#include "cmPrefix.h" #include "cmGlobal.h" #include "cmFloatTypes.h" #include "cmComplexTypes.h" #include "cmRpt.h" #include "cmErr.h" #include "cmCtx.h" #include "cmMem.h" #include "cmMallocDebug.h" #include "cmLinkedHeap.h" #include "cmFile.h" #include "cmSymTbl.h" #include "cmJson.h" #include "cmText.h" #include "cmPrefs.h" #include "cmDspValue.h" #include "cmMsgProtocol.h" #include "cmThread.h" #include "cmUdpPort.h" #include "cmUdpNet.h" #include "cmAudioSys.h" #include "cmDspCtx.h" #include "cmDspClass.h" #include "cmDspStore.h" #include "cmDspUi.h" #include "cmDspSys.h" #include "cmMath.h" #include "cmAudioFile.h" #include "cmFileSys.h" #include "cmProcObj.h" #include "cmProcTemplateMain.h" #include "cmProc.h" #include "cmMidi.h" #include "cmProc2.h" #include "cmVectOpsTemplateMain.h" #include "cmAudioFile.h" #include "cmMidiFile.h" #include "cmTimeLine.h" #include "cmScore.h" #include "cmProc4.h" enum { kWndSmpCntKrId, kHopFactKrId, kModeKrId, kThreshKrId, kLwrSlopeKrId, kUprSlopeKrId, kOffsetKrId, kInvertKrId, kBypassKrId, kWetKrId, kAudioInKrId, kAudioOutKrId }; typedef struct { cmDspInst_t inst; cmCtx* ctx; cmSpecDist_t* sdp; } cmDspKr_t; cmDspClass_t _cmKrDC; //========================================================================================================================================== cmDspInst_t* _cmDspKrAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "wndn", kWndSmpCntKrId, 0, 0, kInDsvFl | kUIntDsvFl | kReqArgDsvFl, "Window sample count" }, { "hopf", kHopFactKrId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Hop factor" }, { "mode", kModeKrId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Mode 0=bypass 1=basic 2=spec cnt 3=amp env" }, { "thrh", kThreshKrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Threshold" }, { "lwrs", kLwrSlopeKrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Lower Slope"}, { "uprs", kUprSlopeKrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Upper Slope"}, { "offs", kOffsetKrId, 0, 0, kInDsvFl | kDoubleDsvFl | kOptArgDsvFl, "Offset"}, { "invt", kInvertKrId, 0, 0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Invert"}, { "bypass", kBypassKrId, 0, 0, kInDsvFl | kBoolDsvFl | kOptArgDsvFl, "Bypass enable flag." }, { "wet", kWetKrId, 0, 0, kInDsvFl | kSampleDsvFl, "Wet mix level."}, { "in", kAudioInKrId, 0, 0, kInDsvFl | kAudioBufDsvFl, "Audio Input" }, { "out", kAudioOutKrId, 0, 1, kOutDsvFl | kAudioBufDsvFl, "Audio Output" }, { NULL, 0, 0, 0, 0 } }; cmDspKr_t* p = cmDspInstAlloc(cmDspKr_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); unsigned defWndSmpCnt = cmDspDefaultUInt(&p->inst,kWndSmpCntKrId); unsigned wndSmpCnt = cmNextPowerOfTwo( defWndSmpCnt ); cmDspSetDefaultUInt( ctx,&p->inst, kWndSmpCntKrId, defWndSmpCnt, wndSmpCnt ); cmDspSetDefaultUInt( ctx,&p->inst, kHopFactKrId, 0, 4 ); cmDspSetDefaultUInt( ctx,&p->inst, kModeKrId, 0, kBasicModeSdId ); cmDspSetDefaultDouble( ctx,&p->inst, kThreshKrId, 0, 60.0 ); cmDspSetDefaultDouble( ctx,&p->inst, kLwrSlopeKrId, 0, 2.0 ); cmDspSetDefaultDouble( ctx,&p->inst, kUprSlopeKrId, 0, 0.0 ); cmDspSetDefaultDouble( ctx,&p->inst, kOffsetKrId, 0, 30.0); cmDspSetDefaultUInt( ctx,&p->inst, kInvertKrId, 0, 0 ); cmDspSetDefaultUInt( ctx,&p->inst, kBypassKrId, 0, 0 ); cmDspSetDefaultSample( ctx,&p->inst, kWetKrId, 0, 1.0); //_cmDspKrCmInit(ctx,p); // initialize the cm library p->ctx = cmCtxAlloc(NULL,ctx->rpt,ctx->lhH,ctx->stH); return &p->inst; } cmDspRC_t _cmDspKrFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspKr_t* p = (cmDspKr_t*)inst; cmSpecDistFree(&p->sdp); cmCtxFree(&p->ctx); //_cmDspKrCmFinal(ctx,p); // finalize the cm library return rc; } cmDspRC_t _cmDspKrSetup(cmDspCtx_t* ctx, cmDspKr_t* p ) { cmDspRC_t rc = kOkDspRC; unsigned wndSmpCnt = cmDspUInt(&p->inst,kWndSmpCntKrId); unsigned hopFact = cmDspUInt(&p->inst,kHopFactKrId); unsigned olaWndTypeId =kHannWndId; cmSpecDistFree(&p->sdp); p->sdp = cmSpecDistAlloc(p->ctx, NULL, cmDspSamplesPerCycle(ctx), cmDspSampleRate(ctx), wndSmpCnt, hopFact, olaWndTypeId); assert(p->sdp != NULL ); if((rc = cmDspZeroAudioBuf(ctx,&p->inst,kAudioOutKrId)) != kOkDspRC ) return rc; return rc; } cmDspRC_t _cmDspKrReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspKr_t* p = (cmDspKr_t*)inst; cmDspRC_t rc; if((rc = cmDspApplyAllDefaults(ctx,inst)) != kOkDspRC ) return rc; return _cmDspKrSetup(ctx,p); } cmDspRC_t _cmDspKrExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspKr_t* p = (cmDspKr_t*)inst; cmDspRC_t rc = kOkDspRC; unsigned iChIdx = 0; const cmSample_t* ip = cmDspAudioBuf(ctx,inst,kAudioInKrId,iChIdx); unsigned iSmpCnt = cmDspVarRows(inst,kAudioInKrId); // if no connected if( iSmpCnt == 0 ) return rc; unsigned oChIdx = 0; cmSample_t* op = cmDspAudioBuf(ctx,inst,kAudioOutKrId,oChIdx); unsigned oSmpCnt = cmDspVarRows(inst,kAudioOutKrId); const cmSample_t* sp; cmSample_t wet = cmDspSample(inst,kWetKrId); cmSpecDistExec(p->sdp,ip,iSmpCnt); if((sp = cmSpecDistOut(p->sdp)) != NULL ) { cmVOS_MultVVS(op,oSmpCnt,sp,wet); } if( wet<1.0 ) cmVOS_MultSumVVS(op,oSmpCnt,ip,1.0-wet); return rc; } cmDspRC_t _cmDspKrRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspKr_t* p = (cmDspKr_t*)inst; cmDspRC_t rc = kOkDspRC; cmDspSetEvent(ctx,inst,evt); switch( evt->dstVarId ) { case kWndSmpCntKrId: case kHopFactKrId: _cmDspKrSetup(ctx,p); // THIS IS A HACK // WHEN WND OR HOP CHANGE THE RESULTING CHANGES // SHOULD BE ISOLATED IN cmSpecDist() AND THE // CURRENT STATE OF THE PARAMETERS SHOULD NOT BE // LOST - IF THE CHANGES WERE ISOLATED WITHIN PVANL // AND PVSYN IT MIGHT BE POSSIBLE TO DO WITH // MINIMAL AUDIO INTERUPTION. p->sdp->mode = cmDspUInt(inst,kModeKrId); p->sdp->thresh = cmDspDouble(inst,kThreshKrId); p->sdp->uprSlope = cmDspDouble(inst,kUprSlopeKrId); p->sdp->lwrSlope = cmDspDouble(inst,kLwrSlopeKrId); p->sdp->offset = cmDspDouble(inst,kOffsetKrId); p->sdp->invertFl = cmDspUInt(inst,kInvertKrId)!=0; printf("wsn:%i hsn:%i\n",p->sdp->wndSmpCnt,p->sdp->hopSmpCnt); break; case kModeKrId: p->sdp->mode = cmDspUInt(inst,kModeKrId); printf("mode:%i\n",p->sdp->mode); break; case kThreshKrId: p->sdp->thresh = cmDspDouble(inst,kThreshKrId); //printf("thr:p:%p sdp:%p %f\n",p,p->sdp,p->sdp->thresh); break; case kUprSlopeKrId: p->sdp->uprSlope = cmDspDouble(inst,kUprSlopeKrId); //printf("upr slope:%f\n",p->sdp->uprSlope); break; case kLwrSlopeKrId: p->sdp->lwrSlope = cmDspDouble(inst,kLwrSlopeKrId); //printf("upr slope:%f\n",p->sdp->lwrSlope); break; case kOffsetKrId: p->sdp->offset = cmDspDouble(inst,kOffsetKrId); break; case kInvertKrId: p->sdp->invertFl = cmDspUInt(inst,kInvertKrId)!