libcm/cmProc2.h
2013-05-24 15:07:38 -07:00

878 satır
36 KiB
C

#ifndef cmProc2_h
#define cmProc2_h
#ifdef __cplusplus
extern "C" {
#endif
//------------------------------------------------------------------------------------------------------------
// cmArray is an expandable array designed to work easily with the alloc/init/final/free model
// used by this library. The arrays can be safely used by using the cmArrayAllocXXX macros
// with static cmArray member fields during object allocation. cmArrayResizeXXX macros are then
// used during the object initialization phase to allocate the actual array data space. Notice that
// when used this way there is no need to call cmArrayFinal() prior to cmArrayResizeXXX().
// The data memory used by cmArray's is allocated through the cmAllocData() and cmAllocDataZ()
// macros. The resulting base memory address is therefore guaranteed to be aligned to a
// 16 byte address boundary.
typedef struct
{
cmObj obj;
char* ptr;
unsigned allocByteCnt;
unsigned eleCnt;
unsigned eleByteCnt;
} cmArray;
enum
{
kZeroArrayFl = 0x01
};
cmArray* cmArrayAllocate( cmCtx* c, cmArray* p, unsigned eleCnt, unsigned eleByteCnt, unsigned flags );
cmRC_t cmArrayFree( cmArray** pp );
cmRC_t cmArrayInit( cmArray* p, unsigned eleCnt, unsigned eleByteCnt, unsigned flags );
cmRC_t cmArrayFinal( cmArray* p );
char* cmArrayReallocDestroy( cmArray* p, unsigned newEleCnt, unsigned newEleByteCnt, unsigned flags );
void cmArrayReallocDestroyV(cmArray* p, int eleByteCnt,unsigned flags, ... );
char* cmArrayReallocPreserve(cmArray* p, unsigned newEleCnt, unsigned newEleByteCnt, unsigned flags );
#define cmArrayAlloc( c, p ) cmArrayAllocate(c,p,0,0,0);
#define cmArrayAllocInit( c, p, eleCnt, type ) cmArrayAllocate(c,p,eleCnt,sizeof(type),0)
#define cmArrayAllocInitZ( c, p, eleCnt, type ) cmArrayAllocate(c,p,eleCnt,sizeof(type),kZeroArrayFl)
#define cmArrayResize( c, p, newEleCnt, type ) (type*)cmArrayReallocDestroy(c,p,newEleCnt,sizeof(type), 0 )
#define cmArrayResizeZ( c, p, newEleCnt, type ) (type*)cmArrayReallocDestroy(c,p,newEleCnt,sizeof(type), kZeroArrayFl )
#define cmArrayResizePreserve( c, p, newEleCnt, type ) (type*)cmArrayReallocPreserve(c,p,newEleCnt,sizeof(type), 0 )
#define cmArrayResizePreserveZ(c, p, newEleCnt, type ) (type*)cmArrayReallocPreserve(c,p,newEleCnt,sizeof(type), kZeroArrayFl )
#define cmArrayResizeV( c, p, type, ... ) cmArrayReallocDestroyV(c,p,sizeof(type),0,##__VA_ARGS__)
#define cmArrayResizeVZ( c, p, type, ... ) cmArrayReallocDestroyV(c,p,sizeof(type),kZeroArrayFl,##__VA_ARGS__)
#define cmArrayPtr( type, p ) (type*)(p)->ptr
#define cmArrayCount( p ) (p)->eleCnt
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmAudioFileH_t h;
unsigned chCnt;
unsigned curChCnt;
unsigned procSmpCnt;
char* fn;
cmSample_t* bufV;
} cmAudioFileWr;
cmAudioFileWr* cmAudioFileWrAlloc( cmCtx* c, cmAudioFileWr* p, unsigned procSmpCnt, const char* fn, double srate, unsigned chCnt, unsigned bitsPerSample );
cmRC_t cmAudioFileWrFree( cmAudioFileWr** pp );
cmRC_t cmAudioFileWrInit( cmAudioFileWr* p, unsigned procSmpCnt, const char* fn, double srate, unsigned chCnt, unsigned bitsPerSample );
cmRC_t cmAudioFileWrFinal( cmAudioFileWr* p );
cmRC_t cmAudioFileWrExec( cmAudioFileWr* p, unsigned chIdx, const cmSample_t* sp, unsigned sn );
void cmAudioFileWrTest();
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
unsigned rn;
unsigned cn;
cmSample_t *bufPtr;
} cmMatrixBuf;
/// Set p to NULL to dynamically allocate the object
