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- #ifndef cmProc_h
- #define cmProc_h
-
- #ifdef __cplusplus
- extern "C" {
- #endif
-
- //( { file_desc:"Processor Library 1" kw:[proclib]}
- //)
-
- //( { label:cmAudioFileRd file_desc:"Audio file reader based on cmAudioFile" kw:[proc] }
- typedef struct
- {
- cmObj obj;
- cmAudioFileH_t h; // audio file handle
- cmAudioFileInfo_t info; // audio file info record
- unsigned chIdx;
- cmSample_t* outV; // buffer of audio from last read
- unsigned outN; // length of outV in samples
- cmChar_t* fn; // name of audio file
- unsigned lastReadFrmCnt; // count of samples actually read on last read
- bool eofFl;
- unsigned begFrmIdx;
- unsigned endFrmIdx;
- unsigned curFrmIdx; // frame index of the next frame to read
- cmMtxFile* mfp;
- } cmAudioFileRd;
-
- // set p to NULL to dynamically allocate the object
- // fn and chIdx are optional - set fn to NULL to allocate the reader without opening a file.
- // If fn is valid then chIdx must also be valid.
- // Set 'endSmpIdx' to cmInvalidIdx to return the entire signal in cmAudioFileRdRead().
- // Set 'endSmpIdx' to 0 to return all samples between 0 and the end of the file.
- cmAudioFileRd* cmAudioFileRdAlloc( cmCtx* c, cmAudioFileRd* p, unsigned procSmpCnt, const char* fn, unsigned chIdx, unsigned begSmpIdx, unsigned endSmpIdx );
- cmRC_t cmAudioFileRdFree( cmAudioFileRd** p );
- cmRC_t cmAudioFileRdOpen( cmAudioFileRd* p, unsigned procSmpCnt, const cmChar_t* fn, unsigned chIdx, unsigned begSmpIdx, unsigned endSmpIdx );
- cmRC_t cmAudioFileRdClose( cmAudioFileRd* p );
-
-
- // Returns cmEofRC if the end of file is encountered.
- cmRC_t cmAudioFileRdRead( cmAudioFileRd* p );
- cmRC_t cmAudioFileRdSeek( cmAudioFileRd* p, unsigned frmIdx );
-
- // Find the overall minimum, maximum, and mean sample values without changing the current file location.
- cmRC_t cmAudioFileRdMinMaxMean( cmAudioFileRd* p, unsigned chIdx, cmSample_t* minPtr, cmSample_t* maxPtr, cmSample_t* meanPtr );
-
- //)
-
- //( { label:cmShiftBuf file_desc:"Audio shift buffer processor" kw:[proc] }
- //------------------------------------------------------------------------------------------------------------
- // The buffer is intended to synchronize sample block rates between processes and to provide an overlapped
- // input buffer.
- typedef struct cmShiftBuf_str
- {
- cmObj obj;
- unsigned bufSmpCnt; // wndSmpCnt + hopSmpCnt
- cmSample_t* bufV; // bufV[bufSmpCnt] all other pointers use this memory
- cmSample_t* outV; // output window outV[ outN ]
- unsigned outN; // outN == wndSmpCnt
- unsigned procSmpCnt; // input sample count
- unsigned wndSmpCnt; // output sample count
- unsigned hopSmpCnt; // count of samples to shift the buffer by on each call to cmShiftExec()
- cmSample_t* inPtr; // ptr to location in outV[] to recv next sample
- bool fl; // reflects the last value returned by cmShiftBufExec().
- } cmShiftBuf;
-
-
-
- // Set p to NULL to dynamically allocate the object. hopSmpCnt must be <= wndSmpCnt.
- cmShiftBuf* cmShiftBufAlloc( cmCtx* c, cmShiftBuf* p, unsigned procSmpCnt, unsigned wndSmpCnt, unsigned hopSmpCnt );
- cmRC_t cmShiftBufFree( cmShiftBuf** p );
- cmRC_t cmShiftBufInit( cmShiftBuf* p, unsigned procSmpCnt, unsigned wndSmpCnt, unsigned hopSmpCnt );
- cmRC_t cmShiftBufFinal( cmShiftBuf* p );
-
- // Returns true if a new hop is ready to be read otherwise returns false.
- // In general cmShiftBufExec() should be called in a loop until it returns false.
- // Note that 'sp' and 'sn' are ignored except for the first call after the function returns false.
- // This means that when called in a loop 'sp' and 'sn' are only used on the first time through the loop.
- // When procSmpCnt is less than hopSmpCnt the loop will only execute when at least wndSmpCnt
- // new samples have been buffered.
- // When procSmpCnt is greater than hopSmpCnt the loop will execute multiple times until less
- // than wndSmpCnt new samples are available.
- // Note that 'sn' must always be less than or equal to procSmpCnt.
