libcm is a C development framework with an emphasis on audio signal processing applications.
Du kannst nicht mehr als 25 Themen auswählen Themen müssen mit entweder einem Buchstaben oder einer Ziffer beginnen. Sie können Bindestriche („-“) enthalten und bis zu 35 Zeichen lang sein.

cmDspFx.c 202KB

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  1. //( { file_desc:"'snap' audio effects processor units." kw:[snap]}
  2. #include "cmPrefix.h"
  3. #include "cmGlobal.h"
  4. #include "cmFloatTypes.h"
  5. #include "cmComplexTypes.h"
  6. #include "cmRpt.h"
  7. #include "cmErr.h"
  8. #include "cmCtx.h"
  9. #include "cmMem.h"
  10. #include "cmMallocDebug.h"
  11. #include "cmLinkedHeap.h"
  12. #include "cmText.h"
  13. #include "cmMath.h"
  14. #include "cmFile.h"
  15. #include "cmFileSys.h"
  16. #include "cmSymTbl.h"
  17. #include "cmJson.h"
  18. #include "cmPrefs.h"
  19. #include "cmDspValue.h"
  20. #include "cmMsgProtocol.h"
  21. #include "cmThread.h"
  22. #include "cmUdpPort.h"
  23. #include "cmUdpNet.h"
  24. #include "cmSerialPort.h"
  25. #include "cmTime.h"
  26. #include "cmAudioSys.h"
  27. #include "cmProcObj.h"
  28. #include "cmDspCtx.h"
  29. #include "cmDspClass.h"
  30. #include "cmDspUi.h"
  31. #include "cmAudioFile.h"
  32. #include "cmProcObj.h"
  33. #include "cmProcTemplateMain.h"
  34. #include "cmProc.h"
  35. #include "cmMidi.h"
  36. #include "cmProc2.h"
  37. #include "cmProc3.h"
  38. #include "cmVectOpsTemplateMain.h"
  39. #include "app/cmPickup.h"
  40. #include "cmDspSys.h"
  41. //------------------------------------------------------------------------------------------------------------
  42. //)
  43. //( { label:cmDspDelay file_desc:"Simple audio delay with feedback." kw:[sunit] }
  44. enum
  45. {
  46. kBypassDyId,
  47. kTimeDyId,
  48. kFbDyId,
  49. kInDyId,
  50. kOutDyId
  51. };
  52. cmDspClass_t _cmDelayDC;
  53. typedef struct
  54. {
  55. cmDspInst_t inst;
  56. cmMDelay* delay;
  57. } cmDspDelay_t;
  58. cmDspInst_t* _cmDspDelayAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  59. {
  60. unsigned chs = 1;
  61. cmDspVarArg_t args[] =
  62. {
  63. { "bypass",kBypassDyId,0,0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Bypass enable flag." },
  64. { "time", kTimeDyId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Max delay time in milliseconds" },
  65. { "fb", kFbDyId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Feedback" },
  66. { "in", kInDyId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  67. { "out", kOutDyId, 0, chs, kOutDsvFl | kAudioBufDsvFl, "Audio output." },
  68. { NULL, 0, 0, 0, 0 }
  69. };
  70. cmDspDelay_t* p = cmDspInstAlloc(cmDspDelay_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl);
  71. // set default values for the parameters that were not explicitely set in the va_arg list
  72. cmDspSetDefaultBool( ctx, &p->inst, kBypassDyId,0, 0 );
  73. cmDspSetDefaultUInt( ctx, &p->inst, kTimeDyId, 0, 1000 );
  74. cmDspSetDefaultDouble( ctx, &p->inst ,kFbDyId, 0.0, 0.0 );
  75. cmReal_t dtimeMs = cmDspDefaultUInt(&p->inst,kTimeDyId);
  76. cmReal_t fbCoeff = cmDspDefaultDouble(&p->inst,kFbDyId);
  77. p->delay = cmMDelayAlloc(ctx->cmProcCtx,NULL, cmDspSamplesPerCycle(ctx), cmDspSampleRate(ctx), fbCoeff, 1, &dtimeMs, NULL );
  78. return &p->inst;
  79. }
  80. cmDspRC_t _cmDspDelayFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  81. {
  82. cmDspRC_t rc = kOkDspRC;
  83. cmDspDelay_t* p = (cmDspDelay_t*)inst;
  84. cmMDelayFree(&p->delay);
  85. //cmCtxFree(&p->ctx);
  86. return rc;
  87. }
  88. cmDspRC_t _cmDspDelayReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  89. {
  90. cmDspRC_t rc = kOkDspRC;
  91. rc = cmDspApplyAllDefaults(ctx,inst);
  92. return rc;
  93. }
  94. cmDspRC_t _cmDspDelayExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  95. {
  96. cmDspDelay_t* p = (cmDspDelay_t*)inst;
  97. cmDspRC_t rc = kOkDspRC;
  98. unsigned iChIdx = 0;
  99. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInDyId,iChIdx);
  100. unsigned iSmpCnt = cmDspVarRows(inst,kInDyId);
  101. unsigned oChIdx = 0;
  102. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutDyId,oChIdx);
  103. unsigned oSmpCnt = cmDspVarRows(inst,kOutDyId);
  104. bool bypassFl= cmDspBool(inst,kBypassDyId);
  105. cmMDelayExec(p->delay,ip,op,cmMin(iSmpCnt,oSmpCnt),bypassFl);
  106. return rc;
  107. }
  108. cmDspRC_t _cmDspDelayRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  109. {
  110. cmDspDelay_t* p = (cmDspDelay_t*)inst;
  111. cmDspRC_t rc= kOkDspRC;
  112. cmDspSetEvent(ctx,inst,evt);
  113. switch( evt->dstVarId )
  114. {
  115. case kBypassDyId:
  116. break;
  117. case kTimeDyId:
  118. p->delay->delayArray[0].delayMs = cmDspDouble(inst,kTimeDyId);
  119. break;
  120. case kFbDyId:
  121. p->delay->fbCoeff = cmDspDouble(inst,kFbDyId);
  122. break;
  123. default:
  124. { assert(0); }
  125. }
  126. return rc;
  127. }
  128. cmDspClass_t* cmDelayClassCons( cmDspCtx_t* ctx )
  129. {
  130. cmDspClassSetup(&_cmDelayDC,ctx,"Delay",
  131. NULL,
  132. _cmDspDelayAlloc,
  133. _cmDspDelayFree,
  134. _cmDspDelayReset,
  135. _cmDspDelayExec,
  136. _cmDspDelayRecv,
  137. NULL,NULL,
  138. "Simple delay.");
  139. return &_cmDelayDC;
  140. }
  141. //------------------------------------------------------------------------------------------------------------
  142. //)
  143. //( { label:cmDspMtDelay file_desc:"Multi-tap audio delay with feedback." kw:[sunit] }
  144. enum
  145. {
  146. kBypassMtId,
  147. kScaleMtId,
  148. kFbMtId,
  149. kInMtId,
  150. kOutMtId,
  151. kBaseMsMtId
  152. };
  153. cmDspClass_t _cmMtDelayDC;
  154. typedef struct
  155. {
  156. cmDspInst_t inst;
  157. cmMDelay* p;
  158. unsigned baseGainMtId;
  159. unsigned tapCnt;
  160. cmReal_t* msV;
  161. cmReal_t* gainV;
  162. unsigned printSymId;
  163. } cmDspMtDelay_t;
  164. // args: bypassFl, time_scale, feedback, tap_ms0, tap_gain0, tapms1, tap_gain1, ....
  165. cmDspInst_t* _cmDspMtDelayAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  166. {
  167. va_list vl1;
  168. cmDspVarArg_t args[] =
  169. {
  170. { "bypass",kBypassMtId,0, 0, kInDsvFl | kBoolDsvFl | kReqArgDsvFl, "Bypass enable flag." },
  171. { "scale", kScaleMtId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Scale tap times. (0.0 - 1.0)" },
  172. { "fb", kFbMtId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Feedback" },
  173. { "in", kInMtId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  174. { "out", kOutMtId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio output." },
  175. };
  176. // verify that at least one var arg exists
  177. if( va_cnt < 5 || cmIsEvenU(va_cnt) )
  178. {
  179. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The 'multi-tap delay requires at least 5 arguments. Three fixed arguments and groups of two tap specification arguments.");
  180. return NULL;
  181. }
  182. va_copy(vl1,vl);
  183. unsigned reqArgCnt = 3;
  184. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  185. unsigned tapCnt = (va_cnt - reqArgCnt)/2;
  186. cmReal_t* msV = cmMemAllocZ(cmReal_t,tapCnt);
  187. cmReal_t* gainV = cmMemAllocZ(cmReal_t,tapCnt);
  188. unsigned argCnt = fixArgCnt + 2 * tapCnt;
  189. unsigned baseGainMtId = kBaseMsMtId + tapCnt;
  190. cmDspVarArg_t a[ argCnt+1 ];
  191. unsigned i;
  192. // Get the taps and gains
  193. va_arg(vl1,int); // enable
  194. va_arg(vl1,double); // time scale
  195. va_arg(vl1,double); // feedback
  196. for(i=0; i<tapCnt; ++i)
  197. {
  198. msV[i] = va_arg(vl1,double);
  199. gainV[i] = va_arg(vl1,double);
  200. }
  201. // setup the output gain args
  202. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  203. cmDspArgSetupN(ctx, a, argCnt, kBaseMsMtId, tapCnt, "ms", kBaseMsMtId, 0, 0, kInDsvFl | kDoubleDsvFl, "Tap delay times in milliseconds.");
  204. cmDspArgSetupN(ctx, a, argCnt, baseGainMtId, tapCnt, "gain", baseGainMtId, 0, 0, kInDsvFl | kDoubleDsvFl, "Tap delay linear gain.");
  205. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  206. cmDspMtDelay_t* p = cmDspInstAlloc(cmDspMtDelay_t,ctx,classPtr,a,instSymId,id,storeSymId,reqArgCnt,vl1);
  207. p->p = cmMDelayAlloc(ctx->cmProcCtx,NULL,0, 0, 0, 0, NULL, NULL );
  208. p->baseGainMtId = baseGainMtId;
  209. p->tapCnt = tapCnt;
  210. p->msV = msV;
  211. p->gainV = gainV;
  212. p->printSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"_print");
  213. for(i=0; i<tapCnt; ++i)
  214. {
  215. cmDspSetDefaultDouble(ctx,&p->inst,kBaseMsMtId+i, 0.0, msV[i]);
  216. cmDspSetDefaultDouble(ctx,&p->inst,baseGainMtId+i, 0.0, gainV[i]);
  217. }
  218. va_end(vl1);
  219. return &p->inst;
  220. }
  221. cmDspRC_t _cmDspMtDelayFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  222. {
  223. cmDspRC_t rc = kOkDspRC;
  224. cmDspMtDelay_t* p = (cmDspMtDelay_t*)inst;
  225. cmMemFree(p->msV);
  226. cmMemFree(p->gainV);
  227. cmMDelayFree(&p->p);
  228. return rc;
  229. }
  230. cmDspRC_t _cmDspMtDelayReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  231. {
  232. cmDspRC_t rc = kOkDspRC;
  233. cmDspMtDelay_t* p = (cmDspMtDelay_t*)inst;
  234. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  235. {
  236. cmMDelayInit(p->p,cmDspSamplesPerCycle(ctx), cmDspSampleRate(ctx), cmDspDouble(&p->inst,kFbMtId), p->tapCnt, p->msV, p->gainV );
  237. }
  238. return rc;
  239. }
  240. cmDspRC_t _cmDspMtDelayExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  241. {
  242. cmDspMtDelay_t* p = (cmDspMtDelay_t*)inst;
  243. cmDspRC_t rc = kOkDspRC;
  244. unsigned iChIdx = 0;
  245. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInMtId,iChIdx);
  246. unsigned iSmpCnt = cmDspVarRows(inst,kInMtId);
  247. unsigned oChIdx = 0;
  248. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutMtId,oChIdx);
  249. unsigned oSmpCnt = cmDspVarRows(inst,kOutMtId);
  250. bool bypassFl= cmDspBool(inst,kBypassMtId);
  251. if( ip != NULL )
  252. cmMDelayExec(p->p,ip,op,cmMin(iSmpCnt,oSmpCnt),bypassFl);
  253. return rc;
  254. }
  255. cmDspRC_t _cmDspMtDelayRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  256. {
  257. cmDspMtDelay_t* p = (cmDspMtDelay_t*)inst;
  258. cmDspRC_t rc= kOkDspRC;
  259. cmDspSetEvent(ctx,inst,evt);
  260. // set tap times
  261. if( kBaseMsMtId <= evt->dstVarId && evt->dstVarId < kBaseMsMtId + p->p->delayCnt )
  262. cmMDelaySetTapMs(p->p,evt->dstVarId - kBaseMsMtId, cmDspDouble(inst,evt->dstVarId));
  263. else
  264. // set tap gains
  265. if( p->baseGainMtId <= evt->dstVarId && evt->dstVarId < p->baseGainMtId + p->p->delayCnt )
  266. cmMDelaySetTapGain(p->p,evt->dstVarId - p->baseGainMtId, cmDspDouble(inst,evt->dstVarId));
  267. else
  268. {
  269. switch( evt->dstVarId )
  270. {
  271. case kScaleMtId:
  272. //cmDspDouble(inst,kScaleMtId);
  273. break;
  274. case kFbMtId:
  275. p->p->fbCoeff = cmDspDouble(inst,kFbMtId);
  276. break;
  277. }
  278. }
  279. return rc;
  280. }
  281. cmDspRC_t _cmDspMtDelayRecvFunc( cmDspCtx_t* ctx, cmDspInst_t* inst, unsigned attrSymId, const cmDspValue_t* value )
  282. {
  283. cmDspRC_t rc = kOkDspRC;
  284. cmDspMtDelay_t* p = (cmDspMtDelay_t*)inst;
  285. if( cmDsvIsSymbol(value) && (cmDsvSymbol(value)==p->printSymId) )
  286. {
  287. int i;
  288. cmRptPrintf(ctx->rpt,"taps:%i\n",p->tapCnt);
  289. for(i=0; i<p->tapCnt; ++i)
  290. cmRptPrintf(ctx->rpt,"%f %f\n",p->msV[i],p->gainV[i]);
  291. cmMDelayReport(p->p, ctx->rpt );
  292. }
  293. return rc;
  294. }
  295. cmDspClass_t* cmMtDelayClassCons( cmDspCtx_t* ctx )
  296. {
  297. cmDspClassSetup(&_cmMtDelayDC,ctx,"MtDelay",
  298. NULL,
  299. _cmDspMtDelayAlloc,
  300. _cmDspMtDelayFree,
  301. _cmDspMtDelayReset,
  302. _cmDspMtDelayExec,
  303. _cmDspMtDelayRecv,
  304. NULL,
  305. _cmDspMtDelayRecvFunc,
  306. "Multi-tap delay.");
  307. return &_cmMtDelayDC;
  308. }
  309. //------------------------------------------------------------------------------------------------------------
  310. //)
  311. //( { label:cmDspPShift file_desc:"Time-domain pitch shifter." kw:[sunit] }
  312. enum
  313. {
  314. kBypassPsId,
  315. kRatioPsId,
  316. kInPsId,
  317. kOutPsId
  318. };
  319. cmDspClass_t _cmPShiftDC;
  320. typedef struct
  321. {
  322. cmDspInst_t inst;
  323. //cmCtx* ctx;
  324. cmPitchShift* pshift;
  325. } cmDspPShift_t;
  326. cmDspInst_t* _cmDspPShiftAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  327. {
  328. unsigned chs = 1;
  329. cmDspVarArg_t args[] =
  330. {
  331. { "bypass",kBypassPsId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Bypass enable flag." },
  332. { "ratio", kRatioPsId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Ratio" },
  333. { "in", kInPsId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  334. { "out", kOutPsId, 0, chs, kOutDsvFl | kAudioBufDsvFl, "Audio output." },
  335. { NULL, 0, 0, 0, 0 }
  336. };
  337. cmDspPShift_t* p = cmDspInstAlloc(cmDspPShift_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl);
  338. // set default values for the parameters that were not explicitely set in the va_arg list
  339. cmDspSetDefaultBool( ctx, &p->inst, kBypassPsId, 0, 0 );
  340. cmDspSetDefaultDouble( ctx, &p->inst ,kRatioPsId, 0.0, 1.0 );
  341. p->pshift = cmPitchShiftAlloc(ctx->cmProcCtx,NULL,cmDspSamplesPerCycle(ctx), cmDspSampleRate(ctx) );
  342. return &p->inst;
  343. }
  344. cmDspRC_t _cmDspPShiftFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  345. {
  346. cmDspRC_t rc = kOkDspRC;
  347. cmDspPShift_t* p = (cmDspPShift_t*)inst;
  348. cmPitchShiftFree(&p->pshift);
  349. //cmCtxFree(&p->ctx);
  350. return rc;
  351. }
  352. cmDspRC_t _cmDspPShiftReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  353. {
  354. cmDspRC_t rc = kOkDspRC;
  355. rc = cmDspApplyAllDefaults(ctx,inst);
  356. return rc;
  357. }
  358. cmDspRC_t _cmDspPShiftExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  359. {
  360. cmDspPShift_t* p = (cmDspPShift_t*)inst;
  361. cmDspRC_t rc = kOkDspRC;
  362. unsigned iChIdx = 0;
  363. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInPsId,iChIdx);
  364. unsigned iSmpCnt = cmDspVarRows(inst,kInPsId);
  365. unsigned oChIdx = 0;
  366. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutPsId,oChIdx);
  367. unsigned oSmpCnt = cmDspVarRows(inst,kOutPsId);
  368. bool bypassFl= cmDspBool(inst,kBypassPsId);
  369. cmPitchShiftExec(p->pshift,ip,op,cmMin(iSmpCnt,oSmpCnt),cmDspDouble(inst,kRatioPsId),bypassFl);
  370. return rc;
  371. }
  372. cmDspRC_t _cmDspPShiftRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  373. {
  374. return cmDspSetEvent(ctx,inst,evt);
  375. }
  376. cmDspClass_t* cmPShiftClassCons( cmDspCtx_t* ctx )
  377. {
  378. cmDspClassSetup(&_cmPShiftDC,ctx,"PShift",
  379. NULL,
  380. _cmDspPShiftAlloc,
  381. _cmDspPShiftFree,
  382. _cmDspPShiftReset,
  383. _cmDspPShiftExec,
  384. _cmDspPShiftRecv,
  385. NULL,NULL,
  386. "Pitch Shifter.");
  387. return &_cmPShiftDC;
  388. }
  389. //------------------------------------------------------------------------------------------------------------
  390. //)
  391. //( { label:cmDspLoopRecd file_desc:"Loop recorder." kw:[sunit] }
  392. enum
  393. {
  394. kTimeLrId,
  395. kPGainLrId,
  396. kRGainLrId,
  397. kBypassLrId,
  398. kPlayLrId,
  399. kRecdLrId,
  400. kRatioLrId,
  401. kInLrId,
  402. kOutLrId
  403. };
  404. cmDspClass_t _cmLoopRecdDC;
  405. typedef struct
  406. {
  407. cmDspInst_t inst;
  408. //cmCtx* ctx;
  409. bool playFl;
  410. cmLoopRecord* lrp;
  411. } cmDspLoopRecd_t;
  412. cmDspInst_t* _cmDspLoopRecdAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  413. {
  414. unsigned chs = 1;
  415. cmDspVarArg_t args[] =
  416. {
  417. { "time", kTimeLrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Max record time in seconds" },
  418. { "pgain", kPGainLrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Pass-through gain."},
  419. { "rgain", kRGainLrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Recorder out gain."},
  420. { "bypass",kBypassLrId,0, 0, kInDsvFl | kBoolDsvFl, "Bypass flag"},
  421. { "play", kPlayLrId, 0, 0, kInDsvFl | kBoolDsvFl, "Play gate flag" },
  422. { "recd", kRecdLrId, 0, 0, kInDsvFl | kBoolDsvFl, "Recd gate flag" },
  423. { "ratio", kRatioLrId, 0, 0, kInDsvFl | kDoubleDsvFl, "Playback speed ratio"},
  424. { "in", kInLrId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  425. { "out", kOutLrId, 0, chs, kOutDsvFl | kAudioBufDsvFl, "Audio output." },
  426. { NULL, 0, 0, 0, 0 }
  427. };
  428. cmDspLoopRecd_t* p = cmDspInstAlloc(cmDspLoopRecd_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl);
  429. // set default values for the parameters that were not explicitely set in the va_arg list
  430. cmDspSetDefaultDouble( ctx, &p->inst, kTimeLrId, 0, 10 );
  431. cmDspSetDefaultDouble( ctx, &p->inst, kPGainLrId, 0, 1.0 );
  432. cmDspSetDefaultDouble( ctx, &p->inst, kRGainLrId, 0, 1.0 );
  433. cmDspSetDefaultBool( ctx, &p->inst, kBypassLrId, 0, 0 );
  434. cmDspSetDefaultBool( ctx, &p->inst, kPlayLrId, 0, 0 );
  435. cmDspSetDefaultBool( ctx, &p->inst, kRecdLrId, 0, 0 );
  436. cmDspSetDefaultDouble( ctx, &p->inst, kRatioLrId, 0, 1.0);
  437. p->lrp = cmLoopRecordAlloc(ctx->cmProcCtx,NULL,0,0,0 );
  438. return &p->inst;
  439. }
  440. cmDspRC_t _cmDspLoopRecdFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  441. {
  442. cmDspRC_t rc = kOkDspRC;
  443. cmDspLoopRecd_t* p = (cmDspLoopRecd_t*)inst;
  444. cmLoopRecordFree(&p->lrp);
  445. //cmCtxFree(&p->ctx);
  446. return rc;
  447. }
  448. cmDspRC_t _cmDspLoopRecdReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  449. {
  450. cmDspRC_t rc = kOkDspRC;
  451. cmDspLoopRecd_t* p = (cmDspLoopRecd_t*)inst;
  452. rc = cmDspApplyAllDefaults(ctx,inst);
  453. cmReal_t maxRecdTimeSecs = cmDspDefaultDouble(&p->inst,kTimeLrId);
  454. unsigned maxRecdTimeSmps = floor(cmDspSampleRate(ctx) * maxRecdTimeSecs);
  455. unsigned xfadeTimeSmps = floor(cmDspSampleRate(ctx) * 50.0/1000.0);
  456. if( maxRecdTimeSmps != p->lrp->maxRecdSmpCnt || xfadeTimeSmps != p->lrp->xfadeSmpCnt )
  457. cmLoopRecordInit(p->lrp,cmDspSamplesPerCycle(ctx),maxRecdTimeSmps,xfadeTimeSmps);
  458. return rc;
  459. }
  460. cmDspRC_t _cmDspLoopRecdExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  461. {
  462. cmDspLoopRecd_t* p = (cmDspLoopRecd_t*)inst;
  463. cmDspRC_t rc = kOkDspRC;
  464. unsigned iChIdx = 0;
  465. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInLrId,iChIdx);
  466. unsigned iSmpCnt = cmDspVarRows(inst,kInLrId);
  467. unsigned oChIdx = 0;
  468. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutLrId,oChIdx);
  469. unsigned oSmpCnt = cmDspVarRows(inst,kOutLrId);
  470. bool recdFl = cmDspBool(inst,kRecdLrId);
  471. bool bypassFl = cmDspBool(inst,kBypassLrId);
  472. double ratio = cmDspDouble(inst,kRatioLrId);
  473. double rgain = cmDspDouble(inst,kRGainLrId); // recorder output gain
  474. double pgain = cmDspDouble(inst,kPGainLrId); // pass through gain
  475. if( ip != NULL && op != NULL )
  476. cmLoopRecordExec(p->lrp,ip,op,cmMin(iSmpCnt,oSmpCnt), bypassFl, recdFl, p->playFl, ratio, pgain, rgain );
  477. p->playFl = false;
  478. return rc;
  479. }
  480. cmDspRC_t _cmDspLoopRecdRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  481. {
  482. cmDspLoopRecd_t* p = (cmDspLoopRecd_t*)inst;
  483. cmDspRC_t rc = cmDspSetEvent(ctx,inst,evt);
  484. switch(evt->dstVarId)
  485. {
  486. case kPlayLrId:
  487. p->playFl = cmDspBool(inst,kPlayLrId);
  488. break;
  489. }
  490. return rc;
  491. }
  492. cmDspClass_t* cmLoopRecdClassCons( cmDspCtx_t* ctx )
  493. {
  494. cmDspClassSetup(&_cmLoopRecdDC,ctx,"LoopRecd",
  495. NULL,
  496. _cmDspLoopRecdAlloc,
  497. _cmDspLoopRecdFree,
  498. _cmDspLoopRecdReset,
  499. _cmDspLoopRecdExec,
  500. _cmDspLoopRecdRecv,
  501. NULL,NULL,
  502. "Loop recorder.");
  503. return &_cmLoopRecdDC;
  504. }
  505. //------------------------------------------------------------------------------------------------------------
  506. //)
  507. //( { label:cmDspRectify file_desc:"Full-wave rectifier." kw:[sunit] }
  508. enum
  509. {
  510. kBypassRcId,
  511. kCoeffRcId,
  512. kInRcId,
  513. kOutRcId
  514. };
  515. cmDspClass_t _cmRectifyDC;
  516. typedef struct
  517. {
  518. cmDspInst_t inst;
  519. } cmDspRectify_t;
  520. cmDspInst_t* _cmDspRectifyAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  521. {
  522. unsigned chs = 1;
  523. cmDspVarArg_t args[] =
  524. {
  525. { "bypass",kBypassRcId,0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Bypass enable flag." },
  526. { "coeff", kCoeffRcId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Coefficient" },
  527. { "in", kInRcId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  528. { "out", kOutRcId, 0, chs, kOutDsvFl | kAudioBufDsvFl, "Audio output." },
  529. { NULL, 0, 0, 0, 0 }
  530. };
  531. cmDspRectify_t* p = cmDspInstAlloc(cmDspRectify_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl);
  532. // set default values for the parameters that were not explicitely set in the va_arg list
  533. cmDspSetDefaultBool( ctx, &p->inst, kBypassRcId,0, 0 );
  534. cmDspSetDefaultDouble( ctx, &p->inst, kCoeffRcId, 0, 0.0 );
  535. return &p->inst;
  536. }
  537. cmDspRC_t _cmDspRectifyFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  538. {
  539. return kOkDspRC;
  540. }
  541. cmDspRC_t _cmDspRectifyReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  542. {
  543. cmDspRC_t rc = kOkDspRC;
  544. rc = cmDspApplyAllDefaults(ctx,inst);
  545. return rc;
  546. }
  547. cmDspRC_t _cmDspRectifyExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  548. {
  549. unsigned iChIdx = 0;
  550. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInRcId,iChIdx);
  551. unsigned iSmpCnt = cmDspVarRows(inst,kInRcId);
  552. unsigned oChIdx = 0;
  553. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutRcId,oChIdx);
  554. unsigned oSmpCnt = cmDspVarRows(inst,kOutRcId);
  555. bool bypassFl= cmDspBool(inst,kBypassRcId);
  556. unsigned n = cmMin(iSmpCnt,oSmpCnt);
  557. unsigned i;
  558. if( bypassFl )
  559. memcpy(op,ip,n*sizeof(cmSample_t));
  560. else
  561. {
  562. for(i=0; i<n; ++i)
  563. op[i] = ip[i] > 0 ? ip[i] : 0;
  564. }
  565. return kOkDspRC;
  566. }
  567. cmDspRC_t _cmDspRectifyRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  568. {
  569. return cmDspSetEvent(ctx,inst,evt);
  570. }
  571. cmDspClass_t* cmRectifyClassCons( cmDspCtx_t* ctx )
  572. {
  573. cmDspClassSetup(&_cmRectifyDC,ctx,"Rectify",
  574. NULL,
  575. _cmDspRectifyAlloc,
  576. _cmDspRectifyFree,
  577. _cmDspRectifyReset,
  578. _cmDspRectifyExec,
  579. _cmDspRectifyRecv,
  580. NULL,NULL,
  581. "Half-wave rectifier.");
  582. return &_cmRectifyDC;
  583. }
  584. //------------------------------------------------------------------------------------------------------------
  585. //)
  586. //( { label:cmDspGateDetect file_desc:"Track the onset and offset of an incoming signal." kw:[sunit] }
  587. enum
  588. {
  589. kWndMsGdId,
  590. kOnThreshPctGdId,
  591. kOnThreshDbGdId,
  592. kOffThreshDbGdId,
  593. kInGdId,
  594. kGateGdId,
  595. kRmsGdId,
  596. kMeanGdId
  597. };
  598. cmDspClass_t _cmGateDetectDC;
  599. typedef struct
  600. {
  601. cmDspInst_t inst;
  602. //cmCtx* ctx;
  603. cmShiftBuf* sbp;
  604. cmGateDetect* gdp;
  605. } cmDspGateDetect_t;
  606. cmDspInst_t* _cmDspGateDetectAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  607. {
  608. cmDspVarArg_t args[] =
  609. {
  610. { "wnd", kWndMsGdId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Window length in milliseconds." },
  611. { "onpct", kOnThreshPctGdId,0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Onset slope threshold [0.0 - 1.0]." },
  612. { "ondb", kOnThreshDbGdId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Onset threshold dB [-Inf to 0]" },
  613. { "offdb", kOffThreshDbGdId,0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Offset threshold dB [-Inf to 0]" },
  614. { "in", kInGdId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  615. { "gate", kGateGdId, 0, 0, kOutDsvFl | kBoolDsvFl, "Gate state output." },
  616. { "rms", kRmsGdId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Signal level RMS"},
  617. { "mean", kMeanGdId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Derr mean."},
  618. { NULL, 0, 0, 0, 0 }
  619. };
  620. cmDspGateDetect_t* p = cmDspInstAlloc(cmDspGateDetect_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl);
  621. p->sbp = cmShiftBufAlloc(ctx->cmProcCtx,NULL,0,0,0);
  622. p->gdp = cmGateDetectAlloc(ctx->cmProcCtx,NULL,0,0,0,0);
  623. // set default values for the parameters that were not explicitely set in the va_arg list
  624. cmDspSetDefaultDouble( ctx, &p->inst, kWndMsGdId, 0, 42 );
  625. cmDspSetDefaultDouble( ctx, &p->inst, kOnThreshPctGdId, 0, 0.8 );
  626. cmDspSetDefaultDouble( ctx, &p->inst, kOnThreshDbGdId, 0, -30.0 );
  627. cmDspSetDefaultDouble( ctx, &p->inst, kOffThreshDbGdId, 0, -60.0 );
  628. return &p->inst;
  629. }
  630. cmDspRC_t _cmDspGateDetectFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  631. {
  632. cmDspGateDetect_t* p = (cmDspGateDetect_t*)inst;
  633. cmGateDetectFree(&p->gdp);
  634. cmShiftBufFree(&p->sbp);
  635. //cmCtxFree(&p->ctx);
  636. return kOkDspRC;
  637. }
  638. cmDspRC_t _cmDspGateDetectReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  639. {
  640. cmDspGateDetect_t* p = (cmDspGateDetect_t*)inst;
  641. cmDspRC_t rc = kOkDspRC;
  642. if((rc = cmDspApplyAllDefaults(ctx,inst)) != kOkDspRC )
  643. return rc;
  644. double wndMs = cmDspDouble(inst,kWndMsGdId);
  645. double sr = cmDspSampleRate(ctx);
  646. unsigned wndSmpCnt = floor(wndMs * sr / 1000.0);
  647. if( cmShiftBufInit(p->sbp, cmDspSamplesPerCycle(ctx), wndSmpCnt, wndSmpCnt/4 ) != cmOkRC )
  648. return cmErrMsg(&ctx->cmCtx->err,kInstResetFailDspRC,"The gate detector shift buffer initialization failed.");
  649. if( cmGateDetectInit(p->gdp, cmDspSamplesPerCycle(ctx), cmDspDouble(inst,kOnThreshPctGdId), cmDspDouble(inst,kOnThreshDbGdId), cmDspDouble(inst,kOffThreshDbGdId) ) != cmOkRC )
  650. return cmErrMsg(&ctx->cmCtx->err,kInstResetFailDspRC,"The gate detector shift buffer initialization failed.");
  651. return rc;
  652. }
  653. cmDspRC_t _cmDspGateDetectExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  654. {
  655. cmDspGateDetect_t* p = (cmDspGateDetect_t*)inst;
  656. unsigned iChIdx = 0;
  657. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInGdId,iChIdx);
  658. unsigned iSmpCnt = cmDspVarRows(inst,kInGdId);
  659. while( cmShiftBufExec(p->sbp, ip, iSmpCnt ) )
  660. {
  661. cmGateDetectExec(p->gdp,p->sbp->outV, p->sbp->outN );
  662. cmDspSetDouble(ctx,inst,kRmsGdId,p->gdp->rms);
  663. cmDspSetDouble(ctx,inst,kMeanGdId,p->gdp->mean);
  664. if( p->gdp->deltaFl )
  665. cmDspSetBool( ctx,inst,kGateGdId,p->gdp->gateFl);
  666. }
  667. return kOkDspRC;
  668. }
  669. cmDspRC_t _cmDspGateDetectRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  670. {
  671. cmDspRC_t rc;
  672. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  673. return rc;
  674. switch(evt->dstVarId)
  675. {
  676. case kWndMsGdId:
  677. break;
  678. case kOnThreshPctGdId:
  679. break;
  680. case kOnThreshDbGdId:
  681. break;
  682. case kOffThreshDbGdId:
  683. break;
  684. case kInGdId:
  685. break;
  686. }
  687. return rc;
  688. }
  689. cmDspClass_t* cmGateDetectClassCons( cmDspCtx_t* ctx )
  690. {
  691. cmDspClassSetup(&_cmGateDetectDC,ctx,"GateDetect",
  692. NULL,
  693. _cmDspGateDetectAlloc,
  694. _cmDspGateDetectFree,
  695. _cmDspGateDetectReset,
  696. _cmDspGateDetectExec,
  697. _cmDspGateDetectRecv,
  698. NULL,NULL,
  699. "Gate detector.");
  700. return &_cmGateDetectDC;
  701. }
  702. //------------------------------------------------------------------------------------------------------------
  703. //)
  704. //( { label:cmDspAutoGain file_desc:"Normalize a set of audio input signals to acheive a consistent level." kw:[sunit] }
  705. // The purpose of this object is to calculate, store and retrieve gain coefficents
  706. // for a set of audio channels. The gain coefficients are designed to balance the
  707. // volume of each channel relative to the others. During gain calibration
  708. // a sample of each channel is taken and it's average volume is determined.