=0; break; case kWetKrId: break; default: { assert(0); } } return rc; } struct cmDspClass_str* cmKrClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmKrDC,ctx,"Kr", NULL, _cmDspKrAlloc, _cmDspKrFree, _cmDspKrReset, _cmDspKrExec, _cmDspKrRecv, NULL,NULL, "Fourier based non-linear transformer."); return &_cmKrDC; } //========================================================================================================================================== // Time Line UI Object enum { kTlFileTlId, kPrefixPathTlId, kSelTlId, kCursTlId, kResetTlId, kAudFnTlId, kAudLblTlId, kMidiFnTlId, kMidiLblTlId, kBegAudSmpIdxTlId, kEndAudSmpIdxTlId, kBegMidiSmpIdxTlId, kEndMidiSmpIdxTlId }; cmDspClass_t _cmTimeLineDC; typedef struct { cmDspInst_t inst; cmTlH_t tlH; unsigned afIdx; } cmDspTimeLine_t; cmDspInst_t* _cmDspTimeLineAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "tlfile", kTlFileTlId, 0, 0, kInDsvFl | kStrzDsvFl | kReqArgDsvFl, "Time line file." }, { "path", kPrefixPathTlId, 0, 0, kInDsvFl | kStrzDsvFl | kReqArgDsvFl, "Time line data file prefix path" }, { "sel", kSelTlId, 0, 0, kInDsvFl | kOutDsvFl | kUIntDsvFl, "Selected marker id."}, { "curs", kCursTlId, 0, 0, kInDsvFl | kUIntDsvFl, "Current audio file index."}, { "reset", kResetTlId, 0, 0, kInDsvFl | kSymDsvFl, "Resend all outputs." }, { "afn", kAudFnTlId, 0, 0, kOutDsvFl | kStrzDsvFl, "Selected Audio file." }, { "albl", kAudLblTlId, 0, 0, kOutDsvFl | kStrzDsvFl, "Select Audio file time line label."}, { "mfn", kMidiFnTlId, 0, 0, kOutDsvFl | kStrzDsvFl, "Selected MIDI file." }, { "mlbl", kMidiLblTlId, 0, 0, kOutDsvFl | kStrzDsvFl, "Select MIDI file time line label."}, { "absi", kBegAudSmpIdxTlId, 0, 0, kOutDsvFl | kIntDsvFl, "Begin audio sample index."}, { "aesi", kEndAudSmpIdxTlId, 0, 0, kOutDsvFl | kIntDsvFl, "End audio sample index."}, { "mbsi", kBegMidiSmpIdxTlId, 0, 0, kOutDsvFl | kIntDsvFl, "Begin MIDI sample index."}, { "mesi", kEndMidiSmpIdxTlId, 0, 0, kOutDsvFl | kIntDsvFl, "End MIDI sample index."}, { NULL, 0, 0, 0, 0 } }; cmDspTimeLine_t* p = cmDspInstAlloc(cmDspTimeLine_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); cmDspSetDefaultUInt( ctx, &p->inst, kSelTlId, 0, cmInvalidId); cmDspSetDefaultUInt( ctx, &p->inst, kCursTlId, 0, 0); cmDspSetDefaultStrcz(ctx, &p->inst, kAudFnTlId, NULL, ""); cmDspSetDefaultStrcz(ctx, &p->inst, kAudLblTlId, NULL, ""); cmDspSetDefaultStrcz(ctx, &p->inst, kMidiFnTlId, NULL, ""); cmDspSetDefaultStrcz(ctx, &p->inst, kMidiLblTlId, NULL, ""); cmDspSetDefaultInt( ctx, &p->inst, kBegAudSmpIdxTlId, 0, cmInvalidIdx); cmDspSetDefaultInt( ctx, &p->inst, kEndAudSmpIdxTlId, 0, cmInvalidIdx); cmDspSetDefaultInt( ctx, &p->inst, kBegMidiSmpIdxTlId, 0, cmInvalidIdx); cmDspSetDefaultInt( ctx, &p->inst, kEndMidiSmpIdxTlId, 0, cmInvalidIdx); // create the UI control cmDspUiTimeLineCreate(ctx,&p->inst,kTlFileTlId,kPrefixPathTlId,kSelTlId,kCursTlId); p->tlH = cmTimeLineNullHandle; return &p->inst; } cmDspRC_t _cmDspTimeLineFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspTimeLine_t* p = (cmDspTimeLine_t*)inst; if( cmTimeLineFinalize(&p->tlH) != kOkTlRC ) return cmErrMsg(&inst->classPtr->err, kInstFinalFailDspRC, "Time-line finalize failed."); return rc; } cmDspRC_t _cmDspTimeLineReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspTimeLine_t* p = (cmDspTimeLine_t*)inst; cmDspApplyAllDefaults(ctx,inst); const cmChar_t* tlFn; const cmChar_t* tlPrePath = cmDspStrcz(inst,kPrefixPathTlId); if((tlFn = cmDspStrcz(inst, kTlFileTlId )) != NULL ) if( cmTimeLineInitializeFromFile(ctx->cmCtx, &p->tlH, NULL, NULL, tlFn, tlPrePath ) != kOkTlRC ) rc = cmErrMsg(&inst->classPtr->err, kInstResetFailDspRC, "Time-line file open failed."); return rc; } cmDspRC_t _cmDspTimeLineRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspTimeLine_t* p = (cmDspTimeLine_t*)inst; switch( evt->dstVarId ) { case kPrefixPathTlId: cmDspSetEvent(ctx,inst,evt); break; case kCursTlId: cmDspSetEvent(ctx,inst,evt); break; case kResetTlId: case kSelTlId: { unsigned markerId; cmDspSetEvent(ctx,inst,evt); // get the id of the selected marker if((markerId = cmDspUInt(inst,kSelTlId)) != cmInvalidId ) { // get the marker object cmTlObj_t* op; if((op = cmTimeLineIdToObj(p->tlH, cmInvalidId, markerId )) != NULL ) { assert(op->typeId == kMarkerTlId); p->afIdx = op->begSmpIdx; cmDspSetInt(ctx, inst, kBegAudSmpIdxTlId, op->begSmpIdx ); cmDspSetInt(ctx, inst, kEndAudSmpIdxTlId, op->begSmpIdx + op->durSmpCnt ); // locate the audio file assoc'd with the marker cmTlAudioFile_t* afp; if((afp = cmTimeLineAudioFileAtTime(p->tlH,op->seqId,op->seqSmpIdx)) != NULL) { cmDspSetStrcz(ctx, inst, kAudFnTlId, afp->fn ); cmDspSetStrcz(ctx, inst, kAudLblTlId, afp->obj.name ); } // locate the midi file assoc'd with the marker cmTlMidiFile_t* mfp; if((mfp = cmTimeLineMidiFileAtTime(p->tlH,op->seqId,op->seqSmpIdx)) != NULL ) { cmDspSetInt(ctx, inst, kBegMidiSmpIdxTlId, op->seqSmpIdx - mfp->obj.seqSmpIdx ); cmDspSetInt(ctx, inst, kEndMidiSmpIdxTlId, op->seqSmpIdx + op->durSmpCnt - mfp->obj.seqSmpIdx ); cmDspSetStrcz(ctx, inst, kMidiFnTlId, mfp->fn ); cmDspSetStrcz(ctx, inst, kMidiLblTlId,mfp->obj.name ); } } } } break; default: {assert(0);} } return kOkDspRC; } struct cmDspClass_str* cmTimeLineClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmTimeLineDC,ctx,"TimeLine", NULL, _cmDspTimeLineAlloc, _cmDspTimeLineFree, _cmDspTimeLineReset, NULL, _cmDspTimeLineRecv, NULL,NULL, "Time Line control."); return &_cmTimeLineDC; } //========================================================================================================================================== // Score UI Object enum { kFnScId, kSelScId, kSendScId, kStatusScId, kD0ScId, kD1ScId, kSmpIdxScId, kLocIdxScId, kEvtIdxScId, kDynScId, kValTypeScId, kValueScId }; cmDspClass_t _cmScoreDC; typedef struct { cmDspInst_t inst; cmScH_t scH; cmDspCtx_t* ctx; // temporary ctx ptr used during cmScore callback in _cmDspScoreRecv() } cmDspScore_t; cmDspInst_t* _cmDspScoreAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "fn", kFnScId, 0, 0, kInDsvFl | kStrzDsvFl | kReqArgDsvFl, "Score file." }, { "sel", kSelScId, 0, 0, kInDsvFl | kOutDsvFl | kUIntDsvFl, "Selected score element index input."}, { "send", kSendScId, 0, 0, kInDsvFl | kTypeDsvMask, "Resend last selected score element."}, { "status", kStatusScId, 0, 0, kInDsvFl | kIntDsvFl, "Performed MIDI status value output" }, { "d0", kD0ScId, 0, 0, kInDsvFl | kUIntDsvFl, "Performed MIDI msg data byte 0" }, { "d1", kD1ScId, 0, 0, kInDsvFl | kUIntDsvFl, "Performed MIDI msg data byte 1" }, { "smpidx", kSmpIdxScId, 0, 0, kInDsvFl | kUIntDsvFl, "Performed MIDi msg time tag as a sample index." }, { "loc", kLocIdxScId, 0, 0, kInDsvFl | kUIntDsvFl, "Performance score location."