr, unsigned smpIdx, unsigned smpCnt, unsigned outChIdx );
  553. cmRC_t cmAudioSegPlayerRemove( cmAudioSegPlayer* p, unsigned id, bool delFl );
  554. cmRC_t cmAudioSegPlayerEnable( cmAudioSegPlayer* p, unsigned id, bool enableFl, unsigned outSmpIdx );
  555. cmRC_t cmAudioSegPlayerReset( cmAudioSegPlayer* p );
  556. cmRC_t cmAudioSegPlayerExec( cmAudioSegPlayer* p, cmSample_t** outChPtr, unsigned chCnt, unsigned outSmpCnt );
  557. //------------------------------------------------------------------------------------------------------------
  558. /*
  559. cmReal_t (*cmCluster0DistFunc_t)( void* userPtr, const cmReal_t* v0, const cmReal_t* v1, unsigned binCnt );
  560. typedef struct
  561. {
  562. cmObj obj;
  563. unsigned flags;
  564. unsigned stateCnt;
  565. unsigned binCnt;
  566. cmReal_t* oM; // oM[ binCnt, stateCnt ]
  567. unsigned* tM; // tM[ stateCnt, stateCnt ]
  568. cmReal_t* dV; // dV[ state
  569. cmCluster0DistFunc_t distFunc;
  570. void* distUserPtr;
  571. unsigned cnt;
  572. } cmCluster0;
  573. enum
  574. {
  575. kCalcTransFl = 0x01,
  576. kCalcDurFl = 0x02
  577. };
  578. cmCluster0* cmCluster0Alloc( cmCtx* ctx, cmCluster0* ap, unsigned stateCnt, unsigned binCnt, unsigned flags, cmCluster0DistFunc_t distFunc, void* dstUserPtr );
  579. cmRC_t cmCluster0Free( cmCluster0** pp );
  580. cmRC_t cmCluster0Init( cmCluster0* p, unsigned stateCnt, unsigned binCnt, unsigned flags, cmCluster0DistFunc_t distFunc, void* dstUserPtr );
  581. cmRC_t cmCluster0Final( cmCluster0* p );
  582. cmRC_t cmCluster0Exec( cmCluster0* p, const cmReal_t* v, unsigned vn );
  583. */
  584. //------------------------------------------------------------------------------------------------------------
  585. typedef struct
  586. {
  587. cmObj obj;
  588. unsigned n;
  589. unsigned m;
  590. unsigned r;
  591. unsigned maxIterCnt;
  592. unsigned convergeCnt;
  593. cmReal_t* V; // V[n,m]
  594. cmReal_t* W; // W[n,r]
  595. cmReal_t* H; // H[r,m]
  596. cmReal_t* tr;
  597. cmReal_t* x;
  598. cmReal_t* t0nm;
  599. cmReal_t* t1nm;
  600. cmReal_t* Wt;
  601. cmReal_t* Ht;
  602. cmReal_t* trm;
  603. unsigned* crm;
  604. cmReal_t* tnr;
  605. unsigned* c0;
  606. unsigned* c1;
  607. unsigned* c0m;
  608. unsigned* c1m;
  609. unsigned* idxV;
  610. } cmNmf_t;
  611. cmNmf_t* cmNmfAlloc( cmCtx* ctx, cmNmf_t* ap, unsigned n, unsigned m, unsigned r, unsigned maxIterCnt, unsigned convergeCnt );
  612. cmRC_t cmNmfFree( cmNmf_t** pp );
  613. cmRC_t cmNmfInit( cmNmf_t* p, unsigned n, unsigned m, unsigned r, unsigned maxIterCnt, unsigned convergeCnt );
  614. cmRC_t cmNmfFinal(cmNmf_t* p );
  615. //
  616. cmRC_t cmNmfExec( cmNmf_t* p, const cmReal_t* v, unsigned cn );
  617. //------------------------------------------------------------------------------------------------------------
  618. enum
  619. {
  620. kBypassModeSdId, // 0 - no effect
  621. kBasicModeSdId, // 1 - fixed thresh
  622. kSpecCentSdId, // 2 - thresh = max magn - (offset * spec_cent)
  623. kAmpEnvSdId, // 3 - thresh = max magn - offset
  624. kModeSdCnt
  625. };
  626. typedef struct
  627. {
  628. cmObj obj;
  629. double srate;
  630. unsigned wndSmpCnt;
  631. unsigned hopFcmt;
  632. unsigned hopSmpCnt;
  633. unsigned procSmpCnt;
  634. cmPvAnl* pva;
  635. cmPvSyn* pvs;
  636. unsigned mode;
  637. double thresh;
  638. double uprSlope;
  639. double lwrSlope;
  640. double offset;
  641. bool invertFl;
  642. double spcBwHz; // spectral centroid bandwidth in Hz