  709. // After an example of all channels has been received a new set of gain coefficients
  710. // is calculated which decreases the volume of loud channels and increases the
  711. // volume of quiet channels.
  712. //
  713. // The gain coefficents are made available via a set of 'gain-###' output ports.
  714. //
  715. // This object acts as an interface to the cmAutoGain processor.
  716. //
  717. // As input it takes a channel configuration JSON file of the form:
  718. // {
  719. // ch_array :
  720. // [ ["ch","ssi","pitch","midi","gain"]
  721. // [ 0, 0, "C4", 60, 1.0 ]
  722. // ....
  723. // [ n 0, "C5", 72, 1.0 ]
  724. // ]
  725. // }
  726. //
  727. // Each array in 'ch_array' gives the configuration of a channel.
  728. //
  729. //
  730. // It also requires a JSON resource object of the form
  731. // gdParms:
  732. // {
  733. // medCnt: 5
  734. // avgCnt: 9
  735. // suprCnt: 6
  736. // offCnt: 3
  737. // suprCoeff: 1.400000
  738. // onThreshDb: -53.000000
  739. // offThreshDb: -80.000000
  740. // }
  741. //
  742. // These arguments are used to configure the cmAutoGain Proessor gate detector function.
  743. //
  744. // During runtime the object accepts the following action selector symbol id's:
  745. // a. start - begin a new calibration session
  746. // b. proc - end a calibration session and calculate new gain coeff's
  747. // c. cancel - cancel a calibration session
  748. // d. write - write the channel configuration file
  749. // e. print - print the current auto gain calibration state
  750. //
  751. // After a 'start' msg the object accepts channel id's throught its 'id' input port.
  752. // Each 'id' identifies the channel which it will process next.
  753. // Upon reception of a channel id the object routes subsequent audio to its
  754. // internal cmAutoGain processor until it receives the next channel id
  755. // or a 'proc' or 'cancel' symbol.
  756. //==========================================================================================================================================
  757. enum
  758. {
  759. kChCntAgId,
  760. kHopAgId,
  761. kMedNAgId,
  762. kAvgNAgId,
  763. kSupNAgId,
  764. kOffNAgId,
  765. kSupCoefAgId,
  766. kOnThrAgId,
  767. kOffThrAgId,
  768. kSelAgId,
  769. kIdAgId,
  770. kInBaseAgId
  771. };
  772. typedef struct
  773. {
  774. cmDspInst_t inst;
  775. cmAutoGain* agp;
  776. unsigned gainBaseAgId;
  777. unsigned chCnt;
  778. unsigned chIdx;
  779. unsigned startSymId;
  780. unsigned procSymId;
  781. unsigned cancelSymId;
  782. unsigned writeSymId;
  783. unsigned printSymId;
  784. } cmDspAutoGain_t;
  785. cmDspClass_t _cmAutoGainDC;
  786. cmDspInst_t* _cmDspAutoGainAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  787. {
  788. cmDspVarArg_t args[] =
  789. {
  790. { "chCnt",kChCntAgId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Audio channel count."},
  791. { "hop", kHopAgId, 0, 0, kDoubleDsvFl | kReqArgDsvFl, "RMS hop in milliseconds."},
  792. { "med", kMedNAgId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Median filter hop count."},
  793. { "avg", kAvgNAgId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Average filter hop count."},
  794. { "sup", kSupNAgId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Supression filter hop count."},
  795. { "off", kOffNAgId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Offset filter hop count."},
  796. { "supC", kSupCoefAgId,0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Suppression coefficent."},
  797. { "onThr",kOnThrAgId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Onset threshold in dB."},
  798. { "offThr",kOffThrAgId,0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Offset threshold in dB."},
  799. { "sel", kSelAgId, 0, 0, kInDsvFl | kSymDsvFl | kNoArgDsvFl, "Action Selector: start | proc | cancel." },
  800. { "id", kIdAgId, 0, 0, kInDsvFl | kIntDsvFl | kNoArgDsvFl, "Channel id input."},
  801. };
  802. va_list vl1;
  803. unsigned i;
  804. // verify that at least one var arg exists
  805. if( va_cnt < 1 )
  806. {
  807. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The AutoGain constructor must be given the audio channel count as its first argument.");
  808. return NULL;
  809. }
  810. // copy the va_list so that it can be used again in cmDspInstAlloc()
  811. va_copy(vl1,vl);
  812. // get the first var arg which should be a filename
  813. unsigned chCnt = va_arg(vl,unsigned);
  814. if( chCnt == 0 )
  815. {
  816. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The AutoGain constructor requires at least 1 audio channel.");
  817. va_end(vl1);
  818. return NULL;
  819. }
  820. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  821. unsigned argCnt = fixArgCnt + 2 * chCnt;
  822. unsigned gainBaseAgId = kInBaseAgId + chCnt;
  823. cmDspVarArg_t a[ argCnt+1 ];
  824. assert( fixArgCnt == kInBaseAgId );
  825. // setup the output gain args
  826. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  827. cmDspArgSetupN(ctx, a, argCnt, kInBaseAgId, chCnt, "in", kInBaseAgId, 0, 0, kInDsvFl | kAudioBufDsvFl, "audio in");
  828. cmDspArgSetupN(ctx, a, argCnt, gainBaseAgId, chCnt, "gain", gainBaseAgId, 0, 0, kOutDsvFl | kDoubleDsvFl, "calibrated channel gain");
  829. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  830. // instantiate the object
  831. cmDspAutoGain_t* p = cmDspInstAlloc(cmDspAutoGain_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl1);
  832. // assign the current gain coefficients
  833. for(i=0; i<chCnt; ++i)
  834. cmDspSetDefaultDouble( ctx, &p->inst, gainBaseAgId + i, 0.0, 1.0);
  835. // allocate the auto gain calculation proc
  836. p->agp = cmAutoGainAlloc(ctx->cmProcCtx,NULL,0,0,0,0,NULL);
  837. p->chCnt = chCnt;
  838. p->chIdx = cmInvalidIdx;
  839. p->gainBaseAgId= gainBaseAgId;
  840. p->startSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"start");
  841. p->procSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"proc");
  842. p->cancelSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"cancel");
  843. p->printSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"print");
  844. cmDspSetDefaultSymbol( ctx, &p->inst, kSelAgId, p->cancelSymId );
  845. cmDspSetDefaultInt( ctx, &p->inst, kIdAgId, 0, cmInvalidId );
  846. va_end(vl1);
  847. return &p->inst;
  848. }
  849. cmDspRC_t _cmDspAutoGainFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  850. {
  851. cmDspAutoGain_t* p = (cmDspAutoGain_t*)inst;
  852. cmAutoGainFree(&p->agp);
  853. return kOkDspRC;
  854. }
  855. cmDspRC_t _cmDspAutoGainReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  856. {
  857. cmDspRC_t rc = kOkDspRC;
  858. rc = cmDspApplyAllDefaults(ctx,inst);
  859. return rc;
  860. }
  861. cmDspRC_t _cmDspAutoGainExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  862. {
  863. cmDspAutoGain_t* p = (cmDspAutoGain_t*)inst;
  864. unsigned curInChIdx = cmDspInt( inst, kIdAgId);
  865. if( cmDspSymbol( inst, kSelAgId ) == p->startSymId && curInChIdx != cmInvalidId )
  866. {
  867. unsigned inChVarId = kInBaseAgId+curInChIdx;
  868. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,inChVarId,0);
  869. unsigned iSmpCnt = cmDspVarRows(inst,inChVarId);
  870. cmAutoGainProcCh( p->agp, ip, iSmpCnt );
  871. }
  872. return kOkDspRC;
  873. }
  874. cmDspRC_t _cmDspAutoGainInit( cmDspCtx_t* ctx, cmDspInst_t* inst )
  875. {
  876. cmDspAutoGain_t* p = (cmDspAutoGain_t*)inst;
  877. cmGateDetectParams gd;
  878. unsigned i;
  879. // collect the params into a cmGateDetectParams recd
  880. gd.medCnt = cmDspUInt( inst, kMedNAgId );
  881. gd.avgCnt = cmDspUInt( inst, kAvgNAgId );
  882. gd.suprCnt = cmDspUInt( inst, kSupNAgId );
  883. gd.offCnt = cmDspUInt( inst, kOffNAgId );
  884. gd.suprCoeff = cmDspDouble( inst, kSupCoefAgId );
  885. gd.onThreshDb = cmDspDouble( inst, kOnThrAgId );
  886. gd.offThreshDb = cmDspDouble( inst, kOffThrAgId );
  887. // setup the internal auto-gain object
  888. if( cmAutoGainInit(p->agp, cmDspSamplesPerCycle(ctx), cmDspSampleRate(ctx), cmDspDouble(inst,kHopAgId), p->chCnt, &gd ) != cmOkRC )
  889. return cmDspInstErr(ctx,inst,kSubSysFailDspRC,"The internal auto-gain instance could not be initialized.");
  890. // send out gain's of 1.0 so that the input audio is not
  891. // biased by any existing scaling.
  892. for(i=0; i<p->chCnt; ++i)
  893. cmDspSetDouble( ctx, inst, p->gainBaseAgId+i, 1.0);
  894. return kOkDspRC;
  895. }
  896. cmDspRC_t _cmDspAutoGainRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  897. {
  898. cmDspAutoGain_t* p = (cmDspAutoGain_t*)inst;
  899. cmDspRC_t rc = kOkDspRC;
  900. switch( evt->dstVarId )
  901. {
  902. case kSelAgId:
  903. {
  904. // store the current 'sel' state
  905. unsigned prvSymId = cmDspSymbol(inst,kSelAgId);
  906. // update it 'sel' to the new state
  907. cmDspSetEvent(ctx,inst,evt);
  908. // get the new state
  909. unsigned newSymId = cmDspSymbol(inst,kSelAgId);
  910. //
  911. // if PRINTing was requested
  912. //
  913. if( newSymId == p->printSymId )
  914. {
  915. cmRptPrintf(&ctx->cmCtx->rpt,"Auto-Gain Report\n");
  916. cmAutoGainPrint( p->agp, &ctx->cmCtx->rpt );
  917. goto doneLabel;
  918. }
  919. //
  920. // if calibration was CANCELLED
  921. //
  922. if( newSymId == p->cancelSymId )
  923. {
  924. cmDspSetInt( ctx, inst, kIdAgId, cmInvalidId );
  925. cmRptPrintf(&ctx->cmCtx->rpt,"cancelled\n");
  926. goto doneLabel;
  927. }
  928. //
  929. // if calibration STARTup was requested - initialize the autogain proc
  930. //
  931. if( newSymId == p->startSymId )
  932. {
  933. _cmDspAutoGainInit(ctx,inst);
  934. cmRptPrintf(&ctx->cmCtx->rpt,"started\n");
  935. goto doneLabel;
  936. }
  937. //
  938. // if calibration PROCessing was requested
  939. //
  940. if( newSymId == p->procSymId && prvSymId == p->startSymId )
  941. {
  942. cmRptPrintf(&ctx->cmCtx->rpt,"proc\n");
  943. // set the current channel id to 'cmInvalidId' to stop calls to
  944. // cmAutoGainProcCh() in _cmDspAutoGainExec()
  945. cmDspSetInt( ctx, inst, kIdAgId, cmInvalidId );
  946. // update the auto gain coefficients
  947. if( cmAutoGainCalcGains(p->agp) == cmOkRC )
  948. {
  949. // send the new auto gain coefficients to the output ports
  950. unsigned i;
  951. for(i=0; i<p->chCnt; ++i)
  952. cmDspSetDouble( ctx, inst, p->gainBaseAgId+i, p->agp->chArray[i].gain);
  953. }
  954. goto doneLabel;
  955. }
  956. }
  957. break;
  958. case kIdAgId:
  959. cmDspSetEvent(ctx,inst,evt);
  960. if( cmDspSymbol(inst,kSelAgId) == p->startSymId )
  961. {
  962. cmRptPrintf(&ctx->cmCtx->rpt,"id:%i\n", cmDspInt(inst,kIdAgId));
  963. cmAutoGainStartCh(p->agp, p->chIdx = cmDspInt(inst,kIdAgId));
  964. }
  965. break;
  966. default:
  967. { assert(0); }
  968. }
  969. doneLabel:
  970. return rc;
  971. }
  972. cmDspClass_t* cmAutoGainClassCons( cmDspCtx_t* ctx )
  973. {
  974. cmDspClassSetup(&_cmAutoGainDC,ctx,"AutoGain",
  975. NULL,
  976. _cmDspAutoGainAlloc,
  977. _cmDspAutoGainFree,
  978. _cmDspAutoGainReset,
  979. _cmDspAutoGainExec,
  980. _cmDspAutoGainRecv,
  981. NULL,NULL,
  982. "Auto-gain calibrator.");
  983. return &_cmAutoGainDC;
  984. }
  985. //------------------------------------------------------------------------------------------------------------
  986. //)
  987. //( { label:cmDspEnvFollow file_desc:"Generate a control signal from by analyzing the power envelope of an incoming audio signal." kw:[sunit] }
  988. enum
  989. {
  990. kHopMsEfId, // RMS window length in milliseconds
  991. kMedCntEfId, //
  992. kAvgCntEfId, //
  993. kSuprCntEfId, //
  994. kOffCntEfId, //
  995. kSuprCoefEfId, //
  996. kOnThrDbEfId, //
  997. kOffThrDbEfId, //
  998. kMaxDbEfId,
  999. kInEfId,
  1000. kGateEfId,
  1001. kRmsEfId,
  1002. kLevelEfId,
  1003. kOnEfId,
  1004. kOffEfId
  1005. };
  1006. cmDspClass_t _cmEnvFollowDC;
  1007. typedef struct
  1008. {
  1009. cmDspInst_t inst;
  1010. cmShiftBuf* sbp;
  1011. cmGateDetect2* gdp;
  1012. } cmDspEnvFollow_t;
  1013. cmDspInst_t* _cmDspEnvFollowAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  1014. {
  1015. cmDspVarArg_t args[] =
  1016. {
  1017. { "wnd", kHopMsEfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "RMS Window length"},
  1018. { "med", kMedCntEfId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Median filter length." },
  1019. { "avg", kAvgCntEfId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Averaging filter length." },
  1020. { "sup", kSuprCntEfId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Supression filter length." },
  1021. { "off", kOffCntEfId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Offset detection window length" },
  1022. { "supc", kSuprCoefEfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Suppression shape coefficient" },
  1023. { "ondb", kOnThrDbEfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Onset threshold dB." },
  1024. { "offdb", kOffThrDbEfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Offset threshold dB" },
  1025. { "maxdb", kMaxDbEfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Max reference dB" },
  1026. { "in", kInEfId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input" },
  1027. { "gate", kGateEfId, 0, 0, kOutDsvFl | kBoolDsvFl, "Gate state output." },
  1028. { "rms", kRmsEfId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Signal level RMS"},
  1029. { "level", kLevelEfId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Signal level 0.0-1.0 as scale between offset thresh dB and max dB"},
  1030. { "ons", kOnEfId, 0, 0, kOutDsvFl | kUIntDsvFl, "Onset counter"},
  1031. { "offs", kOffEfId, 0, 0, kOutDsvFl | kUIntDsvFl, "Offset counter"},
  1032. { NULL, 0, 0, 0, 0 }
  1033. };
  1034. cmDspEnvFollow_t* p = cmDspInstAlloc(cmDspEnvFollow_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl);
  1035. p->sbp = cmShiftBufAlloc(ctx->cmProcCtx,NULL,0,0,0);
  1036. p->gdp = cmGateDetectAlloc2(ctx->cmProcCtx,NULL,0,NULL);
  1037. // set default values for the parameters that were not explicitely set in the va_arg list
  1038. cmDspSetDefaultDouble( ctx, &p->inst, kHopMsEfId, 0, 12 );
  1039. cmDspSetDefaultUInt( ctx, &p->inst, kMedCntEfId, 0, 5 );
  1040. cmDspSetDefaultUInt( ctx, &p->inst, kAvgCntEfId, 0, 9 );
  1041. cmDspSetDefaultUInt( ctx, &p->inst, kSuprCntEfId, 0, 6 );
  1042. cmDspSetDefaultUInt( ctx, &p->inst, kOffCntEfId, 0, 3 );
  1043. cmDspSetDefaultDouble( ctx, &p->inst, kSuprCoefEfId, 0, 1.4 );
  1044. cmDspSetDefaultDouble( ctx, &p->inst, kOnThrDbEfId, 0, -45 );
  1045. cmDspSetDefaultDouble( ctx, &p->inst, kOffThrDbEfId, 0, -80 );
  1046. cmDspSetDefaultDouble( ctx, &p->inst, kMaxDbEfId, 0, -10.0 );
  1047. cmDspSetDefaultUInt( ctx, &p->inst, kOnEfId, 0, 0 );
  1048. cmDspSetDefaultUInt( ctx, &p->inst, kOffEfId, 0, 0 );
  1049. return &p->inst;
  1050. }
  1051. cmDspRC_t _cmDspEnvFollowFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1052. {
  1053. cmDspEnvFollow_t* p = (cmDspEnvFollow_t*)inst;
  1054. cmGateDetectFree2(&p->gdp);
  1055. cmShiftBufFree(&p->sbp);
  1056. return kOkDspRC;
  1057. }
  1058. cmDspRC_t _cmDspEnvFollowReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1059. {
  1060. cmDspEnvFollow_t* p = (cmDspEnvFollow_t*)inst;
  1061. cmDspRC_t rc = kOkDspRC;
  1062. if((rc = cmDspApplyAllDefaults(ctx,inst)) != kOkDspRC )
  1063. return rc;
  1064. cmGateDetectParams r;
  1065. r.medCnt = cmDspUInt( inst, kMedCntEfId );
  1066. r.avgCnt = cmDspUInt( inst, kAvgCntEfId );
  1067. r.suprCnt = cmDspUInt( inst, kSuprCntEfId );
  1068. r.offCnt = cmDspUInt( inst, kOffCntEfId );
  1069. r.suprCoeff = cmDspDouble( inst, kSuprCoefEfId );
  1070. r.onThreshDb = cmDspDouble( inst, kOnThrDbEfId );
  1071. r.offThreshDb = cmDspDouble( inst, kOffThrDbEfId );
  1072. double sr = cmDspSampleRate(ctx);
  1073. double hopSmpCnt = floor(sr * cmDspDouble(inst,kHopMsEfId) / 1000 );
  1074. unsigned wndSmpCnt = floor(r.medCnt * hopSmpCnt);
  1075. if( cmShiftBufInit(p->sbp, cmDspSamplesPerCycle(ctx), wndSmpCnt, hopSmpCnt ) != cmOkRC )
  1076. return cmDspInstErr(ctx,inst,kInstResetFailDspRC,"The gate detector shift buffer initialization failed.");
  1077. if( cmGateDetectInit2(p->gdp, cmDspSamplesPerCycle(ctx), &r ) != cmOkRC )
  1078. return cmDspInstErr(ctx,inst,kInstResetFailDspRC,"The gate detector shift buffer initialization failed.");
  1079. return rc;
  1080. }
  1081. cmDspRC_t _cmDspEnvFollowExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1082. {
  1083. cmDspEnvFollow_t* p = (cmDspEnvFollow_t*)inst;
  1084. unsigned iChIdx = 0;
  1085. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInEfId,iChIdx);
  1086. unsigned iSmpCnt = cmDspVarRows(inst,kInEfId);
  1087. double maxDb = cmDspDouble(inst,kMaxDbEfId);
  1088. double offDb = cmDspDouble(inst,kOffThrDbEfId);
  1089. while( cmShiftBufExec(p->sbp, ip, iSmpCnt ) )
  1090. {
  1091. cmGateDetectExec2(p->gdp,p->sbp->outV, p->sbp->outN );
  1092. // RMS is going out at the audio rate - maybe there should be an option
  1093. // to send it only when the gate changes - this could significantly
  1094. // cut down on unnecessary transmission if the RMS is only used
  1095. // when the gate changes
  1096. cmDspSetDouble(ctx,inst,kRmsEfId, p->gdp->rms );
  1097. double rmsDb = p->gdp->rms < 0.00001 ? -100.0 : 20.0 * log10(p->gdp->rms);
  1098. double level = maxDb <= offDb ? 0 : fabs((offDb - cmMax( offDb, cmMin( maxDb, rmsDb ))) / (maxDb - offDb));
  1099. cmDspSetDouble(ctx,inst,kLevelEfId, level );
  1100. if( p->gdp->onFl || p->gdp->offFl )
  1101. {
  1102. cmDspSetBool(ctx, inst, kGateEfId, p->gdp->gateFl);
  1103. if( p->gdp->onFl )
  1104. cmDspSetUInt( ctx, inst, kOnEfId, cmDspUInt(inst,kOnEfId) + 1 );
  1105. if( p->gdp->offFl )
  1106. cmDspSetUInt( ctx, inst, kOffEfId, cmDspUInt(inst,kOffEfId) + 1 );
  1107. }
  1108. }
  1109. return kOkDspRC;
  1110. }
  1111. cmDspRC_t _cmDspEnvFollowRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1112. {
  1113. cmDspRC_t rc;
  1114. cmDspEnvFollow_t* p = (cmDspEnvFollow_t*)inst;
  1115. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  1116. {
  1117. switch( evt->dstVarId )
  1118. {
  1119. case kOnThrDbEfId:
  1120. cmGateDetectSetOnThreshDb2(p->gdp, cmDspDouble(inst,kOnThrDbEfId) );
  1121. break;
  1122. case kOffThrDbEfId:
  1123. cmGateDetectSetOffThreshDb2(p->gdp, cmDspDouble(inst,kOffThrDbEfId) );
  1124. break;
  1125. }
  1126. }
  1127. return rc;
  1128. }
  1129. cmDspClass_t* cmEnvFollowClassCons( cmDspCtx_t* ctx )
  1130. {
  1131. cmDspClassSetup(&_cmEnvFollowDC,ctx,"EnvFollow",
  1132. NULL,
  1133. _cmDspEnvFollowAlloc,
  1134. _cmDspEnvFollowFree,
  1135. _cmDspEnvFollowReset,
  1136. _cmDspEnvFollowExec,
  1137. _cmDspEnvFollowRecv,
  1138. NULL,NULL,
  1139. "Envelope follower and gate detector.");
  1140. return &_cmEnvFollowDC;
  1141. }
  1142. //------------------------------------------------------------------------------------------------------------
  1143. //)
  1144. //( { label:cmDspXfader file_desc:"Gate controlled fader bank." kw:[sunit] }
  1145. // Fade in and out an arbitrary number of audio signals based on gate signals.
  1146. // When the gate is high the signal fades in and when the gate is low the signal fades out.
  1147. // Constructor Args:
  1148. // Required: Count of input and output channels.
  1149. // Optional: Fade time in milliseconds.
  1150. //
  1151. // Inputs:
  1152. // bool Control gates
  1153. // audio Input audio.
  1154. // Outputs:
  1155. // audio Output audio
  1156. // double Channel gains.
  1157. enum
  1158. {
  1159. kChCntXfId,
  1160. kFadeTimeMsXfId,
  1161. kMstrGateXfId,
  1162. kFadeInTimeMsXfId,
  1163. kFadeOutTimeMsXfId,
  1164. kResetXfId,
  1165. kOnXfId,
  1166. kOffXfId,
  1167. kGateBaseXfId,
  1168. };
  1169. cmDspClass_t _cmXfaderDC;
  1170. typedef struct
  1171. {
  1172. cmDspInst_t inst;
  1173. cmXfader* xfdp;
  1174. unsigned inBaseXfId;
  1175. unsigned outBaseXfId;
  1176. unsigned stateBaseXfId;
  1177. unsigned gainBaseXfId;
  1178. unsigned chCnt;
  1179. bool* chGateV;
  1180. unsigned onSymId;
  1181. unsigned offSymId;
  1182. } cmDspXfader_t;
  1183. cmDspInst_t* _cmDspXfaderAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  1184. {
  1185. cmDspVarArg_t args[] =
  1186. {
  1187. { "chs", kChCntXfId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Input and Output channel count"},
  1188. { "ms", kFadeTimeMsXfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Fade time in milliseonds."},
  1189. { "mgate", kMstrGateXfId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Master gate - can be used to set all gates."},
  1190. { "ims", kFadeInTimeMsXfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Fade in time in milliseonds."},
  1191. { "oms", kFadeOutTimeMsXfId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Fade out time in milliseonds."},
  1192. { "reset", kResetXfId, 0, 0, kInDsvFl | kBoolDsvFl, "Jump to gate states rather than fade."},
  1193. { "on", kOnXfId, 0, 0, kOutDsvFl | kSymDsvFl, "Send 'on' when all ch's transition from off to on."},
  1194. { "off", kOffXfId, 0, 0, kOutDsvFl | kSymDsvFl, "Send 'off' when all ch's transition from on to off."},
  1195. };
  1196. if( va_cnt < 1 )
  1197. {
  1198. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The Xfader object must be given a channel count argument.");
  1199. return NULL;
  1200. }
  1201. va_list vl1;
  1202. va_copy(vl1,vl);
  1203. unsigned chCnt = va_arg(vl,int);
  1204. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  1205. unsigned argCnt = fixArgCnt + 5*chCnt;
  1206. unsigned inBaseXfId = kGateBaseXfId + chCnt;
  1207. unsigned outBaseXfId = inBaseXfId + chCnt;
  1208. unsigned stateBaseXfId = outBaseXfId + chCnt;
  1209. unsigned gainBaseXfId = stateBaseXfId + chCnt;
  1210. cmDspVarArg_t a[ argCnt+1 ];
  1211. // setup the input gate detectors and the output gain args
  1212. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  1213. cmDspArgSetupN(ctx, a, argCnt, kGateBaseXfId, chCnt, "gate", kGateBaseXfId, 0, 0, kInDsvFl | kBoolDsvFl, "gate flags");
  1214. cmDspArgSetupN(ctx, a, argCnt, inBaseXfId, chCnt, "in", inBaseXfId, 0, 0, kInDsvFl | kAudioBufDsvFl, "audio input");
  1215. cmDspArgSetupN(ctx, a, argCnt, outBaseXfId, chCnt, "out", outBaseXfId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "audio output");
  1216. cmDspArgSetupN(ctx, a, argCnt, stateBaseXfId, chCnt, "state",stateBaseXfId, 0, 0, kOutDsvFl | kBoolDsvFl, "current fader state");
  1217. cmDspArgSetupN(ctx, a, argCnt, gainBaseXfId, chCnt, "gain", gainBaseXfId, 0, 0, kOutDsvFl | kDoubleDsvFl, "gain output");
  1218. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  1219. cmDspXfader_t* p = cmDspInstAlloc(cmDspXfader_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl1);
  1220. double fadeTimeMs = cmDspDouble(&p->inst, kFadeTimeMsXfId );
  1221. p->xfdp = cmXfaderAlloc(ctx->cmProcCtx,NULL,cmDspSampleRate(ctx), chCnt, fadeTimeMs);
  1222. p->inBaseXfId = inBaseXfId;
  1223. p->outBaseXfId = outBaseXfId;
  1224. p->stateBaseXfId = stateBaseXfId;
  1225. p->gainBaseXfId = gainBaseXfId;
  1226. p->chCnt = chCnt;
  1227. p->chGateV = cmMemAllocZ(bool,p->chCnt);
  1228. p->onSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"on");
  1229. p->offSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"off");
  1230. // set default values for the parameters that were not explicitely set in the va_arg list
  1231. cmDspSetDefaultDouble( ctx, &p->inst, kFadeTimeMsXfId, 0, 100 );
  1232. cmDspSetDefaultBool( ctx, &p->inst, kMstrGateXfId, false, false);
  1233. cmDspSetDefaultSymbol( ctx, &p->inst, kOnXfId, p->onSymId );
  1234. cmDspSetDefaultSymbol( ctx, &p->inst, kOffXfId, p->offSymId );
  1235. int i;
  1236. for(i=0; i<chCnt; ++i)
  1237. cmDspSetDefaultBool( ctx, &p->inst, stateBaseXfId+i, false, false );
  1238. va_end(vl1);
  1239. return &p->inst;
  1240. }
  1241. cmDspRC_t _cmDspXfaderFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1242. {
  1243. cmDspXfader_t* p = (cmDspXfader_t*)inst;
  1244. cmMemFree(p->chGateV);
  1245. cmXfaderFree(&p->xfdp);
  1246. return kOkDspRC;
  1247. }
  1248. cmDspRC_t _cmDspXfaderReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1249. {
  1250. cmDspRC_t rc = kOkDspRC;
  1251. rc = cmDspApplyAllDefaults(ctx,inst);
  1252. cmDspXfader_t* p = (cmDspXfader_t*)inst;
  1253. // TODO: zeroing of output audio buffers should be built into cmDspApplyAllDefaults().
  1254. unsigned i;
  1255. for(i=0; i<p->chCnt; ++i)
  1256. cmDspZeroAudioBuf(ctx,inst,p->outBaseXfId + i);
  1257. return rc;
  1258. }
  1259. cmDspRC_t _cmDspXfaderExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1260. {
  1261. cmDspRC_t rc = cmOkRC;
  1262. cmDspXfader_t* p = (cmDspXfader_t*)inst;
  1263. unsigned i;
  1264. // update the internal cross fader by providing it with new gate settings and generate new gain values
  1265. cmXfaderExec( p->xfdp, cmDspSamplesPerCycle(ctx), p->chGateV, p->chCnt );
  1266. for(i=0; i<p->chCnt; ++i)
  1267. {
  1268. unsigned n = cmDspAudioBufSmpCount(ctx,inst,p->outBaseXfId+i,0);
  1269. cmSample_t* op = cmDspAudioBuf(ctx,inst,p->outBaseXfId+i,0);
  1270. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,p->inBaseXfId+i,0);
  1271. cmSample_t gain = (cmSample_t)p->xfdp->chArray[i].ep_gain;
  1272. if( op != NULL )
  1273. {
  1274. if( ip == NULL )
  1275. cmVOS_Zero(op,n);
  1276. else
  1277. cmVOS_MultVVS(op,n,ip,gain);
  1278. }
  1279. if( p->xfdp->chArray[i].onFl )
  1280. {
  1281. cmDspSetBool(ctx,inst,p->stateBaseXfId+i,true);
  1282. }
  1283. if( p->xfdp->chArray[i].offFl )
  1284. {
  1285. cmDspSetBool(ctx,inst,p->stateBaseXfId+i,false);
  1286. }
  1287. // send the gain output
  1288. cmDspSetDouble(ctx,inst,p->gainBaseXfId+i,gain);
  1289. }
  1290. if( p->xfdp->onFl )
  1291. cmDspSetSymbol(ctx,inst,kOnXfId,p->onSymId);
  1292. if( p->xfdp->offFl )
  1293. cmDspSetSymbol(ctx,inst,kOffXfId,p->offSymId);
  1294. return rc;
  1295. }
  1296. cmDspRC_t _cmDspXfaderRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1297. {
  1298. cmDspRC_t rc;
  1299. cmDspXfader_t* p = (cmDspXfader_t*)inst;
  1300. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  1301. return rc;
  1302. switch( evt->dstVarId )
  1303. {
  1304. case kFadeTimeMsXfId:
  1305. // if this is an xfade time event then transfer the new xfade time to the xfade proc
  1306. cmXfaderSetXfadeTime(p->xfdp,cmDspDouble(inst,kFadeTimeMsXfId));
  1307. break;
  1308. case kMstrGateXfId:
  1309. {
  1310. bool fl = cmDspBool(inst,kMstrGateXfId);
  1311. unsigned i;
  1312. for(i=0; i<p->chCnt; ++i)
  1313. p->chGateV[i] = fl;
  1314. }
  1315. break;
  1316. case kFadeInTimeMsXfId:
  1317. cmXfaderSetXfadeInTime(p->xfdp,cmDspDouble(inst,kFadeInTimeMsXfId));
  1318. break;
  1319. case kFadeOutTimeMsXfId:
  1320. cmXfaderSetXfadeOutTime(p->xfdp,cmDspDouble(inst,kFadeOutTimeMsXfId));
  1321. break;
  1322. case kResetXfId:
  1323. {
  1324. cmXfaderExec( p->xfdp, cmDspSamplesPerCycle(ctx), p->chGateV, p->chCnt );
  1325. cmXfaderJumpToDestinationGain(p->xfdp);
  1326. // force the chGateV[] to match the xfaders state
  1327. int i;
  1328. for(i=0; i<p->chCnt; ++i)
  1329. {
  1330. bool gateFl = p->xfdp->chArray[i].gateFl;
  1331. p->chGateV[i] = gateFl;
  1332. cmDspSetBool( ctx,inst,p->stateBaseXfId + i, gateFl);
  1333. cmDspSetDouble(ctx,inst,p->gainBaseXfId + i, gateFl ? 1.0 : 0.0 );
  1334. }
  1335. }
  1336. break;
  1337. }
  1338. // record gate changes into p->chGateV[] for later use in _cmDspXfaderExec().