}, { "evtidx", kEvtIdxScId, 0, 0, kOutDsvFl | kUIntDsvFl, "Performed event index of following dynamcis level."}, { "dyn", kDynScId, 0, 0, kOutDsvFl | kUIntDsvFl, "Dynamic level of previous event index."}, { "type", kValTypeScId,0, 0, kOutDsvFl | kUIntDsvFl, "Output variable type."}, { "value", kValueScId, 0, 0, kOutDsvFl | kDoubleDsvFl, "Output variable value."}, { NULL, 0, 0, 0, 0 } }; cmDspScore_t* p = cmDspInstAlloc(cmDspScore_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); cmDspSetDefaultUInt( ctx, &p->inst, kSelScId, 0, cmInvalidId); // create the UI control cmDspUiScoreCreate(ctx,&p->inst,kFnScId,kSelScId,kSmpIdxScId,kD0ScId,kD1ScId,kLocIdxScId,kEvtIdxScId,kDynScId,kValTypeScId,kValueScId); p->scH = cmScNullHandle; return &p->inst; } cmDspRC_t _cmDspScoreFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspScore_t* p = (cmDspScore_t*)inst; if( cmScoreFinalize(&p->scH) != kOkTlRC ) return cmErrMsg(&inst->classPtr->err, kInstFinalFailDspRC, "Score finalize failed."); return rc; } // Callback from cmScore triggered from _cmDspScoreRecv() during call to cmScoreSetPerfEvent(). void _cmDspScoreCb( void* arg, const void* data, unsigned byteCnt ) { cmDspInst_t* inst = (cmDspInst_t*)arg; cmDspScore_t* p = (cmDspScore_t*)inst; cmScMsg_t m; if( cmScoreDecode(data,byteCnt,&m) == kOkScRC ) { switch( m.typeId ) { case kDynMsgScId: cmDspSetUInt( p->ctx,inst, kEvtIdxScId, m.u.dyn.evtIdx ); cmDspSetUInt( p->ctx,inst, kDynScId, m.u.dyn.dynLvl ); break; case kVarMsgScId: cmDspSetUInt( p->ctx,inst, kValTypeScId, m.u.meas.varId); cmDspSetDouble(p->ctx,inst, kValueScId, m.u.meas.value); break; default: { assert(0); } } } } cmDspRC_t _cmDspScoreReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspScore_t* p = (cmDspScore_t*)inst; const cmChar_t* tlFn = NULL; unsigned* dynRefArray = NULL; unsigned dynRefCnt = 0; cmDspApplyAllDefaults(ctx,inst); if( cmDspRsrcUIntArray(ctx->dspH, &dynRefCnt, &dynRefArray, "dynRef", NULL ) != kOkDspRC ) { rc = cmErrMsg(&inst->classPtr->err, kRsrcNotFoundDspRC, "The dynamics reference array resource was not found."); goto errLabel; } if((tlFn = cmDspStrcz(inst, kFnScId )) != NULL ) if( cmScoreInitialize(ctx->cmCtx, &p->scH, tlFn, cmDspSampleRate(ctx), dynRefArray, dynRefCnt, _cmDspScoreCb, p, cmSymTblNullHandle ) != kOkTlRC ) rc = cmErrMsg(&inst->classPtr->err, kInstResetFailDspRC, "Score file open failed."); errLabel: return rc; } cmDspRC_t _cmDspScoreRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspScore_t* p = (cmDspScore_t*)inst; if( evt->dstVarId == kSendScId ) { unsigned selIdx; if((selIdx = cmDspUInt(inst,kSelScId)) != cmInvalidIdx ) { cmDspSetUInt(ctx,inst,kSelScId, selIdx ); cmScoreClearPerfInfo(p->scH); } return kOkDspRC; } cmDspSetEvent(ctx,inst,evt); switch( evt->dstVarId ) { case kSelScId: cmScoreClearPerfInfo(p->scH); break; case kStatusScId: //printf("st:%x\n",cmDspUInt(inst,kStatusScId)); break; case kLocIdxScId: { assert( cmDspUInt(inst,kStatusScId ) == kNoteOnMdId ); p->ctx = ctx; // setup p->ctx for use in _cmDspScoreCb() // this call may result in callbacks to _cmDspScoreCb() cmScoreExecPerfEvent(p->scH, cmDspUInt(inst,kLocIdxScId), cmDspUInt(inst,kSmpIdxScId), cmDspUInt(inst,kD0ScId), cmDspUInt(inst,kD1ScId) ); } break; } return kOkDspRC; } struct cmDspClass_str* cmScoreClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmScoreDC,ctx,"Score", NULL, _cmDspScoreAlloc, _cmDspScoreFree, _cmDspScoreReset, NULL, _cmDspScoreRecv, NULL,NULL, "Score control."); return &_cmScoreDC; } //========================================================================================================================================== // MIDI File Player enum { kFnMfId, kSelMfId, kBsiMfId, kEsiMfId, kStatusMfId, kD0MfId, kD1MfId, kSmpIdxMfId, kIdMfId }; cmDspClass_t _cmMidiFilePlayDC; typedef struct { cmDspInst_t inst; cmMidiFileH_t mfH; unsigned curMsgIdx; // current midi file msg index int csi; // current sample index int bsi; // starting sample index int esi; // ending sample index unsigned startSymId; unsigned stopSymId; unsigned contSymId; bool errFl; } cmDspMidiFilePlay_t; /* 'bsi' and 'esi' give the starting and ending sample for MIDI file playback. These indexes are relative to the start of the file. When the player recieves a 'start' msg it sets the current sample index 'si' to 'bsi' and begins scanning for the next note to play. On each call to the _cmDspMidiFilePlayExec() msgs that fall in the interval si:si+sPc-1 will be transmitted. (where sPc are the number of samples per DSP cycle). */ cmDspInst_t* _cmDspMidiFilePlayAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "fn", kFnMfId, 0, 0, kInDsvFl | kStrzDsvFl, "File name"}, { "sel", kSelMfId, 0, 0, kInDsvFl | kSymDsvFl, "start | stop | continue" }, { "bsi", kBsiMfId, 0, 0, kInDsvFl | kIntDsvFl, "Starting sample." }, { "esi", kEsiMfId, 0, 0, kInDsvFl | kIntDsvFl, "Ending sample."}, { "status", kStatusMfId, 0, 0, kOutDsvFl | kIntDsvFl, "Status value output" }, { "d0", kD0MfId, 0, 0, kOutDsvFl | kUIntDsvFl, "Data byte 0" }, { "d1", kD1MfId, 0, 0, kOutDsvFl | kUIntDsvFl, "Data byte 1" }, { "smpidx", kSmpIdxMfId, 0, 0, kOutDsvFl | kUIntDsvFl, "Msg time tag as a sample index." }, { "id", kIdMfId, 0, 0, kOutDsvFl | kUIntDsvFl, "MIDI file msg unique id."}, { NULL, 0, 0, 0, 0 } }; cmDspMidiFilePlay_t* p = cmDspInstAlloc(cmDspMidiFilePlay_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); p->startSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"start"); p->stopSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"stop"); p->contSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"continue"); p->mfH = cmMidiFileNullHandle; cmDspSetDefaultStrcz( ctx, &p->inst, kFnMfId, NULL, ""); cmDspSetDefaultSymbol(ctx, &p->inst, kSelMfId, p->stopSymId); cmDspSetDefaultInt( ctx, &p->inst, kBsiMfId, 0, 0); cmDspSetDefaultInt( ctx, &p->inst, kEsiMfId, 0, 0); cmDspSetDefaultUInt( ctx, &p->inst, kStatusMfId, 0, 0); cmDspSetDefaultUInt( ctx, &p->inst, kD0MfId, 0, 0); cmDspSetDefaultUInt( ctx, &p->inst, kD1MfId, 0, 0); return &p->inst; } cmDspRC_t _cmDspMidiFilePlayFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspMidiFilePlay_t* p = (cmDspMidiFilePlay_t*)inst; if( cmMidiFileClose(&p->mfH) ) return cmErrMsg(&inst->classPtr->err, kInstFinalFailDspRC, "MIDI file close failed."); return kOkDspRC; } // return the index of the msg following smpIdx unsigned _cmDspMidiFilePlaySeekMsgIdx( cmDspCtx_t* ctx, cmDspInst_t* inst, unsigned smpIdx ) { cmDspMidiFilePlay_t* p = (cmDspMidiFilePlay_t*)inst; if( cmMidiFileIsValid(p->mfH) == false ) { cmErrMsg(&inst->classPtr->err, kInvalidStateDspRC,"The MIDI file player has not been