- //
- // Example:
- // while( fill(sp,sn) ) // fill sp[] with sn samples
- // {
- // // shift by hopSmpCnt samples on all passes - insert new samples on first pass
- // while( cmShiftBufExec(p,sp,sn) )
- // proc(p->outV,p->outN); // process p->outV[wndSmpCnt]
- // }
- bool cmShiftBufExec( cmShiftBuf* p, const cmSample_t* sp, unsigned sn );
-
- void cmShiftBufTest( cmCtx* c );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmWindowFunc file_desc:"Fourier Transform window function generator." kw:[proc]}
-
- enum
- {
- kInvalidWndId = 0x000,
- kHannWndId = 0x001,
- kHammingWndId = 0x002,
- kTriangleWndId = 0x004,
- kKaiserWndId = 0x008,
- kHannMatlabWndId= 0x010,
- kUnityWndId = 0x020,
-
- kWndIdMask = 0x0ff,
-
- kNormByLengthWndFl = 0x100, // mult by 1/wndSmpCnt
- kNormBySumWndFl = 0x200, // mult by wndSmpCnt/sum(wndV)
- kSlRejIsBetaWndFl = 0x400 // kaiserSideLobeRejectDb param. is actually kaiser beta arg.
- };
-
- typedef struct
- {
- cmObj obj;
- unsigned wndId;
- unsigned flags;
- cmSample_t* wndV;
- cmSample_t* outV;
- unsigned outN; // same as wndSmpCnt
- double kslRejectDb;
- cmMtxFile* mfp;
- } cmWndFunc;
-
- // Set p to NULL to dynamically allocate the object
- // if wndId is set to a valid value this function will internally call cmWndFuncInit()
- cmWndFunc* cmWndFuncAlloc( cmCtx* c, cmWndFunc* p, unsigned wndId, unsigned wndSmpCnt, double kaierSideLobeRejectDb );
- cmRC_t cmWndFuncFree( cmWndFunc** pp );
- cmRC_t cmWndFuncInit( cmWndFunc* p, unsigned wndId, unsigned wndSmpCnt, double kaiserSideLobeRejectDb );
- cmRC_t cmWndFuncFinal( cmWndFunc* p );
- cmRC_t cmWndFuncExec( cmWndFunc* p, const cmSample_t* sp, unsigned sn );
-
-
- void cmWndFuncTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmSpecDelay file_desc:"Spectral frame delay. A circular buffer for spectral (or other fixed length) vectors." kw:[proc]}
-
- typedef struct
- {
- cmObj obj;
- cmSample_t* bufPtr;
- unsigned maxDelayCnt;
- int inIdx;
- unsigned outN; // outN == binCnt
- } cmSpecDelay;
-
-
- // Set p to NULL to dynamically allocate the object.
- // Allocate a spectral frame delay capable of delaying for 'maxDelayCnt' hops and
- // where each vector contains 'binCnt' elements.
- cmSpecDelay* cmSpecDelayAlloc( cmCtx* c, cmSpecDelay* p, unsigned maxDelayCnt, unsigned binCnt );
- cmRC_t cmSpecDelayFree( cmSpecDelay** p );
-
- cmRC_t cmSpecDelayInit( cmSpecDelay* p, unsigned maxDelayCnt, unsigned binCnt );
- cmRC_t cmSpecDelayFinal(cmSpecDelay* p );
-
- // Give an input vector to the delay. 'sn' must <= binCnt
- cmRC_t cmSpecDelayExec( cmSpecDelay* p, const cmSample_t* sp, unsigned sn );
-
- // Get a pointer to a delayed vector. 'delayCnt' indicates the length of the delay in hops.
- // (e.g. 1 is the previous hop, 2 is two hops previous, ... )
- const cmSample_t* cmSpecDelayOutPtr(cmSpecDelay* p, unsigned delayCnt );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmFilter file_desc:"General purpose, LTI, Octave compatible, filter." kw:[proc] }
- typedef struct cmFilter_str
- {
- cmObj obj;
-
- cmReal_t* a; // feedback coeff's
- int an; // count of fb coeff's
- cmReal_t* b; // feedforward coeff's
- int bn; // count of ff coeffs'
-
- cmReal_t* d; // delay
- int di; //
- int cn; // length of delay
- cmReal_t b0; // 1st feedforward coeff
-
- cmSample_t* outSmpV; // signal output vector
- cmReal_t* outRealV;
- unsigned outN; // length of outV (procSmpCnt)
- } cmFilter;
-
- // d[dn] is the initial value of the delay line where dn = max(an,bn)-1.
- // Set d to NULL to intialize the delays to 0.