  1339. if( kGateBaseXfId <= evt->dstVarId && evt->dstVarId < kGateBaseXfId + p->chCnt )
  1340. {
  1341. p->chGateV[ evt->dstVarId - kGateBaseXfId ] = cmDspBool( inst, evt->dstVarId );
  1342. }
  1343. return rc;
  1344. }
  1345. cmDspClass_t* cmXfaderClassCons( cmDspCtx_t* ctx )
  1346. {
  1347. cmDspClassSetup(&_cmXfaderDC,ctx,"Xfader",
  1348. NULL,
  1349. _cmDspXfaderAlloc,
  1350. _cmDspXfaderFree,
  1351. _cmDspXfaderReset,
  1352. _cmDspXfaderExec,
  1353. _cmDspXfaderRecv,
  1354. NULL,NULL,
  1355. "Cross fade gain generator.");
  1356. return &_cmXfaderDC;
  1357. }
  1358. //------------------------------------------------------------------------------------------------------------
  1359. //)
  1360. //( { label:cmDspChCfg file_desc:"Configure a 'fluxo' channel." kw:[sunit] }
  1361. enum
  1362. {
  1363. kFnCcId,
  1364. kSelCcId,
  1365. kDoneCcId,
  1366. kGainBaseCcId
  1367. };
  1368. cmDspClass_t _cmChCfgDC;
  1369. typedef struct
  1370. {
  1371. cmDspInst_t inst;
  1372. cmChCfg* ccp;
  1373. unsigned midiBaseCcId;
  1374. unsigned hzBaseCcId;
  1375. unsigned chBaseCcId;
  1376. unsigned nsflBaseCcId;
  1377. unsigned nshzBaseCcId;
  1378. unsigned printSymId;
  1379. unsigned writeSymId;
  1380. unsigned nsCmdSymId;
  1381. unsigned hzCmdSymId;
  1382. unsigned resetSymId;
  1383. } cmDspChCfg_t;
  1384. cmDspInst_t* _cmDspChCfgAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  1385. {
  1386. cmDspVarArg_t args[] =
  1387. {
  1388. { "fn", kFnCcId, 0, 0, kStrzDsvFl| kReqArgDsvFl, "Channel configuration JSON file name."},
  1389. { "sel", kSelCcId, 0, 0, kInDsvFl | kSymDsvFl, "Action selector: print | write | ns | reset"},
  1390. { "done", kDoneCcId,0, 0, kOutDsvFl | kSymDsvFl, "Trigger following action."}
  1391. };
  1392. if( va_cnt < 1 )
  1393. {
  1394. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The channel configuration object must be given a file name argument.");
  1395. return NULL;
  1396. }
  1397. va_list vl1;
  1398. va_copy(vl1,vl);
  1399. const cmChar_t* chCfgFn = va_arg(vl,cmChar_t*);
  1400. cmChCfg* ccp = cmChCfgAlloc( ctx->cmProcCtx, NULL, ctx->cmCtx, chCfgFn );
  1401. if( ccp == NULL || ccp->chCnt==0 )
  1402. {
  1403. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The channel configuration object could not be initialized with the file name '%s'.",cmStringNullGuard(chCfgFn));
  1404. return NULL;
  1405. }
  1406. unsigned chCnt = ccp->chCnt;
  1407. unsigned nsChCnt = ccp->nsChCnt;
  1408. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  1409. unsigned argCnt = fixArgCnt + 5*chCnt + nsChCnt;
  1410. unsigned midiBaseCcId = kGainBaseCcId + chCnt;
  1411. unsigned hzBaseCcId = midiBaseCcId + chCnt;
  1412. unsigned chBaseCcId = hzBaseCcId + chCnt;
  1413. unsigned nsflBaseCcId = chBaseCcId + chCnt;
  1414. unsigned nshzBaseCcId = nsflBaseCcId + chCnt;
  1415. cmDspChCfg_t* p = NULL;
  1416. cmDspVarArg_t a[ argCnt+1 ];
  1417. unsigned i,j;
  1418. // setup the input gate detectors and the output gain args
  1419. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  1420. cmDspArgSetupN(ctx, a, argCnt, kGainBaseCcId, chCnt, "gain", kGainBaseCcId, 0, 0, kSendDfltDsvFl | kInDsvFl | kOutDsvFl | kDoubleDsvFl, "Gain input and output.");
  1421. cmDspArgSetupN(ctx, a, argCnt, midiBaseCcId, chCnt, "midi", midiBaseCcId, 0, 0, kSendDfltDsvFl | kOutDsvFl | kUIntDsvFl, "MIDI pitch output");
  1422. cmDspArgSetupN(ctx, a, argCnt, hzBaseCcId, chCnt, "hz", hzBaseCcId, 0, 0, kSendDfltDsvFl | kOutDsvFl | kDoubleDsvFl, "pitch output in Hz");
  1423. cmDspArgSetupN(ctx, a, argCnt, chBaseCcId, chCnt, "ch", chBaseCcId, 0, 0, kSendDfltDsvFl | kOutDsvFl | kUIntDsvFl , "Audio channel index");
  1424. cmDspArgSetupN(ctx, a, argCnt, nsflBaseCcId, chCnt, "nsfl", nsflBaseCcId, 0, 0, kOutDsvFl | kBoolDsvFl, "noise shaper enables");
  1425. cmDspArgSetupN(ctx, a, argCnt, nshzBaseCcId, nsChCnt, "nshz", nshzBaseCcId, 0, 0, kOutDsvFl | kDoubleDsvFl, "noise-shaper pitch output in Hz");
  1426. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  1427. if((p = cmDspInstAlloc(cmDspChCfg_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl1)) == NULL )
  1428. return NULL;
  1429. p->ccp = ccp;
  1430. p->midiBaseCcId = midiBaseCcId;
  1431. p->hzBaseCcId = hzBaseCcId;
  1432. p->chBaseCcId = chBaseCcId;
  1433. p->nsflBaseCcId = nsflBaseCcId;
  1434. p->nshzBaseCcId = nshzBaseCcId;
  1435. p->writeSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"write");
  1436. p->printSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"print");
  1437. p->nsCmdSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"ns");
  1438. p->hzCmdSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"hz");
  1439. p->resetSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"reset");
  1440. for(i=0,j=0; i<chCnt; ++i)
  1441. {
  1442. double hz = cmMidiToHz(ccp->chArray[i].midi);
  1443. cmDspSetDefaultDouble(ctx, &p->inst, kGainBaseCcId + i, 0.0, ccp->chArray[i].gain);
  1444. cmDspSetDefaultUInt( ctx, &p->inst, p->midiBaseCcId + i, 0, ccp->chArray[i].midi );
  1445. cmDspSetDefaultDouble(ctx, &p->inst, p->hzBaseCcId + i, 0.0, hz );
  1446. cmDspSetDefaultUInt( ctx, &p->inst, p->chBaseCcId + i, 0, ccp->chArray[i].ch );
  1447. cmDspSetDefaultBool( ctx, &p->inst, p->nsflBaseCcId+i, false, false );
  1448. if( ccp->chArray[i].nsFl )
  1449. {
  1450. cmDspSetDefaultDouble(ctx,&p->inst, p->nshzBaseCcId+j, 0.0, hz);
  1451. ++j;
  1452. }
  1453. }
  1454. cmDspSetDefaultSymbol(ctx, &p->inst, kDoneCcId, cmInvalidId );
  1455. cmDspSetDefaultSymbol(ctx, &p->inst, kSelCcId, cmInvalidId );
  1456. return &p->inst;
  1457. }
  1458. cmDspRC_t _cmDspChCfgFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1459. {
  1460. cmDspChCfg_t* p = (cmDspChCfg_t*)inst;
  1461. cmChCfgFree(&p->ccp);
  1462. return kOkDspRC;
  1463. }
  1464. cmDspRC_t _cmDspChCfgReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1465. {
  1466. cmDspRC_t rc = kOkDspRC;
  1467. rc = cmDspApplyAllDefaults(ctx,inst);
  1468. return rc;
  1469. }
  1470. cmDspRC_t _cmDspChCfgRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1471. {
  1472. cmDspRC_t rc;
  1473. cmDspChCfg_t* p = (cmDspChCfg_t*)inst;
  1474. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  1475. {
  1476. if( evt->dstVarId == kSelCcId )
  1477. {
  1478. unsigned selId = cmDspSymbol(inst,kSelCcId);
  1479. if( selId == p->resetSymId )
  1480. {
  1481. _cmDspChCfgReset(ctx,inst,evt);
  1482. }
  1483. else
  1484. if( selId == p->hzCmdSymId )
  1485. {
  1486. unsigned i;
  1487. // snd the hz
  1488. for(i=0; i<p->ccp->chCnt; ++i)
  1489. cmDspSetDouble(ctx,inst,p->hzBaseCcId+i,cmDspDouble(inst,p->hzBaseCcId+i));
  1490. }
  1491. else
  1492. if( selId == p->nsCmdSymId )
  1493. {
  1494. cmRptPrintf(ctx->rpt,"ChCfg:NS\n");
  1495. unsigned i;
  1496. // send the ns flags
  1497. for(i=0; i<p->ccp->chCnt; ++i)
  1498. cmDspSetBool(ctx,inst,p->nsflBaseCcId+i,p->ccp->chArray[i].nsFl);
  1499. // snd the ns hz
  1500. for(i=0; i<p->ccp->nsChCnt; ++i)
  1501. cmDspSetDouble(ctx,inst,p->nshzBaseCcId+i,cmDspDouble(inst,p->nshzBaseCcId+i));
  1502. cmDspSetSymbol(ctx,inst,kDoneCcId,p->nsCmdSymId);
  1503. }
  1504. else
  1505. if( selId == p->printSymId )
  1506. {
  1507. cmRptPrintf(&ctx->cmCtx->rpt,"Channel Cfg Report\n");
  1508. cmChCfgPrint(p->ccp, ctx->rpt );
  1509. }
  1510. else
  1511. {
  1512. if( selId == p->writeSymId )
  1513. {
  1514. unsigned i;
  1515. cmRptPrintf(&ctx->cmCtx->rpt,"writing\n");
  1516. // copy the gain values into the internal chCfg object ...
  1517. for(i=0; i<p->ccp->chCnt; ++i)
  1518. p->ccp->chArray[i].gain = cmDspDouble(inst,kGainBaseCcId+i);
  1519. // ... and write the object
  1520. cmChCfgWrite(p->ccp);
  1521. }
  1522. }
  1523. }
  1524. }
  1525. return rc;
  1526. }
  1527. cmDspClass_t* cmChCfgClassCons( cmDspCtx_t* ctx )
  1528. {
  1529. cmDspClassSetup(&_cmChCfgDC,ctx,"ChCfg",
  1530. NULL,
  1531. _cmDspChCfgAlloc,
  1532. _cmDspChCfgFree,
  1533. _cmDspChCfgReset,
  1534. NULL,
  1535. _cmDspChCfgRecv,
  1536. NULL,NULL,
  1537. "PP Channel Configuration Object.");
  1538. return &_cmChCfgDC;
  1539. }
  1540. //------------------------------------------------------------------------------------------------------------
  1541. //)
  1542. //( { label:cmDspChordDetect file_desc:"Detect a predefined chord based on signal gates." kw:[sunit] }
  1543. enum
  1544. {
  1545. kRsrcCdId,
  1546. kMaxTimeSpanCdId,
  1547. kMinNoteCntCdId,
  1548. kDetectCdId,
  1549. kCountCdId,
  1550. kGateBaseCdId
  1551. };
  1552. cmDspClass_t _cmChordDetectDC;
  1553. typedef struct
  1554. {
  1555. cmDspInst_t inst;
  1556. cmChordDetect* cdp;
  1557. unsigned rmsBaseCdId;
  1558. unsigned chCnt;
  1559. bool* chGateV; // chGateV[ chCnt ]
  1560. cmReal_t* chRmsV; // chRmsV[ chCnt ]
  1561. unsigned* chEnaV; // chEnaV[ chCnt ]
  1562. unsigned count;
  1563. } cmDspChordDetect_t;
  1564. cmDspInst_t* _cmDspChordDetectAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  1565. {
  1566. cmDspVarArg_t args[] =
  1567. {
  1568. { "rsrc", kRsrcCdId, 0, 0, kStrzDsvFl | kReqArgDsvFl, "Channel enable flag array."},
  1569. { "span", kMaxTimeSpanCdId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Max. onset time span."},
  1570. { "notes", kMinNoteCntCdId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Min. note count per chord."},
  1571. { "detect", kDetectCdId, 0, 0, kOutDsvFl | kBoolDsvFl, "Chord detect flag."},
  1572. { "count", kCountCdId, 0, 0, kOutDsvFl | kUIntDsvFl, "Count of chords detected since last reset."}
  1573. };
  1574. if( va_cnt < 1 )
  1575. {
  1576. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The chord detector must be given a channel enable flags array resource argument .");
  1577. return NULL;
  1578. }
  1579. va_list vl1;
  1580. va_copy(vl1,vl);
  1581. const cmChar_t* rsrc = va_arg(vl,const cmChar_t*);
  1582. unsigned* enaV = NULL;
  1583. unsigned chCnt = 0;
  1584. if( cmDspRsrcUIntArray( ctx->dspH, &chCnt, &enaV, rsrc, NULL ) != kOkDspRC )
  1585. {
  1586. va_end(vl1);
  1587. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The chord detector channel index resource '%s' could not be read.",cmStringNullGuard(rsrc));
  1588. return NULL;
  1589. }
  1590. //cmRptPrintf(ctx->rpt,"cd %s chs:%i\n",rsrc,chCnt);
  1591. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  1592. unsigned argCnt = fixArgCnt + 2*chCnt;
  1593. unsigned rmsBaseCdId = kGateBaseCdId + chCnt;
  1594. cmDspVarArg_t a[ argCnt+1 ];
  1595. unsigned i;
  1596. cmDspChordDetect_t* p;
  1597. // setup the input gate detectors and the output gain args
  1598. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  1599. cmDspArgSetupN(ctx, a, argCnt, kGateBaseCdId, chCnt, "gate", kGateBaseCdId, 0, 0, kInDsvFl | kOutDsvFl | kBoolDsvFl, "Channel gate input and output.");
  1600. cmDspArgSetupN(ctx, a, argCnt, rmsBaseCdId, chCnt, "rms", rmsBaseCdId, 0, 0, kInDsvFl | kOutDsvFl | kDoubleDsvFl, "Channel RMS input and output");
  1601. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  1602. if((p = cmDspInstAlloc(cmDspChordDetect_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl1)) == NULL )
  1603. return NULL;
  1604. double dfltMaxTimeSpanMs = 50.0;
  1605. unsigned dfltMinNoteCnt = 2;
  1606. cmDspSetDefaultDouble( ctx, &p->inst, kMaxTimeSpanCdId, 0.0, dfltMaxTimeSpanMs );
  1607. cmDspSetDefaultUInt( ctx, &p->inst, kMinNoteCntCdId, 0, dfltMinNoteCnt );
  1608. cmDspSetDefaultBool( ctx, &p->inst, kDetectCdId, false, false );
  1609. cmDspSetDefaultUInt( ctx, &p->inst, kCountCdId, 0, 0 );
  1610. for(i=0; i<chCnt; ++i)
  1611. {
  1612. cmDspSetDefaultBool( ctx, &p->inst, kGateBaseCdId + i, false, false );
  1613. cmDspSetDefaultDouble(ctx, &p->inst, rmsBaseCdId + i, 0.0, 0.0 );
  1614. }
  1615. p->cdp = cmChordDetectAlloc( ctx->cmProcCtx, NULL, cmDspSampleRate(ctx), chCnt, cmDspDouble(&p->inst,kMaxTimeSpanCdId), cmDspUInt(&p->inst,kMinNoteCntCdId) );
  1616. p->rmsBaseCdId = rmsBaseCdId;
  1617. p->chCnt = chCnt;
  1618. p->chGateV = cmMemAllocZ(bool, chCnt);
  1619. p->chRmsV = cmMemAllocZ(cmReal_t, chCnt);
  1620. p->chEnaV = enaV;
  1621. va_end(vl1);
  1622. return &p->inst;
  1623. }
  1624. cmDspRC_t _cmDspChordDetectFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1625. {
  1626. cmDspChordDetect_t* p = (cmDspChordDetect_t*)inst;
  1627. cmChordDetectFree(&p->cdp);
  1628. cmMemFree(p->chGateV);
  1629. cmMemFree(p->chRmsV);
  1630. return kOkDspRC;
  1631. }
  1632. cmDspRC_t _cmDspChordDetectReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1633. {
  1634. cmDspRC_t rc = kOkDspRC;
  1635. rc = cmDspApplyAllDefaults(ctx,inst);
  1636. return rc;
  1637. }
  1638. cmDspRC_t _cmDspChordDetectExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1639. {
  1640. cmDspRC_t rc = kOkDspRC;
  1641. cmDspChordDetect_t* p = (cmDspChordDetect_t*)inst;
  1642. cmChordDetectExec(p->cdp, cmDspSamplesPerCycle(ctx), p->chGateV, p->chRmsV, p->chCnt );
  1643. if( p->cdp->detectFl )
  1644. {
  1645. unsigned i;
  1646. for(i=0; i<p->chCnt; ++i)
  1647. {
  1648. bool fl = p->cdp->chArray[i].chordFl;
  1649. cmDspSetBool( ctx, inst, kGateBaseCdId + i, fl );
  1650. cmDspSetDouble( ctx, inst, p->rmsBaseCdId + i, fl ? p->cdp->chArray[i].candRMS : 0 );
  1651. }
  1652. cmDspSetBool(ctx, inst, kDetectCdId, true);
  1653. cmDspSetUInt(ctx, inst, kCountCdId, cmDspUInt(inst,kCountCdId) + 1 );
  1654. }
  1655. cmVOB_Zero(p->chGateV,p->chCnt);
  1656. cmVOR_Zero(p->chRmsV,p->chCnt);
  1657. return rc;
  1658. }
  1659. cmDspRC_t _cmDspChordDetectRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1660. {
  1661. cmDspRC_t rc = kOkDspRC;
  1662. cmDspChordDetect_t* p = (cmDspChordDetect_t*)inst;
  1663. if( kGateBaseCdId <= evt->dstVarId && evt->dstVarId < kGateBaseCdId + p->chCnt )
  1664. {
  1665. unsigned idx = evt->dstVarId - kGateBaseCdId;
  1666. if( p->chEnaV[idx] )
  1667. p->chGateV[ idx ] = cmDsvGetBool(evt->valuePtr);
  1668. //cmRptPrintf(ctx->rpt,"cd gate:%i e:%i v:%i\n",idx,p->chEnaV[idx],p->chGateV[idx]);
  1669. }
  1670. else
  1671. if( p->rmsBaseCdId <= evt->dstVarId && evt->dstVarId < p->rmsBaseCdId + p->chCnt )
  1672. {
  1673. unsigned idx = evt->dstVarId - p->rmsBaseCdId;
  1674. if( p->chEnaV[idx] )
  1675. p->chRmsV[ idx ] = cmDsvGetReal( evt->valuePtr );
  1676. }
  1677. else
  1678. {
  1679. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  1680. {
  1681. switch( evt->dstVarId )
  1682. {
  1683. case kMaxTimeSpanCdId:
  1684. cmChordDetectSetSpanMs(p->cdp,cmDspDouble(inst,kMaxTimeSpanCdId));
  1685. break;
  1686. case kMinNoteCntCdId:
  1687. p->cdp->minNotesPerChord = cmDspUInt(inst,kMinNoteCntCdId);
  1688. break;
  1689. }
  1690. }
  1691. }
  1692. return rc;
  1693. }
  1694. cmDspClass_t* cmChordDetectClassCons( cmDspCtx_t* ctx )
  1695. {
  1696. cmDspClassSetup(&_cmChordDetectDC,ctx,"ChordDetect",
  1697. NULL,
  1698. _cmDspChordDetectAlloc,
  1699. _cmDspChordDetectFree,
  1700. _cmDspChordDetectReset,
  1701. _cmDspChordDetectExec,
  1702. _cmDspChordDetectRecv,
  1703. NULL,NULL,
  1704. "Chord detector.");
  1705. return &_cmChordDetectDC;
  1706. }
  1707. //------------------------------------------------------------------------------------------------------------
  1708. //)
  1709. //( { label:cmDspFader file_desc:"Single channel gate controlled fader." kw:[sunit] }
  1710. enum
  1711. {
  1712. kTimeFaId,
  1713. kGateFaId,
  1714. kInFaId,
  1715. kGainFaId,
  1716. kOutFaId
  1717. };
  1718. cmDspClass_t _cmFaderDC;
  1719. typedef struct
  1720. {
  1721. cmDspInst_t inst;
  1722. cmFader* fdp;
  1723. } cmDspFader_t;
  1724. cmDspInst_t* _cmDspFaderAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  1725. {
  1726. cmDspVarArg_t args[] =
  1727. {
  1728. { "time", kTimeFaId, 0, 0, kDoubleDsvFl | kOptArgDsvFl, "Fade time in milliseconds."},
  1729. { "gate", kGateFaId, 0, 0, kInDsvFl | kBoolDsvFl, "Gate control signal."},
  1730. { "in", kInFaId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input."},
  1731. { "gain", kGainFaId, 0, 0, kOutDsvFl | kDoubleDsvFl, "gain output."},
  1732. { "out", kOutFaId, 0, 0, kOutDsvFl | kAudioBufDsvFl, "Audio out."},
  1733. { NULL, 0, 0, 0, 0, NULL }
  1734. };
  1735. cmDspFader_t* p;
  1736. if((p = cmDspInstAlloc(cmDspFader_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl)) == NULL )
  1737. return NULL;
  1738. double dfltFadeTimeMs = 100.0;
  1739. cmDspSetDefaultDouble( ctx, &p->inst, kTimeFaId, 0.0, dfltFadeTimeMs );
  1740. p->fdp = cmFaderAlloc(ctx->cmProcCtx, NULL, cmDspSampleRate(ctx), dfltFadeTimeMs );
  1741. return &p->inst;
  1742. }
  1743. cmDspRC_t _cmDspFaderFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1744. {
  1745. cmDspFader_t* p = (cmDspFader_t*)inst;
  1746. cmFaderFree(&p->fdp);
  1747. return kOkDspRC;
  1748. }
  1749. cmDspRC_t _cmDspFaderReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1750. {
  1751. cmDspRC_t rc = kOkDspRC;
  1752. cmDspFader_t* p = (cmDspFader_t*)inst;
  1753. rc = cmDspApplyAllDefaults(ctx,inst);
  1754. cmDspZeroAudioBuf(ctx,inst,kOutFaId);
  1755. cmFaderSetFadeTime(p->fdp,cmDspDouble(inst,kTimeFaId));
  1756. return rc;
  1757. }
  1758. cmDspRC_t _cmDspFaderExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1759. {
  1760. cmDspRC_t rc = kOkDspRC;
  1761. cmDspFader_t* p = (cmDspFader_t*)inst;
  1762. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutFaId,0);
  1763. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutFaId,0);
  1764. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInFaId,0);
  1765. cmFaderExec(p->fdp,n,cmDspBool(inst,kGateFaId),false,ip,op);
  1766. cmDspSetDouble(ctx,inst,kGainFaId,p->fdp->gain);
  1767. return rc;
  1768. }
  1769. cmDspRC_t _cmDspFaderRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1770. {
  1771. cmDspRC_t rc = kOkDspRC;
  1772. cmDspFader_t* p = (cmDspFader_t*)inst;
  1773. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  1774. {
  1775. if( evt->dstVarId == kTimeFaId )
  1776. cmFaderSetFadeTime(p->fdp,cmDspDouble(inst,kTimeFaId));
  1777. }
  1778. return rc;
  1779. }
  1780. cmDspClass_t* cmFaderClassCons( cmDspCtx_t* ctx )
  1781. {
  1782. cmDspClassSetup(&_cmFaderDC,ctx,"Fader",
  1783. NULL,
  1784. _cmDspFaderAlloc,
  1785. _cmDspFaderFree,
  1786. _cmDspFaderReset,
  1787. _cmDspFaderExec,
  1788. _cmDspFaderRecv,
  1789. NULL,NULL,
  1790. "Audio fade in/out controller.");
  1791. return &_cmFaderDC;
  1792. }
  1793. //------------------------------------------------------------------------------------------------------------
  1794. //)
  1795. //( { label:cmDspNoteSelect file_desc:"'fluxo' gate based logic controller." kw:[sunit fluxo] }
  1796. enum
  1797. {
  1798. kChCntNsId,
  1799. kTrigNsId,
  1800. kDoneNsId,
  1801. kGateBaseNsId
  1802. };
  1803. enum
  1804. {
  1805. kGroupNonNsId,
  1806. kGroup0NsId,
  1807. kGroup1NsId
  1808. };
  1809. cmDspClass_t _cmNoteSelectDC;
  1810. typedef struct
  1811. {
  1812. cmDspInst_t inst;
  1813. unsigned chCnt;
  1814. unsigned rmsBaseNsId;
  1815. unsigned gate0BaseNsId;
  1816. unsigned gate1BaseNsId;
  1817. unsigned gate2BaseNsId;
  1818. unsigned gate3BaseNsId;
  1819. unsigned gate4BaseNsId;
  1820. bool* chGateV; // chGateV[chCnt]
  1821. cmReal_t* chRmsV; // chRmsV[ chCnt ];
  1822. unsigned* chGroupV; // chGroupV[ chCnt ] (0=non-chord 1=low/high 2=middle)
  1823. unsigned count;
  1824. unsigned doneSymId;
  1825. } cmDspNoteSelect_t;
  1826. cmDspInst_t* _cmDspNoteSelectAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  1827. {
  1828. cmDspVarArg_t args[] =
  1829. {
  1830. { "ch_cnt", kChCntNsId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Channel count."},
  1831. { "trig", kTrigNsId, 0, 0, kInDsvFl | kBoolDsvFl, "Trigger note selection."},
  1832. { "done", kDoneNsId, 0, 0, kOutDsvFl | kSymDsvFl, "Sends 'done' after new set of outputs have been sent."},
  1833. };
  1834. if( va_cnt < 1 )
  1835. {
  1836. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The note selector must be given a channel count argument .");
  1837. return NULL;
  1838. }
  1839. va_list vl1;
  1840. unsigned CD0chanN = 0;
  1841. unsigned CD1chanN = 0;
  1842. unsigned* CD0chan = NULL;
  1843. unsigned* CD1chan = NULL;
  1844. const cmChar_t* CD0rsrc = "CD0chan";
  1845. const cmChar_t* CD1rsrc = "CD1chan";
  1846. if( cmDspRsrcUIntArray( ctx->dspH, &CD0chanN, &CD0chan, CD0rsrc, NULL ) != kOkDspRC )
  1847. {
  1848. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The chord detector channel index resource '%s' could not be read.",cmStringNullGuard(CD0rsrc));
  1849. return NULL;
  1850. }
  1851. if( cmDspRsrcUIntArray( ctx->dspH, &CD1chanN, &CD1chan, CD1rsrc, NULL ) != kOkDspRC )
  1852. {
  1853. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The chord detector channel index resource '%s' could not be read.",cmStringNullGuard(CD1rsrc));
  1854. return NULL;
  1855. }
  1856. va_copy(vl1,vl);
  1857. unsigned chCnt = va_arg(vl,unsigned);
  1858. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  1859. unsigned argCnt = fixArgCnt + 7*chCnt;
  1860. unsigned rmsBaseNsId = kGateBaseNsId + 1 * chCnt;
  1861. unsigned gate0BaseNsId = kGateBaseNsId + 2 * chCnt;
  1862. unsigned gate1BaseNsId = kGateBaseNsId + 3 * chCnt;
  1863. unsigned gate2BaseNsId = kGateBaseNsId + 4 * chCnt;
  1864. unsigned gate3BaseNsId = kGateBaseNsId + 5 * chCnt;
  1865. unsigned gate4BaseNsId = kGateBaseNsId + 6 * chCnt;
  1866. cmDspVarArg_t a[ argCnt+1 ];
  1867. unsigned i;
  1868. cmDspNoteSelect_t* p;
  1869. // setup the input gate detectors and the output gain args
  1870. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  1871. cmDspArgSetupN(ctx, a, argCnt, kGateBaseNsId, chCnt, "gate", kGateBaseNsId, 0, 0, kInDsvFl | kBoolDsvFl, "Channel gate input.");
  1872. cmDspArgSetupN(ctx, a, argCnt, rmsBaseNsId, chCnt, "rms", rmsBaseNsId, 0, 0, kInDsvFl | kDoubleDsvFl, "Channel RMS input");
  1873. cmDspArgSetupN(ctx, a, argCnt, gate0BaseNsId, chCnt, "gate-0", gate0BaseNsId, 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 0 output.");
  1874. cmDspArgSetupN(ctx, a, argCnt, gate1BaseNsId, chCnt, "gate-1", gate1BaseNsId, 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 1 output.");
  1875. cmDspArgSetupN(ctx, a, argCnt, gate2BaseNsId, chCnt, "gate-2", gate2BaseNsId, 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 2 output.");
  1876. cmDspArgSetupN(ctx, a, argCnt, gate3BaseNsId, chCnt, "gate-3", gate3BaseNsId, 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 3 output.");
  1877. cmDspArgSetupN(ctx, a, argCnt, gate4BaseNsId, chCnt, "gate-4", gate4BaseNsId, 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 4 output.");
  1878. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  1879. if((p = cmDspInstAlloc(cmDspNoteSelect_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl1)) == NULL )
  1880. return NULL;
  1881. cmDspSetDefaultBool( ctx, &p->inst, kTrigNsId, false, false );
  1882. cmDspSetDefaultSymbol( ctx, &p->inst, kDoneNsId, cmInvalidId );
  1883. p->rmsBaseNsId = rmsBaseNsId;
  1884. p->gate0BaseNsId = gate0BaseNsId;
  1885. p->gate1BaseNsId = gate1BaseNsId;
  1886. p->gate2BaseNsId = gate2BaseNsId;
  1887. p->gate3BaseNsId = gate3BaseNsId;
  1888. p->gate4BaseNsId = gate4BaseNsId;
  1889. p->chCnt = chCnt;
  1890. p->chGateV = cmMemAllocZ(bool,chCnt);
  1891. p->chRmsV = cmMemAllocZ(cmReal_t,chCnt);
  1892. p->chGroupV = cmMemAllocZ(unsigned,chCnt);
  1893. p->doneSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"done");
  1894. for(i=0; i<CD0chanN; ++i)
  1895. {
  1896. if( CD0chan[i] >= chCnt )
  1897. cmDspInstErr(ctx,&p->inst,kInvalidArgDspRC,"The chord detector resource array '%s' value %i is out of range %i.",cmStringNullGuard(CD0rsrc),CD0chan[i],chCnt);
  1898. else
  1899. p->chGroupV[ CD0chan[i] ] = kGroup0NsId;
  1900. }
  1901. for(i=0; i<CD1chanN; ++i)
  1902. {
  1903. if( CD1chan[i] >= chCnt )
  1904. cmDspInstErr(ctx,&p->inst,kInvalidArgDspRC,"The chord detector resource array '%s' value %i is out of range %i.",cmStringNullGuard(CD1rsrc),CD1chan[i],chCnt);
  1905. else
  1906. p->chGroupV[ CD1chan[i] ] = kGroup1NsId;
  1907. }
  1908. for(i=0; i<chCnt; ++i)
  1909. {
  1910. cmDspSetDefaultDouble(ctx, &p->inst, rmsBaseNsId+i, 0.0, 0.0 );
  1911. cmDspSetDefaultBool( ctx, &p->inst, gate0BaseNsId+i, false, false );
  1912. cmDspSetDefaultBool( ctx, &p->inst, gate1BaseNsId+i, false, false );
  1913. cmDspSetDefaultBool( ctx, &p->inst, gate2BaseNsId+i, false, false );
  1914. cmDspSetDefaultBool( ctx, &p->inst, gate3BaseNsId+i, false, false );
  1915. // the non-chord channel selections should always be on
  1916. cmDspSetDefaultBool( ctx, &p->inst, gate4BaseNsId+i, false, p->chGroupV[i] == kGroupNonNsId );
  1917. }
  1918. va_end(vl1);
  1919. return &p->inst;
  1920. }
  1921. cmDspRC_t _cmDspNoteSelectFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1922. {
  1923. cmDspNoteSelect_t* p = (cmDspNoteSelect_t*)inst;
  1924. cmMemFree(p->chGateV);
  1925. cmMemFree(p->chRmsV);
  1926. cmMemFree(p->chGroupV);
  1927. return kOkDspRC;
  1928. }
  1929. cmDspRC_t _cmDspNoteSelectReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1930. {
  1931. cmDspRC_t rc = kOkDspRC;
  1932. cmDspNoteSelect_t* p = (cmDspNoteSelect_t*)inst;
  1933. rc = cmDspApplyAllDefaults(ctx,inst);
  1934. cmVOR_Zero(p->chRmsV,p->chCnt);
  1935. return rc;
  1936. }
  1937. cmDspRC_t _cmDspNoteSelectRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  1938. {
  1939. cmDspRC_t rc = kOkDspRC;
  1940. cmDspNoteSelect_t* p = (cmDspNoteSelect_t*)inst;
  1941. // store incoming gate values
  1942. if( kGateBaseNsId <= evt->dstVarId && evt->dstVarId < kGateBaseNsId + p->chCnt )
  1943. p->chGateV[ evt->dstVarId - kGateBaseNsId ] = cmDsvGetBool(evt->valuePtr);
  1944. else
  1945. // store incoming RMS values
  1946. if( p->rmsBaseNsId <= evt->dstVarId && evt->dstVarId < p->rmsBaseNsId + p->chCnt )
  1947. p->chRmsV[ evt->dstVarId - p->rmsBaseNsId ] = cmDsvGetReal( evt->valuePtr );
  1948. else
  1949. {
  1950. // if a chord detection was triggered
  1951. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC && evt->dstVarId == kTrigNsId )
  1952. {
  1953. unsigned i;
  1954. cmReal_t maxRms = 0;
  1955. unsigned maxIdx = cmInvalidIdx;
  1956. for(i=1; i<p->chCnt; ++i)
  1957. {
  1958. // if this channel had an onset and is a possible chord note and is the max RMS chord note
  1959. if( p->chGroupV[i] != kGroupNonNsId && p->chGateV[i] && (maxIdx==cmInvalidIdx || p->chRmsV[i] > maxRms) )
  1960. {
  1961. maxRms = p->chRmsV[i];
  1962. maxIdx = i;
  1963. }
  1964. }
  1965. for(i=0; i<p->chCnt; ++i)
  1966. {
  1967. bool fl = p->chGroupV[i] != kGroupNonNsId;
  1968. bool chosenFl = fl && i==maxIdx;
  1969. bool otherFl = fl && i!=maxIdx && p->chGateV[i];
  1970. bool cd0Fl = p->chGroupV[i]==kGroup0NsId && (!otherFl) && (!chosenFl);
  1971. bool cd1Fl = p->chGroupV[i]==kGroup1NsId && (!otherFl) && (!chosenFl);
  1972. // gate set 0: set output gate for max chord note
  1973. cmDspSetBool(ctx,inst,p->gate0BaseNsId+i, chosenFl );
  1974. // gate set 1: set output gate for non-max chord notes
  1975. cmDspSetBool(ctx,inst,p->gate1BaseNsId+i, otherFl );
  1976. // gate set 2: set output gate for non-chord notes
  1977. cmDspSetBool(ctx,inst,p->gate2BaseNsId+i, cd0Fl );
  1978. // gate set 3: set output gate for non-chord notes
  1979. cmDspSetBool(ctx,inst,p->gate3BaseNsId+i, cd1Fl);
  1980. // gate set 4: set output gate for non-chord notes
  1981. cmDspSetBool(ctx,inst,p->gate4BaseNsId+i, !fl );
  1982. }
  1983. // send the 'done' symbol to notify the gate receivers that the
  1984. // new set of gates is complete
  1985. cmDspSetSymbol(ctx,inst,kDoneNsId, p->doneSymId);
  1986. // zero the RMS vector
  1987. cmVOR_Zero(p->chRmsV,p->chCnt);
  1988. }
  1989. }
  1990. return rc;
  1991. }
  1992. cmDspClass_t* cmNoteSelectClassCons( cmDspCtx_t* ctx )
  1993. {
  1994. cmDspClassSetup(&_cmNoteSelectDC,ctx,"NoteSelect",
  1995. NULL,
  1996. _cmDspNoteSelectAlloc,