cmMatrixBuf* cmMatrixBufAllocFile(cmCtx* c, cmMatrixBuf* p, const char* fn );
cmMatrixBuf* cmMatrixBufAllocCopy(cmCtx* c, cmMatrixBuf* p, unsigned rn, unsigned cn, const cmSample_t* sp );
cmMatrixBuf* cmMatrixBufAlloc( cmCtx* c, cmMatrixBuf* p, unsigned rn, unsigned cn );
cmRC_t cmMatrixBufFree( cmMatrixBuf**p );
cmRC_t cmMatrixBufInitFile( cmMatrixBuf* p, const char* fn );
cmRC_t cmMatrixBufInitCopy( cmMatrixBuf* p, unsigned rn, unsigned cn, const cmSample_t* sp );
cmRC_t cmMatrixBufInit( cmMatrixBuf* p, unsigned rn, unsigned cn );
cmRC_t cmMatrixBufFinal( cmMatrixBuf* p );
cmSample_t* cmMatrixBufColPtr( cmMatrixBuf* p, unsigned ci );
cmSample_t* cmMatrixBufRowPtr( cmMatrixBuf* p, unsigned ri );
void cmMatrixBufTest();
//------------------------------------------------------------------------------------------------------------
enum
{
kInvalidWfId,
kSineWfId,
kCosWfId,
kSquareWfId,
kTriangleWfId,
kSawtoothWfId,
kWhiteWfId,
kPinkWfId,
kPulseWfId,
kImpulseWfId,
kSilenceWfId,
kPhasorWfId,
kSeqWfId, // always incrementing integer sequence (srate,frq,otCnt is ignored)
};
typedef struct
{
cmObj obj;
unsigned wfId;
unsigned overToneCnt;
double fundFrqHz;
cmSample_t* outV;
unsigned outN; // outN == procSmpCnt
unsigned phase;
cmSample_t delaySmp;
double srate;
} cmSigGen;
/// Set p to NULL to dynamically allocate the object
/// The last three arguments are optional. Set wfId to kInvalidWfId to allocate the signal generator without initializint it.
cmSigGen* cmSigGenAlloc( cmCtx* c, cmSigGen* p, unsigned procSmpCnt, double srate, unsigned wfId, double fundFrqHz, unsigned overToneCnt );
cmRC_t cmSigGenFree( cmSigGen** p );
cmRC_t cmSigGenInit( cmSigGen* p, unsigned procSmpCnt, double srate, unsigned wfId, double fundFrqHz, unsigned overToneCnt );
cmRC_t cmSigGenFinal( cmSigGen* p );
cmRC_t cmSigGenExec( cmSigGen* p );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj* obj;
cmSample_t* bufPtr;
unsigned bufSmpCnt; // count of samples in the delay line (bufSmpCnt = procSmpCnt+delaySmpCnt)
unsigned procSmpCnt; // maximum legal samples to receive in a single call to cmDelayExec()
unsigned delaySmpCnt; // delay time in samples
int delayInIdx; // index into bufPtr[] of next element to receive an incoming sample
unsigned outCnt; // count of valid buffers in outV[]
cmSample_t* outV[2]; // pointers to output buffers
unsigned outN[2]; // length of output buffers (the sum of the length of both output buffers is always procSmpCnt)
} cmDelay;
cmDelay* cmDelayAlloc( cmCtx* c, cmDelay* p, unsigned procSmpCnt, unsigned delaySmpCnt );
cmRC_t cmDelayFree( cmDelay** p );
cmRC_t cmDelayInit( cmDelay* p, unsigned procSmpCnt, unsigned delaySmpCnt );
cmRC_t cmDelayFinal( cmDelay* p );
cmRC_t cmDelayCopyIn( cmDelay* p, const cmSample_t* sp, unsigned sn );
cmRC_t cmDelayAdvance( cmDelay* p, unsigned sn );
cmRC_t cmDelayExec( cmDelay* p, const cmSample_t* sp, unsigned sn, bool bypassFl );
void cmDelayTest();
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
double* coeffV; // FIR coefficient vector (impulse response)
unsigned coeffCnt; // count of elements in coeffV
double* delayV; // delay vector contains one less elements than the coeff array
cmSample_t* outV; // output signal
unsigned outN; // length of the output signal (outN == ctx.procSmpCnt)
unsigned delayIdx; // current next sample to receive input in the the delay line
} cmFIR;
enum { kHighPassFIRFl = 0x01 };
/// Set p to NULL to dynamically allocate the object.