- cmFilter* cmFilterAlloc( cmCtx* c, cmFilter* p, const cmReal_t* b, unsigned bn, const cmReal_t* a, unsigned an, unsigned procSmpCnt, const cmReal_t* d );
- cmFilter* cmFilterAllocEllip( cmCtx* c, cmFilter* p, cmReal_t srate, cmReal_t passHz, cmReal_t stopHz, cmReal_t passDb, cmReal_t stopDb, unsigned procSmpCnt, const cmReal_t* d );
- cmRC_t cmFilterFree( cmFilter** pp );
- cmRC_t cmFilterInit( cmFilter* p, const cmReal_t* b, unsigned bn, const cmReal_t* a, unsigned an, unsigned procSmpCnt, const cmReal_t* d );
- cmRC_t cmFilterInitEllip( cmFilter* p, cmReal_t srate, cmReal_t passHz, cmReal_t stopHz, cmReal_t passDb, cmReal_t stopDb, unsigned procSmpCnt, const cmReal_t* d );
- cmRC_t cmFilterFinal( cmFilter* p );
-
- // If y==NULL or yn==0 then the output is sent to p->outV[p->outN].
- // This function can safely filter a signal in plcme therefore it is allowable for x[] and y[] to refer to the same memory.
- // If x[] overlaps y[] then y must be <= x.
- cmRC_t cmFilterExecS( cmFilter* p, const cmSample_t* x, unsigned xn, cmSample_t* y, unsigned yn );
- cmRC_t cmFilterExecR( cmFilter* p, const cmReal_t* x, unsigned xn, cmReal_t* y, unsigned yn );
-
- cmRC_t cmFilterSignal( cmCtx* c, const cmReal_t b[], unsigned bn, const cmReal_t a[], unsigned an, const cmSample_t* x, unsigned xn, cmSample_t* y, unsigned yn );
-
- // Perform forward-reverse filtering.
- cmRC_t cmFilterFilterS(cmCtx* c, const cmReal_t bb[], unsigned bn, const cmReal_t aa[], unsigned an, const cmSample_t* x, unsigned xn, cmSample_t* y, unsigned yn );
- cmRC_t cmFilterFilterR(cmCtx* c, const cmReal_t bb[], unsigned bn, const cmReal_t aa[], unsigned an, const cmReal_t* x, unsigned xn, cmReal_t* y, unsigned yn );
-
- void cmFilterTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
- void cmFilterFilterTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmComplexDetect file_desc:"Complex domain onset detection function." kw:[proc] }
- typedef struct
- {
- cmObj obj;
- cmSpecDelay phsDelay;
- cmSpecDelay magDelay;
- unsigned binCnt;
- cmSample_t out;
- //cmMtxFile* mfp;
- //unsigned cdfSpRegId;
- } cmComplexDetect;
-
- // Set p to NULL to dynamically allocate the object.
- cmComplexDetect* cmComplexDetectAlloc(cmCtx* c, cmComplexDetect* p, unsigned binCnt );
- cmRC_t cmComplexDetectFree( cmComplexDetect** pp);
- cmRC_t cmComplexDetectInit( cmComplexDetect* p, unsigned binCnt );
- cmRC_t cmComplexDetectFinal(cmComplexDetect* p);
- cmRC_t cmComplexDetectExec( cmComplexDetect* p, const cmSample_t* magV, const cmSample_t* phsV, unsigned binCnt );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmComplexOnset file_desc:"Complex onset detection function" kw:[proc]}
- typedef struct
- {
- cmObj obj;
- double threshold;
- unsigned medSmpCnt;
- unsigned frmCnt; // expected number of frames to store
- unsigned dfi;
- cmSample_t* df;
- cmSample_t* fdf;
- cmSample_t onrate;
- //cmMtxFile* mfp;
- } cmComplexOnset;
-
- cmComplexOnset* cmComplexOnsetAlloc( cmCtx* c, cmComplexOnset* p, unsigned procSmpCnt, double srate, unsigned medFiltWndSmpCnt, double threshold, unsigned frameCnt );
- cmRC_t cmComplexOnsetFree( cmComplexOnset** pp);
- cmRC_t cmComplexOnsetInit( cmComplexOnset* p, unsigned procSmpCnt, double srate, unsigned medFiltWndSmpCnt, double threshold, unsigned frameCnt );
- cmRC_t cmComplexOnsetFinal( cmComplexOnset* p);
- cmRC_t cmComplexOnsetExec( cmComplexOnset* p, cmSample_t cdf );
- cmRC_t cmComplexOnsetCalc( cmComplexOnset* p );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmMfcc file_desc:"Mel Frequency Cepstral Coefficient (MFCC) measurement function." kw:[proc] }
- typedef struct
- {
- cmObj obj;
- unsigned melBandCnt;
- unsigned dctCoeffCnt;
- unsigned binCnt;
- cmReal_t* melM;
- cmReal_t* dctM;
- cmReal_t* outV;
- unsigned outN; // outN == dctCoeffCnt
- cmMtxFile* mfp;
- unsigned mfccSpRegId; // cmStatsProc regId
- } cmMfcc;
-
- cmMfcc* cmMfccAlloc( cmCtx* c, cmMfcc* p, double srate, unsigned melBandCnt, unsigned dctCoeffCnt, unsigned binCnt );
- cmRC_t cmMfccFree( cmMfcc** pp );