  1997. _cmDspNoteSelectFree,
  1998. _cmDspNoteSelectReset,
  1999. NULL,
  2000. _cmDspNoteSelectRecv,
  2001. NULL,NULL,
  2002. "Chord detector.");
  2003. return &_cmNoteSelectDC;
  2004. }
  2005. //------------------------------------------------------------------------------------------------------------
  2006. //)
  2007. //( { label:cmDspNetNoteSelect file_desc:"'fluxo' transmit gate information over the UDP network." kw:[sunit fluxo] }
  2008. enum
  2009. {
  2010. kTrigNnId,
  2011. kDoneNnId,
  2012. kGateBaseNnId
  2013. };
  2014. cmDspClass_t _cmNetNoteSelectDC;
  2015. #define _cmNetNoteSelPortCnt (10)
  2016. typedef struct
  2017. {
  2018. cmDspInst_t inst;
  2019. unsigned chCnt;
  2020. unsigned rmsBaseNnId;
  2021. unsigned gateBaseNNId[ _cmNetNoteSelPortCnt ];
  2022. bool* chGateV; // chGateV[chCnt]
  2023. cmReal_t* chRmsV; // chRmsV[ chCnt ];
  2024. unsigned* portChCntV; // portChCntV[ 10 ]
  2025. unsigned* portBaseIdV; // portBaseIdV[ 10 ]
  2026. unsigned* chPortV; // chPortV[ chCnt ]
  2027. unsigned* chPortIdxV; // chPortIdxV[ chCnt ]
  2028. unsigned* ncPortV; // ncPortV[ chCnt ]
  2029. unsigned* ncPortIdxV; // ncPortIdxV[ chCnt ]
  2030. unsigned count;
  2031. unsigned doneSymId;
  2032. } cmDspNetNoteSelect_t;
  2033. cmDspInst_t* _cmDspNetNoteSelectAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2034. {
  2035. unsigned chCnt = 0;
  2036. const cmChar_t* label = NULL;
  2037. const cmChar_t* chPortRsrc = "nsChSelChV";
  2038. unsigned* chPortV = NULL;
  2039. const cmChar_t* chPortIdxRsrc = "nsChSelChIdxV";
  2040. unsigned* chPortIdxV = NULL;
  2041. const cmChar_t* ncPortRsrc = "nsNcSelChV";
  2042. unsigned* ncPortV = NULL;
  2043. const cmChar_t* ncPortIdxRsrc = "nsNcSelChIdxV";
  2044. unsigned* ncPortIdxV = NULL;
  2045. unsigned i,j,n;
  2046. cmDspVarArg_t args[] =
  2047. {
  2048. { "trig", kTrigNnId, 0, 0, kInDsvFl | kBoolDsvFl, "Trigger note selection."},
  2049. { "done", kDoneNnId, 0, 0, kOutDsvFl | kSymDsvFl, "Sends 'done' after new set of outputs have been sent."},
  2050. };
  2051. if( cmDspRsrcUIntArray( ctx->dspH, &chCnt, &chPortV, label = chPortRsrc, NULL ) != kOkDspRC )
  2052. {
  2053. cmDspClassErr(ctx,classPtr,kRsrcNotFoundDspRC,"The resource '%s' could not be read.",label);
  2054. return NULL;
  2055. }
  2056. if( cmDspRsrcUIntArray( ctx->dspH, &n, &chPortIdxV, label = chPortIdxRsrc, NULL ) != kOkDspRC )
  2057. {
  2058. cmDspClassErr(ctx,classPtr,kRsrcNotFoundDspRC,"The resource '%s' could not be read.",label);
  2059. return NULL;
  2060. }
  2061. assert(n == chCnt );
  2062. if( cmDspRsrcUIntArray( ctx->dspH, &n, &ncPortV, label = ncPortRsrc, NULL ) != kOkDspRC )
  2063. {
  2064. cmDspClassErr(ctx,classPtr,kRsrcNotFoundDspRC,"The resource '%s' could not be read.",label);
  2065. return NULL;
  2066. }
  2067. assert(n == chCnt );
  2068. if( cmDspRsrcUIntArray( ctx->dspH, &n, &ncPortIdxV, label = ncPortIdxRsrc, NULL ) != kOkDspRC )
  2069. {
  2070. cmDspClassErr(ctx,classPtr,kRsrcNotFoundDspRC,"The resource '%s' could not be read.",label);
  2071. return NULL;
  2072. }
  2073. assert(n == chCnt );
  2074. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  2075. unsigned rmsBaseNnId = kGateBaseNnId + chCnt;
  2076. // get the count of ch's on each port
  2077. unsigned* portChCntV = cmLhAllocZ( ctx->lhH, unsigned, _cmNetNoteSelPortCnt );
  2078. unsigned* portBaseIdV = cmLhAllocZ( ctx->lhH, unsigned, _cmNetNoteSelPortCnt );
  2079. for(i=0; i<_cmNetNoteSelPortCnt; ++i)
  2080. {
  2081. // get the count of ch's in the ith gate output port
  2082. portChCntV[i] = cmVOU_Count( chPortV, chCnt, i ) + cmVOU_Count( ncPortV, chCnt, i );
  2083. // ports 1 and 6 are duplicates of ports 0 and 5
  2084. if( i == 1 || i == 6 )
  2085. portChCntV[i] = portChCntV[i-1];
  2086. // set the base port id for this port
  2087. if( i > 0 )
  2088. portBaseIdV[i] = portBaseIdV[i-1] + portChCntV[i-1];
  2089. else
  2090. portBaseIdV[ i ] = rmsBaseNnId + chCnt;
  2091. }
  2092. unsigned argCnt = fixArgCnt + (2*chCnt) + cmVOU_Sum(portChCntV,_cmNetNoteSelPortCnt );
  2093. cmDspVarArg_t a[ argCnt+1 ];
  2094. cmDspNetNoteSelect_t* p;
  2095. // setup the input gate detectors and the output gain args
  2096. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  2097. cmDspArgSetupN(ctx, a, argCnt, kGateBaseNnId, chCnt, "gate", kGateBaseNnId, 0, 0, kInDsvFl | kBoolDsvFl, "Channel gate input.");
  2098. cmDspArgSetupN(ctx, a, argCnt, rmsBaseNnId, chCnt, "rms", rmsBaseNnId, 0, 0, kInDsvFl | kDoubleDsvFl, "Channel RMS input");
  2099. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[0], portChCntV[0], "gate-0", portBaseIdV[0], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 0 output.");
  2100. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[1], portChCntV[1], "gate-1", portBaseIdV[1], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 1 output.");
  2101. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[2], portChCntV[2], "gate-2", portBaseIdV[2], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 2 output.");
  2102. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[3], portChCntV[3], "gate-3", portBaseIdV[3], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 3 output.");
  2103. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[4], portChCntV[4], "gate-4", portBaseIdV[4], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 4 output.");
  2104. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[5], portChCntV[5], "gate-5", portBaseIdV[5], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 5 output.");
  2105. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[6], portChCntV[6], "gate-6", portBaseIdV[6], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 6 output.");
  2106. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[7], portChCntV[7], "gate-7", portBaseIdV[7], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 7 output.");
  2107. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[8], portChCntV[8], "gate-8", portBaseIdV[8], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 8 output.");
  2108. cmDspArgSetupN(ctx, a, argCnt, portBaseIdV[9], portChCntV[9], "gate-9", portBaseIdV[9], 0, 0, kOutDsvFl | kBoolDsvFl, "Channel gate set 9 output.");
  2109. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  2110. if((p = cmDspInstAlloc(cmDspNetNoteSelect_t,ctx,classPtr,a,instSymId,id,storeSymId,0,vl)) == NULL )
  2111. return NULL;
  2112. cmDspSetDefaultBool( ctx, &p->inst, kTrigNnId, false, false );
  2113. cmDspSetDefaultSymbol( ctx, &p->inst, kDoneNnId, cmInvalidId );
  2114. p->rmsBaseNnId = rmsBaseNnId;
  2115. p->chCnt = chCnt;
  2116. p->chGateV = cmMemAllocZ(bool,chCnt);
  2117. p->chRmsV = cmMemAllocZ(cmReal_t,chCnt);
  2118. p->portChCntV = portChCntV;
  2119. p->portBaseIdV = portBaseIdV;
  2120. p->doneSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"done");
  2121. p->chPortV = chPortV;
  2122. p->chPortIdxV = chPortIdxV;
  2123. p->ncPortV = ncPortV;
  2124. p->ncPortIdxV = ncPortIdxV;
  2125. for(i=0; i<chCnt; ++i)
  2126. {
  2127. cmDspSetDefaultBool( ctx, &p->inst, kGateBaseNnId+i, false, false );
  2128. cmDspSetDefaultDouble(ctx, &p->inst, rmsBaseNnId+i, 0.0, 0.0 );
  2129. }
  2130. for(i=0; i<_cmNetNoteSelPortCnt; ++i)
  2131. for(j=0; j<p->portChCntV[i]; ++j)
  2132. cmDspSetDefaultBool( ctx, &p->inst, p->portBaseIdV[i]+j, false, false );
  2133. return &p->inst;
  2134. }
  2135. cmDspRC_t _cmDspNetNoteSelectFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2136. {
  2137. cmDspNetNoteSelect_t* p = (cmDspNetNoteSelect_t*)inst;
  2138. cmMemFree(p->chGateV);
  2139. cmMemFree(p->chRmsV);
  2140. return kOkDspRC;
  2141. }
  2142. cmDspRC_t _cmDspNetNoteSelectReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2143. {
  2144. cmDspRC_t rc = kOkDspRC;
  2145. cmDspNetNoteSelect_t* p = (cmDspNetNoteSelect_t*)inst;
  2146. rc = cmDspApplyAllDefaults(ctx,inst);
  2147. cmVOR_Zero(p->chRmsV,p->chCnt);
  2148. return rc;
  2149. }
  2150. cmDspRC_t _cmDspNetNoteSelectRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2151. {
  2152. cmDspRC_t rc = kOkDspRC;
  2153. cmDspNetNoteSelect_t* p = (cmDspNetNoteSelect_t*)inst;
  2154. // store incoming gate values
  2155. if( kGateBaseNnId <= evt->dstVarId && evt->dstVarId < kGateBaseNnId + p->chCnt )
  2156. {
  2157. p->chGateV[ evt->dstVarId - kGateBaseNnId ] = cmDsvGetBool(evt->valuePtr);
  2158. //unsigned idx = evt->dstVarId - kGateBaseNnId;
  2159. //cmRptPrintf(ctx->rpt,"ns gate:%i %i\n",idx, p->chGateV[ idx ]);
  2160. }
  2161. else
  2162. // store incoming RMS values
  2163. if( p->rmsBaseNnId <= evt->dstVarId && evt->dstVarId < p->rmsBaseNnId + p->chCnt )
  2164. {
  2165. p->chRmsV[ evt->dstVarId - p->rmsBaseNnId ] = cmDsvGetReal( evt->valuePtr );
  2166. }
  2167. else
  2168. {
  2169. // if a chord detection was triggered
  2170. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC && evt->dstVarId == kTrigNnId )
  2171. {
  2172. unsigned i;
  2173. cmReal_t maxRms = 0;
  2174. unsigned maxIdx = cmInvalidIdx;
  2175. for(i=1; i<p->chCnt; ++i)
  2176. {
  2177. // if this channel had an onset and is a possible chord note and is the max RMS chord note
  2178. if( p->chGateV[i] && (maxIdx==cmInvalidIdx || p->chRmsV[i] > maxRms) )
  2179. {
  2180. maxRms = p->chRmsV[i];
  2181. maxIdx = i;
  2182. }
  2183. }
  2184. for(i=0; i<p->chCnt; ++i)
  2185. {
  2186. bool chosenFl = i==maxIdx;
  2187. bool otherFl = i!=maxIdx && p->chGateV[i];
  2188. bool nonFl = chosenFl==false && otherFl==false;
  2189. unsigned k;
  2190. // if this is a chord channel
  2191. if( p->chPortV[i] != cmInvalidIdx )
  2192. {
  2193. // get the port associated with this chord note
  2194. k = p->chPortV[i];
  2195. assert( k+1 < _cmNetNoteSelPortCnt );
  2196. assert( p->chPortIdxV[i] < p->portChCntV[k] && p->chPortIdxV[i] < p->portChCntV[k+1] );
  2197. // set the chosen and other gate outputs based on the state of
  2198. // chosenFl and otherFl
  2199. cmDspSetBool(ctx,inst,p->portBaseIdV[ k ] + p->chPortIdxV[i],chosenFl);
  2200. cmDspSetBool(ctx,inst,p->portBaseIdV[ k+1 ] + p->chPortIdxV[i],otherFl);
  2201. }
  2202. // all channels have a 'single' note channel
  2203. assert( p->ncPortV[i] != cmInvalidIdx );
  2204. k = p->ncPortV[i];
  2205. assert( k < _cmNetNoteSelPortCnt );
  2206. assert( p->ncPortIdxV[i] < p->portChCntV[k] );
  2207. cmDspSetBool(ctx,inst,p->portBaseIdV[k] + p->ncPortIdxV[i],nonFl);
  2208. }
  2209. // send the 'done' symbol to notify the gate receivers that the
  2210. // new set of gates is complete
  2211. cmDspSetSymbol(ctx,inst,kDoneNnId, p->doneSymId);
  2212. // zero the RMS vector
  2213. cmVOR_Zero(p->chRmsV,p->chCnt);
  2214. }
  2215. }
  2216. return rc;
  2217. }
  2218. cmDspClass_t* cmNetNoteSelectClassCons( cmDspCtx_t* ctx )
  2219. {
  2220. cmDspClassSetup(&_cmNetNoteSelectDC,ctx,"NetNoteSelect",
  2221. NULL,
  2222. _cmDspNetNoteSelectAlloc,
  2223. _cmDspNetNoteSelectFree,
  2224. _cmDspNetNoteSelectReset,
  2225. NULL,
  2226. _cmDspNetNoteSelectRecv,
  2227. NULL,NULL,
  2228. "Chord detector.");
  2229. return &_cmNetNoteSelectDC;
  2230. }
  2231. //------------------------------------------------------------------------------------------------------------
  2232. //)
  2233. //( { label:cmDspCombFilt file_desc:"Comb and Inverse comb filter." kw:[sunit] }
  2234. enum
  2235. {
  2236. kBypassCfId,
  2237. kMinHzCfId,
  2238. kFbFlCfId,
  2239. kHzCfId,
  2240. kAlphaCfId,
  2241. kInCfId,
  2242. kOutCfId
  2243. };
  2244. cmDspClass_t _cmCombFiltDC;
  2245. typedef struct
  2246. {
  2247. cmDspInst_t inst;
  2248. cmCombFilt* cfp;
  2249. } cmDspCombFilt_t;
  2250. cmDspInst_t* _cmDspCombFiltAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2251. {
  2252. cmDspVarArg_t args[] =
  2253. {
  2254. { "bypass",kBypassCfId, 0, 0, kInDsvFl | kBoolDsvFl | kReqArgDsvFl, "Bypass enable flag." },
  2255. { "minhz", kMinHzCfId, 0, 0, kDoubleDsvFl | kReqArgDsvFl, "Minimum frequency limit."},
  2256. { "fb", kFbFlCfId, 0, 0, kInDsvFl | kBoolDsvFl | kReqArgDsvFl, "Configure the filter in feedback mode."},
  2257. { "hz", kHzCfId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Lowest comb frequency." },
  2258. { "alpha", kAlphaCfId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Filter coefficent."},
  2259. { "in", kInCfId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input."},
  2260. { "out", kOutCfId, 0, 1, kOutDsvFl| kAudioBufDsvFl, "Audio out."},
  2261. { NULL, 0, 0, 0, 0, NULL }
  2262. };
  2263. cmDspCombFilt_t* p;
  2264. if((p = cmDspInstAlloc(cmDspCombFilt_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl)) == NULL )
  2265. return NULL;
  2266. p->cfp = cmCombFiltAlloc(ctx->cmProcCtx, NULL,
  2267. cmDspSampleRate(ctx),
  2268. cmDspBool(&p->inst,kFbFlCfId),
  2269. cmDspDouble(&p->inst,kMinHzCfId),
  2270. cmDspDouble(&p->inst,kAlphaCfId),
  2271. cmDspDouble(&p->inst,kHzCfId),
  2272. cmDspBool(&p->inst,kBypassCfId));
  2273. return &p->inst;
  2274. }
  2275. cmDspRC_t _cmDspCombFiltFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2276. {
  2277. cmDspCombFilt_t* p = (cmDspCombFilt_t*)inst;
  2278. cmCombFiltFree(&p->cfp);
  2279. return kOkDspRC;
  2280. }
  2281. cmDspRC_t _cmDspCombFiltReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2282. {
  2283. cmDspRC_t rc = kOkDspRC;
  2284. cmDspCombFilt_t* p = (cmDspCombFilt_t*)inst;
  2285. rc = cmDspApplyAllDefaults(ctx,inst);
  2286. cmDspZeroAudioBuf(ctx,inst,kOutCfId);
  2287. cmCombFiltInit(p->cfp,
  2288. cmDspSampleRate(ctx),
  2289. cmDspBool(inst,kFbFlCfId),
  2290. cmDspDouble(inst,kMinHzCfId),
  2291. cmDspDouble(inst,kAlphaCfId),
  2292. cmDspDouble(inst,kHzCfId),
  2293. cmDspBool(inst,kBypassCfId));
  2294. return rc;
  2295. }
  2296. cmDspRC_t _cmDspCombFiltExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2297. {
  2298. cmDspRC_t rc = kOkDspRC;
  2299. cmDspCombFilt_t* p = (cmDspCombFilt_t*)inst;
  2300. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutCfId,0);
  2301. cmSample_t* op = cmDspAudioBuf(ctx,inst,kOutCfId,0);
  2302. const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kInCfId,0);
  2303. cmCombFiltExec(p->cfp,ip,op,n);
  2304. return rc;
  2305. }
  2306. cmDspRC_t _cmDspCombFiltRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2307. {
  2308. cmDspRC_t rc = kOkDspRC;
  2309. cmDspCombFilt_t* p = (cmDspCombFilt_t*)inst;
  2310. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  2311. {
  2312. switch( evt->dstVarId )
  2313. {
  2314. case kHzCfId:
  2315. cmCombFiltSetHz(p->cfp,cmDspDouble(inst,evt->dstVarId));
  2316. //printf("%s hz:%f\n",cmSymTblLabel(ctx->stH,inst->symId),cmDspDouble(inst,evt->dstVarId));
  2317. break;
  2318. case kAlphaCfId:
  2319. cmCombFiltSetAlpha(p->cfp,cmDspDouble(inst,evt->dstVarId));
  2320. break;
  2321. case kBypassCfId:
  2322. p->cfp->bypassFl = cmDspBool(inst,evt->dstVarId);
  2323. break;
  2324. }
  2325. }
  2326. return rc;
  2327. }
  2328. cmDspClass_t* cmCombFiltClassCons( cmDspCtx_t* ctx )
  2329. {
  2330. cmDspClassSetup(&_cmCombFiltDC,ctx,"CombFilt",
  2331. NULL,
  2332. _cmDspCombFiltAlloc,
  2333. _cmDspCombFiltFree,
  2334. _cmDspCombFiltReset,
  2335. _cmDspCombFiltExec,
  2336. _cmDspCombFiltRecv,
  2337. NULL,NULL,
  2338. "Comb Filter");
  2339. return &_cmCombFiltDC;
  2340. }
  2341. //------------------------------------------------------------------------------------------------------------
  2342. //)
  2343. //( { label:cmDspScalarOp file_desc:"Perform arithmetic functions on scalar values." kw:[sunit] }
  2344. enum
  2345. {
  2346. kPortCntSoId,
  2347. kOpSoId,
  2348. kOutSoId,
  2349. kBaseOpdSoId
  2350. };
  2351. cmDspClass_t _cmScalarOpDC;
  2352. struct cmDspScalarOp_str;
  2353. typedef cmDspRC_t (*_cmDspScalarOpFunc_t)(cmDspCtx_t* ctx, cmDspInst_t* inst );
  2354. typedef struct cmDspScalar_str
  2355. {
  2356. cmDspInst_t inst;
  2357. _cmDspScalarOpFunc_t func;
  2358. unsigned inPortCnt;
  2359. } cmDspScalarOp_t;
  2360. cmDspRC_t _cmDspScalarOpFuncMult(cmDspCtx_t* ctx, cmDspInst_t* inst )
  2361. {
  2362. cmDspScalarOp_t* p = (cmDspScalarOp_t*)inst;
  2363. double val = 1.0;
  2364. unsigned i;
  2365. for(i=0; i<p->inPortCnt; ++i)
  2366. val *= cmDspDouble( inst, kBaseOpdSoId+i );
  2367. cmDspSetDouble( ctx, inst, kOutSoId, val );
  2368. return kOkDspRC;
  2369. }
  2370. cmDspRC_t _cmDspScalarOpFuncAdd(cmDspCtx_t* ctx, cmDspInst_t* inst )
  2371. {
  2372. cmDspScalarOp_t* p = (cmDspScalarOp_t*)inst;
  2373. double val = 0;
  2374. unsigned i;
  2375. for(i=0; i<p->inPortCnt; ++i)
  2376. val += cmDspDouble( inst, kBaseOpdSoId+i );
  2377. cmDspSetDouble( ctx, inst, kOutSoId, val );
  2378. return kOkDspRC;
  2379. }
  2380. // var args syntax: "<in_port_cnt> <op_string> <opd_label_0> <opd_dflt_val_0> <opd_label_1> <opd_dflt_val_1> ... <opd_label_n> <opd_dflt_val_n>
  2381. cmDspInst_t* _cmDspScalarOpAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2382. {
  2383. cmDspVarArg_t args[] =
  2384. {
  2385. { "cnt", kPortCntSoId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Input port count" },
  2386. { "op", kOpSoId, 0, 0, kStrzDsvFl | kReqArgDsvFl, "Operation symbol as a string."},
  2387. { "out", kOutSoId, 0, 0, kDoubleDsvFl | kOutDsvFl, "Operation output."},
  2388. };
  2389. cmDspScalarOp_t* p;
  2390. if( va_cnt < 2 )
  2391. {
  2392. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'ScalarOp' constructor must have a count of input ports and operation identifier string.");
  2393. return NULL;
  2394. }
  2395. va_list vl1;
  2396. va_copy(vl1,vl);
  2397. unsigned inPortCnt = va_arg(vl,unsigned);
  2398. const cmChar_t* opIdStr = va_arg(vl,const cmChar_t*);
  2399. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  2400. unsigned argCnt = fixArgCnt + inPortCnt;
  2401. cmDspVarArg_t a[ argCnt+1 ];
  2402. double dfltVal[ inPortCnt ];
  2403. unsigned i;
  2404. _cmDspScalarOpFunc_t fp = NULL;
  2405. // validate the count of input ports
  2406. if( inPortCnt == 0 )
  2407. {
  2408. cmDspClassErr(ctx,classPtr,kVarNotValidDspRC,"The 'ScalarOp' constructor input port argument must be non-zero.");
  2409. goto errLabel;
  2410. }
  2411. // locate the operation function
  2412. if( strcmp(opIdStr,"*") == 0 )
  2413. fp = _cmDspScalarOpFuncMult;
  2414. else
  2415. if( strcmp(opIdStr,"+") == 0 )
  2416. fp = _cmDspScalarOpFuncAdd;
  2417. // validate the operation function
  2418. if( fp == NULL )
  2419. {
  2420. cmDspClassErr(ctx,classPtr,kVarNotValidDspRC,"The 'ScalarOp' constructor operation string id '%s' did not match a known operation.",cmStringNullGuard(opIdStr));
  2421. goto errLabel;
  2422. }
  2423. // setup the fixed args
  2424. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  2425. for(i=0; i<inPortCnt; ++i)
  2426. {
  2427. // get the operand label
  2428. const cmChar_t* label = va_arg(vl,const cmChar_t*);
  2429. // get the operand default value
  2430. dfltVal[i] = va_arg(vl,double);
  2431. // setup the arg recd
  2432. cmDspArgSetup(ctx,a + fixArgCnt + i, label, cmInvalidId, kBaseOpdSoId+i,0,0,kDoubleDsvFl|kInDsvFl,"Operand");
  2433. }
  2434. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  2435. if((p = cmDspInstAlloc(cmDspScalarOp_t,ctx,classPtr,a,instSymId,id,storeSymId,2,vl1)) == NULL )
  2436. goto errLabel;
  2437. for(i=0; i<inPortCnt; ++i)
  2438. cmDspSetDefaultDouble(ctx,&p->inst,kBaseOpdSoId+i,0.0,dfltVal[i]);
  2439. p->inPortCnt = inPortCnt;
  2440. p->func = fp;
  2441. va_end(vl1);
  2442. return &p->inst;
  2443. errLabel:
  2444. va_end(vl1);
  2445. return NULL;
  2446. }
  2447. cmDspRC_t _cmDspScalarOpReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2448. {
  2449. cmDspRC_t rc = kOkDspRC;
  2450. rc = cmDspApplyAllDefaults(ctx,inst);
  2451. return rc;
  2452. }
  2453. cmDspRC_t _cmDspScalarOpRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2454. {
  2455. cmDspRC_t rc = kOkDspRC;
  2456. cmDspScalarOp_t* p = (cmDspScalarOp_t*)inst;
  2457. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  2458. {
  2459. if( evt->dstVarId == kBaseOpdSoId )
  2460. p->func(ctx,inst);
  2461. }
  2462. return rc;
  2463. }
  2464. cmDspClass_t* cmScalarOpClassCons( cmDspCtx_t* ctx )
  2465. {
  2466. cmDspClassSetup(&_cmScalarOpDC,ctx,"ScalarOp",
  2467. NULL,
  2468. _cmDspScalarOpAlloc,
  2469. NULL,
  2470. _cmDspScalarOpReset,
  2471. NULL,
  2472. _cmDspScalarOpRecv,
  2473. NULL,NULL,
  2474. "Scalar Operations");
  2475. return &_cmScalarOpDC;
  2476. }
  2477. //------------------------------------------------------------------------------------------------------------
  2478. //)
  2479. //( { label:cmDspGroupSel file_desc:"Select one group of audio channels from a set of audio channel groups." kw:[sunit] }
  2480. enum
  2481. {
  2482. kChCntGsId,
  2483. kGroupCntGsId,
  2484. kChsPerGroupGsId,
  2485. kBaseGateGsId,
  2486. };
  2487. cmDspClass_t _cmGroupSelDC;
  2488. typedef struct
  2489. {
  2490. cmDspInst_t inst;
  2491. unsigned chCnt;
  2492. unsigned groupCnt;
  2493. cmGroupSel* gsp;
  2494. unsigned baseRmsGsId;
  2495. unsigned baseOutGsId;
  2496. } cmDspGroupSel_t;
  2497. cmDspInst_t* _cmDspGroupSelAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2498. {
  2499. cmDspVarArg_t args[] =
  2500. {
  2501. { "chCnt", kChCntGsId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Channel count." },
  2502. { "groupCnt", kGroupCntGsId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Group count." },
  2503. { "chsPerGroup", kChsPerGroupGsId, 0, 0, kUIntDsvFl | kInDsvFl | kReqArgDsvFl, "Channels per group." }
  2504. };
  2505. if( va_cnt < 2 )
  2506. {
  2507. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'GroupSel' constructor must have a channel and group count.");
  2508. return NULL;
  2509. }
  2510. va_list vl1;
  2511. va_copy(vl1,vl);
  2512. cmDspGroupSel_t* p;
  2513. unsigned i;
  2514. unsigned chCnt = va_arg(vl,unsigned);
  2515. unsigned groupCnt = va_arg(vl,unsigned);
  2516. unsigned outCnt = chCnt * groupCnt;
  2517. unsigned fixArgCnt = sizeof(args)/sizeof(args[0]);
  2518. unsigned baseRmsGsId = kBaseGateGsId + chCnt;
  2519. unsigned baseOutGsId = baseRmsGsId + chCnt;
  2520. unsigned argCnt = baseOutGsId + outCnt;
  2521. cmDspVarArg_t a[ argCnt + 1 ];
  2522. cmDspArgCopy( a, argCnt, 0, args, fixArgCnt );
  2523. cmDspArgSetupN(ctx, a, argCnt, kBaseGateGsId, chCnt, "gate", kBaseGateGsId, 0, 0, kInDsvFl | kBoolDsvFl, "Channel gate input.");
  2524. cmDspArgSetupN(ctx, a, argCnt, baseRmsGsId, chCnt, "rms", baseRmsGsId, 0, 0, kInDsvFl | kDoubleDsvFl, "Channel RMS input");
  2525. for(i=0; i<groupCnt; ++i)
  2526. {
  2527. int labelCharCnt = 31;
  2528. char label[ labelCharCnt + 1 ];
  2529. snprintf(label,labelCharCnt,"gate-%i",i);
  2530. cmDspArgSetupN(ctx, a, argCnt, baseOutGsId + (i*chCnt), chCnt, label, baseOutGsId + (i*chCnt), 0, 0, kOutDsvFl | kBoolDsvFl, "Output gates");
  2531. }
  2532. cmDspArgSetupNull( a+argCnt); // set terminating arg. flag
  2533. if((p = cmDspInstAlloc(cmDspGroupSel_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl1)) == NULL )
  2534. {
  2535. va_end(vl1);
  2536. return NULL;
  2537. }
  2538. p->chCnt = chCnt;
  2539. p->groupCnt = groupCnt;
  2540. p->gsp = cmGroupSelAlloc(ctx->cmProcCtx, NULL, 0, 0, 0 );
  2541. p->baseRmsGsId = baseRmsGsId;
  2542. p->baseOutGsId = baseOutGsId;
  2543. for(i=0; i<chCnt; ++i)
  2544. {
  2545. cmDspSetDefaultBool( ctx, &p->inst, kBaseGateGsId, false, false );
  2546. cmDspSetDefaultDouble(ctx,&p->inst, baseRmsGsId, 0.0, 0.0 );
  2547. }
  2548. for(i=0; i<outCnt; ++i)
  2549. cmDspSetDefaultBool( ctx, &p->inst, baseOutGsId, false, false );
  2550. va_end(vl1);
  2551. return &p->inst;
  2552. }
  2553. cmDspRC_t _cmDspGroupSelFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2554. {
  2555. cmDspGroupSel_t* p = (cmDspGroupSel_t*)inst;
  2556. cmGroupSelFree(&p->gsp);
  2557. return kOkDspRC;
  2558. }
  2559. cmDspRC_t _cmDspGroupSelReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2560. {
  2561. cmDspRC_t rc = kOkDspRC;
  2562. cmDspGroupSel_t* p = (cmDspGroupSel_t*)inst;
  2563. rc = cmDspApplyAllDefaults(ctx,inst);
  2564. cmGroupSelInit(p->gsp,p->chCnt,p->groupCnt,cmDspUInt(&p->inst,kChsPerGroupGsId));
  2565. return rc;
  2566. }
  2567. cmDspRC_t _cmDspGroupSelExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2568. {
  2569. cmDspRC_t rc = kOkDspRC;
  2570. cmDspGroupSel_t* p = (cmDspGroupSel_t*)inst;
  2571. if( cmGroupSelExec(p->gsp) == cmOkRC && p->gsp->updateFl )
  2572. {
  2573. unsigned i,j;
  2574. for(i=0; i<p->groupCnt; ++i)
  2575. {
  2576. cmGroupSelGrp* gp = p->gsp->groupArray + i;
  2577. if( gp->releaseFl )
  2578. {
  2579. for(j=0; j<gp->chIdxCnt; ++j)
  2580. cmDspSetBool(ctx,inst,p->baseOutGsId + (i*p->chCnt) + gp->chIdxArray[j], false);
  2581. }
  2582. if( gp->createFl )
  2583. {
  2584. for(j=0; j<gp->chIdxCnt; ++j)
  2585. cmDspSetBool(ctx,inst,p->baseOutGsId + (i*p->chCnt) + gp->chIdxArray[j], true);
  2586. }
  2587. }
  2588. }
  2589. return rc;
  2590. }
  2591. cmDspRC_t _cmDspGroupSelRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2592. {
  2593. cmDspRC_t rc = kOkDspRC;
  2594. cmDspGroupSel_t* p = (cmDspGroupSel_t*)inst;
  2595. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  2596. {
  2597. if( evt->dstVarId == kChsPerGroupGsId )
  2598. p->gsp->chsPerGroup = cmDspUInt(inst, kChsPerGroupGsId );
  2599. else
  2600. if( kBaseGateGsId <= evt->dstVarId && evt->dstVarId < (kBaseGateGsId + p->chCnt) )
  2601. cmGroupSetChannelGate(p->gsp, evt->dstVarId - kBaseGateGsId, cmDspDouble(inst,evt->dstVarId));
  2602. else
  2603. if( p->baseRmsGsId <= evt->dstVarId && evt->dstVarId < (p->baseRmsGsId + p->chCnt) )
  2604. cmGroupSetChannelRMS(p->gsp, evt->dstVarId - p->baseRmsGsId, cmDspDouble(inst,evt->dstVarId));
  2605. }
  2606. return rc;
  2607. }
  2608. cmDspClass_t* cmGroupSelClassCons( cmDspCtx_t* ctx )
  2609. {
  2610. cmDspClassSetup(&_cmGroupSelDC,ctx,"GroupSel",
  2611. NULL,
  2612. _cmDspGroupSelAlloc,
  2613. _cmDspGroupSelFree,
  2614. _cmDspGroupSelReset,
  2615. _cmDspGroupSelExec,
  2616. _cmDspGroupSelRecv,
  2617. NULL,NULL,
  2618. "Group selector.");
  2619. return &_cmGroupSelDC;
  2620. }
  2621. //------------------------------------------------------------------------------------------------------------
  2622. //)
  2623. //( { label:cmDspNofM file_desc:"Select N channels from a set of M channels based on their current gate states." kw:[sunit] }
  2624. enum
  2625. {
  2626. kInChCntNmId,
  2627. kOutChCntNmId,
  2628. kFadeTimeNmId,
  2629. kBaseGateNmId,
  2630. };
  2631. cmDspClass_t _cmAudioNofM_DC;
  2632. typedef struct
  2633. {
  2634. cmDspInst_t inst;
  2635. unsigned inChCnt;
  2636. unsigned outChCnt;
  2637. cmAudioNofM* nmp;
  2638. unsigned baseInNmId;
  2639. unsigned baseOutNmId;
  2640. unsigned baseGainNmId;
  2641. } cmDspAudioNofM_t;
  2642. cmDspInst_t* _cmDspAudioNofM_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2643. {
  2644. if( va_cnt < 2 )
  2645. {
  2646. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'AudioNofM' constructor must given input and output channel counts.");
  2647. return NULL;
  2648. }
  2649. va_list vl1;
  2650. va_copy(vl1,vl);
  2651. int inChCnt = va_arg(vl,int);
  2652. int outChCnt = va_arg(vl,int);
  2653. unsigned baseInNmId = kBaseGateNmId + inChCnt;
  2654. unsigned baseOutNmId = baseInNmId + inChCnt;
  2655. unsigned baseGainNmId= baseOutNmId + outChCnt;
  2656. unsigned i;
  2657. cmDspAudioNofM_t* p = cmDspInstAllocV(cmDspAudioNofM_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  2658. 1, "ichs", kInChCntNmId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Input channel count.",
  2659. 1, "ochs", kOutChCntNmId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Output channel count.",
  2660. 1, "time", kFadeTimeNmId, 0, 0, kDoubleDsvFl | kOptArgDsvFl | kInDsvFl, "Fade time in milliseconds.",
  2661. inChCnt, "gate", kBaseGateNmId, 0, 0, kBoolDsvFl | kInDsvFl, "Gate inputs.",