given a valid MIDI file."); return cmInvalidIdx; } unsigned i; unsigned n = cmMidiFileMsgCount(p->mfH); const cmMidiTrackMsg_t** a = cmMidiFileMsgArray(p->mfH); for(i=0; idtick > smpIdx ) break; return i==n ? cmInvalidIdx : i; } cmDspRC_t _cmDspMidiFilePlayOpen(cmDspCtx_t* ctx, cmDspInst_t* inst ) { cmDspRC_t rc = kOkDspRC; const cmChar_t* fn = cmDspStrcz(inst,kFnMfId); cmDspMidiFilePlay_t* p = (cmDspMidiFilePlay_t*)inst; p->errFl = false; if( fn==NULL || strlen(fn)==0 ) return rc; if( cmMidiFileOpen( fn, &p->mfH, ctx->cmCtx ) != kOkFileRC ) rc = cmErrMsg(&inst->classPtr->err, kInstResetFailDspRC, "MIDI file open failed."); else { p->curMsgIdx = 0; p->bsi = cmDspInt(inst,kBsiMfId); p->esi = cmDspInt(inst,kEsiMfId); p->csi = 0; // force the first msg to occurr one quarter note into the file cmMidiFileSetDelay(p->mfH, cmMidiFileTicksPerQN(p->mfH) ); // convert midi msg times to absolute time in samples cmMidiFileTickToSamples(p->mfH,cmDspSampleRate(ctx),true); } return rc; } cmDspRC_t _cmDspMidiFilePlayReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspApplyAllDefaults(ctx,inst); return _cmDspMidiFilePlayOpen(ctx,inst); } cmDspRC_t _cmDspMidiFilePlayExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspMidiFilePlay_t* p = (cmDspMidiFilePlay_t*)inst; unsigned sPc = cmDspSamplesPerCycle(ctx); if( cmDspSymbol(inst,kSelMfId) != p->stopSymId ) { if( cmMidiFileIsValid(p->mfH) == false ) { if( p->errFl==false ) { rc = cmErrMsg(&inst->classPtr->err, kInvalidStateDspRC,"The MIDI file player has not been given a valid MIDI file."); p->errFl = true; } return rc; } const cmMidiTrackMsg_t** mpp = cmMidiFileMsgArray(p->mfH); unsigned msgN = cmMidiFileMsgCount(p->mfH); for(; p->curMsgIdx < msgN && p->csi <= mpp[p->curMsgIdx]->dtick && mpp[p->curMsgIdx]->dtick < (p->csi + sPc); ++p->curMsgIdx ) { const cmMidiTrackMsg_t* mp = mpp[p->curMsgIdx]; switch( mp->status ) { case kNoteOnMdId: case kCtlMdId: cmDspSetUInt(ctx,inst, kSmpIdxMfId, mp->dtick); cmDspSetUInt(ctx,inst, kD1MfId, mp->u.chMsgPtr->d1); cmDspSetUInt(ctx,inst, kD0MfId, mp->u.chMsgPtr->d0); cmDspSetUInt(ctx,inst, kStatusMfId, mp->status); cmDspSetUInt(ctx,inst, kIdMfId, mp->uid); break; } } } p->csi += sPc; return rc; } cmDspRC_t _cmDspMidiFilePlayRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspMidiFilePlay_t* p = (cmDspMidiFilePlay_t*)inst; cmDspSetEvent(ctx,inst,evt); switch(evt->dstVarId) { case kFnMfId: _cmDspMidiFilePlayOpen(ctx, inst ); break; case kSelMfId: { if( cmDspSymbol(inst,kSelMfId)==p->startSymId ) { p->csi = cmDspInt(inst,kBsiMfId); p->curMsgIdx = _cmDspMidiFilePlaySeekMsgIdx(ctx, inst, p->csi ); } break; } } return kOkDspRC; } struct cmDspClass_str* cmMidiFilePlayClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmMidiFilePlayDC,ctx,"MidiFilePlay", NULL, _cmDspMidiFilePlayAlloc, _cmDspMidiFilePlayFree, _cmDspMidiFilePlayReset, _cmDspMidiFilePlayExec, _cmDspMidiFilePlayRecv, NULL,NULL, "MIDI file player."); return &_cmMidiFilePlayDC; } //========================================================================================================================================== enum { kFnSfId, kBufCntSfId, kMinLkAhdSfId, kMaxWndCntSfId, kMinVelSfId, kIndexSfId, kStatusSfId, kD0SfId, kD1SfId, kSmpIdxSfId, kCmdSfId, kOutSfId, kDynSfId, kEvenSfId, kTempoSfId, kCostSfId, kSymSfId }; cmDspClass_t _cmScFolDC; struct cmDspScFol_str; typedef struct { cmDspCtx_t* ctx; struct cmDspScFol_str* sfp; } cmDspScFolCbArg_t; typedef struct cmDspScFol_str { cmDspInst_t inst; cmScMatcher* sfp; cmScMeas* smp; cmScH_t scH; cmDspScFolCbArg_t arg; unsigned printSymId; unsigned quietSymId; } cmDspScFol_t; cmDspInst_t* _cmDspScFolAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "fn", kFnSfId, 0, 0, kInDsvFl | kStrzDsvFl | kReqArgDsvFl, "Score file." }, { "bufcnt",kBufCntSfId, 0, 0, kInDsvFl | kUIntDsvFl, "Event buffer element count." }, { "lkahd", kMinLkAhdSfId, 0, 0, kInDsvFl | kUIntDsvFl, "Minimum window look-ahead."}, { "wndcnt",kMaxWndCntSfId,0, 0, kInDsvFl | kUIntDsvFl, "Maximum window length."}, { "minvel",kMinVelSfId, 0, 0, kInDsvFl | kUIntDsvFl, "Minimum velocity."}, { "index", kIndexSfId, 0, 0, kInDsvFl | kUIntDsvFl, "Tracking start location."}, { "status",kStatusSfId, 0, 0, kInDsvFl | kUIntDsvFl, "MIDI status byte"}, { "d0", kD0SfId, 0, 0, kInDsvFl | kUIntDsvFl, "MIDI data byte 0"}, { "d1", kD1SfId, 0, 0, kInDsvFl | kUIntDsvFl, "MIDI data byte 1"}, { "smpidx",kSmpIdxSfId, 0, 0, kInDsvFl | kUIntDsvFl, "MIDI time tag as a sample index"}, { "cmd", kCmdSfId, 0, 0, kInDsvFl | kSymDsvFl, "Command input: print | quiet"}, { "out", kOutSfId, 0, 0, kOutDsvFl| kUIntDsvFl, "Current score location index."}, { "dyn", kDynSfId, 0, 0, kOutDsvFl| kDoubleDsvFl, "Dynamic value."}, { "even", kEvenSfId, 0, 0, kOutDsvFl| kDoubleDsvFl, "Evenness value."}, { "tempo", kTempoSfId, 0, 0, kOutDsvFl| kDoubleDsvFl, "Tempo value."}, { "cost", kCostSfId, 0, 0, kOutDsvFl| kDoubleDsvFl, "Match cost value."}, { "sym", kSymSfId, 0, 0, kOutDsvFl| kSymDsvFl, "Symbol associated with a global variable which has changed value."}, { NULL, 0, 0, 0, 0, NULL } }; cmDspScFol_t* p; if((p = cmDspInstAlloc(cmDspScFol_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl)) == NULL ) return NULL; p->sfp = cmScMatcherAlloc(ctx->cmProcCtx, NULL, 0, cmScNullHandle, 0, 0, NULL, NULL ); p->smp = cmScMeasAlloc( ctx->cmProcCtx, NULL, cmScNullHandle, 0, NULL, 0 ); p->printSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"print"); p->quietSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"quiet"); cmDspSetDefaultUInt( ctx, &p->inst, kBufCntSfId, 0, 7); cmDspSetDefaultUInt( ctx, &p->inst, kMaxWndCntSfId, 0, 10); cmDspSetDefaultUInt( ctx, &p->inst, kMinLkAhdSfId, 0, 3); cmDspSetDefaultUInt( ctx, &p->inst, kMinVelSfId, 0, 5); cmDspSetDefaultUInt( ctx, &p->inst, kIndexSfId, 0, 0); cmDspSetDefaultUInt( ctx, &p->inst, kOutSfId, 0, 0); cmDspSetDefaultDouble( ctx, &p->inst, kDynSfId, 0, 0); cmDspSetDefaultDouble( ctx, &p->inst, kEvenSfId, 0, 0); cmDspSetDefaultDouble( ctx, &p->inst, kTempoSfId, 0, 0); cmDspSetDefaultDouble( ctx, &p->inst, kCostSfId, 0, 0); cmDspSetDefaultSymbol(ctx,&p->inst, kCmdSfId, p->quietSymId ); return &p->inst; } cmDspRC_t _cmDspScFolFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspScFol_t* p = (cmDspScFol_t*)inst; cmScMatcherFree(&p->sfp); cmScMeasFree(&p->smp); cmScoreFinalize(&p->scH); return kOkDspRC; } // This is a callback function from cmScMatcherExec() which is called when // this cmDspFol object receives a new score location index. void _cmScFolMatcherCb( cmScMatcher* p, void* arg, cmScMatcherResult_t* rp ) { cmDspScFolCbArg_t* ap = (cmDspScFolCbArg_t*)arg; if( cmScMeasExec(ap->sfp->smp, rp->mni, rp->locIdx, rp->scEvtIdx, rp->flags, rp->smpIdx, rp->pitch, rp->vel ) == cmOkRC ) { cmDspInst_t* inst = &(ap->sfp->inst); // send 'set' values that were calculated on the previous call to cmScMeasExec() unsigned i; for(i=ap->sfp->smp->vsi; isfp->smp->nsi; ++i) if(ap->sfp->smp->set[i].value != DBL_MAX ) { switch( ap->sfp->smp->set[i].sp->varId ) { case kEvenVarScId: cmDspSetDouble(ap->ctx,inst,kEvenSfId,ap->sfp->smp->set[i].value); break; case kDynVarScId: cmDspSetDouble(ap->ctx,inst,kDynSfId,ap->sfp->smp->set[i].value); break; case kTempoVarScId: cmDspSetDouble(ap->ctx,inst,kTempoSfId,ap->sfp->smp->set[i].value); break; default: { assert(0); } } cmDspSetDouble(ap->ctx,inst,kCostSfId,ap->sfp->smp->set[i].match_cost); // Set the values in the global variable storage cmDspValue_t vv,cv; unsigned j; cmDsvSetDouble(&vv,ap->sfp->smp->set[i].value); cmDsvSetDouble(&cv,ap->sfp->smp->set[i].match_cost); for(j=0; jsfp->smp->set[i].sp->sectCnt; ++j) { cmDspStoreSetValueViaSym(ap->ctx->dsH, ap->sfp->smp->set[i].sp->symArray[j], &vv ); cmDspStoreSetValueViaSym(ap->ctx->dsH, ap->sfp->smp->set[i].sp->costSymArray[j], &cv ); cmDspSetSymbol(ap->ctx,inst,kSymSfId,ap->sfp->smp->set[i].sp->symArray[j]); cmDspSetSymbol(ap->ctx,inst,kSymSfId,ap->sfp->smp->set[i].sp->costSymArray[j]); } } /* // trigger 'section' starts for(i=ap->sfp->smp->vsli; isfp->smp->nsli; ++i) { const cmScoreLoc_t* locPtr = cmScoreLoc(ap->sfp->smp->mp->scH,i); if( locPtr->begSectPtr != NULL ) cmDspSetUInt(ap->ctx,inst,kSectIndexSfId,locPtr->begSectPtr->index); } */ } } cmDspRC_t _cmDspScFolOpenScore( cmDspCtx_t* ctx, cmDspInst_t* inst ) { cmDspRC_t rc = kOkDspRC; cmDspScFol_t* p = (cmDspScFol_t*)inst; const cmChar_t* fn; if((fn = cmDspStrcz(inst,kFnSfId)) == NULL || strlen(fn)==0 ) return cmErrMsg(&inst->classPtr->err, kInvalidArgDspRC, "No score file name supplied."); if( cmScoreInitialize(ctx->cmCtx, &p->scH, fn, cmDspSampleRate(ctx), NULL, 0, NULL, NULL, ctx->stH ) != kOkScRC ) return cmErrMsg(&inst->classPtr->err, kSubSysFailDspRC, "Unable to open the score '%s'.",fn); if( cmScoreIsValid(p->scH) ) { unsigned* dynRefArray = NULL; unsigned dynRefCnt = 0; // initialize the cmScMatcher if( cmScMatcherInit(p->sfp, cmDspSampleRate(ctx), p->scH, cmDspUInt(inst,kMaxWndCntSfId), cmDspUInt(inst,kBufCntSfId), _cmScFolMatcherCb, p->smp ) != cmOkRC ) rc = cmErrMsg(&inst->classPtr->err, kSubSysFailDspRC, "Internal score follower allocation failed."); // read the dynamics reference array if( cmDspRsrcUIntArray(ctx->dspH, &dynRefCnt, &dynRefArray, "dynRef", NULL ) != kOkDspRC ) { rc = cmErrMsg(&inst->classPtr->err, kRsrcNotFoundDspRC, "The dynamics reference array resource was not found."); goto errLabel; } // initialize the cmScMeas object. if( cmScMeasInit(p->smp, p->scH, cmDspSampleRate(ctx), dynRefArray, dynRefCnt ) != cmOkRC ) rc = cmErrMsg(&inst->classPtr->err, kSubSysFailDspRC, "Internal scMeas object initialization failed."); } errLabel: return rc; } cmDspRC_t _cmDspScFolReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc; if((rc = cmDspApplyAllDefaults(ctx,inst)) != kOkDspRC ) return rc; return _cmDspScFolOpenScore(ctx,inst); } cmDspRC_t _cmDspScFolRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspScFol_t* p = (cmDspScFol_t*)inst; if((rc = cmDspSetEvent(ctx,inst,evt)) == kOkDspRC && p->sfp != NULL ) { switch( evt->dstVarId ) { case kIndexSfId: if( cmScoreIsValid(p->scH) ) { if( cmScMeasReset( p->smp ) != cmOkRC ) cmErrMsg(&inst->classPtr->err, kSubSysFailDspRC, "Score measure unit reset to score index '%i' failed."); if( cmScMatcherReset( p->sfp, cmDspUInt(inst,kIndexSfId) ) != cmOkRC ) cmErrMsg(&inst->classPtr->err, kSubSysFailDspRC, "Score follower reset to score index '%i' failed."); } break; case kStatusSfId: if( cmScoreIsValid(p->scH)) { unsigned scLocIdx = cmInvalidIdx; // setup the cmScMeas() callback arg. p->arg.ctx = ctx; p->arg.sfp = p; p->sfp->cbArg = &p->arg; // this call may result in a callback to _cmScFolMatcherCb() if( cmScMatcherExec(p->sfp, cmDspUInt(inst,kSmpIdxSfId), cmDspUInt(inst,kStatusSfId), cmDspUInt(inst,kD0SfId), cmDspUInt(inst,kD1SfId), &scLocIdx) == cmOkRC ) if( scLocIdx != cmInvalidIdx ) cmDspSetUInt(ctx,inst,kOutSfId,scLocIdx); } break; case kFnSfId: _cmDspScFolOpenScore(ctx,inst); break; case kCmdSfId: if( cmDspSymbol(inst,kCmdSfId) == p->printSymId ) p->sfp->printFl = true; else if( cmDspSymbol(inst,kCmdSfId) == p->quietSymId ) p->sfp->printFl = false; break; } } return rc; } struct cmDspClass_str* cmScFolClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmScFolDC,ctx,"ScFol", NULL, _cmDspScFolAlloc, _cmDspScFolFree, _cmDspScFolReset, NULL, _cmDspScFolRecv, NULL,NULL, "Score Follower"); return &_cmScFolDC; } //========================================================================================================================================== enum { kScLocIdxMdId, kResetIdxMdId, kCmdMdId }; cmDspClass_t _cmModulatorDC; typedef struct { cmDspInst_t inst; cmScModulator* mp; cmDspCtx_t* tmp_ctx; // used to temporarily hold the current cmDspCtx during callback cmChar_t* fn; cmChar_t* modLabel; unsigned onSymId; unsigned offSymId; } cmDspScMod_t; void _cmDspScModCb( void* arg, unsigned varSymId, double value ) { cmDspScMod_t* p = (cmDspScMod_t*)arg; cmDspVar_t* varPtr; if((varPtr = cmDspVarSymbolToPtr( p->tmp_ctx, &p->inst, varSymId, 0 )) == NULL ) return; cmDspSetDouble(p->tmp_ctx,&p->inst,varPtr->constId,value); } cmDspInst_t* _cmDspScModAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { va_list vl1; va_copy(vl1,vl); cmDspVarArg_t args[] = { { "index", kScLocIdxMdId, 0,0, kInDsvFl | kUIntDsvFl, "Score follower index input."}, { "reset", kResetIdxMdId, 0,0, kInDsvFl | kUIntDsvFl | kOptArgDsvFl, "Reset the modulator and go to the score index."}, { "cmd", kCmdMdId, 0,0, kInDsvFl | kSymDsvFl | kOptArgDsvFl, "on | off."