- cmRC_t cmMfccInit( cmMfcc* p, double srate, unsigned melBandCnt, unsigned dctCoeffCnt, unsigned binCnt );
- cmRC_t cmMfccFinal( cmMfcc* p );
- cmRC_t cmMfccExecPower( cmMfcc* p, const cmReal_t* magPowV, unsigned binCnt );
- cmRC_t cmMfccExecAmplitude( cmMfcc* p, const cmReal_t* magAmpV, unsigned binCnt );
- void cmMfccTest();
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmSones file_desc:"Sones measurement function." kw:[proc] }
- typedef struct
- {
- cmObj obj;
- cmReal_t* ttmV; // Terhardt outer ear filter
- cmReal_t* sfM; // Shroeder spreading function
- unsigned* barkIdxV; // Bark to bin map
- unsigned* barkCntV; //
- cmReal_t* outV; // specific loudness in sones
- unsigned outN; // outN == barkBandCnt;
- cmReal_t overallLoudness; // overall loudness in sones
- unsigned binCnt; // expected length of incoming power spectrum
- unsigned barkBandCnt; // count of bark bands
- unsigned flags; //
- cmMtxFile* mfp;
- unsigned sonesSpRegId;
- unsigned loudSpRegId;
- } cmSones;
-
- enum { kDontUseEqlLoudSonesFl=0x00, kUseEqlLoudSonesFl=0x01 };
-
- cmSones* cmSonesAlloc( cmCtx* c, cmSones* p, double srate, unsigned barkBandCnt, unsigned binCnt, unsigned flags );
- cmRC_t cmSonesFree( cmSones** pp );
- cmRC_t cmSonesInit( cmSones* p, double srate, unsigned barkBandCnt, unsigned binCnt, unsigned flags );
- cmRC_t cmSonesFinal( cmSones* p );
- cmRC_t cmSonesExec( cmSones* p, const cmReal_t* magPowV, unsigned binCnt );
-
- void cmSonesTest();
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label: cmAudioOffsetScale file_desc:"Audio signal pre-processing normalizer." kw:[proc] }
- typedef struct
- {
- cmObj obj;
- unsigned cBufCnt;
- unsigned cBufCurCnt;
- unsigned cBufIdx;
- double cBufSum;
- unsigned cCntSum;
- cmReal_t* cBufPtr;
- unsigned* cCntPtr;
- cmSample_t offset;
- double dBref;
- cmSample_t* outV;
- unsigned outN; // (outN == procSmpCnt)
- unsigned flags;
- cmMtxFile* mfp;
- } cmAudioOffsetScale;
-
-
- // This processor adds an offset to an audio signal and scales into dB (SPL) using one of two techniques
- // 1) Measures the effective sound pressure (via RMS) and then scales the signal to the reference dB (SPL)
- // In this case dBref is commonly set to 70. See Timony, 2004, Implementing Loudness Models in Matlab.
- //
- // 2) treats the dBref as the maximum dB (SPL) and scales the signal by this amount without regard
- // measured signal level. In this case dBref is commonly set to 96 (max. dB (SPL) value for 16 bits)
- // and rmsWndSecs is ignored.
- //
- // Note that setting rmsWndSecs to zero has the effect of using procSmpCnt as the window length.
-
- enum { kNoAudioScaleFl=0x01, kRmsAudioScaleFl=0x02, kFixedAudioScaleFl=0x04 };
-
- cmAudioOffsetScale* cmAudioOffsetScaleAlloc( cmCtx* c, cmAudioOffsetScale* p, unsigned procSmpCnt, double srate, cmSample_t offset, double rmsWndSecs, double dBref, unsigned flags );
- cmRC_t cmAudioOffsetScaleFree( cmAudioOffsetScale** pp );
- cmRC_t cmAudioOffsetScaleInit( cmAudioOffsetScale* p, unsigned procSmpCnt, double srate, cmSample_t offset, double rmsWndSecs, double dBref, unsigned flags );
- cmRC_t cmAudioOffsetScaleFinal( cmAudioOffsetScale* p );
- cmRC_t cmAudioOffsetScaleExec( cmAudioOffsetScale* p, const cmSample_t* sp, unsigned sn );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmSpecMeas file_desc:"Measure a signals RMS, High-Frequency Content, Spectral Centroid, and Spectral Spread." kw:[proc]}
- typedef struct
- {
- cmObj obj;
-
- cmReal_t* rmsV;
- cmReal_t* hfcV;
- cmReal_t* scnV;
-
- cmReal_t rmsSum;
- cmReal_t hfcSum;
- cmReal_t scnSum;
- cmReal_t ssSum;
-
- cmReal_t rms; // RMS output
- cmReal_t hfc; // high-frequency content output
- cmReal_t sc; // spectral centroid output
- cmReal_t ss; // spectral spread output
-
- unsigned binCnt;
- unsigned flags;
- unsigned wndFrmCnt;
- unsigned frameIdx;
- unsigned frameCnt;
- double binHz;
- cmMtxFile* mfp;
-
- unsigned rmsSpRegId;
- unsigned hfcSpRegId;
- unsigned scSpRegId;
- unsigned ssSpRegId;
- } cmSpecMeas;
-
- // Set wndFrmCnt to the number of spectral frames to take the measurement over.