  2662. inChCnt, "in", baseInNmId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input",
  2663. outChCnt, "out", baseOutNmId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio output",
  2664. outChCnt, "gain", baseGainNmId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Gain output",
  2665. 0 );
  2666. cmDspSetDefaultDouble( ctx, &p->inst, kFadeTimeNmId, 0.0, 25.0 );
  2667. p->inChCnt = inChCnt;
  2668. p->outChCnt = outChCnt;
  2669. p->nmp = cmAudioNofMAlloc(ctx->cmProcCtx,NULL,0,0,0,0);
  2670. p->baseInNmId = baseInNmId;
  2671. p->baseOutNmId = baseOutNmId;
  2672. p->baseGainNmId = baseGainNmId;
  2673. for(i=0; i<outChCnt; ++i)
  2674. cmDspSetDefaultDouble( ctx, &p->inst, baseGainNmId + i, 0.0, 0.0 );
  2675. va_end(vl1);
  2676. return &p->inst;
  2677. }
  2678. cmDspRC_t _cmDspAudioNofM_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2679. {
  2680. cmDspAudioNofM_t* p = (cmDspAudioNofM_t*)inst;
  2681. cmAudioNofMFree(&p->nmp);
  2682. return kOkDspRC;
  2683. }
  2684. cmDspRC_t _cmDspAudioNofM_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2685. {
  2686. cmDspRC_t rc = kOkDspRC;
  2687. cmDspAudioNofM_t* p = (cmDspAudioNofM_t*)inst;
  2688. unsigned i;
  2689. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  2690. {
  2691. for(i=0; i<p->outChCnt; ++i)
  2692. cmDspZeroAudioBuf(ctx,inst,p->baseOutNmId+i);
  2693. cmAudioNofMInit(p->nmp, cmDspSampleRate(ctx), p->inChCnt, p->outChCnt, cmDspDouble(&p->inst, kFadeTimeNmId ));
  2694. }
  2695. return rc;
  2696. }
  2697. cmDspRC_t _cmDspAudioNofM_Exec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2698. {
  2699. cmDspRC_t rc = kOkDspRC;
  2700. cmDspAudioNofM_t* p = (cmDspAudioNofM_t*)inst;
  2701. unsigned i;
  2702. const cmSample_t* x[ p->inChCnt ];
  2703. cmSample_t* y[ p->outChCnt ];
  2704. unsigned n = 0;
  2705. for(i=0; i<p->inChCnt; ++i)
  2706. {
  2707. if( i==0 )
  2708. n = cmDspAudioBufSmpCount(ctx,inst,p->baseInNmId+i,0);
  2709. else
  2710. { assert( n == cmDspAudioBufSmpCount(ctx,inst,p->baseInNmId+i,0)); }
  2711. x[i] = cmDspAudioBuf(ctx,inst,p->baseInNmId+i,0);
  2712. }
  2713. for(i=0; i<p->outChCnt; ++i)
  2714. {
  2715. y[i] = cmDspAudioBuf(ctx,inst,p->baseOutNmId+i,0);
  2716. assert( n == cmDspAudioBufSmpCount(ctx,inst,p->baseOutNmId+i,0));
  2717. cmVOS_Zero(y[i],n);
  2718. }
  2719. cmAudioNofMExec(p->nmp,x,p->inChCnt,y,p->outChCnt,n);
  2720. for(i=0; i<p->outChCnt; ++i)
  2721. {
  2722. cmAudioNofM_In* ip = p->nmp->outArray[i].list;
  2723. double v = 0;
  2724. for(; ip != NULL; ip=ip->link)
  2725. v += ip->fader->gain;
  2726. cmDspSetDouble(ctx, inst,p->baseGainNmId + i,v );
  2727. }
  2728. return rc;
  2729. }
  2730. cmDspRC_t _cmDspAudioNofM_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2731. {
  2732. cmDspRC_t rc = kOkDspRC;
  2733. cmDspAudioNofM_t* p = (cmDspAudioNofM_t*)inst;
  2734. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  2735. {
  2736. if( kBaseGateNmId <= evt->dstVarId && evt->dstVarId <= kBaseGateNmId + p->inChCnt )
  2737. cmAudioNofMSetChannelGate( p->nmp, evt->dstVarId - kBaseGateNmId, cmDspBool(inst,evt->dstVarId) );
  2738. }
  2739. return rc;
  2740. }
  2741. cmDspClass_t* cmAudioNofMClassCons( cmDspCtx_t* ctx )
  2742. {
  2743. cmDspClassSetup(&_cmAudioNofM_DC,ctx,"AudioNofM",
  2744. NULL,
  2745. _cmDspAudioNofM_Alloc,
  2746. _cmDspAudioNofM_Free,
  2747. _cmDspAudioNofM_Reset,
  2748. _cmDspAudioNofM_Exec,
  2749. _cmDspAudioNofM_Recv,
  2750. NULL,NULL,
  2751. "Audio N of M Switch");
  2752. return &_cmAudioNofM_DC;
  2753. }
  2754. //------------------------------------------------------------------------------------------------------------
  2755. //)
  2756. //( { label:cmDspRingMod file_desc:"Ring modulator." kw:[sunit] }
  2757. enum
  2758. {
  2759. kInChCntRmId,
  2760. kBypassRmId,
  2761. kGainRmId,
  2762. kOutRmId,
  2763. kBaseInRmId
  2764. };
  2765. cmDspClass_t _cmRingModDC;
  2766. typedef struct
  2767. {
  2768. cmDspInst_t inst;
  2769. unsigned inChCnt;
  2770. } cmDspRingMod_t;
  2771. cmDspInst_t* _cmDspRingModAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2772. {
  2773. if( va_cnt < 1 )
  2774. {
  2775. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'RingMod' constructor must given an input channel counts.");
  2776. return NULL;
  2777. }
  2778. va_list vl1;
  2779. va_copy(vl1,vl);
  2780. int inChCnt = va_arg(vl,int);
  2781. cmDspRingMod_t* p = cmDspInstAllocV(cmDspRingMod_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  2782. 1, "ichs", kInChCntRmId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Input channel count.",
  2783. 1, "bypass",kBypassRmId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Bypass enable",
  2784. 1, "gain", kGainRmId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Output gain (default:1.0)",
  2785. 1, "out", kOutRmId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio output",
  2786. inChCnt, "in", kBaseInRmId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input",
  2787. 0 );
  2788. cmDspSetDefaultBool( ctx, &p->inst, kBypassRmId, false, false );
  2789. cmDspSetDefaultDouble( ctx, &p->inst, kGainRmId, 0.0, 1.0 );
  2790. p->inChCnt = inChCnt;
  2791. va_end(vl1);
  2792. return &p->inst;
  2793. }
  2794. cmDspRC_t _cmDspRingModReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2795. {
  2796. cmDspRC_t rc = kOkDspRC;
  2797. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  2798. {
  2799. cmDspZeroAudioBuf(ctx,inst,kOutRmId);
  2800. }
  2801. return rc;
  2802. }
  2803. cmDspRC_t _cmDspRingModExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2804. {
  2805. cmDspRC_t rc = kOkDspRC;
  2806. cmDspRingMod_t* p = (cmDspRingMod_t*)inst;
  2807. unsigned i,j;
  2808. cmSample_t* y = cmDspAudioBuf(ctx,inst,kOutRmId, 0);
  2809. const cmSample_t* x0 = cmDspAudioBuf(ctx,inst,kBaseInRmId,0);
  2810. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutRmId,0);
  2811. double gain = cmDspDouble(inst,kGainRmId);
  2812. bool bypassFl = cmDspBool(inst,kBypassRmId);
  2813. for(i=1; i<p->inChCnt; ++i)
  2814. {
  2815. assert( n == cmDspAudioBufSmpCount(ctx,inst,kBaseInRmId+i,0));
  2816. const cmSample_t* x1 = cmDspAudioBuf(ctx,inst,kBaseInRmId+i,0);
  2817. if( bypassFl )
  2818. {
  2819. for(j=0; j<n; ++j)
  2820. y[j] = x0[j] + x1[j];
  2821. }
  2822. else
  2823. {
  2824. for(j=0; j<n; ++j)
  2825. y[j] = x0[j] * x1[j] * gain;
  2826. }
  2827. x0 = y;
  2828. }
  2829. return rc;
  2830. }
  2831. cmDspRC_t _cmDspRingModRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2832. {
  2833. return cmDspSetEvent(ctx,inst,evt);
  2834. }
  2835. cmDspClass_t* cmRingModClassCons( cmDspCtx_t* ctx )
  2836. {
  2837. cmDspClassSetup(&_cmRingModDC,ctx,"RingMod",
  2838. NULL,
  2839. _cmDspRingModAlloc,
  2840. NULL,
  2841. _cmDspRingModReset,
  2842. _cmDspRingModExec,
  2843. _cmDspRingModRecv,
  2844. NULL,NULL,
  2845. "Ring modulator");
  2846. return &_cmRingModDC;
  2847. }
  2848. //------------------------------------------------------------------------------------------------------------
  2849. //)
  2850. //( { label:cmDspMsgDelay file_desc:"Delay an arbitrary value." kw:[sunit] }
  2851. enum
  2852. {
  2853. kMaxCntMdId,
  2854. kDelayMdId,
  2855. kClearMdId,
  2856. kInMdId,
  2857. kOutMdId,
  2858. };
  2859. cmDspClass_t _cmMsgDelayDC;
  2860. typedef struct cmDspMsgDelayEle_str
  2861. {
  2862. unsigned outTimeSmp;
  2863. cmDspValue_t value;
  2864. struct cmDspMsgDelayEle_str* link;
  2865. } cmDspMsgDelayEle_t;
  2866. typedef struct
  2867. {
  2868. cmDspInst_t inst;
  2869. unsigned maxCnt;
  2870. cmDspMsgDelayEle_t* array; // array[maxCnt];
  2871. cmDspMsgDelayEle_t* avail;
  2872. cmDspMsgDelayEle_t* active;
  2873. } cmDspMsgDelay_t;
  2874. cmDspInst_t* _cmDspMsgDelayAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  2875. {
  2876. cmDspMsgDelay_t* p = cmDspInstAllocV(cmDspMsgDelay_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  2877. 1, "maxcnt", kMaxCntMdId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Maximum count of elements in the delay",
  2878. 1, "delay", kDelayMdId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Delay time in millisecond.",
  2879. 1, "clear", kClearMdId, 0, 0, kInDsvFl | kTypeDsvMask, "Clear delay",
  2880. 1, "in", kInMdId, 0, 0, kInDsvFl | kUIntDsvFl, "Msg input",
  2881. 1, "out", kOutMdId, 0, 0, kOutDsvFl | kUIntDsvFl, "Msg output",
  2882. 0 );
  2883. if( p == NULL )
  2884. return NULL;
  2885. cmDspSetDefaultDouble( ctx, &p->inst, kDelayMdId, 0.0, 0.0 );
  2886. cmDspSetDefaultBool( ctx, &p->inst, kOutMdId, false, false );
  2887. p->maxCnt = cmDspUInt(&p->inst,kMaxCntMdId);
  2888. p->array = cmMemAllocZ(cmDspMsgDelayEle_t, p->maxCnt );
  2889. return &p->inst;
  2890. }
  2891. cmDspRC_t _cmDspMsgDelayFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2892. {
  2893. cmDspMsgDelay_t* p = (cmDspMsgDelay_t*)inst;
  2894. cmMemFree(p->array);
  2895. return kOkDspRC;
  2896. }
  2897. // insert a value in the delay list
  2898. cmDspRC_t _cmDspMsgDelayInsert( cmDspCtx_t* ctx, cmDspMsgDelay_t* p, unsigned delayTimeSmp, const cmDspValue_t* valPtr )
  2899. {
  2900. cmDspRC_t rc = kOkDspRC;
  2901. // protect against pre-reset calls
  2902. if( p->avail == NULL && p->active == NULL )
  2903. return kOkDspRC;
  2904. // if there are no available delay elements
  2905. if( p->avail == NULL )
  2906. return cmDspInstErr(ctx,&p->inst,kInvalidStateDspRC,"The message delay has exhausted it's internal message store.");
  2907. // we only do the simplest kind of copying to avoid allocating memory
  2908. // TODO: fix this
  2909. if( cmDsvIsMtx(valPtr) || cmIsFlag(valPtr->flags,kProxyDsvFl))
  2910. return cmDspInstErr(ctx,&p->inst,kInvalidArgDspRC,"The message delay cannot yet store matrix or proxy types.");
  2911. // get a pointer to the next available element
  2912. cmDspMsgDelayEle_t* np = p->avail;
  2913. // remove the new ele from the avail list
  2914. p->avail = np->link;
  2915. // calc the new ele's exec time
  2916. np->outTimeSmp = ctx->cycleCnt * cmDspSamplesPerCycle(ctx) + delayTimeSmp;
  2917. // copy the msg value into the delay line element
  2918. // TODO: this should be a real copy that supports all types
  2919. np->value = *valPtr;
  2920. cmDspMsgDelayEle_t* ep = p->active;
  2921. cmDspMsgDelayEle_t* pp = NULL;
  2922. // if the active list is empty ...
  2923. if( ep == NULL )
  2924. {
  2925. // ... make the avail element the first on the list
  2926. p->active = np;
  2927. np->link = NULL;
  2928. }
  2929. else
  2930. {
  2931. // iterate through the list and find the active links which
  2932. // the new ele falls between based on its execution time
  2933. while(ep != NULL )
  2934. {
  2935. // ep's exec time is greater than the new ele's exec time
  2936. if( ep->outTimeSmp > np->outTimeSmp )
  2937. {
  2938. // insert the new ele in the active list before 'ep'
  2939. if( pp == NULL )
  2940. {
  2941. np->link = p->active;
  2942. p->active = np;
  2943. }
  2944. else
  2945. {
  2946. np->link = pp->link;
  2947. pp->link = np;
  2948. }
  2949. break;
  2950. }
  2951. pp = ep;
  2952. ep = ep->link;
  2953. }
  2954. // if the new element is last on the list
  2955. if( ep == NULL )
  2956. {
  2957. assert(pp != NULL && pp->link == NULL);
  2958. pp->link = np;
  2959. np->link = NULL;
  2960. }
  2961. }
  2962. return rc;
  2963. }
  2964. void _cmDspMsgDelayClear(cmDspInst_t* inst )
  2965. {
  2966. unsigned i;
  2967. cmDspMsgDelay_t* p = (cmDspMsgDelay_t*)inst;
  2968. unsigned maxCnt = cmDspUInt(inst,kMaxCntMdId);
  2969. p->active = NULL;
  2970. p->avail = NULL;
  2971. // put all ele's on the available list
  2972. for(i=0; i<maxCnt; ++i)
  2973. {
  2974. p->array[i].link = p->avail;
  2975. p->avail = p->array + i;
  2976. }
  2977. }
  2978. cmDspRC_t _cmDspMsgDelayReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  2979. {
  2980. cmDspRC_t rc = kOkDspRC;
  2981. if((rc = cmDspApplyDefault(ctx,inst,kDelayMdId)) == kOkDspRC )
  2982. {
  2983. _cmDspMsgDelayClear(inst);
  2984. }
  2985. return rc;
  2986. }
  2987. cmDspRC_t _cmDspMsgDelayExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* e )
  2988. {
  2989. cmDspRC_t rc = kOkDspRC;
  2990. cmDspMsgDelay_t* p = (cmDspMsgDelay_t*)inst;
  2991. unsigned framesPerCycle = cmDspSamplesPerCycle(ctx);
  2992. unsigned begTimeSmp = ctx->cycleCnt * framesPerCycle;
  2993. unsigned endTimeSmp = begTimeSmp + framesPerCycle;
  2994. while( p->active != NULL )
  2995. {
  2996. if( p->active->outTimeSmp >= endTimeSmp )
  2997. break;
  2998. cmDspMsgDelayEle_t* ep = p->active;
  2999. // remove the element from the active list and place it on the available list.
  3000. p->active = p->active->link; // advance the active list
  3001. ep->link = p->avail; // put the cur. element on the avail list
  3002. p->avail = ep; //
  3003. // output the element value
  3004. if((rc = cmDspValueSet(ctx,inst,kOutMdId,&ep->value,0)) != kOkDspRC )
  3005. return cmDspInstErr(ctx,inst,rc,"Message delay output failed.");
  3006. }
  3007. return rc;
  3008. }
  3009. cmDspRC_t _cmDspMsgDelayRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3010. {
  3011. cmDspRC_t rc = kOkDspRC;
  3012. cmDspMsgDelay_t* p = (cmDspMsgDelay_t*)inst;
  3013. switch( evt->dstVarId )
  3014. {
  3015. case kDelayMdId:
  3016. rc = cmDspSetEvent(ctx,inst,evt);
  3017. break;
  3018. case kClearMdId:
  3019. _cmDspMsgDelayClear(inst);
  3020. break;
  3021. case kInMdId:
  3022. {
  3023. unsigned delayTimeSmp = floor(cmDspDouble(&p->inst,kDelayMdId) * cmDspSampleRate(ctx) / 1000.0);
  3024. rc = _cmDspMsgDelayInsert(ctx,p,delayTimeSmp,evt->valuePtr);
  3025. }
  3026. break;
  3027. }
  3028. return rc;
  3029. }
  3030. cmDspClass_t* cmMsgDelayClassCons( cmDspCtx_t* ctx )
  3031. {
  3032. cmDspClassSetup(&_cmMsgDelayDC,ctx,"MsgDelay",
  3033. NULL,
  3034. _cmDspMsgDelayAlloc,
  3035. _cmDspMsgDelayFree,
  3036. _cmDspMsgDelayReset,
  3037. _cmDspMsgDelayExec,
  3038. _cmDspMsgDelayRecv,
  3039. NULL,NULL,
  3040. "Message Delay");
  3041. return &_cmMsgDelayDC;
  3042. }
  3043. //------------------------------------------------------------------------------------------------------------
  3044. //)
  3045. //( { label:cmDspLine file_desc:"Programmable line generator." kw:[sunit] }
  3046. enum
  3047. {
  3048. kBegLnId,
  3049. kEndLnId,
  3050. kDurLnId,
  3051. kCmdLnId,
  3052. kRateLnId,
  3053. kOutLnId,
  3054. };
  3055. cmDspClass_t _cmLineDC;
  3056. typedef struct cmDspLineEle_str
  3057. {
  3058. unsigned outTimeSmp;
  3059. cmDspValue_t value;
  3060. struct cmDspLineEle_str* link;
  3061. } cmDspLineEle_t;
  3062. typedef struct
  3063. {
  3064. cmDspInst_t inst;
  3065. unsigned onSymId;
  3066. unsigned offSymId;
  3067. unsigned resetSymId;
  3068. unsigned curSmpIdx;
  3069. double phase;
  3070. bool onFl;
  3071. } cmDspLine_t;
  3072. cmDspInst_t* _cmDspLineAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3073. {
  3074. cmDspLine_t* p = cmDspInstAllocV(cmDspLine_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  3075. 1, "beg", kBegLnId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Begin value.",
  3076. 1, "end", kEndLnId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "End value.",
  3077. 1, "dur", kDurLnId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Duration (ms)",
  3078. 1, "cmd", kCmdLnId, 0, 0, kInDsvFl | kSymDsvFl | kOptArgDsvFl, "Command: on | off | reset",
  3079. 1, "rate", kRateLnId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Output messages per second",
  3080. 1, "out", kOutLnId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Output",
  3081. 0 );
  3082. if( p == NULL )
  3083. return NULL;
  3084. cmDspSetDefaultDouble( ctx, &p->inst, kOutLnId, 0.0, cmDspDefaultDouble(&p->inst,kBegLnId) );
  3085. cmDspSetDefaultDouble( ctx, &p->inst, kRateLnId, 0.0, 0.0 );
  3086. p->onSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"on");
  3087. p->offSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"off");
  3088. p->resetSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"reset");
  3089. return &p->inst;
  3090. }
  3091. cmDspRC_t _cmDspLineFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3092. {
  3093. return kOkDspRC;
  3094. }
  3095. cmDspRC_t _cmDspLineReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3096. {
  3097. cmDspLine_t* p = (cmDspLine_t*)inst;
  3098. p->curSmpIdx = 0;
  3099. p->onFl = false;
  3100. p->phase = 0;
  3101. return cmDspApplyAllDefaults(ctx,inst);
  3102. }
  3103. cmDspRC_t _cmDspLineExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* e )
  3104. {
  3105. cmDspRC_t rc = kOkDspRC;
  3106. cmDspLine_t* p = (cmDspLine_t*)inst;
  3107. if( p->onFl == false )
  3108. return kOkDspRC;
  3109. unsigned sPc = cmDspSamplesPerCycle(ctx);
  3110. double beg = cmDspDouble(inst,kBegLnId);
  3111. double end = cmDspDouble(inst,kEndLnId);
  3112. double rate = cmDspDouble(inst,kRateLnId);
  3113. double ms = cmDspDouble(inst,kDurLnId);
  3114. double durSmpCnt = floor(ms * cmDspSampleRate(ctx) / 1000);
  3115. double out = beg + (end - beg) * p->curSmpIdx / durSmpCnt;
  3116. double phsMax = rate==0 ? sPc : cmDspSampleRate(ctx) / rate;
  3117. // we can never output with a period shorter than
  3118. // the length of one audio buffer
  3119. if( phsMax < sPc )
  3120. phsMax = sPc;
  3121. if( beg < end )
  3122. {
  3123. if( out >= end )
  3124. {
  3125. out = end;
  3126. p->onFl = false;
  3127. }
  3128. }
  3129. else
  3130. {
  3131. if( out <= end )
  3132. {
  3133. out = end;
  3134. p->onFl = false;
  3135. }
  3136. }
  3137. p->phase += sPc;
  3138. if( p->phase >= sPc )
  3139. {
  3140. cmDspSetDouble(ctx,inst,kOutLnId,out);
  3141. p->phase -= sPc;
  3142. }
  3143. p->curSmpIdx += sPc;
  3144. return rc;
  3145. }
  3146. cmDspRC_t _cmDspLineRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3147. {
  3148. cmDspRC_t rc = kOkDspRC;
  3149. cmDspLine_t* p = (cmDspLine_t*)inst;
  3150. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  3151. {
  3152. switch( evt->dstVarId )
  3153. {
  3154. case kCmdLnId:
  3155. {
  3156. unsigned symId = cmDspSymbol(inst,kCmdLnId);
  3157. if( symId == p->onSymId )
  3158. p->onFl = true;
  3159. else
  3160. if( symId == p->offSymId )
  3161. p->onFl = false;
  3162. else
  3163. if( symId == p->resetSymId )
  3164. {
  3165. p->curSmpIdx = 0;
  3166. p->onFl = true;
  3167. }
  3168. }
  3169. break;
  3170. }
  3171. }
  3172. return rc;
  3173. }
  3174. cmDspClass_t* cmLineClassCons( cmDspCtx_t* ctx )
  3175. {
  3176. cmDspClassSetup(&_cmLineDC,ctx,"Line",
  3177. NULL,
  3178. _cmDspLineAlloc,
  3179. _cmDspLineFree,
  3180. _cmDspLineReset,
  3181. _cmDspLineExec,
  3182. _cmDspLineRecv,
  3183. NULL,NULL,
  3184. "Line");
  3185. return &_cmLineDC;
  3186. }
  3187. //------------------------------------------------------------------------------------------------------------
  3188. //)
  3189. //( { label:cmDspAdsr file_desc:"ADSR envelope generator." kw:[sunit] }
  3190. enum
  3191. {
  3192. kTrigModeAdId,
  3193. kMinLvlAdId,
  3194. kDlyMsAdId,
  3195. kAtkMsAdId,
  3196. kAtkLvlAdId,
  3197. kDcyMsAdId,
  3198. kSusLvlAdId,
  3199. kSusMsAdId,
  3200. kRlsMsAdId,
  3201. kTScaleAdId,
  3202. kAScaleAdId,
  3203. kGateAdId,
  3204. kRmsAdId,
  3205. kOutAdId,
  3206. kCmdAdId
  3207. };
  3208. cmDspClass_t _cmAdsrDC;
  3209. typedef struct
  3210. {
  3211. cmDspInst_t inst;
  3212. cmAdsr* p;
  3213. } cmDspAdsr_t;
  3214. cmDspInst_t* _cmDspAdsrAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3215. {
  3216. cmDspAdsr_t* p = cmDspInstAllocV(cmDspAdsr_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  3217. 1, "trig", kTrigModeAdId, 0, 0, kBoolDsvFl | kInDsvFl | kOptArgDsvFl, "Trigger mode (offset ignored).",
  3218. 1, "min", kMinLvlAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Minimum level (dflt:0.0).",
  3219. 1, "dly", kDlyMsAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Delay milliseconds.",
  3220. 1, "atk", kAtkMsAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Attack milliseconds.",
  3221. 1, "alvl", kAtkLvlAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Attack Level.",
  3222. 1, "dcy", kDcyMsAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Decay milliseconds.",
  3223. 1, "sus", kSusLvlAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Sustain Level.",
  3224. 1, "hold", kSusMsAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Sustain Ms (trig mode only).",
  3225. 1, "rls", kRlsMsAdId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl, "Release milliseconds.",
  3226. 1, "tscale",kTScaleAdId, 0, 0, kDoubleDsvFl | kInDsvFl, "Time scale.",
  3227. 1, "ascale",kAScaleAdId, 0, 0, kDoubleDsvFl | kInDsvFl, "Amplitude scale.",
  3228. 1, "gate", kGateAdId, 0, 0, kBoolDsvFl | kInDsvFl, "Gate input.",
  3229. 1, "rms", kRmsAdId, 0, 0, kDoubleDsvFl | kInDsvFl, "RMS input.",
  3230. 1, "out", kOutAdId, 0, 0, kDoubleDsvFl | kOutDsvFl, "Level output.",
  3231. 1, "cmd", kCmdAdId, 0, 0, kSymDsvFl | kInDsvFl, "Command input.",
  3232. 0 );
  3233. cmDspSetDefaultBool( ctx, &p->inst, kTrigModeAdId, false, false );
  3234. cmDspSetDefaultDouble( ctx, &p->inst, kMinLvlAdId, 0.0, 0.0 );
  3235. cmDspSetDefaultDouble( ctx, &p->inst, kDlyMsAdId, 0.0, 0.0 );
  3236. cmDspSetDefaultDouble( ctx, &p->inst, kAtkMsAdId, 0.0, 5.0 );
  3237. cmDspSetDefaultDouble( ctx, &p->inst, kAtkLvlAdId, 0.0, 1.0 );
  3238. cmDspSetDefaultDouble( ctx, &p->inst, kDcyMsAdId, 0.0, 10.0 );
  3239. cmDspSetDefaultDouble( ctx, &p->inst, kSusLvlAdId, 0.0, 0.8 );
  3240. cmDspSetDefaultDouble( ctx, &p->inst, kSusMsAdId, 0.0, 50.0);
  3241. cmDspSetDefaultDouble( ctx, &p->inst, kRlsMsAdId, 0.0, 20.0 );
  3242. cmDspSetDefaultDouble( ctx, &p->inst, kTScaleAdId, 0.0, 1.0 );
  3243. cmDspSetDefaultDouble( ctx, &p->inst, kAScaleAdId, 0.0, 1.0 );
  3244. cmDspSetDefaultBool( ctx, &p->inst, kGateAdId, false,false);
  3245. cmDspSetDefaultDouble( ctx, &p->inst, kRmsAdId, 0.0, 0.0);
  3246. cmDspSetDefaultDouble( ctx, &p->inst, kOutAdId, 0.0, cmDspDouble(&p->inst,kMinLvlAdId));
  3247. p->p = cmAdsrAlloc(ctx->cmProcCtx,NULL,false,0,0,0,0,0,0,0,0,0);
  3248. return &p->inst;
  3249. }
  3250. cmDspRC_t _cmDspAdsrFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3251. {
  3252. cmDspAdsr_t* p = (cmDspAdsr_t*)inst;
  3253. cmAdsrFree(&p->p);
  3254. return kOkDspRC;
  3255. }
  3256. cmDspRC_t _cmDspAdsrReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3257. {
  3258. cmDspRC_t rc = kOkDspRC;
  3259. cmDspAdsr_t* p = (cmDspAdsr_t*)inst;
  3260. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  3261. {
  3262. bool trigFl= cmDspBool( inst, kTrigModeAdId );
  3263. cmReal_t minL = cmDspDouble( inst, kMinLvlAdId );
  3264. cmReal_t dlyMs = cmDspDouble( inst, kDlyMsAdId );
  3265. cmReal_t atkMs = cmDspDouble( inst, kAtkMsAdId );
  3266. cmReal_t atkL = cmDspDouble( inst, kAtkLvlAdId );
  3267. cmReal_t dcyMs = cmDspDouble( inst, kDcyMsAdId );
  3268. cmReal_t susMs = cmDspDouble( inst, kSusMsAdId );
  3269. cmReal_t susL = cmDspDouble( inst, kSusLvlAdId );
  3270. cmReal_t rlsMs = cmDspDouble( inst, kRlsMsAdId );
  3271. cmAdsrInit( p->p, cmDspSampleRate(ctx), trigFl, minL, dlyMs, atkMs, atkL, dcyMs, susMs, susL, rlsMs );
  3272. }
  3273. return rc;
  3274. }
  3275. cmDspRC_t _cmDspAdsrExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3276. {
  3277. cmDspRC_t rc = kOkDspRC;
  3278. cmDspAdsr_t* p = (cmDspAdsr_t*)inst;
  3279. bool gateFl = cmDspBool( inst, kGateAdId );
  3280. //double rms = cmDspDouble(inst,kRmsAdId);
  3281. double tscale = cmDspDouble(inst,kTScaleAdId);
  3282. double ascale = cmDspDouble(inst,kAScaleAdId);
  3283. //
  3284. // HACK HACK HACK HACK
  3285. // HACK HACK HACK HACK
  3286. // HACK HACK HACK HACK see the accompanying hack in cmProc3.c cmAdsrExec()
  3287. // HACK HACK HACK HACK
  3288. // HACK HACK HACK HACK
  3289. //
  3290. // double db = rms<0.00001 ? -100.0 : 20.0*log10(rms);
  3291. // double dbMax = -15.0;
  3292. // double dbMin = -58.0;
  3293. //
  3294. // db = cmMin(dbMax,cmMax(dbMin,db));
  3295. // double scale = (db - dbMin) / (dbMax-dbMin);
  3296. cmReal_t out = cmAdsrExec( p->p, cmDspSamplesPerCycle(ctx), gateFl, tscale, ascale );
  3297. rc = cmDspSetDouble( ctx, inst, kOutAdId, out );
  3298. return rc;
  3299. }
  3300. cmDspRC_t _cmDspAdsrRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3301. {
  3302. cmDspRC_t rc = kOkDspRC;
  3303. cmDspAdsr_t* p = (cmDspAdsr_t*)inst;
  3304. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  3305. return rc;
  3306. if( evt->dstVarId == kCmdAdId )
  3307. {
  3308. cmAdsrReport(p->p,ctx->rpt);
  3309. return rc;
  3310. }
  3311. cmReal_t v = cmDspDouble(inst,evt->dstVarId);
  3312. switch( evt->dstVarId )
  3313. {
  3314. case kTrigModeAdId:
  3315. p->p->trigModeFl = cmDspBool(inst, kTrigModeAdId);
  3316. break;
  3317. case kMinLvlAdId:
  3318. cmAdsrSetLevel(p->p, v, kDlyAdsrId );
  3319. break;
  3320. case kDlyMsAdId:
  3321. cmAdsrSetTime(p->p, v, kDlyAdsrId );
  3322. break;
  3323. case kAtkMsAdId:
  3324. cmAdsrSetTime(p->p, v, kAtkAdsrId );
  3325. break;
  3326. case kAtkLvlAdId:
  3327. cmAdsrSetLevel(p->p, v, kAtkAdsrId );
  3328. break;
  3329. case kDcyMsAdId:
  3330. cmAdsrSetTime(p->p, v, kDcyAdsrId );
  3331. break;
  3332. case kSusMsAdId:
  3333. cmAdsrSetTime(p->p, v, kSusAdsrId );
  3334. break;
  3335. case kSusLvlAdId:
  3336. cmAdsrSetLevel(p->p, v, kSusAdsrId );
  3337. break;
  3338. case kRlsMsAdId:
  3339. cmAdsrSetTime(p->p, v, kRlsAdsrId );
  3340. break;
  3341. }
  3342. return rc;
  3343. }
  3344. cmDspClass_t* cmAdsrClassCons( cmDspCtx_t* ctx )
  3345. {
  3346. cmDspClassSetup(&_cmAdsrDC,ctx,"Adsr",
  3347. NULL,
  3348. _cmDspAdsrAlloc,
  3349. _cmDspAdsrFree,
  3350. _cmDspAdsrReset,
  3351. _cmDspAdsrExec,
  3352. _cmDspAdsrRecv,
  3353. NULL,NULL,
  3354. "ADSR Envelope Generator");
  3355. return &_cmAdsrDC;
  3356. }
  3357. //------------------------------------------------------------------------------------------------------------
  3358. //)
  3359. //( { label:cmDspAdsr file_desc:"Audio dynamics compressor." kw:[sunit] }
  3360. enum
  3361. {
  3362. kBypassCmId,
  3363. kThreshDbCmId,
  3364. kRatioCmId,
  3365. kAtkMsCmId,
  3366. kRlsMsCmId,
  3367. kInGainCmId,
  3368. kOutGainCmId,
  3369. kWndMsCmId,
  3370. kMaxWndMsCmId,
  3371. kInCmId,
  3372. kOutCmId,
  3373. kEnvCmId
  3374. };
  3375. cmDspClass_t _cmCompressorDC;
  3376. typedef struct
  3377. {
  3378. cmDspInst_t inst;
  3379. cmCompressor* p;
  3380. } cmDspCompressor_t;
  3381. cmDspInst_t* _cmDspCompressorAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3382. {
  3383. cmDspCompressor_t* p = cmDspInstAllocV(cmDspCompressor_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  3384. 1, "bypass",kBypassCmId, 0, 0, kInDsvFl | kBoolDsvFl | kReqArgDsvFl, "Bypass enable",
  3385. 1, "thr", kThreshDbCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Threshold in dB.",
  3386. 1, "ratio", kRatioCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Ratio numerator.",
  3387. 1, "atk", kAtkMsCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Attack milliseconds",
  3388. 1, "rls", kRlsMsCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Release milliseconds",
  3389. 1, "igain", kInGainCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Input gain.",
  3390. 1, "ogain", kOutGainCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Makeup Gain",
  3391. 1, "wnd", kWndMsCmId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "RMS window milliseconds.",
  3392. 1, "maxwnd",kMaxWndMsCmId, 0, 0, kDoubleDsvFl | kOptArgDsvFl, "Max. RMS window milliseconds.",
  3393. 1, "in", kInCmId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input",
  3394. 1, "out", kOutCmId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio output",
  3395. 1, "env", kEnvCmId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Envelope out",