cmFIR* cmFIRAllocKaiser(cmCtx* c, cmFIR* p, unsigned procSmpCnt, double srate, double passHz, double stopHz, double passDb, double stopDb );
cmFIR* cmFIRAllocSinc( cmCtx* c, cmFIR* p, unsigned procSmpCnt, double srate, unsigned sincSmpCnt, double fcHz, unsigned flags );
cmRC_t cmFIRFree( cmFIR** pp );
cmRC_t cmFIRInitKaiser( cmFIR* p, unsigned procSmpCnt, double srate, double passHz, double stopHz, double passDb, double stopDb );
cmRC_t cmFIRInitSinc( cmFIR* p, unsigned procSmpCnt, double srate, unsigned sincSmpCnt, double fcHz, unsigned flags );
cmRC_t cmFIRFinal( cmFIR* p );
cmRC_t cmFIRExec( cmFIR* p, const cmSample_t* sp, unsigned sn );
void cmFIRTest();
//------------------------------------------------------------------------------------------------------------
// Apply a generic function to a windowed signal with a one sample hop size.
typedef cmSample_t (*cmFuncFiltPtr_t)( const cmSample_t* sp, unsigned sn, void* userPtr );
typedef struct
{
cmObj obj;
cmFuncFiltPtr_t funcPtr;
cmShiftBuf shiftBuf;
cmSample_t* outV;
unsigned outN; // outN == procSmpCnt
unsigned curWndSmpCnt;
unsigned wndSmpCnt;
void* userPtr;
} cmFuncFilter;
/// Set p to NULL to dynamically allocate the object.
cmFuncFilter* cmFuncFilterAlloc( cmCtx* c, cmFuncFilter* p, unsigned procSmpCnt, cmFuncFiltPtr_t funcPtr, void* userPtr, unsigned wndSmpCnt );
cmRC_t cmFuncFilterFree( cmFuncFilter** pp );
cmRC_t cmFuncFilterInit( cmFuncFilter* p, unsigned procSmpCnt, cmFuncFiltPtr_t funcPtr, void* userPtr, unsigned wndSmpCnt );
cmRC_t cmFuncFilterFinal( cmFuncFilter* p );
cmRC_t cmFuncFilterExec( cmFuncFilter* p, const cmSample_t* sp, unsigned sn );
void cmFuncFilterTest();
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
unsigned stateN; // count of states
unsigned symN; // count of discrete observation symbols
cmReal_t* initV; // initial state probability vector init[ stateN ]
cmReal_t* transM; // transition probability matrix trans[ stateN (current), stateN (next) ]
cmReal_t* stsM; // state to symbol prob. matrix stsM[ stateN, symN ]
} cmDhmm;
cmDhmm* cmDhmmAlloc( cmCtx* c, cmDhmm* p, unsigned stateN, unsigned symN, cmReal_t* initV, cmReal_t* transM, cmReal_t* stsM );
cmRC_t cmDhmmFree( cmDhmm** pp );
cmRC_t cmDhmmInit( cmDhmm* p, unsigned stateN, unsigned symN, cmReal_t* initV, cmReal_t* transM, cmReal_t* stsM );
cmRC_t cmDhmmFinal( cmDhmm* p );
cmRC_t cmDhmmExec( cmDhmm* p );
cmRC_t cmDhmmGenObsSequence( cmDhmm* p, unsigned* dbp, unsigned dn );
cmRC_t cmDhmmForwardEval( cmDhmm* p, const cmReal_t* statePrV, const unsigned* obsV, unsigned obsN, cmReal_t* alphaM, unsigned flags, cmReal_t* logProbPtr );
cmRC_t cmDhmmReport( cmDhmm* p );
void cmDhmmTest();
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmFftSR* fft;
cmIFftRS* ifft;
cmComplexR_t* H;
unsigned hn;
cmSample_t* olaV; // olaV[hn-1];
cmSample_t* outV; // outV[procSmpCnt]
unsigned outN; // outN == procSmpCnt
} cmConvolve;
// After cmConvolveExec() outV[outN] contains the first outN samples
// which are complete and can be used by the application.