- // Setting wndFrmCnt to 1 has the effect of calculating the value on the current frame only.
- // Set flags = kWholeSigSpecMeasFl to ignore wndFrmCnt and calculate the result on the entire signal.
- // In effect this treats the entire signal as the length of the measurement window.
- enum { kWholeSigSpecMeasFl=0x00, kUseWndSpecMeasFl=0x01 };
-
- cmSpecMeas* cmSpecMeasAlloc( cmCtx* c, cmSpecMeas* p, double srate, unsigned binCnt, unsigned wndFrmCnt, unsigned flags );
- cmRC_t cmSpecMeasFree( cmSpecMeas** pp );
- cmRC_t cmSpecMeasInit( cmSpecMeas* p, double srate, unsigned binCnt, unsigned wndFrmCnt, unsigned flags );
- cmRC_t cmSpecMeasFinal( cmSpecMeas* p );
- cmRC_t cmSpecMeasExec( cmSpecMeas* p, const cmReal_t* magPowV, unsigned binCnt );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmSigMeas file_desc:"Measure a time domain signals zero crossing rate." kw:[proc]}
- typedef struct
- {
- cmObj obj;
- cmShiftBuf* sbp; // shift buffer used internally if procSmpCnt < measSmpCnt
- cmShiftBuf shiftBuf;
- double srate; //
- cmReal_t zcr; // zero crossing rate per second
- cmSample_t zcrDelay; // used internally by zero crossing count algorithm
- unsigned measSmpCnt; // length of measurement window in samples
- unsigned procSmpCnt; // expected number of samples per call to exec
- unsigned zcrSpRegId;
- cmMtxFile* mfp;
- } cmSigMeas;
-
- // procSmpCnt must be <= measSmpCnt
-
- cmSigMeas* cmSigMeasAlloc( cmCtx* c, cmSigMeas* p, double srate, unsigned procSmpCnt, unsigned measSmpCnt );
- cmRC_t cmSigMeasFree( cmSigMeas** pp );
- cmRC_t cmSigMeasInit( cmSigMeas* p, double srate, unsigned procSmpCnt, unsigned measSmpCnt );
- cmRC_t cmSigMeasFinal( cmSigMeas* p );
- cmRC_t cmSigMeasExec( cmSigMeas* p, const cmSample_t* sigV, unsigned smpCnt );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmSRC file_desc:"Sample rate converter" kw:[proc] }
- typedef struct
- {
- cmObj obj;
- cmFilter filt;
-
- cmSample_t* outV;
- unsigned outN;
-
- unsigned upFact;
- unsigned dnFact;
-
- unsigned upi;
- unsigned dni;
-
- cmMtxFile* mfp;
-
- } cmSRC;
-
- // The srate paramater is the sample rate of the source signal provided via cmSRCExec()
- cmSRC* cmSRCAlloc( cmCtx* c, cmSRC* p, double srate, unsigned procSmpCnt, unsigned upFact, unsigned dnFact );
- cmRC_t cmSRCFree( cmSRC** pp );
- cmRC_t cmSRCInit( cmSRC* p, double srate, unsigned procSmpCnt, unsigned upFact, unsigned dnFact );
- cmRC_t cmSRCFinal( cmSRC* p );
- cmRC_t cmSRCExec( cmSRC* p, const cmSample_t* sp, unsigned sn );
-
- void cmSRCTest();
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmConstQ file_desc:"Contant-Q transform." kw:[proc] }
- typedef struct
- {
- cmObj obj;
- cmComplexR_t* fiV;
- cmComplexR_t* foV;
- cmComplexR_t* skM; // skM[ wndSmpCnt, constQBinCnt ]
- unsigned* skBegV; // skBegV[ constQBinCnt ] indexes used to decrease the size of the mtx mult in cmConstQExex()
- unsigned* skEndV; // skEndV[ constQBinCnt ]
- unsigned wndSmpCnt; // window length of the complex FFT required to feed this transform
- unsigned constQBinCnt; // count of bins in the const Q output
- unsigned binsPerOctave; //
-
- cmComplexR_t* outV; // outV[ constQBinCnt ]
- cmReal_t* magV; // outV[ constQBinCnt ]
-
- cmMtxFile* mfp;
-
- } cmConstQ;
-
- cmConstQ* cmConstQAlloc( cmCtx* c, cmConstQ* p, double srate, unsigned minMidiPitch, unsigned maxMidiPitch, unsigned binsPerOctave, double thresh );
- cmRC_t cmConstQFree( cmConstQ** pp );
- cmRC_t cmConstQInit( cmConstQ* p, double srate, unsigned minMidiPitch, unsigned maxMidiPitch, unsigned binsPerOctave, double thresh );
- cmRC_t cmConstQFinal( cmConstQ* p );
- cmRC_t cmConstQExec( cmConstQ* p, const cmComplexR_t* ftV, unsigned binCnt );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmTuneHpcp file_desc:"Generate a tuned chromagram." kw:[proc]}
- typedef struct