  3396. 0 );
  3397. p->p = cmCompressorAlloc(ctx->cmProcCtx, NULL, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, false );
  3398. cmDspSetDefaultBool( ctx, &p->inst, kBypassCmId, false, false );
  3399. cmDspSetDefaultDouble( ctx, &p->inst, kAtkMsCmId, 0.0, 20.0 );
  3400. cmDspSetDefaultDouble( ctx, &p->inst, kRlsMsCmId, 0.0, 20.0 );
  3401. cmDspSetDefaultDouble( ctx, &p->inst, kInGainCmId, 0.0, 1.0 );
  3402. cmDspSetDefaultDouble( ctx, &p->inst, kOutGainCmId, 0.0, 1.0 );
  3403. cmDspSetDefaultDouble( ctx, &p->inst, kWndMsCmId, 0.0, 200.0);
  3404. cmDspSetDefaultDouble( ctx, &p->inst, kMaxWndMsCmId, 0.0, 1000.0);
  3405. cmDspSetDefaultDouble( ctx, &p->inst, kEnvCmId, 0.0, 0.0 );
  3406. return &p->inst;
  3407. }
  3408. cmDspRC_t _cmDspCompressorFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3409. {
  3410. cmDspCompressor_t* p = (cmDspCompressor_t*)inst;
  3411. cmCompressorFree(&p->p);
  3412. return kOkDspRC;
  3413. }
  3414. cmDspRC_t _cmDspCompressorReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3415. {
  3416. cmDspRC_t rc = kOkDspRC;
  3417. cmDspCompressor_t* p = (cmDspCompressor_t*)inst;
  3418. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  3419. {
  3420. cmDspZeroAudioBuf(ctx,inst,kOutCmId);
  3421. cmReal_t threshDb = cmDspDouble(inst, kThreshDbCmId );
  3422. cmReal_t ratio = cmDspDouble(inst, kRatioCmId );
  3423. cmReal_t atkMs = cmDspDouble(inst, kAtkMsCmId );
  3424. cmReal_t rlsMs = cmDspDouble(inst, kRlsMsCmId );
  3425. cmReal_t inGain = cmDspDouble(inst, kInGainCmId );
  3426. cmReal_t outGain = cmDspDouble(inst, kOutGainCmId );
  3427. cmReal_t wndMs = cmDspDouble(inst, kWndMsCmId );
  3428. cmReal_t maxWndMs = cmDspDouble(inst, kMaxWndMsCmId);
  3429. bool bypassFl = cmDspBool( inst, kBypassCmId );
  3430. cmCompressorInit(p->p,cmDspSampleRate(ctx),cmDspSamplesPerCycle(ctx), inGain, maxWndMs, wndMs, threshDb, ratio, atkMs, rlsMs, outGain, bypassFl );
  3431. }
  3432. return rc;
  3433. }
  3434. cmDspRC_t _cmDspCompressorExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3435. {
  3436. cmDspRC_t rc = kOkDspRC;
  3437. cmDspCompressor_t* p = (cmDspCompressor_t*)inst;
  3438. cmSample_t* y = cmDspAudioBuf(ctx,inst,kOutCmId, 0);
  3439. const cmSample_t* x = cmDspAudioBuf(ctx,inst,kInCmId,0);
  3440. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutCmId,0);
  3441. if( x != NULL )
  3442. {
  3443. cmCompressorExec(p->p,x,y,n);
  3444. rc = cmDspSetDouble( ctx, inst, kEnvCmId, p->p->gain );
  3445. }
  3446. return rc;
  3447. }
  3448. cmDspRC_t _cmDspCompressorRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3449. {
  3450. cmDspRC_t rc;
  3451. cmDspCompressor_t* p = (cmDspCompressor_t*)inst;
  3452. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  3453. return rc;
  3454. cmReal_t v = cmDspDouble(inst,evt->dstVarId);
  3455. switch( evt->dstVarId )
  3456. {
  3457. case kThreshDbCmId:
  3458. cmCompressorSetThreshDb(p->p,v);
  3459. break;
  3460. case kRatioCmId:
  3461. p->p->ratio_num = v;
  3462. break;
  3463. case kAtkMsCmId:
  3464. cmCompressorSetAttackMs(p->p,v);
  3465. break;
  3466. case kRlsMsCmId:
  3467. cmCompressorSetReleaseMs(p->p,v);
  3468. break;
  3469. case kInGainCmId:
  3470. p->p->inGain = v;
  3471. break;
  3472. case kOutGainCmId:
  3473. p->p->outGain = v;
  3474. break;
  3475. case kWndMsCmId:
  3476. cmCompressorSetRmsWndMs(p->p,v);
  3477. break;
  3478. case kBypassCmId:
  3479. p->p->bypassFl = cmDspBool(inst,kBypassCmId);
  3480. break;
  3481. }
  3482. return rc;
  3483. }
  3484. cmDspClass_t* cmCompressorClassCons( cmDspCtx_t* ctx )
  3485. {
  3486. cmDspClassSetup(&_cmCompressorDC,ctx,"Compressor",
  3487. NULL,
  3488. _cmDspCompressorAlloc,
  3489. _cmDspCompressorFree,
  3490. _cmDspCompressorReset,
  3491. _cmDspCompressorExec,
  3492. _cmDspCompressorRecv,
  3493. NULL,NULL,
  3494. "Compressor");
  3495. return &_cmCompressorDC;
  3496. }
  3497. //------------------------------------------------------------------------------------------------------------
  3498. //)
  3499. //( { label:cmDspBiquad file_desc:"Programmable Biquad EQ filter." kw:[sunit] }
  3500. enum
  3501. {
  3502. kBypassBqId,
  3503. kModeBqId,
  3504. kF0HzBqId,
  3505. kQBqId,
  3506. kGainDbBqId,
  3507. kInBqId,
  3508. kOutBqId
  3509. };
  3510. cmDspClass_t _cmBiQuadEqDC;
  3511. typedef struct
  3512. {
  3513. const cmChar_t* label;
  3514. unsigned mode;
  3515. unsigned symbol;
  3516. } cmDspBiQuadMap_t;
  3517. cmDspBiQuadMap_t _cmDspBiQuadMap[] =
  3518. {
  3519. {"LP", kLpfBqId, cmInvalidId },
  3520. {"HP", kHpFBqId, cmInvalidId },
  3521. {"BP", kBpfBqId, cmInvalidId },
  3522. {"Notch", kNotchBqId, cmInvalidId },
  3523. {"AP", kAllpassBqId, cmInvalidId },
  3524. {"Peak", kPeakBqId, cmInvalidId },
  3525. {"LSh", kLowShelfBqId, cmInvalidId },
  3526. {"HSh", kHighShelfBqId, cmInvalidId },
  3527. { NULL, cmInvalidId, cmInvalidId }
  3528. };
  3529. typedef struct
  3530. {
  3531. cmDspInst_t inst;
  3532. cmBiQuadEq* p;
  3533. } cmDspBiQuadEq_t;
  3534. cmDspInst_t* _cmDspBiQuadEqAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3535. {
  3536. cmDspBiQuadEq_t* p = cmDspInstAllocV(cmDspBiQuadEq_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  3537. 1, "bypass",kBypassBqId, 0, 0, kInDsvFl | kBoolDsvFl | kReqArgDsvFl, "Bypass enable.",
  3538. 1, "mode", kModeBqId, 0, 0, kInDsvFl | kSymDsvFl | kReqArgDsvFl, "Mode Symbol: LP|HP|BP|AP|Notch|Pk|LSh|HSh.",
  3539. 1, "f0", kF0HzBqId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Center or edge frequecy in Hz.",
  3540. 1, "Q", kQBqId, 0, 0, kInDsvFl | kDoubleDsvFl | kReqArgDsvFl, "Q",
  3541. 1, "gain", kGainDbBqId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Gain Db (Pk,LSh,Hsh only)",
  3542. 1, "in", kInBqId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input",
  3543. 1, "out", kOutBqId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio output",
  3544. 0 );
  3545. cmDspSetDefaultDouble( ctx, &p->inst, kGainDbBqId, 0.0, 1.0 );
  3546. p->p = cmBiQuadEqAlloc(ctx->cmProcCtx,NULL,0,0,0,0,0,false);
  3547. // register the filter mode symbols
  3548. unsigned i;
  3549. for(i=0; _cmDspBiQuadMap[i].label != NULL; ++i)
  3550. if( _cmDspBiQuadMap[i].symbol == cmInvalidId )
  3551. _cmDspBiQuadMap[i].symbol = cmSymTblRegisterStaticSymbol(ctx->stH,_cmDspBiQuadMap[i].label);
  3552. return &p->inst;
  3553. }
  3554. cmDspRC_t _cmDspBiQuadEqFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3555. {
  3556. cmDspBiQuadEq_t* p = (cmDspBiQuadEq_t*)inst;
  3557. cmBiQuadEqFree(&p->p);
  3558. return kOkDspRC;
  3559. }
  3560. unsigned _cmDspBiQuadEqModeId( cmDspCtx_t* ctx, cmDspInst_t* inst, unsigned modeSymId )
  3561. {
  3562. unsigned i;
  3563. for(i=0; _cmDspBiQuadMap[i].label!=NULL; ++i)
  3564. if( _cmDspBiQuadMap[i].symbol == modeSymId )
  3565. return _cmDspBiQuadMap[i].mode;
  3566. cmDspInstErr(ctx,inst,kVarNotValidDspRC,"The mode string '%s' is not valid.",cmStringNullGuard(cmSymTblLabel(ctx->stH,modeSymId)));
  3567. return cmInvalidId;
  3568. }
  3569. cmDspRC_t _cmDspBiQuadEqReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3570. {
  3571. cmDspRC_t rc = kOkDspRC;
  3572. cmDspBiQuadEq_t* p = (cmDspBiQuadEq_t*)inst;
  3573. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  3574. {
  3575. cmDspZeroAudioBuf(ctx,inst,kOutBqId);
  3576. unsigned modeSymId = cmDspSymbol(inst, kModeBqId );
  3577. cmReal_t f0Hz = cmDspDouble(inst, kF0HzBqId );
  3578. cmReal_t Q = cmDspDouble(inst, kQBqId );
  3579. cmReal_t gainDb = cmDspDouble(inst, kGainDbBqId );
  3580. unsigned mode = _cmDspBiQuadEqModeId(ctx,inst,modeSymId );
  3581. bool bypassFl = cmDspBool(inst, kBypassBqId );
  3582. if( mode != cmInvalidId )
  3583. cmBiQuadEqInit(p->p, cmDspSampleRate(ctx), mode, f0Hz, Q, gainDb, bypassFl );
  3584. }
  3585. return rc;
  3586. }
  3587. cmDspRC_t _cmDspBiQuadEqExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3588. {
  3589. cmDspRC_t rc = kOkDspRC;
  3590. cmDspBiQuadEq_t* p = (cmDspBiQuadEq_t*)inst;
  3591. cmSample_t* y = cmDspAudioBuf(ctx,inst,kOutBqId, 0);
  3592. const cmSample_t* x = cmDspAudioBuf(ctx,inst,kInBqId,0);
  3593. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutBqId,0);
  3594. cmBiQuadEqExec(p->p,x,y,n);
  3595. return rc;
  3596. }
  3597. cmDspRC_t _cmDspBiQuadEqRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3598. {
  3599. cmDspRC_t rc;
  3600. cmDspBiQuadEq_t* p = (cmDspBiQuadEq_t*)inst;
  3601. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  3602. return rc;
  3603. cmReal_t f0Hz = p->p->f0Hz;
  3604. cmReal_t Q = p->p->Q;
  3605. cmReal_t gainDb = p->p->gainDb;
  3606. unsigned mode = p->p->mode;
  3607. if( evt->dstVarId == kModeBqId )
  3608. {
  3609. if((mode = _cmDspBiQuadEqModeId(ctx,inst,cmDspSymbol(inst,kModeBqId) )) == cmInvalidId )
  3610. rc = kVarNotValidDspRC;
  3611. }
  3612. else
  3613. {
  3614. cmReal_t v = cmDspDouble(inst,evt->dstVarId);
  3615. switch( evt->dstVarId )
  3616. {
  3617. case kF0HzBqId:
  3618. f0Hz = v;
  3619. break;
  3620. case kQBqId:
  3621. Q = v;
  3622. break;
  3623. case kGainDbBqId:
  3624. gainDb = v;
  3625. break;
  3626. case kBypassBqId:
  3627. p->p->bypassFl = cmDspBool(inst,kBypassBqId);
  3628. break;
  3629. }
  3630. }
  3631. cmBiQuadEqSet(p->p,mode,f0Hz,Q,gainDb);
  3632. return rc;
  3633. }
  3634. cmDspClass_t* cmBiQuadEqClassCons( cmDspCtx_t* ctx )
  3635. {
  3636. cmDspClassSetup(&_cmBiQuadEqDC,ctx,"BiQuadEq",
  3637. NULL,
  3638. _cmDspBiQuadEqAlloc,
  3639. _cmDspBiQuadEqFree,
  3640. _cmDspBiQuadEqReset,
  3641. _cmDspBiQuadEqExec,
  3642. _cmDspBiQuadEqRecv,
  3643. NULL,NULL,
  3644. "Bi-Quad EQ Filters");
  3645. return &_cmBiQuadEqDC;
  3646. }
  3647. //------------------------------------------------------------------------------------------------------------
  3648. //)
  3649. //( { label:cmDspDistDs file_desc:"Guitar style distortion effect." kw:[sunit] }
  3650. enum
  3651. {
  3652. kBypassDsId,
  3653. kInGainDsId,
  3654. kSrateDsId,
  3655. kBitsDsId,
  3656. kRectDsId,
  3657. kFullDsId,
  3658. kClipDbDsId,
  3659. kOutGainDsId,
  3660. kInDsId,
  3661. kOutDsId
  3662. };
  3663. cmDspClass_t _cmDistDsDC;
  3664. typedef struct
  3665. {
  3666. cmDspInst_t inst;
  3667. cmDistDs* p;
  3668. } cmDspDistDs_t;
  3669. cmDspInst_t* _cmDspDistDsAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3670. {
  3671. cmDspDistDs_t* p = cmDspInstAllocV(cmDspDistDs_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  3672. 1, "bypass", kBypassDsId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Bypass enable.",
  3673. 1, "igain", kInGainDsId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Input gain.",
  3674. 1, "srate", kSrateDsId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Down-sample rate.",
  3675. 1, "bits", kBitsDsId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Bits per sample",
  3676. 1, "rect", kRectDsId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Rectify flag",
  3677. 1, "full", kFullDsId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "1=Full 0=Half rectify",
  3678. 1, "clip", kClipDbDsId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Clip dB",
  3679. 1, "ogain", kOutGainDsId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Output gain",
  3680. 1, "in", kInDsId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio input",
  3681. 1, "out", kOutDsId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio output",
  3682. 0 );
  3683. cmDspSetDefaultBool( ctx, &p->inst, kBypassDsId, false, false );
  3684. cmDspSetDefaultDouble( ctx, &p->inst, kInGainDsId, 0.0, 1.0 );
  3685. cmDspSetDefaultDouble( ctx, &p->inst, kSrateDsId, 0.0, cmDspSampleRate(ctx));
  3686. cmDspSetDefaultDouble( ctx, &p->inst, kBitsDsId, 0.0, 24.0 );
  3687. cmDspSetDefaultBool( ctx, &p->inst, kRectDsId, false, false );
  3688. cmDspSetDefaultBool( ctx, &p->inst, kFullDsId, false, false );
  3689. cmDspSetDefaultDouble( ctx, &p->inst, kClipDbDsId, 0.0, 0.0 );
  3690. cmDspSetDefaultDouble( ctx, &p->inst, kOutGainDsId, 0.0, 1.0 );
  3691. p->p = cmDistDsAlloc(ctx->cmProcCtx, NULL, 0, 0, 0, 0, false, false, 0, 0, false );
  3692. return &p->inst;
  3693. }
  3694. cmDspRC_t _cmDspDistDsFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3695. {
  3696. cmDspDistDs_t* p = (cmDspDistDs_t*)inst;
  3697. cmDistDsFree(&p->p);
  3698. return kOkDspRC;
  3699. }
  3700. cmDspRC_t _cmDspDistDsReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3701. {
  3702. cmDspRC_t rc = kOkDspRC;
  3703. cmDspDistDs_t* p = (cmDspDistDs_t*)inst;
  3704. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  3705. {
  3706. cmDspZeroAudioBuf(ctx,inst,kOutDsId);
  3707. bool bypassFl = cmDspBool( inst, kBypassDsId );
  3708. cmReal_t inGain = cmDspDouble( inst, kInGainDsId );
  3709. cmReal_t downSrate = cmDspDouble( inst, kSrateDsId );
  3710. cmReal_t bits = cmDspDouble( inst, kBitsDsId );
  3711. bool rectFl = cmDspBool( inst, kRectDsId );
  3712. bool fullFl = cmDspBool( inst, kFullDsId );
  3713. cmReal_t clipDb = cmDspDouble( inst, kClipDbDsId );
  3714. cmReal_t outGain = cmDspDouble( inst, kOutGainDsId );
  3715. cmDistDsInit(p->p, cmDspSampleRate(ctx), inGain, downSrate, bits, rectFl, fullFl, clipDb, outGain, bypassFl );
  3716. }
  3717. return rc;
  3718. }
  3719. cmDspRC_t _cmDspDistDsExec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3720. {
  3721. cmDspRC_t rc = kOkDspRC;
  3722. cmDspDistDs_t* p = (cmDspDistDs_t*)inst;
  3723. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutDsId,0);
  3724. cmSample_t* y = cmDspAudioBuf(ctx,inst,kOutDsId,0);
  3725. const cmSample_t* x = cmDspAudioBuf(ctx,inst,kInDsId,0);
  3726. cmDistDsExec(p->p,x,y,n);
  3727. return rc;
  3728. }
  3729. cmDspRC_t _cmDspDistDsRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3730. {
  3731. cmDspRC_t rc = kOkDspRC;
  3732. cmDspDistDs_t* p = (cmDspDistDs_t*)inst;
  3733. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  3734. {
  3735. switch( evt->dstVarId )
  3736. {
  3737. case kInGainDsId:
  3738. p->p->inGain = cmDspDouble(inst,kInGainDsId);
  3739. break;
  3740. case kSrateDsId:
  3741. p->p->downSrate = cmDspDouble(inst,kSrateDsId);
  3742. break;
  3743. case kBitsDsId:
  3744. p->p->bits = cmDspDouble(inst,kBitsDsId);
  3745. break;
  3746. case kRectDsId:
  3747. p->p->rectFl = cmDspBool(inst,kRectDsId);
  3748. break;
  3749. case kFullDsId:
  3750. p->p->fullFl = cmDspBool(inst,kFullDsId);
  3751. break;
  3752. case kClipDbDsId:
  3753. p->p->clipDb = cmDspDouble(inst,kClipDbDsId);
  3754. break;
  3755. case kOutGainDsId:
  3756. p->p->outGain = cmDspDouble(inst,kOutGainDsId);
  3757. break;
  3758. case kBypassDsId:
  3759. p->p->bypassFl = cmDspBool(inst,kBypassDsId);
  3760. break;
  3761. }
  3762. }
  3763. return rc;
  3764. }
  3765. cmDspClass_t* cmDistDsClassCons( cmDspCtx_t* ctx )
  3766. {
  3767. cmDspClassSetup(&_cmDistDsDC,ctx,"DistDs",
  3768. NULL,
  3769. _cmDspDistDsAlloc,
  3770. _cmDspDistDsFree,
  3771. _cmDspDistDsReset,
  3772. _cmDspDistDsExec,
  3773. _cmDspDistDsRecv,
  3774. NULL,NULL,
  3775. "Distortion and Downsampler");
  3776. return &_cmDistDsDC;
  3777. }
  3778. //------------------------------------------------------------------------------------------------------------
  3779. //)
  3780. //( { label:cmDspDbToLin file_desc:"Convert decibel units to linear units." kw:[sunit] }
  3781. enum
  3782. {
  3783. kInDlId,
  3784. kOutDlId
  3785. };
  3786. cmDspClass_t _cmDbToLinDC;
  3787. typedef struct
  3788. {
  3789. cmDspInst_t inst;
  3790. } cmDspDbToLin_t;
  3791. cmDspInst_t* _cmDspDbToLinAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3792. {
  3793. cmDspDbToLin_t* p = cmDspInstAllocV(cmDspDbToLin_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  3794. 1, "in", kInDlId, 0, 0, kInDsvFl | kDoubleDsvFl, "Input",
  3795. 1, "out", kOutDlId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Output",
  3796. 0 );
  3797. cmDspSetDefaultDouble( ctx, &p->inst, kInDlId, 0.0, -1000.0);
  3798. cmDspSetDefaultDouble( ctx, &p->inst, kOutDlId, 0.0, 0.0 );
  3799. return &p->inst;
  3800. }
  3801. cmDspRC_t _cmDspDbToLinReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3802. {
  3803. return cmDspApplyAllDefaults(ctx,inst);
  3804. }
  3805. cmDspRC_t _cmDspDbToLinRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3806. {
  3807. cmDspRC_t rc = kOkDspRC;
  3808. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  3809. {
  3810. if( evt->dstVarId == kInDlId )
  3811. {
  3812. double db = cmMax(0.0,cmMin(100.0,cmDspDouble(inst,kInDlId)));
  3813. double lin = db==0 ? 0.0 : pow(10.0, (db-100.0)/20.0);
  3814. cmDspSetDouble(ctx,inst,kOutDlId,lin);
  3815. }
  3816. }
  3817. return rc;
  3818. }
  3819. cmDspClass_t* cmDbToLinClassCons( cmDspCtx_t* ctx )
  3820. {
  3821. cmDspClassSetup(&_cmDbToLinDC,ctx,"DbToLin",
  3822. NULL,
  3823. _cmDspDbToLinAlloc,
  3824. NULL,
  3825. _cmDspDbToLinReset,
  3826. NULL,
  3827. _cmDspDbToLinRecv,
  3828. NULL,NULL,
  3829. "dB to Linear converter");
  3830. return &_cmDbToLinDC;
  3831. }
  3832. //------------------------------------------------------------------------------------------------------------
  3833. //)
  3834. //( { label:cmDspNofM2 file_desc:"Pass an N of M possible inputs to the output." kw:[sunit] }
  3835. // Pass any N of M inputs
  3836. enum
  3837. {
  3838. kInChCntNoId,
  3839. kOutChCntNoId,
  3840. kXfadeMsNoId,
  3841. kCmdNoId,
  3842. kSelIdxNoId,
  3843. kBaseGateNoId
  3844. };
  3845. cmDspClass_t _cmNofM_DC;
  3846. typedef struct
  3847. {
  3848. cmDspInst_t inst;
  3849. unsigned iChCnt;
  3850. unsigned oChCnt;
  3851. unsigned* map; // map[ oChCnt ]
  3852. cmXfader** xf; // xf[ oChCnt ];
  3853. unsigned cfgSymId;
  3854. unsigned onSymId;
  3855. unsigned offSymId;
  3856. bool verboseFl;
  3857. unsigned baseBaseInNoId; // first data input port id
  3858. unsigned baseBaseOutNoId; // first data output port id
  3859. unsigned baseInFloatNoId;
  3860. unsigned baseInBoolNoId;
  3861. unsigned baseInSymNoId;
  3862. unsigned baseInAudioNoId;
  3863. unsigned baseOutFloatNoId;
  3864. unsigned baseOutBoolNoId;
  3865. unsigned baseOutSymNoId;
  3866. unsigned baseOutAudioNoId;
  3867. bool printFl;
  3868. } cmDspNofM_t;
  3869. cmDspInst_t* _cmDspNofM_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  3870. {
  3871. if( va_cnt < 2 )
  3872. {
  3873. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'NofM' constructor must given input and output channel counts.");
  3874. return NULL;
  3875. }
  3876. va_list vl1;
  3877. va_copy(vl1,vl);
  3878. int iChCnt = va_arg(vl,int);
  3879. int oChCnt = va_arg(vl,int);
  3880. if( oChCnt > iChCnt )
  3881. {
  3882. va_end(vl1);
  3883. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'NofM' output count must be less than or equal to the input count.");
  3884. return NULL;
  3885. }
  3886. unsigned baseInFloatNoId = kBaseGateNoId + iChCnt;
  3887. unsigned baseInBoolNoId = baseInFloatNoId + iChCnt;
  3888. unsigned baseInSymNoId = baseInBoolNoId + iChCnt;
  3889. unsigned baseInAudioNoId = baseInSymNoId + iChCnt;
  3890. unsigned baseOutFloatNoId = baseInAudioNoId + iChCnt;
  3891. unsigned baseOutBoolNoId = baseOutFloatNoId + oChCnt;
  3892. unsigned baseOutSymNoId = baseOutBoolNoId + oChCnt;
  3893. unsigned baseOutAudioNoId = baseOutSymNoId + oChCnt;
  3894. unsigned i;
  3895. cmDspNofM_t* p = cmDspInstAllocV(cmDspNofM_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  3896. 1, "ichs", kInChCntNoId, 0, 0, kUIntDsvFl | kReqArgDsvFl,"Input channel count.",
  3897. 1, "ochs", kOutChCntNoId, 0, 0, kUIntDsvFl | kReqArgDsvFl,"Output channel count.",
  3898. 1, "ms", kXfadeMsNoId, 0, 0, kDoubleDsvFl | kInDsvFl | kOptArgDsvFl,"Audio Cross-fade time in milliseconds.",
  3899. 1, "cmd", kCmdNoId, 0, 0, kSymDsvFl | kInDsvFl, "Command input.",
  3900. 1, "seli", kSelIdxNoId, 0, 0, kUIntDsvFl | kInDsvFl, "Enable gate at index.",
  3901. iChCnt, "sel", kBaseGateNoId, 0, 0, kBoolDsvFl | kInDsvFl, "Selector Gate inputs.",
  3902. iChCnt, "f-in", baseInFloatNoId, 0, 0, kDoubleDsvFl | kInDsvFl, "Float input",
  3903. iChCnt, "b-in", baseInBoolNoId, 0, 0, kBoolDsvFl | kInDsvFl, "Bool input",
  3904. iChCnt, "s-in", baseInSymNoId, 0, 0, kSymDsvFl | kInDsvFl, "Symbol input",
  3905. iChCnt, "a-in", baseInAudioNoId, 0, 0, kAudioBufDsvFl | kInDsvFl, "Audio input",
  3906. oChCnt, "f-out", baseOutFloatNoId, 0, 0, kDoubleDsvFl | kOutDsvFl, "Float output",
  3907. oChCnt, "b-out", baseOutBoolNoId, 0, 0, kBoolDsvFl | kOutDsvFl, "Bool output",
  3908. oChCnt, "s-out", baseOutSymNoId, 0, 0, kSymDsvFl | kOutDsvFl, "Symbol output",
  3909. oChCnt, "a-out", baseOutAudioNoId, 0, 1, kAudioBufDsvFl | kOutDsvFl, "Audio output",
  3910. 0 );
  3911. p->iChCnt = iChCnt;
  3912. p->oChCnt = oChCnt;
  3913. p->map = cmMemAllocZ(unsigned,oChCnt);
  3914. p->xf = cmMemAllocZ(cmXfader*,oChCnt);
  3915. p->cfgSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"cfg");
  3916. p->onSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"on");
  3917. p->offSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"off");
  3918. p->verboseFl = false;
  3919. p->baseBaseInNoId = baseInFloatNoId;
  3920. p->baseBaseOutNoId = baseOutFloatNoId;
  3921. p->baseInFloatNoId = baseInFloatNoId;
  3922. p->baseInBoolNoId = baseInBoolNoId;
  3923. p->baseInSymNoId = baseInSymNoId;
  3924. p->baseInAudioNoId = baseInAudioNoId;
  3925. p->baseOutFloatNoId = baseOutFloatNoId;
  3926. p->baseOutBoolNoId = baseOutBoolNoId;
  3927. p->baseOutSymNoId = baseOutSymNoId;
  3928. p->baseOutAudioNoId = baseOutAudioNoId;
  3929. for(i=0; i<oChCnt; ++i)
  3930. {
  3931. cmDspSetDefaultDouble( ctx, &p->inst, baseOutFloatNoId + i, 0.0, 0.0 );
  3932. cmDspSetDefaultBool( ctx, &p->inst, baseOutBoolNoId + i, false, false );
  3933. cmDspSetDefaultSymbol( ctx, &p->inst, baseOutSymNoId + i, cmInvalidId );
  3934. p->xf[i] = cmXfaderAlloc( ctx->cmProcCtx, NULL, 0, 0, 0 );
  3935. }
  3936. cmDspSetDefaultDouble( ctx, &p->inst, kXfadeMsNoId, 0.0, 15.0 );
  3937. va_end(vl1);
  3938. return &p->inst;
  3939. }
  3940. cmDspRC_t _cmDspNofM_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3941. {
  3942. cmDspNofM_t* p = (cmDspNofM_t*)inst;
  3943. unsigned i;
  3944. for(i=0; i<p->oChCnt; ++i)
  3945. cmXfaderFree(&p->xf[i]);
  3946. cmMemFree(p->map);
  3947. cmMemFree(p->xf);
  3948. return kOkDspRC;
  3949. }
  3950. cmDspRC_t _cmDspNofM_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3951. {
  3952. cmDspRC_t rc = kOkDspRC;
  3953. cmDspNofM_t* p = (cmDspNofM_t*)inst;
  3954. unsigned i;
  3955. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  3956. {
  3957. for(i=0; i<p->oChCnt; ++i)
  3958. {
  3959. cmDspZeroAudioBuf(ctx,inst,p->baseOutAudioNoId+i);
  3960. p->map[i] = cmInvalidIdx;
  3961. double xfadeMs = cmDspDouble(inst,kXfadeMsNoId);
  3962. cmXfaderInit(p->xf[i], cmDspSampleRate(ctx), p->iChCnt, xfadeMs );
  3963. }
  3964. }
  3965. return rc;
  3966. }
  3967. cmDspRC_t _cmDspNofM_Exec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3968. {
  3969. cmDspRC_t rc = kOkDspRC;
  3970. cmDspNofM_t* p = (cmDspNofM_t*)inst;
  3971. unsigned i;
  3972. const cmSample_t* x[ p->iChCnt ];
  3973. for(i=0; i<p->iChCnt; ++i)
  3974. x[i] = cmDspAudioBuf(ctx,inst,p->baseInAudioNoId + i ,0);
  3975. // for each valid p->map[] element
  3976. for(i=0; i<p->oChCnt; ++i)
  3977. {
  3978. cmSample_t* y = cmDspAudioBuf(ctx,inst,p->baseOutAudioNoId+ i,0);
  3979. unsigned n = cmDspAudioBufSmpCount(ctx,inst,p->baseOutAudioNoId+i,0);
  3980. if( y != NULL )
  3981. {
  3982. y = cmVOS_Zero(y,n);
  3983. cmXfaderExecAudio(p->xf[i],n,NULL,p->iChCnt,x,y);
  3984. }
  3985. }
  3986. return rc;
  3987. }
  3988. cmDspRC_t _cmDspNofM_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  3989. {
  3990. cmDspRC_t rc = kOkDspRC;
  3991. cmDspNofM_t* p = (cmDspNofM_t*)inst;
  3992. unsigned i,j;
  3993. assert( evt->dstVarId < p->baseBaseOutNoId );
  3994. // store the incoming value
  3995. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  3996. return rc;
  3997. // if this is a fade time
  3998. if( evt->dstVarId == kXfadeMsNoId )
  3999. {
  4000. for(i=0; i<p->oChCnt; ++i)
  4001. cmXfaderSetXfadeTime( p->xf[i], cmDspDouble(inst,kXfadeMsNoId) );
  4002. return rc;
  4003. }
  4004. // if this is an index selector
  4005. if( kSelIdxNoId == evt->dstVarId )
  4006. {
  4007. unsigned idx;
  4008. if((idx = cmDspUInt(inst,kSelIdxNoId)) >= p->iChCnt )
  4009. rc = cmDspInstErr(ctx,inst,kInvalidArgDspRC,"The selection index ('%i') is out of the channel range, (%i).",idx,p->iChCnt);
  4010. else
  4011. {
  4012. cmDspSetBool( ctx, inst, kBaseGateNoId+idx , true );
  4013. if( p->verboseFl )
  4014. cmRptPrintf(ctx->rpt,"nom seli:%i\n",idx);
  4015. }
  4016. return rc;
  4017. }
  4018. // NOTE: the internal state DOES NOT CHANGE until a message arrives
  4019. // on the 'cmd' port
  4020. // if anything arrives on the command port - then read the gate states and rebuild the map
  4021. if( evt->dstVarId == kCmdNoId )
  4022. {
  4023. unsigned cmdSymId = cmDspSymbol(inst,kCmdNoId);
  4024. // if cmdSymId == 'on' then turn on all selection gates
  4025. if(cmdSymId == p->onSymId )
  4026. {
  4027. for(i=0; i<p->oChCnt; ++i)
  4028. cmDspSetBool(ctx,inst,kBaseGateNoId+i,true);
  4029. }
  4030. else
  4031. // if cmdSymId == 'off' then turn off all selection gates
  4032. if( cmdSymId == p->offSymId )
  4033. {
  4034. if( p->verboseFl )
  4035. cmRptPrintf(ctx->rpt,"nom: off\n");
  4036. for(i=0; i<p->oChCnt; ++i)
  4037. cmDspSetBool(ctx,inst,kBaseGateNoId+i,false);
  4038. }
  4039. else
  4040. // cmdSymId == 'print' then print the in/out map[]
  4041. if( cmdSymId == cmSymTblId(ctx->stH,"print") )
  4042. {
  4043. for(i=0; i<p->oChCnt; ++i)
  4044. cmRptPrintf(ctx->rpt,"%i:%i ",i,p->map[i]);
  4045. cmRptPrintf(ctx->rpt,"\n");
  4046. cmRptPrintf(ctx->rpt,"%i usecs\n",ctx->execDurUsecs);
  4047. p->printFl = !p->printFl;
  4048. }
  4049. if( p->verboseFl )
  4050. cmRptPrintf(ctx->rpt,"Nom: %s ", inst->symId != cmInvalidId ? cmSymTblLabel(ctx->stH,inst->symId) : "");
  4051. // 5/26
  4052. if( p->iChCnt == p->oChCnt )
  4053. cmVOU_Fill(p->map,p->oChCnt,cmInvalidIdx);
  4054. // for each input
  4055. for(i=0,j=0; i<p->iChCnt; ++i)
  4056. {
  4057. // if this input is switched on
  4058. if( cmDspBool(inst,kBaseGateNoId+i) )
  4059. {
  4060. if( j >= p->oChCnt )
  4061. {
  4062. cmDspInstErr(ctx,inst,kVarNotValidDspRC,"To many inputs have been turned on for %i outputs.",p->oChCnt);
  4063. break;
  4064. }
  4065. // assign input i to output j
  4066. p->map[j] = i;
  4067. // fade in ch i and fade out all others
  4068. cmXfaderSelectOne(p->xf[j],i);
  4069. ++j;
  4070. if( p->verboseFl )
  4071. cmRptPrintf(ctx->rpt,"%i ",i);
  4072. }
  4073. else // 5/26
  4074. {
  4075. if( p->iChCnt == p->oChCnt )
  4076. ++j;
  4077. }
  4078. }
  4079. // deselect all other output channels
  4080. //for(; j<p->oChCnt; ++j)
  4081. //{
  4082. // p->map[j] = cmInvalidIdx;
  4083. // cmXfaderAllOff(p->xf[j]);
  4084. //}
  4085. // 5/26
  4086. if( p->iChCnt == p->oChCnt )
  4087. {
  4088. for(j=0; j<p->oChCnt; ++j)
  4089. if( p->map[j] == cmInvalidIdx )
  4090. cmXfaderAllOff(p->xf[j]);
  4091. }
  4092. else
  4093. {
  4094. for(; j<p->oChCnt; ++j)
  4095. {
  4096. p->map[j] = cmInvalidIdx;
  4097. cmXfaderAllOff(p->xf[j]);
  4098. }
  4099. }
  4100. if( p->verboseFl )
  4101. cmRptPrintf(ctx->rpt,"\n");
  4102. // zero the audio buffers of unused output channels
  4103. for(i=0; i<p->oChCnt; ++i)
  4104. if( p->map[i] == cmInvalidIdx )
  4105. cmDspZeroAudioBuf(ctx,inst,p->baseOutAudioNoId+i);
  4106. }
  4107. // if this is an input data event
  4108. if( p->baseBaseInNoId <= evt->dstVarId && evt->dstVarId < p->baseBaseOutNoId )
  4109. {
  4110. // get the input channel this event occurred on
  4111. unsigned iChIdx = (evt->dstVarId - p->baseBaseInNoId) % p->iChCnt;
  4112. // is iChIdx mapped to an output ...