}, { NULL, 0, 0, 0, 0 } }; // validate the argument count if( va_cnt != 2 ) { cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The Modulator requires at least two arguments."); return NULL; } // read the modulator file and label strings const cmChar_t* fn = va_arg(vl1,const cmChar_t*); const cmChar_t* modLabel = va_arg(vl1,const cmChar_t*); va_end(vl1); // validate the file if( fn==NULL || cmFsIsFile(fn)==false ) { cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The Modulator file '%s' is not valid.",cmStringNullGuard(fn)); return NULL; } // allocate the internal modulator object cmScModulator* mp = cmScModulatorAlloc(ctx->cmProcCtx, NULL, ctx->cmCtx, ctx->stH, cmDspSampleRate(ctx), cmDspSamplesPerCycle(ctx), fn, modLabel, _cmDspScModCb, NULL ); if(mp == NULL ) { cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The internal modulator object initialization failed."); return NULL; } unsigned fixArgCnt = sizeof(args)/sizeof(args[0]) - 1; unsigned argCnt = fixArgCnt + cmScModulatorOutVarCount(mp); cmDspVarArg_t a[ argCnt+1 ]; unsigned i; cmDspArgCopy( a, argCnt, 0, args, fixArgCnt ); for(i=fixArgCnt; istH, vp->varSymId ); const cmChar_t* docStr = cmTsPrintfS("Variable output for %s",label); cmDspArgSetup(ctx, a + i, label, cmInvalidId, i, 0, 0, kOutDsvFl | kDoubleDsvFl, docStr ); } cmDspArgSetupNull(a+argCnt); // set terminating arg. flags cmDspScMod_t* p = cmDspInstAlloc(cmDspScMod_t,ctx,classPtr,a,instSymId,id,storeSymId,va_cnt,vl); p->fn = cmMemAllocStr(fn); p->modLabel = cmMemAllocStr(modLabel); p->mp = mp; p->onSymId = cmSymTblId(ctx->stH,"on"); p->offSymId = cmSymTblId(ctx->stH,"off"); mp->cbArg = p; // set the modulator callback arg cmDspSetDefaultUInt(ctx,&p->inst,kScLocIdxMdId,0,0); cmDspSetDefaultSymbol(ctx,&p->inst,kCmdMdId,p->offSymId); return &p->inst; } cmDspRC_t _cmDspScModFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspScMod_t* p = (cmDspScMod_t*)inst; if( cmScModulatorFree(&p->mp) != kOkTlRC ) return cmErrMsg(&inst->classPtr->err, kInstFinalFailDspRC, "Modulator release failed."); cmMemFree(p->fn); cmMemFree(p->modLabel); return rc; } cmDspRC_t _cmDspScModReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspApplyAllDefaults(ctx,inst); return rc; } cmDspRC_t _cmDspScModRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspScMod_t* p = (cmDspScMod_t*)inst; cmDspSetEvent(ctx,inst,evt); switch( evt->dstVarId ) { case kResetIdxMdId: cmDspSetUInt(ctx,inst,kScLocIdxMdId,cmDspUInt(inst,kResetIdxMdId)); break; case kCmdMdId: { unsigned symId = cmDspSymbol(inst,kCmdMdId); if( symId == p->onSymId ) cmScModulatorReset(p->mp, ctx->cmCtx, cmDspUInt(inst,kScLocIdxMdId)); } break; } return kOkDspRC; } cmDspRC_t _cmDspScModExec(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspScMod_t* p = (cmDspScMod_t*)inst; if( cmDspSymbol(inst,kCmdMdId) != p->offSymId ) { p->tmp_ctx = ctx; cmScModulatorExec(p->mp,cmDspUInt(inst,kScLocIdxMdId)); } return rc; } struct cmDspClass_str* cmScModClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmModulatorDC,ctx,"ScMod", NULL, _cmDspScModAlloc, _cmDspScModFree, _cmDspScModReset, _cmDspScModExec, _cmDspScModRecv, NULL,NULL, "Score Driven Variable Modulator."); return &_cmModulatorDC; } //========================================================================================================================================== enum { kInChCntGsId, kOutGroupCntGsId, kGroupSelIdxGsId, kBaseInFloatGsId }; cmDspClass_t _cmGSwitchDC; typedef struct { cmDspInst_t inst; unsigned iChCnt; unsigned oGroupCnt; unsigned baseInFloatGsId; unsigned baseInSymGsId; unsigned baseInBoolGsId; unsigned baseOutFloatGsId; unsigned baseOutSymGsId; unsigned baseOutBoolGsId; } cmDspGSwitch_t; cmDspInst_t* _cmDspGSwitchAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { va_list vl1; va_copy(vl1,vl); cmDspVarArg_t args[] = { { "ichs", kInChCntGsId, 0,0, kUIntDsvFl | kReqArgDsvFl, "Input channel count."}, { "ochs", kOutGroupCntGsId, 0,0, kUIntDsvFl | kReqArgDsvFl, "Output group count."}, { "sel", kGroupSelIdxGsId, 0,0, kInDsvFl | kUIntDsvFl, "Group select index."}, { NULL, 0, 0, 0, 0 } }; // validate the argument count if( va_cnt != 2 ) { cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The GSwitch requires at least two arguments."); return NULL; } // read the input ch and output group count unsigned iChCnt = va_arg(vl1,unsigned); unsigned oGroupCnt = va_arg(vl1,unsigned); va_end(vl1); // validate the channel counts if( iChCnt == 0 || oGroupCnt==0 ) { cmDspClassErr(ctx,classPtr,kInvalidArgDspRC,"The GSwitch input channel count and group count must be greater than zero."); return NULL; } unsigned typeCnt = 3; // i.e. float,sym,bool unsigned baseInFloatGsId = kBaseInFloatGsId; unsigned baseInSymGsId = baseInFloatGsId + iChCnt; unsigned baseInBoolGsId = baseInSymGsId + iChCnt; unsigned baseOutFloatGsId = baseInBoolGsId + iChCnt; unsigned baseOutSymGsId = baseOutFloatGsId + (iChCnt * oGroupCnt); unsigned baseOutBoolGsId = baseOutSymGsId + (iChCnt * oGroupCnt); unsigned fixArgCnt = 3; unsigned varArgCnt = (iChCnt * typeCnt) + (iChCnt * typeCnt * oGroupCnt); unsigned argCnt = fixArgCnt + varArgCnt; cmDspVarArg_t a[ argCnt+1 ]; unsigned i; cmDspArgCopy( a, argCnt, 0, args, fixArgCnt ); cmDspArgSetupN( ctx, a, argCnt, baseInFloatGsId, iChCnt, "f-in", baseInFloatGsId, 0, 0, kInDsvFl | kDoubleDsvFl, "Float input"); cmDspArgSetupN( ctx, a, argCnt, baseInSymGsId, iChCnt, "s-in", baseInSymGsId, 0, 0, kInDsvFl | kSymDsvFl, "Symbol input"); cmDspArgSetupN( ctx, a, argCnt, baseInBoolGsId, iChCnt, "b-in", baseInBoolGsId, 0, 0, kInDsvFl | kBoolDsvFl, "Bool input"); unsigned labelCharCnt = 63; cmChar_t label[labelCharCnt+1]; label[labelCharCnt] = 0; unsigned gsid = baseOutFloatGsId; for(i=0; iiChCnt = iChCnt; p->oGroupCnt = oGroupCnt; p->baseInFloatGsId = baseInFloatGsId; p->baseInSymGsId = baseInSymGsId; p->baseInBoolGsId = baseInBoolGsId; p->baseOutFloatGsId = baseOutFloatGsId; p->baseOutSymGsId = baseOutSymGsId; p->baseOutBoolGsId = baseOutBoolGsId; cmDspSetDefaultUInt(ctx,&p->inst,kGroupSelIdxGsId,0,0); return &p->inst; } cmDspRC_t _cmDspGSwitchReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspApplyAllDefaults(ctx,inst); return rc; } cmDspRC_t _cmDspGSwitchRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspGSwitch_t* p = (cmDspGSwitch_t*)inst; // if this is the group selector if( evt->dstVarId == kGroupSelIdxGsId ) { unsigned idx; if( (idx = cmDsvGetUInt(evt->valuePtr)) > p->oGroupCnt ) cmDspInstErr(ctx,inst,kInvalidArgDspRC,"The GSwitch group select index %i is out of range %i.",idx,p->oGroupCnt); else cmDspSetEvent(ctx,inst,evt); return rc; } // get the group selector unsigned groupIdx = cmDspUInt(inst,kGroupSelIdxGsId); assert( groupIdx < p->oGroupCnt); // if this is a float input if( p->baseInFloatGsId <= evt->dstVarId && evt->dstVarId < p->baseInFloatGsId + p->iChCnt ) { unsigned outVarId = p->baseOutFloatGsId + (groupIdx * p->iChCnt) + (evt->dstVarId - p->baseInFloatGsId); cmDspValueSet(ctx, inst, outVarId, evt->valuePtr, 0 ); return rc; } // if this is a symbol input if( p->baseInSymGsId <= evt->dstVarId && evt->dstVarId < p->baseInSymGsId + p->iChCnt ) { unsigned outVarId = p->baseOutSymGsId + (groupIdx * p->iChCnt) + (evt->dstVarId - p->baseInSymGsId); cmDspValueSet(ctx, inst, outVarId, evt->valuePtr, 0 ); return rc; } // if this is a bool input if( p->baseInBoolGsId <= evt->dstVarId && evt->dstVarId < p->baseInBoolGsId + p->iChCnt ) { unsigned outVarId = p->baseOutBoolGsId + (groupIdx * p->iChCnt) + (evt->dstVarId - p->baseInBoolGsId); cmDspValueSet(ctx, inst, outVarId, evt->valuePtr, 0 ); return rc; } return rc; } struct cmDspClass_str* cmGSwitchClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmGSwitchDC,ctx,"GSwitch", NULL, _cmDspGSwitchAlloc, NULL, _cmDspGSwitchReset, NULL, _cmDspGSwitchRecv, NULL,NULL, "Ganged switch."); return &_cmGSwitchDC; } //========================================================================================================================================== enum { kMinInSrId, kMaxInSrId, kMinOutSrId, kMaxOutSrId, kValInSrId, kValOutSrId, }; cmDspClass_t _cmScaleRangeDC; typedef struct { cmDspInst_t inst; } cmDspScaleRange_t; cmDspInst_t* _cmDspScaleRangeAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { va_list vl1; va_copy(vl1,vl); cmDspVarArg_t args[] = { { "min_in", kMinInSrId, 0,0, kInDsvFl | kDoubleDsvFl , "Min Input value."