- {
- cmObj obj;
-
- cmReal_t* hpcpM; // hpcpM[ frameCnt , binsPerOctave ] - stored hpcp
- cmReal_t* fhpcpM;// fhpcpM[ binsPerOctave, frameCnt ] - filtered hpcp (note transposed relative to hpcpA)
- unsigned* histV; // histM[ binsPerOctave/12 ]
- cmReal_t* outM; // outM[ 12, frameCnt ];
-
- unsigned histN; // binsPerOctave/12
- unsigned binsPerOctave; // const-q bins representing 1 octave
- unsigned constQBinCnt; // total count of const-q bins
- unsigned frameCnt; // expected count of hpcp vectors to store.
- unsigned frameIdx; // next column in hpcpM[] to receive input
- unsigned cqMinMidiPitch;
- unsigned medFiltOrder;
-
- cmReal_t* meanV; // meanV[12]
- cmReal_t* varV; // varV[12]
-
- cmMtxFile* mf0p; // debug files
- cmMtxFile* mf1p;
- cmMtxFile* mf2p;
-
- } cmHpcp;
-
- cmHpcp* cmTunedHpcpAlloc( cmCtx* c, cmHpcp* p, unsigned binsPerOctave, unsigned constQBinCnt, unsigned cqMinMidiPitch, unsigned frameCnt, unsigned medFiltOrder );
- cmRC_t cmTunedHpcpFree( cmHpcp** pp );
- cmRC_t cmTunedHpcpInit( cmHpcp* p, unsigned binsPerOctave, unsigned constQBinCnt, unsigned cqMinMidiPitch, unsigned frameCnt, unsigned medFiltOrder );
- cmRC_t cmTunedHpcpFinal( cmHpcp* p );
- cmRC_t cmTunedHpcpExec( cmHpcp* p, const cmComplexR_t* constQBinPtr, unsigned constQBinCnt );
- cmRC_t cmTunedHpcpTuneAndFilter( cmHpcp* p);
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmBeatHist file_desc:"Generate a beat candidate histogram." kw:[proc]}
-
- struct cmFftRR_str;
- struct cmIFftRR_str;
-
- typedef struct
- {
- cmObj obj;
- struct cmFftRR_str* fft;
- struct cmIFftRR_str* ifft;
-
- unsigned frmCnt; // 512 length of df
- unsigned maxLagCnt; // 128 length of longest CMF lag
- unsigned histBinCnt; // 15 count of histogram elements and rows in H[]
- unsigned hColCnt; // 128 count of columns in H[]
-
- cmReal_t* m; // m[ frmCnt x maxLagCnt ]
- cmReal_t* H; // histogram transformation mtx
- cmReal_t* df; // df[ frmCnt ] onset detection function
- cmReal_t* fdf; // fdf[ frmCnt ] filtered onset detection function
- unsigned dfi; // index next df[] location to receive an incoming value
- cmReal_t* histV; // histV[ histBinCnt ] histogram output
- cmMtxFile* mfp;
- } cmBeatHist;
-
- cmBeatHist* cmBeatHistAlloc( cmCtx* c, cmBeatHist* p, unsigned frmCnt );
- cmRC_t cmBeatHistFree( cmBeatHist** pp );
- cmRC_t cmBeatHistInit( cmBeatHist* p, unsigned frmCnt );
- cmRC_t cmBeatHistFinal( cmBeatHist* p );
- cmRC_t cmBeatHistExec( cmBeatHist* p, cmSample_t df );
- cmRC_t cmBeatHistCalc( cmBeatHist* p );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmGmm file_desc"Gaussian Mixture Model containing N Gaussian PDF's each of dimension D." kw:[proc model]}
-
- typedef struct
- {
- cmObj obj;
- unsigned K; // count of components
- unsigned D; // dimensionality of each component
- cmReal_t* gV; // gM[ K ] mixture gain vector
- cmReal_t* uM; // uM[ D x K ] component mean column vectors
- cmReal_t* sMM; // sMM[D x D x K ] component covariance matrices - each column is a DxD matrix
- cmReal_t* isMM; // isMM[D x D x K] inverted covar matrices
- cmReal_t* uMM; // uMM[ D x D x K] upper triangle factor of chol(sMM)
- cmReal_t* logDetV;// detV[ K ] determinent of covar matrices
- cmReal_t* t; // t[ D x D ]scratch matrix used for training
- unsigned uflags; // user defined flags
-
- } cmGmm_t;
-
- enum { cmMdgNoFlags=0x0, cmGmmDiagFl=0x01, cmGmmSkipKmeansFl=0x02 };
-
- cmGmm_t* cmGmmAlloc( cmCtx* c, cmGmm_t* p, unsigned N, unsigned D, const cmReal_t* gV, const cmReal_t* uM, const cmReal_t* sMM, unsigned flags );
- cmRC_t cmGmmFree( cmGmm_t** pp );
- cmRC_t cmGmmInit( cmGmm_t* p, unsigned N, unsigned D, const cmReal_t* gV, const cmReal_t* uM, const cmReal_t* sMM, unsigned flags );
- cmRC_t cmGmmFinal( cmGmm_t* p );
-
- // Estimate the parameters of the GMM using the training data in xM[p->D,xN].