  4113. for(i=0; i<p->oChCnt; ++i)
  4114. if( p->map[i] == iChIdx )
  4115. break;
  4116. // ... no - nothing else to do
  4117. if( i==p->oChCnt )
  4118. return kOkDspRC;
  4119. // ... yes set the output ...
  4120. // double
  4121. if( p->baseInFloatNoId <= evt->dstVarId && evt->dstVarId < p->baseInFloatNoId + p->iChCnt )
  4122. {
  4123. cmDspSetDouble(ctx,inst,p->baseOutFloatNoId + i, cmDspDouble(inst,evt->dstVarId));
  4124. }
  4125. else
  4126. // bool
  4127. if( p->baseInBoolNoId <= evt->dstVarId && evt->dstVarId < p->baseInBoolNoId + p->iChCnt )
  4128. {
  4129. cmDspSetBool(ctx,inst,p->baseOutBoolNoId + i, cmDspBool(inst,evt->dstVarId));
  4130. if(p->printFl)
  4131. cmRptPrintf(ctx->rpt,"%i %i\n",p->baseOutBoolNoId + i, cmDspBool(inst,evt->dstVarId));
  4132. }
  4133. else
  4134. // symbol
  4135. if( p->baseInSymNoId <= evt->dstVarId && evt->dstVarId < p->baseInSymNoId + p->iChCnt )
  4136. cmDspSetSymbol(ctx,inst,p->baseOutSymNoId + i, cmDspSymbol(inst,evt->dstVarId));
  4137. }
  4138. return rc;
  4139. }
  4140. cmDspClass_t* cmNofMClassCons( cmDspCtx_t* ctx )
  4141. {
  4142. cmDspClassSetup(&_cmNofM_DC,ctx,"NofM",
  4143. NULL,
  4144. _cmDspNofM_Alloc,
  4145. _cmDspNofM_Free,
  4146. _cmDspNofM_Reset,
  4147. _cmDspNofM_Exec,
  4148. _cmDspNofM_Recv,
  4149. NULL,NULL,
  4150. "N of M Switch");
  4151. return &_cmNofM_DC;
  4152. }
  4153. //------------------------------------------------------------------------------------------------------------
  4154. //)
  4155. //( { label:cmDsp1ofN file_desc:"Pass 1 or N possible inputs to the output." kw:[sunit] }
  4156. enum
  4157. {
  4158. kInChCnt1oId,
  4159. kInChIdx1oId,
  4160. kOutFloat1oId,
  4161. kOutBool1oId,
  4162. kOutSym1oId,
  4163. kOutAudio1oId,
  4164. kBaseInFloat1oId
  4165. };
  4166. cmDspClass_t _cm1ofN_DC;
  4167. typedef struct
  4168. {
  4169. cmDspInst_t inst;
  4170. unsigned iChCnt;
  4171. unsigned oChCnt;
  4172. unsigned iChIdx;
  4173. unsigned baseBaseIn1oId; // first data input port id
  4174. unsigned baseInFloat1oId;
  4175. unsigned baseInBool1oId;
  4176. unsigned baseInSym1oId;
  4177. unsigned baseInAudio1oId;
  4178. unsigned baseOutFloat1oId;
  4179. unsigned baseOutBool1oId;
  4180. unsigned baseOutSym1oId;
  4181. unsigned baseOutAudio1oId;
  4182. } cmDsp1ofN_t;
  4183. cmDspInst_t* _cmDsp1ofN_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  4184. {
  4185. if( va_cnt < 1 )
  4186. {
  4187. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The '1ofN' constructor must given input channel count.");
  4188. return NULL;
  4189. }
  4190. va_list vl1;
  4191. va_copy(vl1,vl);
  4192. int iChCnt = va_arg(vl,int);
  4193. unsigned baseInFloat1oId = kBaseInFloat1oId;
  4194. unsigned baseInBool1oId = baseInFloat1oId + iChCnt;
  4195. unsigned baseInSym1oId = baseInBool1oId + iChCnt;
  4196. unsigned baseInAudio1oId = baseInSym1oId + iChCnt;
  4197. cmDsp1ofN_t* p = cmDspInstAllocV(cmDsp1ofN_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  4198. 1, "ichs", kInChCnt1oId, 0, 0, kUIntDsvFl | kReqArgDsvFl,"Input channel count.",
  4199. 1, "chidx", kInChIdx1oId, 0, 0, kUIntDsvFl | kReqArgDsvFl | kInDsvFl, "Input channel selector index.",
  4200. 1, "f-out", kOutFloat1oId, 0, 0, kDoubleDsvFl | kOutDsvFl, "Float output",
  4201. 1, "b-out", kOutBool1oId, 0, 0, kBoolDsvFl | kOutDsvFl, "Bool output",
  4202. 1, "s-out", kOutSym1oId, 0, 0, kSymDsvFl | kOutDsvFl, "Symbol output",
  4203. 1, "a-out", kOutAudio1oId, 0, 1, kAudioBufDsvFl | kOutDsvFl, "Audio output",
  4204. iChCnt, "f-in", baseInFloat1oId, 0, 0, kDoubleDsvFl | kInDsvFl, "Float input",
  4205. iChCnt, "b-in", baseInBool1oId, 0, 0, kBoolDsvFl | kInDsvFl, "Bool input",
  4206. iChCnt, "s-in", baseInSym1oId, 0, 0, kSymDsvFl | kInDsvFl, "Symbol input",
  4207. iChCnt, "a-in", baseInAudio1oId, 0, 0, kAudioBufDsvFl | kInDsvFl, "Audio input",
  4208. 0 );
  4209. p->iChCnt = iChCnt;
  4210. p->baseBaseIn1oId = kBaseInFloat1oId;
  4211. p->baseInFloat1oId = baseInFloat1oId;
  4212. p->baseInBool1oId = baseInBool1oId;
  4213. p->baseInSym1oId = baseInSym1oId;
  4214. p->baseInAudio1oId = baseInAudio1oId;
  4215. cmDspSetDefaultDouble( ctx, &p->inst, kOutFloat1oId, 0.0, 0.0 );
  4216. cmDspSetDefaultBool( ctx, &p->inst, kOutBool1oId, false, false );
  4217. cmDspSetDefaultSymbol( ctx, &p->inst, kOutSym1oId, cmInvalidId );
  4218. va_end(vl1);
  4219. return &p->inst;
  4220. }
  4221. cmDspRC_t _cmDsp1ofN_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4222. {
  4223. return kOkDspRC;
  4224. }
  4225. cmDspRC_t _cmDsp1ofN_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4226. {
  4227. cmDspRC_t rc = kOkDspRC;
  4228. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  4229. {
  4230. cmDspZeroAudioBuf(ctx,inst,kOutAudio1oId);
  4231. }
  4232. return rc;
  4233. }
  4234. cmDspRC_t _cmDsp1ofN_Exec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4235. {
  4236. cmDspRC_t rc = kOkDspRC;
  4237. cmDsp1ofN_t* p = (cmDsp1ofN_t*)inst;
  4238. unsigned iChIdx = cmDspUInt(inst,kInChIdx1oId);
  4239. cmSample_t* dp = cmDspAudioBuf(ctx,inst,kOutAudio1oId,0);
  4240. const cmSample_t* sp = cmDspAudioBuf(ctx,inst,p->baseInAudio1oId + iChIdx ,0);
  4241. unsigned n = cmDspAudioBufSmpCount(ctx,inst,kOutAudio1oId,0);
  4242. if( dp != NULL )
  4243. {
  4244. if( sp == NULL )
  4245. cmVOS_Zero(dp,n);
  4246. else
  4247. cmVOS_Copy(dp,n,sp);
  4248. }
  4249. return rc;
  4250. }
  4251. cmDspRC_t _cmDsp1ofN_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4252. {
  4253. cmDspRC_t rc = kOkDspRC;
  4254. cmDsp1ofN_t* p = (cmDsp1ofN_t*)inst;
  4255. // ignore out of range input channel
  4256. if( evt->dstVarId == kInChIdx1oId && cmDsvGetUInt(evt->valuePtr) >= p->iChCnt )
  4257. {
  4258. cmDspInstErr(ctx,inst,kVarNotValidDspRC,"The selector channel index %i is out of range.",cmDsvGetUInt(evt->valuePtr));
  4259. return kOkDspRC;
  4260. }
  4261. // store the incoming value
  4262. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  4263. return rc;
  4264. // if this is an input data event
  4265. if( p->baseBaseIn1oId <= evt->dstVarId )
  4266. {
  4267. // get the input channel this event occurred on
  4268. unsigned iChIdx = (evt->dstVarId - p->baseBaseIn1oId) % p->iChCnt;
  4269. // if the event did not arrive on the selected input channel - there is nothing else to do
  4270. if( iChIdx != cmDspUInt(inst,kInChIdx1oId) )
  4271. return kOkDspRC;
  4272. // The event arrived on the input channel - send it out the output
  4273. // double
  4274. if( p->baseInFloat1oId <= evt->dstVarId && evt->dstVarId < p->baseInFloat1oId + p->iChCnt )
  4275. cmDspSetDouble(ctx,inst,kOutFloat1oId, cmDspDouble(inst,evt->dstVarId));
  4276. else
  4277. // bool
  4278. if( p->baseInBool1oId <= evt->dstVarId && evt->dstVarId < p->baseInBool1oId + p->iChCnt )
  4279. cmDspSetBool(ctx,inst,kOutBool1oId, cmDspBool(inst,evt->dstVarId));
  4280. else
  4281. // symbol
  4282. if( p->baseInSym1oId <= evt->dstVarId && evt->dstVarId < p->baseInSym1oId + p->iChCnt )
  4283. cmDspSetSymbol(ctx,inst,kOutSym1oId, cmDspSymbol(inst,evt->dstVarId));
  4284. }
  4285. return rc;
  4286. }
  4287. cmDspClass_t* cm1ofNClassCons( cmDspCtx_t* ctx )
  4288. {
  4289. cmDspClassSetup(&_cm1ofN_DC,ctx,"1ofN",
  4290. NULL,
  4291. _cmDsp1ofN_Alloc,
  4292. _cmDsp1ofN_Free,
  4293. _cmDsp1ofN_Reset,
  4294. _cmDsp1ofN_Exec,
  4295. _cmDsp1ofN_Recv,
  4296. NULL,NULL,
  4297. " 1 of N Switch");
  4298. return &_cm1ofN_DC;
  4299. }
  4300. //------------------------------------------------------------------------------------------------------------
  4301. //)
  4302. //( { label:cmDsp1Up file_desc:"Send 'true' on the selected channel and 'false' on the deselected channel." kw:[sunit] }
  4303. // Send a 'true' out on the selected channel.
  4304. // Send a 'false' out on the deselected channel.
  4305. enum
  4306. {
  4307. kChCnt1uId,
  4308. kSel1uId,
  4309. kBaseOut1uId
  4310. };
  4311. cmDspClass_t _cm1Up_DC;
  4312. typedef struct
  4313. {
  4314. cmDspInst_t inst;
  4315. } cmDsp1Up_t;
  4316. cmDspInst_t* _cmDsp1Up_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  4317. {
  4318. if( va_cnt < 1 )
  4319. {
  4320. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The '1Up' constructor must given output channel count.");
  4321. return NULL;
  4322. }
  4323. va_list vl1;
  4324. va_copy(vl1,vl);
  4325. int chCnt = va_arg(vl,int);
  4326. cmDsp1Up_t* p = cmDspInstAllocV(cmDsp1Up_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  4327. 1, "chcnt", kChCnt1uId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Output channel count.",
  4328. 1, "sel", kSel1uId, 0, 0, kUIntDsvFl | kOptArgDsvFl | kInDsvFl, "Channel index selector.",
  4329. chCnt, "out", kBaseOut1uId, 0, 0, kBoolDsvFl | kOutDsvFl, "Gate outputs",
  4330. 0 );
  4331. unsigned i;
  4332. cmDspSetDefaultUInt( ctx, &p->inst, kSel1uId, 0.0, 0.0 );
  4333. for(i=0; i<chCnt; ++i)
  4334. cmDspSetDefaultBool( ctx, &p->inst, kBaseOut1uId + i, false, false );
  4335. va_end(vl1);
  4336. return &p->inst;
  4337. }
  4338. cmDspRC_t _cmDsp1Up_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4339. {
  4340. cmDspRC_t rc = kOkDspRC;
  4341. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  4342. {
  4343. unsigned chIdx = cmDspUInt(inst,kSel1uId);
  4344. unsigned chCnt = cmDspUInt(inst,kChCnt1uId);
  4345. unsigned i;
  4346. for(i=0; i<chCnt; ++i)
  4347. cmDspSetBool(ctx,inst,kBaseOut1uId+i, i == chIdx );
  4348. }
  4349. return rc;
  4350. }
  4351. cmDspRC_t _cmDsp1Up_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4352. {
  4353. cmDspRC_t rc = kOkDspRC;
  4354. if( evt->dstVarId == kSel1uId)
  4355. {
  4356. unsigned chIdx = cmDspUInt(inst,kSel1uId);
  4357. unsigned chCnt = cmDspUInt(inst,kChCnt1uId);
  4358. // turn off the previously selected channel
  4359. if( chIdx != cmInvalidIdx && chIdx < chCnt )
  4360. cmDspSetBool(ctx,inst,kBaseOut1uId+chIdx,false);
  4361. // set the new channel index
  4362. cmDspSetEvent(ctx,inst,evt);
  4363. // get the new channel index
  4364. chIdx = cmDspUInt(inst,kSel1uId);
  4365. // send the new channel index
  4366. if( chIdx != cmInvalidIdx && chIdx < chCnt )
  4367. cmDspSetBool(ctx,inst,kBaseOut1uId+chIdx,true);
  4368. }
  4369. return rc;
  4370. }
  4371. cmDspClass_t* cm1UpClassCons( cmDspCtx_t* ctx )
  4372. {
  4373. cmDspClassSetup(&_cm1Up_DC,ctx,"1Up",
  4374. NULL,
  4375. _cmDsp1Up_Alloc,
  4376. NULL,
  4377. _cmDsp1Up_Reset,
  4378. NULL,
  4379. _cmDsp1Up_Recv,
  4380. NULL,NULL,
  4381. "Set one input high and all others low.");
  4382. return &_cm1Up_DC;
  4383. }
  4384. //------------------------------------------------------------------------------------------------------------
  4385. //)
  4386. //( { label:cmDspGateToSym file_desc:"Convert a 'true'/'false' gate to an 'on'/'off' symbol." kw:[sunit] }
  4387. //
  4388. enum
  4389. {
  4390. kOnSymGsId,
  4391. kOffSymGsId,
  4392. kOnGsId,
  4393. kOffGsId,
  4394. kBothGsId,
  4395. kOutGsId
  4396. };
  4397. cmDspClass_t _cmGateToSym_DC;
  4398. typedef struct
  4399. {
  4400. cmDspInst_t inst;
  4401. } cmDspGateToSym_t;
  4402. cmDspInst_t* _cmDspGateToSym_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  4403. {
  4404. cmDspGateToSym_t* p = cmDspInstAllocV(cmDspGateToSym_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  4405. 1, "on_sym", kOnSymGsId, 0, 0, kSymDsvFl | kInDsvFl | kOptArgDsvFl,"'on' symbol id (default:'on')",
  4406. 1, "off_sym",kOffSymGsId, 0, 0, kSymDsvFl | kInDsvFl | kOptArgDsvFl,"'off' symbol id (default:'off')",
  4407. 1, "on", kOnGsId, 0, 0, kBoolDsvFl | kInDsvFl, "On - send out 'on' symbol when a 'true' is received.",
  4408. 1, "off", kOffGsId, 0, 0, kBoolDsvFl | kInDsvFl, "Off - send out 'off' symbol when a 'false' is received.",
  4409. 1, "both", kBothGsId, 0, 0, kBoolDsvFl | kInDsvFl, "Send 'on' on 'true' and 'off' on 'false'.",
  4410. 1, "out", kOutGsId, 0, 0, kSymDsvFl | kOutDsvFl, "Output",
  4411. 0 );
  4412. unsigned onSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"on");
  4413. unsigned offSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"off");
  4414. cmDspSetDefaultSymbol( ctx, &p->inst, kOnSymGsId, onSymId );
  4415. cmDspSetDefaultSymbol( ctx, &p->inst, kOffSymGsId, offSymId );
  4416. cmDspSetDefaultSymbol( ctx, &p->inst, kOutGsId, cmInvalidId );
  4417. return &p->inst;
  4418. }
  4419. cmDspRC_t _cmDspGateToSym_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4420. {
  4421. cmDspRC_t rc = kOkDspRC;
  4422. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  4423. {
  4424. }
  4425. return rc;
  4426. }
  4427. cmDspRC_t _cmDspGateToSym_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4428. {
  4429. cmDspRC_t rc = kOkDspRC;
  4430. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  4431. {
  4432. unsigned onSymId = cmDspSymbol(inst,kOnSymGsId);
  4433. unsigned offSymId = cmDspSymbol(inst,kOffSymGsId);
  4434. switch( evt->dstVarId )
  4435. {
  4436. case kOnGsId:
  4437. if( cmDspBool(inst,kOnGsId) )
  4438. cmDspSetSymbol(ctx,inst,kOutGsId,onSymId);
  4439. break;
  4440. case kOffGsId:
  4441. if( !cmDspBool(inst,kOffGsId) )
  4442. cmDspSetSymbol(ctx,inst,kOutGsId,offSymId);
  4443. break;
  4444. case kBothGsId:
  4445. cmDspSetSymbol(ctx,inst, kOutGsId, cmDspBool(inst,kBothGsId) ? onSymId : offSymId);
  4446. break;
  4447. }
  4448. }
  4449. return rc;
  4450. }
  4451. cmDspClass_t* cmGateToSymClassCons( cmDspCtx_t* ctx )
  4452. {
  4453. cmDspClassSetup(&_cmGateToSym_DC,ctx,"GateToSym",
  4454. NULL,
  4455. _cmDspGateToSym_Alloc,
  4456. NULL,
  4457. _cmDspGateToSym_Reset,
  4458. NULL,
  4459. _cmDspGateToSym_Recv,
  4460. NULL,NULL,
  4461. "Convert a 'true'/'false' gate to an 'on'/'off' symbol.");
  4462. return &_cmGateToSym_DC;
  4463. }
  4464. //------------------------------------------------------------------------------------------------------------
  4465. //)
  4466. //( { label:cmDspPortToSym file_desc:"Send a pre-defined symbol every time a message arrives a given input port." kw:[sunit] }
  4467. enum
  4468. {
  4469. kOutPtsId,
  4470. kBaseInPtsId
  4471. };
  4472. cmDspClass_t _cmPortToSym_DC;
  4473. typedef struct
  4474. {
  4475. cmDspInst_t inst;
  4476. unsigned* symIdArray;
  4477. unsigned symIdCnt;
  4478. unsigned baseOutPtsId;
  4479. } cmDspPortToSym_t;
  4480. cmDspInst_t* _cmDspPortToSym_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  4481. {
  4482. va_list vl1;
  4483. va_copy(vl1,vl);
  4484. if( va_cnt < 1 )
  4485. {
  4486. va_end(vl1);
  4487. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'PortToSym' constructor argument list must contain at least one symbol label.");
  4488. return NULL;
  4489. }
  4490. unsigned symCnt = va_cnt;
  4491. unsigned argCnt = 1 + 2*symCnt;
  4492. cmDspVarArg_t args[argCnt+1];
  4493. unsigned* symIdArray = cmMemAllocZ(unsigned,symCnt);
  4494. unsigned baseOutPtsId = kBaseInPtsId + symCnt;
  4495. // setup the output port arg recd
  4496. cmDspArgSetup(ctx,args,"out",cmInvalidId,kOutPtsId,0,0,kOutDsvFl | kSymDsvFl, "Output" );
  4497. unsigned i;
  4498. for(i=0; i<symCnt; ++i)
  4499. {
  4500. // get the symbol label
  4501. const cmChar_t* symLabel = va_arg(vl,const char*);
  4502. assert( symLabel != NULL );
  4503. // register the symbol
  4504. symIdArray[i] = cmSymTblRegisterSymbol(ctx->stH,symLabel);
  4505. cmDspArgSetup(ctx, args+kBaseInPtsId+i, symLabel, cmInvalidId, kBaseInPtsId+i, 0, 0, kInDsvFl | kTypeDsvMask, cmTsPrintfH(ctx->lhH,"%s Input.",symLabel) );
  4506. cmDspArgSetup(ctx, args+baseOutPtsId+i, symLabel, cmInvalidId, baseOutPtsId+i, 0, 0, kOutDsvFl | kSymDsvFl, cmTsPrintfH(ctx->lhH,"%s Output.",symLabel) );
  4507. }
  4508. cmDspArgSetupNull(args + argCnt);
  4509. cmDspPortToSym_t* p = cmDspInstAlloc(cmDspPortToSym_t,ctx,classPtr,args,instSymId,id,storeSymId,0,vl1);
  4510. p->symIdCnt = symCnt;
  4511. p->symIdArray = symIdArray;
  4512. p->baseOutPtsId = baseOutPtsId;
  4513. cmDspSetDefaultSymbol(ctx,&p->inst,kOutPtsId,cmInvalidId);
  4514. va_end(vl1);
  4515. return &p->inst;
  4516. }
  4517. cmDspRC_t _cmDspPortToSym_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4518. {
  4519. cmDspPortToSym_t* p = (cmDspPortToSym_t*)inst;
  4520. cmMemFree(p->symIdArray);
  4521. return kOkDspRC;
  4522. }
  4523. cmDspRC_t _cmDspPortToSym_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4524. {
  4525. return cmDspApplyAllDefaults(ctx,inst);
  4526. }
  4527. cmDspRC_t _cmDspPortToSym_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4528. {
  4529. cmDspRC_t rc = kOkDspRC;
  4530. cmDspPortToSym_t* p = (cmDspPortToSym_t*)inst;
  4531. // if a msg of any type is recieved on an input port - send out the associated symbol
  4532. if( kBaseInPtsId <= evt->dstVarId && evt->dstVarId < kBaseInPtsId + p->symIdCnt )
  4533. {
  4534. unsigned idx = evt->dstVarId - kBaseInPtsId;
  4535. assert( idx < p->symIdCnt );
  4536. cmDspSetSymbol(ctx,inst,p->baseOutPtsId + idx, p->symIdArray[idx]);
  4537. return cmDspSetSymbol(ctx,inst,kOutPtsId,p->symIdArray[ evt->dstVarId - kBaseInPtsId ]);
  4538. }
  4539. return rc;
  4540. }
  4541. cmDspClass_t* cmPortToSymClassCons( cmDspCtx_t* ctx )
  4542. {
  4543. cmDspClassSetup(&_cmPortToSym_DC,ctx,"PortToSym",
  4544. NULL,
  4545. _cmDspPortToSym_Alloc,
  4546. _cmDspPortToSym_Free,
  4547. _cmDspPortToSym_Reset,
  4548. NULL,
  4549. _cmDspPortToSym_Recv,
  4550. NULL,NULL,
  4551. "If a message of any kind is received on a port then send the symbol associated with the port.");
  4552. return &_cmPortToSym_DC;
  4553. }
  4554. //------------------------------------------------------------------------------------------------------------
  4555. //)
  4556. //( { label:cmDspRouter file_desc:"Route the input value to one of multiple output ports." kw:[sunit] }
  4557. enum
  4558. {
  4559. kOutChCntRtId,
  4560. kOutChIdxRtId,
  4561. kInFloatRtId,
  4562. kInBoolRtId,
  4563. kInSymRtId,
  4564. kInAudioRtId,
  4565. kBaseOutFloatRtId
  4566. };
  4567. cmDspClass_t _cmRouter_DC;
  4568. typedef struct
  4569. {
  4570. cmDspInst_t inst;
  4571. unsigned oChCnt;
  4572. unsigned oChIdx;
  4573. unsigned baseBaseOutRtId; // first data input port id
  4574. unsigned baseInFloatRtId;
  4575. unsigned baseInBoolRtId;
  4576. unsigned baseInSymRtId;
  4577. unsigned baseInAudioRtId;
  4578. unsigned baseOutFloatRtId;
  4579. unsigned baseOutBoolRtId;
  4580. unsigned baseOutSymRtId;
  4581. unsigned baseOutAudioRtId;
  4582. } cmDspRouter_t;
  4583. cmDspInst_t* _cmDspRouter_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  4584. {
  4585. if( va_cnt < 1 )
  4586. {
  4587. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'Router' constructor must be given an output channel count.");
  4588. return NULL;
  4589. }
  4590. va_list vl1;
  4591. va_copy(vl1,vl);
  4592. int oChCnt = va_arg(vl,int);
  4593. unsigned baseOutFloatRtId = kBaseOutFloatRtId;
  4594. unsigned baseOutBoolRtId = baseOutFloatRtId + oChCnt;
  4595. unsigned baseOutSymRtId = baseOutBoolRtId + oChCnt;
  4596. unsigned baseOutAudioRtId = baseOutSymRtId + oChCnt;
  4597. cmDspRouter_t* p = cmDspInstAllocV(cmDspRouter_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  4598. 1, "ochs", kOutChCntRtId, 0, 0, kUIntDsvFl | kReqArgDsvFl,"Output channel count.",
  4599. 1, "sel", kOutChIdxRtId, 0, 0, kUIntDsvFl | kReqArgDsvFl | kInDsvFl, "Output channel index selector.",
  4600. 1, "f-in", kInFloatRtId, 0, 0, kDoubleDsvFl | kInDsvFl, "Float input",
  4601. 1, "b-in", kInBoolRtId, 0, 0, kBoolDsvFl | kInDsvFl, "Bool input",
  4602. 1, "s-in", kInSymRtId, 0, 0, kSymDsvFl | kInDsvFl, "Symbol input",
  4603. 1, "a-in", kInAudioRtId, 0, 0, kAudioBufDsvFl | kInDsvFl, "Audio input",
  4604. oChCnt, "f-out", baseOutFloatRtId, 0, 0, kDoubleDsvFl | kOutDsvFl, "Float output",
  4605. oChCnt, "b-out", baseOutBoolRtId, 0, 0, kBoolDsvFl | kOutDsvFl, "Bool output",
  4606. oChCnt, "s-out", baseOutSymRtId, 0, 0, kSymDsvFl | kOutDsvFl, "Symbol output",
  4607. oChCnt, "a-out", baseOutAudioRtId, 0, 1, kAudioBufDsvFl | kOutDsvFl, "Audio output",
  4608. 0 );
  4609. p->oChCnt = oChCnt;
  4610. p->baseBaseOutRtId = kBaseOutFloatRtId;
  4611. p->baseOutFloatRtId = baseOutFloatRtId;
  4612. p->baseOutBoolRtId = baseOutBoolRtId;
  4613. p->baseOutSymRtId = baseOutSymRtId;
  4614. p->baseOutAudioRtId = baseOutAudioRtId;
  4615. unsigned i;
  4616. for(i=0; i<oChCnt; ++i)
  4617. {
  4618. cmDspSetDefaultDouble( ctx, &p->inst, baseOutFloatRtId+i, 0.0, 0.0 );
  4619. cmDspSetDefaultBool( ctx, &p->inst, baseOutBoolRtId+i, false, false );
  4620. cmDspSetDefaultSymbol( ctx, &p->inst, baseOutSymRtId+i, cmInvalidId );
  4621. }
  4622. va_end(vl1);
  4623. return &p->inst;
  4624. }
  4625. cmDspRC_t _cmDspRouter_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4626. {
  4627. return kOkDspRC;
  4628. }
  4629. cmDspRC_t _cmDspRouter_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4630. {
  4631. cmDspRC_t rc = kOkDspRC;
  4632. cmDspRouter_t* p = (cmDspRouter_t*)inst;
  4633. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  4634. {
  4635. unsigned i;
  4636. for(i=0; i<p->oChCnt; ++i)
  4637. cmDspZeroAudioBuf(ctx,inst,p->baseOutAudioRtId+i);
  4638. }
  4639. return rc;
  4640. }
  4641. cmDspRC_t _cmDspRouter_Exec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4642. {
  4643. cmDspRC_t rc = kOkDspRC;
  4644. cmDspRouter_t* p = (cmDspRouter_t*)inst;
  4645. unsigned oChIdx = cmDspUInt(inst,kOutChIdxRtId);
  4646. cmSample_t* dp = cmDspAudioBuf(ctx,inst,p->baseOutAudioRtId + oChIdx,0);
  4647. const cmSample_t* sp = cmDspAudioBuf(ctx,inst,kInAudioRtId ,0);
  4648. unsigned n = cmDspAudioBufSmpCount(ctx,inst,p->baseOutAudioRtId,0);
  4649. if( dp != NULL )
  4650. {
  4651. if( sp == NULL )
  4652. cmVOS_Zero(dp,n);
  4653. else
  4654. cmVOS_Copy(dp,n,sp);
  4655. }
  4656. return rc;
  4657. }
  4658. cmDspRC_t _cmDspRouter_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4659. {
  4660. cmDspRC_t rc = kOkDspRC;
  4661. cmDspRouter_t* p = (cmDspRouter_t*)inst;
  4662. // ignore out of range output channel selection
  4663. if( evt->dstVarId == kOutChIdxRtId && cmDsvGetUInt(evt->valuePtr) >= p->oChCnt )
  4664. {
  4665. cmDspInstErr(ctx,inst,kVarNotValidDspRC,"The selector channel index %i is out of of range.",cmDsvGetUInt(evt->valuePtr));
  4666. return kOkDspRC;
  4667. }
  4668. // if( evt->dstVarId == kOutChIdxRtId && cmDsvGetUInt(evt->valuePtr) < p->oChCnt )
  4669. // {
  4670. // const cmChar_t* symLbl = cmSymTblLabel(ctx->stH,inst->symId);
  4671. // cmDspInstErr(ctx,inst,kOkDspRC,"Router: ch:%i %s\n",cmDsvGetUInt(evt->valuePtr),symLbl==NULL?"":symLbl);
  4672. // }
  4673. // store the incoming value
  4674. if( evt->dstVarId < p->baseBaseOutRtId )
  4675. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  4676. return rc;
  4677. unsigned chIdx = cmDspUInt(inst,kOutChIdxRtId);
  4678. switch( evt->dstVarId )
  4679. {
  4680. case kInFloatRtId:
  4681. cmDspSetDouble(ctx,inst,p->baseOutFloatRtId + chIdx, cmDspDouble(inst,kInFloatRtId) );
  4682. break;
  4683. case kInBoolRtId:
  4684. cmDspSetBool(ctx,inst,p->baseOutBoolRtId + chIdx, cmDspBool(inst,kInBoolRtId) );
  4685. break;
  4686. case kInSymRtId:
  4687. cmDspSetSymbol(ctx,inst,p->baseOutSymRtId + chIdx, cmDspSymbol(inst,kInSymRtId));
  4688. break;
  4689. }
  4690. return rc;
  4691. }
  4692. cmDspClass_t* cmRouterClassCons( cmDspCtx_t* ctx )
  4693. {
  4694. cmDspClassSetup(&_cmRouter_DC,ctx,"Router",
  4695. NULL,
  4696. _cmDspRouter_Alloc,
  4697. _cmDspRouter_Free,
  4698. _cmDspRouter_Reset,
  4699. _cmDspRouter_Exec,
  4700. _cmDspRouter_Recv,
  4701. NULL,NULL,
  4702. "1 to N Router");
  4703. return &_cmRouter_DC;
  4704. }
  4705. //------------------------------------------------------------------------------------------------------------
  4706. //)
  4707. //( { label:cmDspAvailCh file_desc:"Track active an inactive processing channels." kw:[sunit] }
  4708. //
  4709. // Purpose: AvailCh can be used to implement a channel switching circuit.