  643. double spcSmArg; // spectral centroid smoothing
  644. double spcMin;
  645. double spcMax;
  646. unsigned spcBinCnt; // count of bins used in the spectral centroid
  647. cmReal_t* hzV; // hzV[spcBinCnt];
  648. cmReal_t spc;
  649. unsigned spcCnt;
  650. cmReal_t spcSum;
  651. cmReal_t spcSqSum;
  652. cmReal_t aeSmMax; // smoothed max bin magn - used by spectral centroid
  653. cmReal_t aeSmOffs; // smoothed offset
  654. cmReal_t ae;
  655. cmReal_t aeMin;
  656. cmReal_t aeMax;
  657. cmReal_t aeUnit;
  658. } cmSpecDist_t;
  659. cmSpecDist_t* cmSpecDistAlloc( cmCtx* ctx,cmSpecDist_t* ap, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopFcmt, unsigned olaWndTypeId );
  660. cmRC_t cmSpecDistFree( cmSpecDist_t** pp );
  661. cmRC_t cmSpecDistInit( cmSpecDist_t* p, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopFcmt, unsigned olaWndTypeId );
  662. cmRC_t cmSpecDistFinal(cmSpecDist_t* p );
  663. cmRC_t cmSpecDistExec( cmSpecDist_t* p, const cmSample_t* sp, unsigned sn );
  664. const cmSample_t* cmSpecDistOut( cmSpecDist_t* p );
  665. //------------------------------------------------------------------------------------------------------------
  666. // Write a binary matrix file in the format acceppted by the octave function readBinFile.m
  667. typedef struct
  668. {
  669. cmObj obj;
  670. cmFileH_t fh;
  671. unsigned rowCnt;
  672. unsigned maxRowEleCnt;
  673. unsigned eleByteCnt;
  674. } cmBinMtxFile_t;
  675. cmBinMtxFile_t* cmBinMtxFileAlloc( cmCtx* ctx, cmBinMtxFile_t* ap, const cmChar_t* fn );
  676. cmRC_t cmBinMtxFileFree( cmBinMtxFile_t** pp );
  677. cmRC_t cmBinMtxFileInit( cmBinMtxFile_t* p, const cmChar_t* fn );
  678. cmRC_t cmBinMtxFileFinal( cmBinMtxFile_t* p );
  679. // Write one row of 'xn' columns to the matrix file.
  680. cmRC_t cmBinMtxFileExecS( cmBinMtxFile_t* p, const cmSample_t* x, unsigned xn );
  681. cmRC_t cmBinMtxFileExecR( cmBinMtxFile_t* p, const cmReal_t* x, unsigned xn );
  682. bool cmBinMtxFileIsValid( cmBinMtxFile_t* p );
  683. // Write a binary matrix file.
  684. // The matrix data is provided as sp[rowCnt,colCnt] or rp[rowCnt,colCnt].
  685. // The matrix is assumed to be in column major order (like all matrices in the cm library)
  686. // Either 'sp' or 'rp' must be given but not both.
  687. // 'ctx' is optional and defaults to NULL.
  688. // If 'ctx' is not provided then 'rpt' must be provided.
  689. // If 'ctx' is provided then 'rpt' is not used.
  690. // See cmAudioFileReadWriteTest() in cmProcTest.c for an example usage.
  691. cmRC_t cmBinMtxFileWrite( const cmChar_t* fn, unsigned rowCnt, unsigned colCnt, const cmSample_t* sp, const cmReal_t* rp, cmCtx* ctx, cmRpt_t* rpt );
  692. // Return the matrix file geometry.
  693. // rowCntPtr,colCntPtr and eleByteCntPtr are optional
  694. cmRC_t cmBinMtxFileSize( cmCtx_t* ctx, const cmChar_t* fn, unsigned* rowCntPtr, unsigned* colCntPtr, unsigned* eleByteCntPtr );
  695. // Fill buf[rowCnt*colCnt*byteEleCnt] buffer from the binary matrix file 'fn'.
  696. // rowCnt,colCnt,eleByteCnt must be exactly the same as the actual file.
  697. // Use cmBinMtxFileSize() to determine the buffer size prior to calling this function.
  698. // colCntV[colCnt] is optional.
  699. cmRC_t cmBinMtxFileRead( cmCtx_t* ctx, const cmChar_t* fn, unsigned rowCnt, unsigned colCnt, unsigned eleByteCnt, void* buf, unsigned* colCntV );
  700. #ifdef __cplusplus
  701. }
  702. #endif
  703. #endif