// The tail of the convolution is held in olaV[hn-1] and will
// be automatically summed with the beginning of the next convolution
// frame.
// BUG BUG BUG
// This code seems to have a problem when hn != procSmpCnt (or maybe hn > procSmpCnt ???).
// See mas/main.c convolve() where procSmpCnt must be set to wndSmpCnt size or
// only the first half of the window is emitted.
// h[hn] is the impulse response to convolve with
cmConvolve* cmConvolveAlloc( cmCtx* c, cmConvolve* p, const cmSample_t* h, unsigned hn, unsigned procSmpCnt );
cmRC_t cmConvolveFree( cmConvolve** pp );
cmRC_t cmConvolveInit( cmConvolve* p, const cmSample_t* h, unsigned hn, unsigned procSmpCnt );
cmRC_t cmConvolveFinal( cmConvolve* p );
// xn must be <= procSmpCnt
cmRC_t cmConvolveExec( cmConvolve* p, const cmSample_t* x, unsigned xn );
cmRC_t cmConvolveSignal( cmCtx* c, const cmSample_t* h, unsigned hn, const cmSample_t* x, unsigned xn, cmSample_t* y, unsigned yn );
cmRC_t cmConvolveTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmReal_t* dctMtx; // dctMtx[ binCnt, bandCnt ]
cmReal_t* filtMask; // filtMask[ bandCnt, bandCnt ]
unsigned binCnt; // bin cnt of input magnitude spectrum
unsigned bandCnt; // must be <= kDefaultBarkBandCnt
cmReal_t* outV; // outV[binCnt]
} cmBfcc;
cmBfcc* cmBfccAlloc( cmCtx* ctx, cmBfcc* p, unsigned bandCnt, unsigned binCnt, double binHz );
cmRC_t cmBfccFree( cmBfcc** pp );
cmRC_t cmBfccInit( cmBfcc* p, unsigned bandCnt, unsigned binCnt, double binHz );
cmRC_t cmBfccFinal( cmBfcc* p );
cmRC_t cmBfccExec( cmBfcc* p, const cmReal_t* magV, unsigned binCnt );
void cmBfccTest( cmRpt_t* rpt, cmLHeapH_t lhH, cmSymTblH_t stH );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
//cmIFftRR ft;
unsigned dct_cn; // (binCnt-1)*2
cmReal_t* dctM; // dctM[ outN, dct_cn ]
unsigned binCnt; // bin cnt of input magnitude spectrum
unsigned outN; // count of cepstral coeff's
cmReal_t* outV; // outV[outN]
} cmCeps;
// outN is the number of cepstral coeff's in the output vector
cmCeps* cmCepsAlloc( cmCtx* ctx, cmCeps* p, unsigned binCnt, unsigned outN );
cmRC_t cmCepsFree( cmCeps** pp );
cmRC_t cmCepsInit( cmCeps* p, unsigned binCnt, unsigned outN );
cmRC_t cmCepsFinal( cmCeps* p );
cmRC_t cmCepsExec( cmCeps* p, const cmReal_t* magV, const cmReal_t* phsV, unsigned binCnt );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmWndFunc wf;
unsigned wndSmpCnt;
unsigned hopSmpCnt;
unsigned procSmpCnt;
cmSample_t* bufV; // bufV[wndSmpCnt] overlap add buffer
cmSample_t* outV; // outV[hopSmpCnt] output vector
cmSample_t* outPtr; // outPtr[procSmpCnt] output vector
unsigned idx; // idx of next val in bufV[] to be moved to outV[]
} cmOla;
// hopSmpCnt must be <= wndSmpCnt.