  4710. //
  4711. // Inputs:
  4712. // chs - The count of channels. Constructor only argument.
  4713. // trig - Any input causes the next available channel, i, to be enabled.
  4714. // gate[i] transmits 'true'. In 'exclusive (0) mode all active
  4715. // channels are then requested to shutdown by transmitting 'false' on
  4716. // gate[] - only the new channel will be active. In 'multi' (1) mode
  4717. // no signal is sent out the gate[].
  4718. // dis[chCnt] - Recieves a gate signal from an external object which indicates
  4719. // when a channel is no longer active. When a 'false' is received on dis[i]
  4720. // the channel i is marked as available. In 'multi' mode 'false' is
  4721. // then transmitted on gate[i].
  4722. // Outputs:
  4723. // gate[chCnt] - 'true' is transmitted when a channel is made active (see trig)
  4724. // 'false' is transmitted to notify the channel that it should shutdown.
  4725. // The channel is not considered actually shutdown until dis[i]
  4726. // recieves a 'false'.
  4727. // ch The next prospective available channel is sent whenever it
  4728. // becomes available. A next channel becomes available when
  4729. // a channel is marked as inactive via dis[i] or when
  4730. // a new channel is made active, via trigger, and another
  4731. // channel active channel exists. Note that this channel is
  4732. // sent "prospectively" - possibly long before the associated
  4733. // gate[ch] is raised - in order to switch parameter routers away
  4734. // from the newly active channel and a currently in-active channel.
  4735. // Notes:
  4736. // The gate[] output is designed to work with the gate[] input of Xfader. When
  4737. // availCh.gate[] goes high Xfader fades in, when availCh.gate[] goes low
  4738. // Xfader fades out. The dis[] channel is designed to connect from Xfader.state[].
  4739. // Xfader.state[] goes low when a fade-out is complete, the connected AvailCh
  4740. // is then marked as available.
  4741. enum
  4742. {
  4743. kChCntAvId,
  4744. kModeAvId,
  4745. kTrigAvId,
  4746. kResetAvId,
  4747. kChIdxAvId,
  4748. kBaseDisInAvId,
  4749. kExclusiveModeAvId=0,
  4750. kMultiModeAvId=1
  4751. };
  4752. cmDspClass_t _cmAvailCh_DC;
  4753. typedef struct
  4754. {
  4755. cmDspInst_t inst;
  4756. unsigned chCnt;
  4757. unsigned baseDisInAvId;
  4758. unsigned baseGateOutAvId;
  4759. bool* stateArray;
  4760. unsigned nextAvailChIdx;
  4761. unsigned audioCycleCnt;
  4762. } cmDspAvailCh_t;
  4763. cmDspInst_t* _cmDspAvailCh_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  4764. {
  4765. if( va_cnt < 1 )
  4766. {
  4767. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'AvailCh' constructor must be given an channel count.");
  4768. return NULL;
  4769. }
  4770. va_list vl1;
  4771. va_copy(vl1,vl);
  4772. int chCnt = va_arg(vl,int);
  4773. if( chCnt <= 0 )
  4774. {
  4775. va_end(vl1);
  4776. cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The 'AvailCh' constructor must be given a positive channel count.");
  4777. return NULL;
  4778. }
  4779. unsigned baseDisInAvId = kBaseDisInAvId;
  4780. unsigned baseGateOutAvId = baseDisInAvId + chCnt;
  4781. cmDspAvailCh_t* p = cmDspInstAllocV(cmDspAvailCh_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl1,
  4782. 1, "chs", kChCntAvId, 0, 0, kUIntDsvFl | kReqArgDsvFl, "Channel count.",
  4783. 1, "mode", kModeAvId, 0, 0, kUIntDsvFl | kInDsvFl, "Mode: 0=exclusive (dflt) 1=multi",
  4784. 1, "trig", kTrigAvId, 0, 0, kTypeDsvMask | kInDsvFl, "Trigger the unit to select the next available channel.",
  4785. 1, "reset", kResetAvId, 0, 0, kBoolDsvFl | kInDsvFl | kOutDsvFl, "Reset to default state",
  4786. 1, "ch", kChIdxAvId, 0, 0, kUIntDsvFl | kOutDsvFl, "Currently selected channel.",
  4787. chCnt, "dis", baseDisInAvId, 0, 0, kBoolDsvFl | kInDsvFl, "Disable channel gate",
  4788. chCnt, "gate", baseGateOutAvId, 0, 0, kBoolDsvFl | kOutDsvFl, "Active channel gate",
  4789. 0 );
  4790. p->chCnt = chCnt;
  4791. p->baseDisInAvId = baseDisInAvId;
  4792. p->baseGateOutAvId = baseGateOutAvId;
  4793. p->nextAvailChIdx = cmInvalidIdx;
  4794. p->audioCycleCnt = 0;
  4795. unsigned i;
  4796. for(i=0; i<chCnt; ++i)
  4797. {
  4798. cmDspSetDefaultBool( ctx, &p->inst, baseDisInAvId+i, false, false );
  4799. cmDspSetDefaultBool( ctx, &p->inst, baseGateOutAvId+i, false, false );
  4800. }
  4801. cmDspSetDefaultUInt( ctx, &p->inst, kModeAvId, 0, kExclusiveModeAvId );
  4802. cmDspSetDefaultUInt( ctx, &p->inst, kChIdxAvId, 0, 0 );
  4803. va_end(vl1);
  4804. return &p->inst;
  4805. }
  4806. cmDspRC_t _cmDspAvailCh_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4807. {
  4808. return kOkDspRC;
  4809. }
  4810. cmDspRC_t _cmDspAvailCh_DoReset( cmDspCtx_t* ctx, cmDspInst_t* inst )
  4811. {
  4812. unsigned i;
  4813. cmDspAvailCh_t* p = (cmDspAvailCh_t*)inst;
  4814. // ch 0 is the channel receiving parameters
  4815. cmDspSetUInt(ctx,inst,kChIdxAvId,0);
  4816. for(i=0; i<p->chCnt; ++i)
  4817. {
  4818. cmDspSetBool(ctx, inst, p->baseDisInAvId + i, i==0); // disable all channels except ch zero
  4819. cmDspSetBool(ctx, inst, p->baseGateOutAvId + i, i==0); // enable channel 0
  4820. }
  4821. p->audioCycleCnt = 0;
  4822. p->nextAvailChIdx = cmInvalidIdx;
  4823. // transmit reset
  4824. cmDspSetBool(ctx,inst, kResetAvId, false );
  4825. return kOkDspRC;
  4826. }
  4827. cmDspRC_t _cmDspAvailCh_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4828. {
  4829. cmDspRC_t rc;
  4830. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  4831. {
  4832. rc = _cmDspAvailCh_DoReset(ctx,inst);
  4833. }
  4834. return rc;
  4835. }
  4836. void _cmDspAvailCh_SetNextAvailCh( cmDspCtx_t* ctx, cmDspInst_t* inst, bool warnFl, const char* label )
  4837. {
  4838. cmDspAvailCh_t* p = (cmDspAvailCh_t*)inst;
  4839. unsigned i;
  4840. // if a valid next avail ch already exists then do nothing
  4841. if( p->nextAvailChIdx != cmInvalidIdx )
  4842. return;
  4843. // for each channel
  4844. for(i=0; i<p->chCnt; ++i)
  4845. {
  4846. // the channel's active state is held in the 'dis' variable.
  4847. bool activeFl = cmDspBool(inst,p->baseDisInAvId+i);
  4848. // if ch[i] is the first avail inactive channel
  4849. if( !activeFl )
  4850. {
  4851. p->nextAvailChIdx = i; // then make it the next available channel
  4852. break;
  4853. }
  4854. }
  4855. // if no available channels were found
  4856. if( p->nextAvailChIdx == cmInvalidIdx )
  4857. {
  4858. if( warnFl )
  4859. cmDspInstErr(ctx,inst,kInvalidStateDspRC,"No available channels exist.");
  4860. }
  4861. else
  4862. {
  4863. // Notify the external world which channel is to be used next.
  4864. // This allows routers which are switching parameters between
  4865. // xfade channels to switch new parameter values to go to the
  4866. // next available channel rather than the current channel.
  4867. // The next available channel will then be faded up with the
  4868. // new parameters on the next trigger command.
  4869. cmDspSetUInt(ctx,inst,kChIdxAvId,p->nextAvailChIdx);
  4870. }
  4871. }
  4872. cmDspRC_t _cmDspAvailCh_Exec( cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4873. {
  4874. cmDspRC_t rc = kOkDspRC;
  4875. cmDspAvailCh_t* p = (cmDspAvailCh_t*)inst;
  4876. p->audioCycleCnt += 1;
  4877. // Setting the next available channel here solves the problem of sending the
  4878. // first 'ch' output after the program starts executing.
  4879. // The problem is that 'ch' should be set to 0 for the first
  4880. // execution cycle so that parameters may be set to the initial active channel
  4881. // during the first cycle. After the first cycle however parameters should be
  4882. // sent to the next channel which will be faded up. Setting
  4883. // 'ch' here accomplishes this without relying on an external signal.
  4884. // Note that we wait until the second cycle because we don't know where
  4885. // this 'availCh' will be in the execution cycle relative to other processors.
  4886. // If it is at the beginning then other processors that might be setting
  4887. // initial parameters will not have had a chance to run before the
  4888. // 'ch' change. Waiting unitl the second cycle guarantees that all the
  4889. // other processors had at least one chance to run.
  4890. if( p->audioCycleCnt == 2 )
  4891. {
  4892. _cmDspAvailCh_SetNextAvailCh(ctx,inst,true,"exec");
  4893. }
  4894. return rc;
  4895. }
  4896. cmDspRC_t _cmDspAvailCh_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  4897. {
  4898. cmDspRC_t rc = kOkDspRC;
  4899. cmDspAvailCh_t* p = (cmDspAvailCh_t*)inst;
  4900. bool exclModeFl = cmDspUInt(inst, kModeAvId ) == kExclusiveModeAvId;
  4901. // if this is a reset
  4902. if( evt->dstVarId == kResetAvId )
  4903. {
  4904. return _cmDspAvailCh_DoReset(ctx,inst);
  4905. }
  4906. // if this is a trigger
  4907. if( evt->dstVarId == kTrigAvId )
  4908. {
  4909. // if no available channels were previously found
  4910. if( p->nextAvailChIdx == cmInvalidIdx )
  4911. cmDspInstErr(ctx,inst,kInvalidStateDspRC,"There are no available channels to trigger.");
  4912. else
  4913. {
  4914. // indicate that ch[nexAvailChIdx] is no longer available
  4915. cmDspSetBool(ctx, inst, p->baseDisInAvId + p->nextAvailChIdx, true);
  4916. // raise the gate to start the xfade.
  4917. cmDspSetBool(ctx, inst, p->baseGateOutAvId + p->nextAvailChIdx, true);
  4918. if( exclModeFl )
  4919. {
  4920. unsigned i;
  4921. for(i=0; i<p->chCnt; ++i)
  4922. if( i!=p->nextAvailChIdx && cmDspBool(inst,p->baseDisInAvId+i) )
  4923. cmDspSetBool(ctx,inst, p->baseGateOutAvId+i, false );
  4924. }
  4925. // invalidate nextAvailChIdx
  4926. p->nextAvailChIdx = cmInvalidIdx;
  4927. // It may be possible to know the next avail ch so try to set it here.
  4928. _cmDspAvailCh_SetNextAvailCh(ctx, inst, false, "trig" );
  4929. }
  4930. return rc;
  4931. }
  4932. // if this is an incoming disable message.
  4933. if( p->baseDisInAvId <= evt->dstVarId && evt->dstVarId < p->baseDisInAvId+p->chCnt && cmDsvGetBool(evt->valuePtr) == false)
  4934. {
  4935. cmDspSetEvent(ctx,inst,evt);
  4936. // a channel was disabled so a new channel should be available for selection
  4937. if( p->audioCycleCnt > 0 )
  4938. _cmDspAvailCh_SetNextAvailCh(ctx, inst, true, "dis" );
  4939. if( !exclModeFl )
  4940. cmDspSetBool(ctx, inst, p->baseGateOutAvId + (evt->dstVarId - p->baseDisInAvId), false);
  4941. }
  4942. return rc;
  4943. }
  4944. cmDspClass_t* cmAvailChClassCons( cmDspCtx_t* ctx )
  4945. {
  4946. cmDspClassSetup(&_cmAvailCh_DC,ctx,"AvailCh",
  4947. NULL,
  4948. _cmDspAvailCh_Alloc,
  4949. _cmDspAvailCh_Free,
  4950. _cmDspAvailCh_Reset,
  4951. _cmDspAvailCh_Exec,
  4952. _cmDspAvailCh_Recv,
  4953. NULL,NULL,
  4954. "Enable the next availabled channel");
  4955. return &_cmAvailCh_DC;
  4956. }
  4957. //------------------------------------------------------------------------------------------------------------
  4958. //)
  4959. //( { label:cmDspPreset file_desc:"Store and recall preset. Show a preset list user interface unit." kw:[sunit] }
  4960. enum
  4961. {
  4962. kGroupSymPrId,
  4963. kLabelPrId,
  4964. kCmdPrId,
  4965. kDonePrId,
  4966. kListPrId,
  4967. kSelPrId
  4968. };
  4969. cmDspClass_t _cmPreset_DC;
  4970. typedef struct
  4971. {
  4972. cmDspInst_t inst;
  4973. unsigned storeCmdSymId;
  4974. unsigned recallCmdSymId;
  4975. unsigned doneSymId;
  4976. cmJsonH_t jsH;
  4977. cmJsonNode_t* np;
  4978. } cmDspPreset_t;
  4979. cmDspRC_t _cmDspPresetUpdateList( cmDspCtx_t* ctx, cmDspPreset_t* p, unsigned groupSymId )
  4980. {
  4981. cmDspRC_t rc = kOkDspRC;
  4982. // initialize the JSON tree
  4983. if( cmJsonInitialize(&p->jsH,ctx->cmCtx) != kOkJsRC )
  4984. {
  4985. rc = cmDspInstErr(ctx,&p->inst,kJsonFailDspRC,"JSON preset list handle initialization failed.");
  4986. goto errLabel;
  4987. }
  4988. // create the JSON tree root container
  4989. if( cmJsonCreateObject(p->jsH,NULL) == NULL )
  4990. {
  4991. rc = cmDspInstErr(ctx,&p->inst,kJsonFailDspRC,"JSON preset list root object create failed.");
  4992. goto errLabel;
  4993. }
  4994. // if a valid preset group symbol was given
  4995. if( groupSymId != cmInvalidId )
  4996. {
  4997. // get the JSON list containing the preset labels and symId's for this preset group
  4998. if( cmDspSysPresetPresetJsonList(ctx->dspH, groupSymId, &p->jsH ) != kOkDspRC )
  4999. {
  5000. rc = cmDspInstErr(ctx,&p->inst,kSubSysFailDspRC,"Request for a preset list failed.");
  5001. goto errLabel;
  5002. }
  5003. // get a pointer to the JSON 'presetArray' array node
  5004. if(( p->np = cmJsonFindValue(p->jsH,"presetArray",NULL,kArrayTId)) == NULL )
  5005. {
  5006. rc = cmDspInstErr(ctx,&p->inst,kJsonFailDspRC,"Preset list is empty or synatax is not recognized.");
  5007. goto errLabel;
  5008. }
  5009. // set the JSON list
  5010. if((rc = cmDspSetJson(ctx,&p->inst,kListPrId,p->np)) != kOkDspRC )
  5011. {
  5012. rc = cmDspInstErr(ctx,&p->inst,rc,"Preset list set failed.");
  5013. goto errLabel;
  5014. }
  5015. }
  5016. errLabel:
  5017. return rc;
  5018. }
  5019. cmDspRC_t _cmDspPresetDoRecall( cmDspCtx_t* ctx, cmDspPreset_t* p, const cmChar_t* groupLabel, const cmChar_t* presetLabel )
  5020. {
  5021. cmDspRC_t rc;
  5022. // recall the preset
  5023. if(( rc = cmDspSysPresetRecall(ctx->dspH, groupLabel, presetLabel )) != kOkDspRC )
  5024. return cmDspInstErr(ctx,&p->inst,kSubSysFailDspRC,"Preset recall failed for group:'%s' preset:'%s'.",cmStringNullGuard(groupLabel),cmStringNullGuard(presetLabel));
  5025. // send out a notification that a new preset has been loaded
  5026. return cmDspSetSymbol(ctx,&p->inst,kDonePrId,p->doneSymId);
  5027. }
  5028. // selIdx is base 1, not base 0, because it references the JSON tree rows where the
  5029. // first row contains the titles.
  5030. cmDspRC_t _cmDspPresetListSelectRecall( cmDspCtx_t* ctx, cmDspPreset_t* p, unsigned selIdx )
  5031. {
  5032. cmDspRC_t rc = kOkDspRC;
  5033. const cmChar_t* presetLabel;
  5034. const cmChar_t* groupLabel;
  5035. unsigned groupSymId;
  5036. unsigned presetSymId;
  5037. const cmJsonNode_t* rnp;
  5038. // validate the JSON tree
  5039. if( cmJsonIsValid(p->jsH) == false || p->np == NULL )
  5040. {
  5041. rc = cmDspInstErr(ctx,&p->inst,kJsonFailDspRC,"Preset recall failed. The preset JSON tree does not exist.");
  5042. goto errLabel;
  5043. }
  5044. // validate the group id
  5045. if( (groupSymId = cmDspSymbol(&p->inst,kGroupSymPrId)) == cmInvalidId )
  5046. {
  5047. rc = cmDspInstErr(ctx,&p->inst,kVarNotValidDspRC,"Preset recall failed. The preset group symbol has not been set.");
  5048. goto errLabel;
  5049. }
  5050. // validate the selection index
  5051. if( selIdx >= cmJsonChildCount(p->np) )
  5052. {
  5053. rc = cmDspInstErr(ctx,&p->inst,kVarNotValidDspRC,"Preset recall failed. The preset index: %i is out of range 0-%i", selIdx, cmJsonChildCount(p->np));
  5054. goto errLabel;
  5055. }
  5056. // get the preset element
  5057. if(( rnp = cmJsonArrayElementC(p->np, selIdx )) == NULL )
  5058. {
  5059. rc = cmDspInstErr(ctx,&p->inst,kJsonFailDspRC,"Preset recall failed. Unable to retrieve preset JSON element.");
  5060. goto errLabel;
  5061. }
  5062. // verify the JSON syntax
  5063. assert( rnp->typeId==kArrayTId && cmJsonChildCount(rnp)==2 && cmJsonArrayElementC(rnp,1)->typeId == kIntTId );
  5064. // get the preset symbol id
  5065. if( cmJsonUIntValue( cmJsonArrayElementC(rnp,1), &presetSymId ) != kOkJsRC )
  5066. {
  5067. rc = cmDspInstErr(ctx,&p->inst,kJsonFailDspRC,"Preset recall failed. Unable to retrieve preset symbol id.");
  5068. goto errLabel;
  5069. }
  5070. // convert symbols to strings
  5071. groupLabel = cmSymTblLabel(ctx->stH,groupSymId);
  5072. presetLabel = cmSymTblLabel(ctx->stH,presetSymId);
  5073. rc = _cmDspPresetDoRecall(ctx,p,groupLabel,presetLabel);
  5074. errLabel:
  5075. return rc;
  5076. }
  5077. cmDspInst_t* _cmDspPreset_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  5078. {
  5079. cmDspPreset_t* p = cmDspInstAllocV(cmDspPreset_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  5080. 1, "sym", kGroupSymPrId, 0, 0, kInDsvFl | kSymDsvFl | kReqArgDsvFl, "Preset group symbol.",
  5081. 1, "label", kLabelPrId, 0, 0, kInDsvFl | kStrzDsvFl | kOptArgDsvFl, "Preset label",
  5082. 1, "cmd", kCmdPrId, 0, 0, kInDsvFl | kSymDsvFl, "Command input",
  5083. 1, "done", kDonePrId, 0, 0, kOutDsvFl | kSymDsvFl, "Send 'done' symbol after preset recall.",
  5084. 1, "list", kListPrId, 0, 0, kInDsvFl | kJsonDsvFl, "Preset list as a JSON array.",
  5085. 1, "sel", kSelPrId, 0, 0, kInDsvFl | kUIntDsvFl, "Preset index selection index",
  5086. 0 );
  5087. p->jsH = cmJsonNullHandle;
  5088. p->np = NULL;
  5089. p->storeCmdSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"store");
  5090. p->recallCmdSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"recall");
  5091. p->doneSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"done");
  5092. cmDspSetDefaultBool( ctx, &p->inst, kDonePrId,false,false);
  5093. cmDspSetDefaultSymbol( ctx, &p->inst, kGroupSymPrId, cmInvalidId);
  5094. cmDspSetDefaultStrcz( ctx, &p->inst, kLabelPrId, NULL,"");
  5095. unsigned height = 5;
  5096. cmDspUiMsgListCreate(ctx, &p->inst, height, kListPrId, kSelPrId );
  5097. return &p->inst;
  5098. }
  5099. cmDspRC_t _cmDspPreset_Free(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5100. {
  5101. cmDspPreset_t* p = (cmDspPreset_t*)inst;
  5102. cmJsonFinalize(&p->jsH);
  5103. return kOkDspRC;
  5104. }
  5105. cmDspRC_t _cmDspPreset_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5106. {
  5107. cmDspRC_t rc;
  5108. cmDspPreset_t* p = (cmDspPreset_t*)inst;
  5109. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  5110. {
  5111. _cmDspPresetUpdateList(ctx, p, cmDspSymbol(inst,kGroupSymPrId) );
  5112. }
  5113. return rc;
  5114. }
  5115. cmDspRC_t _cmDspPreset_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5116. {
  5117. cmDspRC_t rc = kOkDspRC;
  5118. cmDspPreset_t* p = (cmDspPreset_t*)inst;
  5119. switch( evt->dstVarId )
  5120. {
  5121. case kListPrId:
  5122. return rc; // we don't yet handle lists arriving by the input port
  5123. case kSelPrId:
  5124. {
  5125. // sel idx is base 1 because the first row in the msg list contains the titles
  5126. unsigned selIdx = cmDsvGetUInt(evt->valuePtr);
  5127. if((rc = _cmDspPresetListSelectRecall(ctx,p,selIdx)) != kOkDspRC)
  5128. return rc;
  5129. }
  5130. break;
  5131. }
  5132. if((rc = cmDspSetEvent(ctx,inst,evt)) != kOkDspRC )
  5133. return rc;
  5134. // if this is a store or recall command
  5135. if( evt->dstVarId == kCmdPrId )
  5136. {
  5137. unsigned cmdSymId = cmDspSymbol(inst,kCmdPrId);
  5138. if( cmdSymId == p->storeCmdSymId || cmdSymId==p->recallCmdSymId )
  5139. {
  5140. unsigned groupSymId;
  5141. const cmChar_t* groupLabel;
  5142. const cmChar_t* presetLabel;
  5143. // get the group symbol
  5144. if((groupSymId = cmDspSymbol(inst,kGroupSymPrId)) == cmInvalidId )
  5145. return cmDspInstErr(ctx,inst,kVarNotValidDspRC,"The preset group symbol id is not set.");
  5146. // get the group label
  5147. if((groupLabel = cmSymTblLabel(ctx->stH,groupSymId)) == NULL )
  5148. return cmDspInstErr(ctx,inst,kVarNotValidDspRC,"The preset group label was not found.");
  5149. // get the preset label
  5150. if(( presetLabel = cmDspStrcz(inst,kLabelPrId)) == NULL || strlen(presetLabel)==0 )
  5151. return cmDspInstErr(ctx,inst,kVarNotValidDspRC,"The preset label was not set.");
  5152. // if this is a store command
  5153. if( cmdSymId == p->storeCmdSymId )
  5154. {
  5155. // create a new preset
  5156. if((rc = cmDspSysPresetCreate(ctx->dspH,groupLabel, presetLabel)) != kOkDspRC )
  5157. return cmDspInstErr(ctx,inst,kSubSysFailDspRC,"Preset create failed for group:'%s' preset:'%s'.",cmStringNullGuard(groupLabel),cmStringNullGuard(presetLabel));
  5158. // update the list with the new preset
  5159. rc = _cmDspPresetUpdateList(ctx, p, groupSymId );
  5160. }
  5161. else // otherwise this must be a recall command
  5162. {
  5163. rc = _cmDspPresetDoRecall(ctx,p,groupLabel, presetLabel);
  5164. }
  5165. }
  5166. }
  5167. return rc;
  5168. }
  5169. cmDspClass_t* cmPresetClassCons( cmDspCtx_t* ctx )
  5170. {
  5171. cmDspClassSetup(&_cmPreset_DC,ctx,"Preset",
  5172. NULL,
  5173. _cmDspPreset_Alloc,
  5174. _cmDspPreset_Free,
  5175. _cmDspPreset_Reset,
  5176. NULL,
  5177. _cmDspPreset_Recv,
  5178. NULL,NULL,
  5179. "Preset Manager");
  5180. return &_cmPreset_DC;
  5181. }
  5182. //------------------------------------------------------------------------------------------------------------
  5183. //)
  5184. //( { label:cmDspBcastSym file_desc:"Broadcast a symbol/value to all units registered to listen for the symbol." kw:[sunit] }
  5185. enum
  5186. {
  5187. kAttrBcId,
  5188. kMsgBcId
  5189. };
  5190. cmDspClass_t _cmBcastSym_DC;
  5191. typedef struct
  5192. {
  5193. cmDspInst_t inst;
  5194. unsigned onSymId;
  5195. unsigned offSymId;
  5196. } cmDspBcastSym_t;
  5197. cmDspInst_t* _cmDspBcastSym_Alloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  5198. {
  5199. cmDspBcastSym_t* p = cmDspInstAllocV(cmDspBcastSym_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  5200. 1, "attr", kAttrBcId, 0, 0, kSymDsvFl | kInDsvFl | kOptArgDsvFl, "Instance which have this attribute symbol will receive the message.",
  5201. 1, "msg", kMsgBcId, 0, 0, kTypeDsvMask | kInDsvFl, "Msg to broadcast.",
  5202. 0 );
  5203. cmDspSetDefaultSymbol( ctx, &p->inst, kAttrBcId, cmInvalidId );
  5204. return &p->inst;
  5205. }
  5206. cmDspRC_t _cmDspBcastSym_Reset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5207. {
  5208. cmDspRC_t rc = kOkDspRC;
  5209. if((rc = cmDspApplyAllDefaults(ctx,inst)) == kOkDspRC )
  5210. {
  5211. }
  5212. return rc;
  5213. }
  5214. cmDspRC_t _cmDspBcastSym_Recv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5215. {
  5216. cmDspRC_t rc = kOkDspRC;
  5217. if( evt->dstVarId == kAttrBcId )
  5218. return cmDspSetEvent(ctx,inst,evt);
  5219. if( evt->dstVarId == kMsgBcId )
  5220. {
  5221. unsigned attrSymId = cmDspSymbol(inst,kAttrBcId);
  5222. if( cmDsvIsSymbol(evt->valuePtr) )
  5223. {
  5224. printf("bcast: %i %s\n",attrSymId,cmSymTblLabel(ctx->stH,cmDsvSymbol(evt->valuePtr)));
  5225. }
  5226. return cmDspSysBroadcastValue(ctx->dspH, attrSymId, evt->valuePtr );
  5227. }
  5228. return rc;
  5229. }
  5230. cmDspClass_t* cmBcastSymClassCons( cmDspCtx_t* ctx )
  5231. {
  5232. cmDspClassSetup(&_cmBcastSym_DC,ctx,"BcastSym",
  5233. NULL,
  5234. _cmDspBcastSym_Alloc,
  5235. NULL,
  5236. _cmDspBcastSym_Reset,
  5237. NULL,
  5238. _cmDspBcastSym_Recv,
  5239. NULL,NULL,
  5240. "Set one input high and all others low.");
  5241. return &_cmBcastSym_DC;
  5242. }
  5243. //------------------------------------------------------------------------------------------------------------
  5244. //)
  5245. //( { label:cmDspSegLine file_desc:"Line segment generator." kw:[sunit] }
  5246. enum
  5247. {
  5248. kRsrcSlId,
  5249. kCmdSlId,
  5250. kTrigSlId,
  5251. kOutSlId,
  5252. };
  5253. cmDspClass_t _cmSegLineDC;
  5254. typedef struct
  5255. {
  5256. cmDspInst_t inst;
  5257. double* x; // x[n]
  5258. unsigned n;
  5259. unsigned i; // current segment
  5260. unsigned m; // cur cnt
  5261. } cmDspSegLine_t;
  5262. cmDspInst_t* _cmDspSegLineAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl )
  5263. {
  5264. cmDspSegLine_t* p = cmDspInstAllocV(cmDspSegLine_t,ctx,classPtr,instSymId,id,storeSymId,va_cnt,vl,
  5265. 1, "rsrc", kRsrcSlId, 0, 0, kInDsvFl | kStrzDsvFl | kReqArgDsvFl, "Name of resource array.",
  5266. 1, "cmd", kCmdSlId, 0, 0, kInDsvFl | kSymDsvFl, "Command",
  5267. 1, "trig", kTrigSlId, 0, 0, kInDsvFl | kTypeDsvMask, "Trigger",
  5268. 1, "out", kOutSlId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Output",
  5269. 0 );
  5270. if( p == NULL )
  5271. return NULL;
  5272. // The array is expected to contain interleaved values:
  5273. // cnt_0, val_0, cnt_1, val_1 .... cnt_n val_n
  5274. // The 'cnt_x' values give the count of trigger values upon which the output will be 'val_x'.
  5275. if( cmDspRsrcDblArray(ctx->dspH,&p->n,&p->x,cmDspDefaultStrcz(&p->inst,kRsrcSlId),NULL) != kOkDspRC )
  5276. {
  5277. cmDspClassErr(ctx,classPtr,kVarArgParseFailDspRC,"The 'SegLine' constructor resource array could not be read.");
  5278. return NULL;
  5279. }
  5280. cmDspSetDefaultDouble( ctx, &p->inst, kOutSlId, 0.0, p->n >= 2 ? p->x[1] : 0.0 );
  5281. p->i = 0;
  5282. p->m = 0;
  5283. return &p->inst;
  5284. }
  5285. cmDspRC_t _cmDspSegLineReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5286. {
  5287. cmDspSegLine_t* p = (cmDspSegLine_t*)inst;
  5288. p->i = 0;
  5289. p->m = 0;
  5290. return cmDspApplyAllDefaults(ctx,inst);
  5291. }
  5292. cmDspRC_t _cmDspSegLineRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt )
  5293. {
  5294. cmDspRC_t rc = kOkDspRC;
  5295. cmDspSegLine_t* p = (cmDspSegLine_t*)inst;
  5296. if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC )
  5297. {
  5298. switch( evt->dstVarId )
  5299. {
  5300. case kTrigSlId:
  5301. {
  5302. double val = cmDspDouble(inst,kOutSlId);
  5303. if( p->i < p->n )
  5304. {
  5305. if( p->m >= p->x[p->i] )
  5306. p->i += 2;
  5307. if( p->i < p->n )
  5308. {
  5309. double x0 = p->x[p->i-2];
  5310. double y0 = p->x[p->i-1];
  5311. double x1 = p->x[p->i+0];
  5312. double y1 = p->x[p->i+1];
  5313. double dx = x1 - x0;
  5314. double dy = y1 - y0;
  5315. val = y0 + (p->m - x0) * dy / dx;
  5316. printf("i:%i m=%i x0:%f y0:%f x1:%f y1:%f : %f\n",p->i,p->m,x0,y0,x1,y1,val);
  5317. }
  5318. else
  5319. {
  5320. val = p->x[p->n-1];
  5321. }
  5322. ++p->m;
  5323. }
  5324. cmDspSetDouble(ctx,inst,kOutSlId,val);
  5325. }
  5326. break;
  5327. case kCmdSlId:
  5328. p->i = 0;
  5329. p->m = 0;
  5330. break;
  5331. }
  5332. }
  5333. return rc;
  5334. }
  5335. cmDspClass_t* cmSegLineClassCons( cmDspCtx_t* ctx )
  5336. {
  5337. cmDspClassSetup(&_cmSegLineDC,ctx,"SegLine",
  5338. NULL,
  5339. _cmDspSegLineAlloc,
  5340. NULL,
  5341. _cmDspSegLineReset,
  5342. NULL,
  5343. _cmDspSegLineRecv,
  5344. NULL,NULL,
  5345. "SegLine");
  5346. return &_cmSegLineDC;
  5347. }
  5348. //)