- // *iterCntPtr on input is the number of iterations with no change in class assignment to signal convergence.
- // *iterCntPtr on output is the total number of interations required to converge.
- cmRC_t cmGmmTrain( cmGmm_t* p, const cmReal_t* xM, unsigned xN, unsigned* iterCntPtr );
-
- // Return a pointer to the feature vector at frmIdx containing D elements.
- typedef const cmReal_t* (*cmGmmReadFunc_t)( void* userPtr, unsigned colIdx );
- // Same as cmGmmTrain() but uses a function to access the feature vector.
- // The optional matrix uM[D,K] contains the initial mean values or NULL if not used.
- // The optional flag array roFlV[K] is used to indicate read-only components and is only used
- // when the uM[] arg. is non-NULL. Set roFlV[i] to true to indicate that the mean value supplied by
- // the uM[] arg. should not be alterned by the training process.
- // If 'maxIterCnt' is positive then it is the maximum number of iterations the training process will make
- // otherwise it is ignored.
- cmRC_t cmGmmTrain2( cmGmm_t* p, cmGmmReadFunc_t readFunc, void* userFuncPtr, unsigned xN, unsigned* iterCntPtr, const cmReal_t* uM, const bool* roFlV, int maxIterCnt );
-
- // Generate data yN data points from the GMM and store the result in yM[p->D,yN].
- cmRC_t cmGmmGenerate( cmGmm_t* p, cmReal_t* yM, unsigned yN );
-
- // Evaluate the probability of each column of xM[p->D,xN] and return the result in y[xN].
- // If yM[xN,K] is non-NULL then the individual component prob. values are returned
- cmRC_t cmGmmEval( cmGmm_t* p, const cmReal_t* xM, unsigned xN, cmReal_t* yV, cmReal_t* yM);
-
- // Same as cmGmmEval() but uses a a function to access each data vector
- cmRC_t cmGmmEval2( cmGmm_t* p, cmGmmReadFunc_t readFunc, void* userFuncPtr, unsigned xN, cmReal_t* yV, cmReal_t* yM);
-
- // Evaluate each component for a single data point
- // xV[D] - observed data point
- // yV[K] - output contains the evaluation for each component
- cmRC_t cmGmmEval3( cmGmm_t* p, const cmReal_t* xV, cmReal_t* yV );
-
- void cmGmmPrint( cmGmm_t* p, bool detailsFl );
-
- void cmGmmTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- //( { label:cmChmm file_desc:"Continuous Hidden Markov Model" kw:[proc model]}
-
- typedef struct
- {
- cmObj obj;
- unsigned N; // count of states
- unsigned K; // count of components per mixture
- unsigned D; // dimensionality of the observation data
- cmReal_t* iV; // iV[ N ] initial state probability mtx
- cmReal_t* aM; // aM[ N x N] transition probability mtx
- cmGmm_t** bV; // bV[ N ] observation probability mtx (array of pointers to GMM's)
- cmReal_t* bM; // bM[ N,T] state-observation probability matrix
- cmMtxFile* mfp;
- } cmChmm_t;
-
- // Continuous HMM consisting of stateN states where the observations
- // associated with each state are generated by a Gaussian mixture PDF.