// hopSmpCnt must be an even multiple of procSmpCnt.
// Call cmOlaExecR() or cmOlaExecS() at the spectral frame rate.
// Call cmOlaExecOut() at the time domain audio frame rate.
// Set wndTypeId to one of the cmWndFuncXXX enumerated widnow type id's.
cmOla* cmOlaAlloc( cmCtx* ctx, cmOla* p, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned procSmpCnt, unsigned wndTypeId );
cmRC_t cmOlaFree( cmOla** pp );
cmRC_t cmOlaInit( cmOla* p, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned procSmpCnt, unsigned wndTypeId );
cmRC_t cmOlaFinal( cmOla* p );
cmRC_t cmOlaExecS( cmOla* p, const cmSample_t* xV, unsigned xN );
cmRC_t cmOlaExecR( cmOla* p, const cmReal_t* xV, unsigned xN );
const cmSample_t* cmOlaExecOut(cmOla* p );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmReal_t* hzV; // hzV[binCnt] output vector - frequency in Hertz
cmReal_t* phsV; // phsV[binCnt]
cmReal_t* wV; // bin freq in rads/hop
double srate;
unsigned hopSmpCnt;
unsigned binCnt;
} cmPhsToFrq;
cmPhsToFrq* cmPhsToFrqAlloc( cmCtx* c, cmPhsToFrq* p, double srate, unsigned binCnt, unsigned hopSmpCnt );
cmRC_t cmPhsToFrqFree( cmPhsToFrq** p );
cmRC_t cmPhsToFrqInit( cmPhsToFrq* p, double srate, unsigned binCnt, unsigned hopSmpCnt );
cmRC_t cmPhsToFrqFinal(cmPhsToFrq* p );
cmRC_t cmPhsToFrqExec( cmPhsToFrq* p, const cmReal_t* phsV );
//------------------------------------------------------------------------------------------------------------
enum
{
kNoCalcHzPvaFl = 0x00,
kCalcHzPvaFl = 0x01
};
typedef struct
{
cmObj obj;
cmShiftBuf sb;
cmFftSR ft;
cmWndFunc wf;
cmPhsToFrq pf;
unsigned flags;
unsigned procSmpCnt;
double srate;
unsigned wndSmpCnt;
unsigned hopSmpCnt;
unsigned binCnt;
const cmReal_t* magV; // amplitude NOT power
const cmReal_t* phsV;
const cmReal_t* hzV;
} cmPvAnl;
cmPvAnl* cmPvAnlAlloc( cmCtx* ctx, cmPvAnl* p, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned flags );
cmRC_t cmPvAnlFree( cmPvAnl** pp );
cmRC_t cmPvAnlInit( cmPvAnl* p, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopSmpCnt, unsigned flags );
cmRC_t cmPvAnlFinal(cmPvAnl* p );
// Returns true when a new spectrum has been computed
bool cmPvAnlExec( cmPvAnl* p, const cmSample_t* x, unsigned xN );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmIFftRS ft;
cmWndFunc wf;
cmOla ola;
cmReal_t* minRphV;
cmReal_t* maxRphV;
cmReal_t* itrV;
cmReal_t* phs0V;
cmReal_t* mag0V;
cmReal_t* phsV;
cmReal_t* magV;
double outSrate;
unsigned procSmpCnt;
unsigned wndSmpCnt;
unsigned hopSmpCnt;
unsigned binCnt;
} cmPvSyn;
cmPvSyn* cmPvSynAlloc( cmCtx* ctx, cmPvSyn* p, unsigned procSmpCnt, double outSrate, unsigned wndSmpCnt, unsigned hopSmpCnt,unsigned wndTypeId );
cmRC_t cmPvSynFree( cmPvSyn** pp );
cmRC_t cmPvSynInit( cmPvSyn* p, unsigned procSmpCnt, double outSrate, unsigned wndSmpCnt, unsigned hopSmpCnt,unsigned wndTypeId );
cmRC_t cmPvSynFinal(cmPvSyn* p );
cmRC_t cmPvSynExec( cmPvSyn* p, const cmReal_t* magV, const cmReal_t* phsV );
const cmSample_t* cmPvSynExecOut(cmPvSyn* p );
//------------------------------------------------------------------------------------------------------------
// callback selector values
enum
{
kAttackMsId,
kReleaseMsId,
kDspMsId // return 0 if the voice is no longer active
};
// voice flags
enum
{
kActiveMsFl = 0x01, // set if the voice is active
kKeyGateMsFl = 0x02, // set if the key is down for this note