}, { "max_in", kMaxInSrId, 0,0, kInDsvFl | kDoubleDsvFl , "Min Input value."}, { "min_out", kMinOutSrId, 0,0, kInDsvFl | kDoubleDsvFl , "Min Input value."}, { "max_out", kMaxOutSrId, 0,0, kInDsvFl | kDoubleDsvFl , "Min Input value."}, { "val_in", kValInSrId, 0,0, kInDsvFl | kDoubleDsvFl, "Input value."}, { "val_out", kValOutSrId, 0,0, kOutDsvFl | kDoubleDsvFl, "Output value"}, { NULL, 0, 0, 0, 0 } }; cmDspScaleRange_t* p = cmDspInstAlloc(cmDspScaleRange_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); cmDspSetDefaultDouble(ctx,&p->inst,kMinInSrId,0,0); cmDspSetDefaultDouble(ctx,&p->inst,kMaxInSrId,0,1.0); cmDspSetDefaultDouble(ctx,&p->inst,kMinOutSrId,0,0); cmDspSetDefaultDouble(ctx,&p->inst,kMaxOutSrId,0,1.0); return &p->inst; } cmDspRC_t _cmDspScaleRangeReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspApplyAllDefaults(ctx,inst); return rc; } cmDspRC_t _cmDspScaleRangeRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; //cmDspScaleRange_t* p = (cmDspScaleRange_t*)inst; cmDspSetEvent(ctx,inst,evt); if( evt->dstVarId == kValInSrId ) { double val = cmDspDouble(inst,kValInSrId); double min_in = cmDspDouble(inst,kMinInSrId); double max_in = cmDspDouble(inst,kMaxInSrId); double min_out = cmDspDouble(inst,kMinOutSrId); double max_out = cmDspDouble(inst,kMaxOutSrId); double x = cmMax(min_in,cmMin(max_in,val)); x = (x - min_in)/(max_in - min_in); x = min_out + x * (max_out - min_out); cmDspSetDouble(ctx,inst,kValOutSrId, x ); //printf("%f (%f %f) : (%f %f) %f\n",val,min_in,max_in,min_out,max_out,x); } return rc; } struct cmDspClass_str* cmScaleRangeClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmScaleRangeDC,ctx,"ScaleRange", NULL, _cmDspScaleRangeAlloc, NULL, _cmDspScaleRangeReset, NULL, _cmDspScaleRangeRecv, NULL,NULL, "Scale a value inside an input range to a value in the output range."); return &_cmScaleRangeDC; } //========================================================================================================================================== enum { kCntAmId, kSflocAmId, kLocAmId, kTypeAmId, kValueAmId, kCstAmId, kCmdAmId, kScLocAmId, kEvenAmId, kDynAmId, kTempoAmId, kCostAmId }; cmDspClass_t _cmActiveMeasDC; typedef struct { unsigned loc; unsigned type; double value; double cost; } cmDspActiveMeasRecd_t; int cmDspActiveMeasRecdCompare(const void * p0, const void * p1) { return ((int)((cmDspActiveMeasRecd_t*)p0)->loc) - (int)(((cmDspActiveMeasRecd_t*)p1)->loc); } typedef struct { cmDspInst_t inst; unsigned addSymId; unsigned clearSymId; unsigned printSymId; unsigned rewindSymId; cmDspActiveMeasRecd_t* array; // array[cnt] unsigned cnt; unsigned nextEmptyIdx; unsigned nextFullIdx; } cmDspActiveMeas_t; cmDspInst_t* _cmDspActiveMeasAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "cnt", kCntAmId, 0,0, kInDsvFl | kUIntDsvFl, "Maximum count of active measurements."}, { "sfloc", kSflocAmId, 0,0, kInDsvFl | kUIntDsvFl, "Score follower location input." }, { "loc", kLocAmId, 0,0, kInDsvFl | kUIntDsvFl, "Meas. location." }, { "type", kTypeAmId, 0,0, kInDsvFl | kUIntDsvFl, "Meas. Type." }, { "val", kValueAmId, 0,0, kInDsvFl | kDoubleDsvFl, "Meas. Value."}, { "cst", kCstAmId, 0,0, kInDsvFl | kDoubleDsvFl, "Meas. Cost."}, { "cmd", kCmdAmId, 0,0, kInDsvFl | kSymDsvFl, "Commands:add | clear | dump | rewind"}, { "scloc", kScLocAmId, 0,0, kOutDsvFl | kUIntDsvFl, "Score location"}, { "even", kEvenAmId, 0,0, kOutDsvFl | kDoubleDsvFl, "Even out"}, { "dyn", kDynAmId, 0,0, kOutDsvFl | kDoubleDsvFl, "Dyn out"}, { "tempo", kTempoAmId, 0,0, kOutDsvFl | kDoubleDsvFl, "Tempo out"}, { "cost", kCostAmId, 0,0, kOutDsvFl | kDoubleDsvFl, "Cost out"}, { NULL, 0, 0, 0, 0 } }; cmDspActiveMeas_t* p = cmDspInstAlloc(cmDspActiveMeas_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); p->addSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"add"); p->clearSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"clear"); p->printSymId = cmSymTblRegisterStaticSymbol(ctx->stH,"dump"); p->rewindSymId= cmSymTblRegisterStaticSymbol(ctx->stH,"rewind"); cmDspSetDefaultUInt( ctx,&p->inst,kCntAmId, 0,100); cmDspSetDefaultUInt( ctx,&p->inst,kScLocAmId,0,0); cmDspSetDefaultDouble(ctx,&p->inst,kEvenAmId, 0,0); cmDspSetDefaultDouble(ctx,&p->inst,kDynAmId, 0,0); cmDspSetDefaultDouble(ctx,&p->inst,kTempoAmId,0,0); cmDspSetDefaultDouble(ctx,&p->inst,kTempoAmId,0,0); return &p->inst; } cmDspRC_t _cmDspActiveMeasPrint(cmDspCtx_t* ctx, cmDspActiveMeas_t* p ) { unsigned i; for(i=0; inextEmptyIdx; ++i) { const cmChar_t* label = ""; switch( p->array[i].type ) { case kEvenVarScId: label="even "; break; case kDynVarScId: label="dyn "; break; case kTempoVarScId: label="tempo"; break; default: { assert(0); } } cmRptPrintf(ctx->rpt,"loc:%i %s %f %f\n",p->array[i].loc,label,p->array[i].value,p->array[i].cost); } return kOkDspRC; } cmDspRC_t _cmDspActiveMeasClear(cmDspCtx_t* ctx, cmDspActiveMeas_t* p ) { p->nextEmptyIdx = 0; p->nextFullIdx = cmInvalidIdx; return kOkDspRC; } cmDspRC_t _cmDspActiveMeasFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspActiveMeas_t* p = (cmDspActiveMeas_t*)inst; _cmDspActiveMeasClear(ctx,p); cmMemPtrFree(&p->array); return kOkDspRC; } cmDspRC_t _cmDspActiveMeasReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspActiveMeas_t* p = (cmDspActiveMeas_t*)inst; cmDspApplyAllDefaults(ctx,inst); unsigned cnt = cmMax(100,cmDspUInt(inst,kCntAmId)); _cmDspActiveMeasFree(ctx,inst,evt); p->array = cmMemAllocZ(cmDspActiveMeasRecd_t,cnt); p->cnt = cnt; return rc; } cmDspRC_t _cmDspActiveMeasRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspActiveMeas_t* p = (cmDspActiveMeas_t*)inst; cmDspSetEvent(ctx,inst,evt); switch( evt->dstVarId ) { case kSflocAmId: if( p->nextFullIdx != cmInvalidIdx ) { // get the recv'd score location unsigned sflocIdx = cmDspUInt(inst,kSflocAmId); unsigned prvLoc = cmInvalidIdx; // for each remaining avail record for(; p->nextFullIdx < p->nextEmptyIdx; p->nextFullIdx++) { cmDspActiveMeasRecd_t* r = p->array + p->nextFullIdx; // if this records score location is after the recv'd score loc then we're done if( r->loc > sflocIdx ) break; // deterimine the records type unsigned varId = cmInvalidId; switch( r->type ) { case kEvenVarScId: varId = kEvenAmId; break; case kDynVarScId: varId = kDynAmId; break; case kTempoVarScId: varId = kTempoAmId; break; default: { assert(0); } } // if this score location has not yet been sent then send it now if( prvLoc != r->loc ) cmDspSetUInt(ctx,inst,kScLocAmId,r->loc); // transmit the records value and cost cmDspSetDouble(ctx,inst,varId,r->value); cmDspSetDouble(ctx,inst,kCostAmId,r->value); prvLoc = r->loc; } } break; case kCmdAmId: { unsigned cmdSymId = cmDspSymbol(inst,kCmdAmId); if( cmdSymId == p->addSymId ) { if( p->nextEmptyIdx >= p->cnt ) cmDspInstErr(ctx,inst,kProcFailDspRC,"The active measurement list is full cnt=%i.",p->cnt); else { cmDspActiveMeasRecd_t* r = p->array + p->nextEmptyIdx; r->loc = cmDspUInt( inst,kLocAmId); r->type = cmDspUInt( inst,kTypeAmId); r->value = cmDspDouble(inst,kValueAmId); r->cost = cmDspDouble(inst,kCstAmId); p->nextEmptyIdx += 1; qsort(p->array,p->nextEmptyIdx,sizeof(p->array[0]),cmDspActiveMeasRecdCompare); if( p->nextEmptyIdx == 1 && p->nextFullIdx == cmInvalidIdx ) p->nextFullIdx = 0; } } if( cmdSymId == p->clearSymId ) rc = _cmDspActiveMeasClear(ctx,p); else if( cmdSymId == p->printSymId ) rc = _cmDspActiveMeasPrint(ctx,p); else if(cmdSymId == p->rewindSymId ) p->nextFullIdx = 0; } break; } return rc; } struct cmDspClass_str* cmActiveMeasClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmActiveMeasDC,ctx,"ActiveMeas", NULL, _cmDspActiveMeasAlloc, _cmDspActiveMeasFree, _cmDspActiveMeasReset, NULL, _cmDspActiveMeasRecv, NULL,NULL, "Scale a value inside an input range to a value in the output range."); return &_cmActiveMeasDC; } //========================================================================================================================================== // Audio MIDI Sync enum { kSelAmId, kAFnAmId, kASmpAmId, kMFnAmId, kMIdAmId, }; enum { kAfnAmFl = 0x01, kMfnAmFl = 0x02, kAsmpAmFl = 0x04, kMidAmFl = 0x08, }; cmDspClass_t _cmAmSyncDC; typedef struct cmDspAmSyncEntry_str { const cmChar_t* afn; const cmChar_t* mfn; unsigned asmp; // Audio sample index to sync to MIDI event unsigned mid; // MIDI event unique id (cmMidiTrackMsg_t.uid) int afi; int mfi; unsigned state; } cmDspAmSyncEntry_t; typedef struct { cmDspInst_t inst; cmDspAmSyncEntry_t* array; unsigned arrayCnt; cmDspAmSyncEntry_t* acur; cmDspAmSyncEntry_t* mcur; } cmDspAmSync_t; cmDspInst_t* _cmDspAmSyncAlloc(cmDspCtx_t* ctx, cmDspClass_t* classPtr, unsigned storeSymId, unsigned instSymId, unsigned id, unsigned va_cnt, va_list vl ) { cmDspVarArg_t args[] = { { "sel", kSelAmId, 0, 0, kInDsvFl | kTypeDsvMask, "Any message to print" }, { "afn", kAFnAmId, 0, 0, kInDsvFl | kStrzDsvFl, "Audio File name"}, { "asmp", kASmpAmId, 0, 0, kInDsvFl | kIntDsvFl, "Audio sample index"}, { "mfn", kMFnAmId, 0, 0, kInDsvFl | kStrzDsvFl, "MIDI File name"}, { "mid", kMIdAmId, 0, 0, kInDsvFl | kIntDsvFl, "MIDI Event Unique Id"}, { NULL, 0, 0, 0, 0 } }; cmDspAmSync_t* p = cmDspInstAlloc(cmDspAmSync_t,ctx,classPtr,args,instSymId,id,storeSymId,va_cnt,vl); return &p->inst; } cmDspRC_t _cmDspAmSyncFree(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspAmSync_t* p = (cmDspAmSync_t*)inst; cmMemFree(p->array); return kOkDspRC; } cmDspRC_t _cmDspAmSyncReset(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspRC_t rc = kOkDspRC; cmDspAmSync_t* p = (cmDspAmSync_t*)inst; cmDspApplyAllDefaults(ctx,inst); cmJsonH_t jsH = cmDspSysPgmRsrcHandle(ctx->dspH); cmJsonNode_t* np; const cmChar_t* errLabelPtr; unsigned i; cmJsRC_t jsRC; if((np = cmJsonFindValue(jsH, "amSync", NULL, kArrayTId)) == NULL ) { rc = cmDspInstErr(ctx,inst,kRsrcNotFoundDspRC,"The AUDIO MIDI Sync cfg. record was not found."); goto errLabel; } p->arrayCnt = cmJsonChildCount(np); p->array = cmMemResizeZ(cmDspAmSyncEntry_t,p->array,p->arrayCnt); for(i=0; iarrayCnt; ++i) { cmJsonNode_t* anp = cmJsonArrayElement(np,i); cmDspAmSyncEntry_t* r = p->array + i; if( (jsRC = cmJsonMemberValues(anp,&errLabelPtr, "af", kStringTId,&r->afn, "asmp",kIntTId, &r->asmp, "mf", kStringTId,&r->mfn, "mid", kIntTId, &r->mid, NULL)) != kOkJsRC ) { if( jsRC == kNodeNotFoundJsRC ) rc = cmDspInstErr(ctx,inst,kRsrcNotFoundDspRC,"The Audio-MIDI Sync cfg. field '%s' was missing in the cfg. record at index %i.",errLabelPtr,i); else rc = cmDspInstErr(ctx,inst,kInvalidArgDspRC,"The AUDIO MIDI Sync cfg. parse failed on the record at index %i.",i); break; } r->afi = cmInvalidIdx; r->mfi = cmInvalidIdx; r->state = 0; } errLabel: return rc; } cmDspRC_t _cmDspAmSyncRecv(cmDspCtx_t* ctx, cmDspInst_t* inst, const cmDspEvt_t* evt ) { cmDspAmSync_t* p = (cmDspAmSync_t*)inst; unsigned i; if( evt->dstVarId != kSelAmId ) cmDspSetEvent(ctx,inst,evt); switch(evt->dstVarId) { case kSelAmId: { double srate = cmDspSysSampleRate(ctx->dspH); int fpc = cmDspSamplesPerCycle(ctx); for(i=0; iarrayCnt; ++i) { const cmDspAmSyncEntry_t* r = p->array + i; int dframes = r->mfi-r->afi; cmRptPrintf(ctx->rpt,"0x%x : %s %i %i - %s %i %i : frm:%i smp:%i sec:%f\n", r->state,r->afn,r->asmp,r->afi,r->mfn,r->mid,r->mfi,dframes,dframes*fpc,dframes*fpc/srate); } } break; case kAFnAmId: { const cmChar_t* fn = cmDspStrcz(inst, kAFnAmId ); for(i=0; iarrayCnt; ++i) if( strcmp(fn,p->array[i].afn) == 0 ) { p->acur = p->array + i; p->array[i].state = cmSetFlag(p->array[i].state,kAfnAmFl); break; } } break; case kMFnAmId: { const cmChar_t* fn = cmDspStrcz(inst, kMFnAmId ); for(i=0; iarrayCnt; ++i) if( strcmp(fn,p->array[i].mfn) == 0 ) { p->mcur = p->array + i; p->array[i].state = cmSetFlag(p->array[i].state,kMfnAmFl); break; } } break; case kASmpAmId: { int v = cmDspInt(inst,kASmpAmId); if( p->acur != NULL && p->acur->asmp <= v ) { p->acur->afi = ctx->cycleCnt; p->acur->state = cmSetFlag(p->acur->state,kAsmpAmFl); } } break; case kMIdAmId: { int v = cmDspInt(inst,kMIdAmId); if( p->mcur != NULL && p->mcur->mid == v ) { p->mcur->mfi = ctx->cycleCnt; p->mcur->state = cmSetFlag(p->mcur->state,kMidAmFl); } } break; } return kOkDspRC; } struct cmDspClass_str* cmAmSyncClassCons( cmDspCtx_t* ctx ) { cmDspClassSetup(&_cmAmSyncDC,ctx,"AmSync", NULL, _cmDspAmSyncAlloc, _cmDspAmSyncFree, _cmDspAmSyncReset, NULL, _cmDspAmSyncRecv, NULL,NULL, "Audio - MIDI Sync Object."); return &_cmAmSyncDC; }