- // stateN - count of states
- // mixN - count of components in the mixtures
- // dimN - dimensionality of the observation data
- cmChmm_t* cmChmmAlloc( cmCtx* c, cmChmm_t* p, unsigned stateN, unsigned mixN, unsigned dimN, const cmReal_t* iV, const cmReal_t* aM );
- cmRC_t cmChmmFree( cmChmm_t** pp );
- cmRC_t cmChmmInit( cmChmm_t* p, unsigned stateN, unsigned mixN, unsigned dimN, const cmReal_t* iV, const cmReal_t* aM );
- cmRC_t cmChmmFinal( cmChmm_t* p );
-
-
- // Set the iV,aM and bV parameters to well-formed random values.
- cmRC_t cmChmmRandomize( cmChmm_t* p, const cmReal_t* oM, unsigned T );
-
- // Train the HMM using segmental k-means to initialize the model parameters.
- // threshProb is the min change in fit between the data and the model above which the procedure will continue to iterate.
- // maxIterCnt is the maximum number of iterations the algorithm will make without regard for threshProb.
- // iterCnt is the value of iterCnt used in the call cmChmmTrain() on each iteration
- cmRC_t cmChmmSegKMeans( cmChmm_t* p, const cmReal_t* oM, unsigned T, cmReal_t threshProb, unsigned maxIterCnt, unsigned iterCnt );
-
- cmRC_t cmChmmSetGmm( cmChmm_t* p, unsigned i, const cmReal_t* wV, const cmReal_t* uM, const cmReal_t* sMM, unsigned flags );
-
- // oM[D,T] - observation matrix
- // alphaM[N,T] - prob of being in each state and observtin oM(:,t)
- // logPrV[T] - (optional) record the log prob of the data given the model at each time step
- // Returns sum(logPrV[T])
- cmReal_t cmChmmForward( const cmChmm_t* p, const cmReal_t* oM, unsigned T, cmReal_t* alphaM, cmReal_t* logPrV );
-
- void cmChmmBackward( const cmChmm_t* p, const cmReal_t* oM, unsigned T, cmReal_t* betaM );
-
- // bM[N,T] the state-observation probability table is optional
- cmReal_t cmChmmCompare( const cmChmm_t* p0, const cmChmm_t* p1, unsigned T );
-
-
- // Generate a series of observations.
- // oM[ p->D , T ] - output matrix
- // sV[ T ] - optional vector to record the state used to generate the ith observation.
- cmRC_t cmChmmGenerate( const cmChmm_t* p, cmReal_t* oM, unsigned T, unsigned* sV );
-
- // Infer the HMM parameters (p->iV,p->aM,p->bV) from the observations oM[D,T]
- enum { kNoTrainMixCoeffChmmFl=0x01, kNoTrainMeanChmmFl=0x02, kNoTrainCovarChmmFl=0x04 };
- cmRC_t cmChmmTrain( cmChmm_t* p, const cmReal_t* oM, unsigned T, unsigned iterCnt, cmReal_t thresh, unsigned flags );
-
- // Determine the ML state sequence yV[T] given the observations oM[D,T].
- cmRC_t cmChmmDecode( cmChmm_t* p, const cmReal_t* oM, unsigned T, unsigned* yV );
-
- void cmChmmPrint( cmChmm_t* p );
-
- void cmChmmTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
- //------------------------------------------------------------------------------------------------------------
- //)
-
-
- //( { label:cmChord file_desc:"HMM based chord recognizer." kw:[proc]}
-
- typedef struct
- {
- cmObj obj;
- cmChmm_t* h; // hmm
-
- unsigned N; // state count N=24
- unsigned D; // data dimension D=12
- unsigned S; // tonal space dim S=6
- unsigned T; // frames in chromaM
- cmReal_t* iV; // iV[N]
- cmReal_t* aM; // aM[N,N]
- cmReal_t* uM; // uM[D,N]
- cmReal_t* sMM; // sMM[D*D,N]
- cmReal_t* phiM; // phiM[S,T]
- cmReal_t* chromaM; // chromaM[D,T]
- cmReal_t* tsM; // tsM[S,T]
- cmReal_t* cdtsV; // cdts[1,T]
-
- cmReal_t triadSeqMode;
- cmReal_t triadSeqVar;
- cmReal_t triadIntMean;
- cmReal_t triadIntVar;
- cmReal_t* tsMeanV; // tsMeanV[S];
- cmReal_t* tsVarV; // tsVarV[S]
- cmReal_t cdtsMean;
- cmReal_t cdtsVar;
-
- } cmChord;
-
- cmChord* cmChordAlloc( cmCtx* c, cmChord* p, const cmReal_t* chromaM, unsigned T );
- cmRC_t cmChordFree( cmChord** p );
- cmRC_t cmChordInit( cmChord* p, const cmReal_t* chromaM, unsigned T );
- cmRC_t cmChordFinal( cmChord* p );
-
- void cmChordTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
- //------------------------------------------------------------------------------------------------------------
- //)
-
- #ifdef __cplusplus
- }
- #endif
-
-
- #endif
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