};
struct cmMidiSynth_str;
struct cmMidiSynthCh_str;
struct cmMidiVoice_str;
// voice update callback - use voicePtr->pgm.cbDataPtr to get voice specific data
typedef int (*cmMidiSynthCb_t)( struct cmMidiVoice_str* voicePtr, unsigned sel, cmSample_t* outChArray[], unsigned outChCnt );
typedef struct
{
cmMidiByte_t pgm; // MIDI pgm number
cmMidiSynthCb_t cbPtr; // voice update callback
void* cbDataPtr; // user data pointer
} cmMidiSynthPgm;
typedef struct cmMidiVoice_str
{
unsigned index; // voice index
unsigned flags; // see kXXXMsFl above
cmMidiByte_t pitch; // note-on pitch
cmMidiByte_t velocity; // note-on/off veloctiy
cmMidiSynthPgm pgm; // pgm associated with this voice
struct cmMidiSynthCh_str* chPtr; // pointer to owning ch
struct cmMidiVoice_str* link; // link to next active/avail voice in chain
} cmMidiVoice;
typedef struct cmMidiSynthCh_str
{
cmMidiByte_t midiCtl[ kMidiCtlCnt ]; // current ctl values
short pitchBend; // current pitch bend value
cmMidiByte_t pgm; // last pgm received
cmMidiVoice* active; // first active voice on this channel
struct cmMidiSynth_str* synthPtr; // owning synth
} cmMidiSynthCh;
typedef struct cmMidiSynth_str
{
cmObj obj;
cmMidiSynthCh chArray[ kMidiChCnt ]; // midi channel array
unsigned voiceCnt; // count of voice records
cmMidiVoice* avail; // avail voice chain
unsigned activeVoiceCnt; // current count of active voices
unsigned voiceStealCnt; // count of times voice stealing was required
cmMidiVoice* voiceArray; // array of voice records
cmMidiSynthPgm pgmArray[ kMidiPgmCnt ]; // array of pgm records
unsigned procSmpCnt; // samples per DSP cycle
unsigned outChCnt; // count of output channels
cmSample_t* outM; // outM[ procSmpCnt, outChCnt ] output buffer
cmSample_t** outChArray; // buffer of pointers to each output channel
cmReal_t srate; // output signal sample rate
} cmMidiSynth;
cmMidiSynth* cmMidiSynthAlloc( cmCtx* ctx, cmMidiSynth* p, const cmMidiSynthPgm* pgmArray, unsigned pgmCnt, unsigned voiceCnt, unsigned procSmpCnt, unsigned outChCnt, cmReal_t srate );
cmRC_t cmMidiSynthFree( cmMidiSynth** pp );
cmRC_t cmMidiSynthInit( cmMidiSynth* p, const cmMidiSynthPgm* pgmArray, unsigned pgmCnt, unsigned voiceCnt, unsigned procSmpCnt, unsigned outChCnt, cmReal_t srate );
cmRC_t cmMidiSynthFinal( cmMidiSynth* p );
cmRC_t cmMidiSynthOnMidi(cmMidiSynth* p, const cmMidiPacket_t* pktArray, unsigned pktCnt );
cmRC_t cmMidiSynthExec( cmMidiSynth* p, cmSample_t** outChArray, unsigned outChCnt );
//------------------------------------------------------------------------------------------------------------
// state id's
enum
{
kOffWtId,
kAtkWtId,
kDcyWtId,
kSusWtId,
kRlsWtId
};
typedef struct
{
cmObj obj;
cmReal_t hz; // current frq in Hz
cmReal_t level; // current gain (0.0 to 1.0)
cmReal_t phase; // osc phase (radians)
unsigned durSmpCnt; // count of samples generated so far
unsigned state; // osc state - see kXXXWtId above
cmSample_t* outV; // signal output vector
unsigned outN; // samples in outV[]
} cmWtVoice;
cmWtVoice* cmWtVoiceAlloc( cmCtx* ctx, cmWtVoice* p, unsigned procSmpCnt, cmReal_t hz );
cmRC_t cmWtVoiceFree( cmWtVoice** pp );
cmRC_t cmWtVoiceInit( cmWtVoice* p, unsigned procSmpCnt, cmReal_t hz );
cmRC_t cmWtVoiceFinal( cmWtVoice* p );
// 'sel' values are cmMidiSynthExec (kXXXMsId) values
// Set outChArray[] to NULL to use internal audio buffer.
int cmWtVoiceExec( cmWtVoice* p, struct cmMidiVoice_str* voicePtr, unsigned sel, cmSample_t* outChArray[], unsigned outChCnt );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmWtVoice** voiceArray; // osc state array
unsigned voiceCnt;
cmSample_t* buf;
cmSample_t** chArray;
unsigned chCnt;
unsigned procSmpCnt; // count of samples in each chArray[i] sample vector
double srate; // synth sample rate
} cmWtVoiceBank;
cmWtVoiceBank* cmWtVoiceBankAlloc( cmCtx* ctx, cmWtVoiceBank* p, double srate, unsigned procSmpCnt, unsigned voiceCnt, unsigned chCnt );
cmRC_t cmWtVoiceBankFree( cmWtVoiceBank** pp );
cmRC_t cmWtVoiceBankInit( cmWtVoiceBank* p, double srate, unsigned procSmpCnt, unsigned voiceCnt, unsigned chCnt );
cmRC_t cmWtVoiceBankFinal( cmWtVoiceBank* p );
// 'sel' values are cmMidiSynthExec (kXXXMsId) values
// Set outChArray[] to NULL to use internal audio buffer.
// Return 0 if the voice has gone inactive otherwise return 1.
int cmWtVoiceBankExec( cmWtVoiceBank* p, struct cmMidiVoice_str* voicePtr, unsigned sel, cmSample_t* chArray[], unsigned chCnt );
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
cmSample_t* bufV; // bufV[ bufN ]
unsigned bufN;
cmAudioFileInfo_t info;
unsigned begSmpIdx;
unsigned chIdx;
char* fn;
} cmAudioFileBuf;
// set 'durSmpCnt' to cmInvalidCnt to include all samples to the end of the file
cmAudioFileBuf* cmAudioFileBufAlloc( cmCtx* ctx, cmAudioFileBuf* p, unsigned procSmpCnt, const char* fn, unsigned chIdx, unsigned begSmpIdx, unsigned durSmpCnt );
cmRC_t cmAudioFileBufFree( cmAudioFileBuf** pp );
cmRC_t cmAudioFileBufInit( cmAudioFileBuf* p, unsigned procSmpCnt, const char* fn, unsigned chIdx, unsigned begSmpIdx, unsigned durSmpCnt );
cmRC_t cmAudioFileBufFinal(cmAudioFileBuf* p );
// Returns the count of samples copied into outV or 0 if smpIdx >= p->bufN.
// If less than outN samples are available then the remaining samples are set to 0.
unsigned cmAudioFileBufExec( cmAudioFileBuf* p, unsigned smpIdx, cmSample_t* outV, unsigned outN, bool sumIntoOutFl );
//------------------------------------------------------------------------------------------------------------
// Multi-delay. Each of the taps of this delay operates as a independent delay with feedback.
// Delay line specification.
typedef struct
{
cmReal_t delayGain; // delay gain
cmReal_t delayMs; // delay time in milliseconds
cmReal_t delaySmpFrac; // delay time in samples (next fractional delay index = inIdx - delaySmpFrac)
cmSample_t* delayBuf; // delayBuf[delayBufSmpCnt] delay line memory
int delayBufSmpCnt; // delay buffer length in samples
int inIdx; // next delay input index
} cmMDelayHead;
typedef struct
{
cmObj obj;
unsigned delayCnt; // count of taps
cmMDelayHead* delayArray; // tap specs
cmSample_t* outV; // outV[outN] output buffer
unsigned outN; // procSmpCnt
cmReal_t fbCoeff; // feedback coeff.
cmReal_t srate; // system sample rate
} cmMDelay;
cmMDelay* cmMDelayAlloc( cmCtx* ctx, cmMDelay* p, unsigned procSmpCnt, cmReal_t srate, cmReal_t fbCoeff, unsigned delayCnt, const cmReal_t* delayMsArray, const cmReal_t* delayGainArray );
cmRC_t cmMDelayFree( cmMDelay** pp );
cmRC_t cmMDelayInit( cmMDelay* p, unsigned procSmpCnt, cmReal_t srate, cmReal_t fbCoeff, unsigned delayCnt, const cmReal_t* delayMsArray, const cmReal_t* delayGainArray );
cmRC_t cmMDelayFinal( cmMDelay* p );
cmRC_t cmMDelayExec( cmMDelay* p, const cmSample_t* sigV, cmSample_t* outV, unsigned sigN, bool bypassFl );
void cmMDelaySetTapMs( cmMDelay* p, unsigned tapIdx, cmReal_t ms );
void cmMDelaySetTapGain(cmMDelay* p, unsigned tapIdx, cmReal_t gain );
void cmMDelayReport( cmMDelay* p, cmRpt_t* rpt );
//------------------------------------------------------------------------------------------------------------
enum
{
kEnableAspFl = 0x01,
kDelAspFl = 0x02
};
typedef struct cmAudioSeg_str
{
cmAudioFileBuf* bufPtr; // pointer to the audio file buffer this segment is contained in
unsigned id; // id (unique amoung segments)
unsigned smpIdx; // offset into audioBuf[] of first sample
unsigned smpCnt; // total count of samples to play
unsigned outChIdx; // output buffer channel
unsigned outSmpIdx; // outSmpIdx + smpIdx == next sample to play
unsigned flags; // see kXXXAspFl
} cmAudioSeg;
typedef struct
{
cmObj obj;
unsigned segCnt;
cmAudioSeg* segArray;
unsigned procSmpCnt;
cmSample_t** outChArray;
unsigned outChCnt;
cmSample_t* outM;
} cmAudioSegPlayer;
cmAudioSegPlayer* cmAudioSegPlayerAlloc( cmCtx* ctx, cmAudioSegPlayer* p, unsigned procSmpCnt, unsigned outChCnt );
cmRC_t cmAudioSegPlayerFree( cmAudioSegPlayer** pp );
cmRC_t cmAudioSegPlayerInit( cmAudioSegPlayer* p, unsigned procSmpCnt, unsigned outChCnt );
cmRC_t cmAudioSegPlayerFinal( cmAudioSegPlayer* p );
cmRC_t cmAudioSegPlayerInsert( cmAudioSegPlayer* p, unsigned id, cmAudioFileBuf* bufPtr, unsigned smpIdx, unsigned smpCnt, unsigned outChIdx );
cmRC_t cmAudioSegPlayerEdit( cmAudioSegPlayer* p, unsigned id, cmAudioFileBuf* bufPtr, unsigned smpIdx, unsigned smpCnt, unsigned outChIdx );
cmRC_t cmAudioSegPlayerRemove( cmAudioSegPlayer* p, unsigned id, bool delFl );
cmRC_t cmAudioSegPlayerEnable( cmAudioSegPlayer* p, unsigned id, bool enableFl, unsigned outSmpIdx );
cmRC_t cmAudioSegPlayerReset( cmAudioSegPlayer* p );
cmRC_t cmAudioSegPlayerExec( cmAudioSegPlayer* p, cmSample_t** outChPtr, unsigned chCnt, unsigned outSmpCnt );
//------------------------------------------------------------------------------------------------------------
/*
cmReal_t (*cmCluster0DistFunc_t)( void* userPtr, const cmReal_t* v0, const cmReal_t* v1, unsigned binCnt );
typedef struct
{
cmObj obj;
unsigned flags;
unsigned stateCnt;
unsigned binCnt;
cmReal_t* oM; // oM[ binCnt, stateCnt ]
unsigned* tM; // tM[ stateCnt, stateCnt ]
cmReal_t* dV; // dV[ state
cmCluster0DistFunc_t distFunc;
void* distUserPtr;
unsigned cnt;
} cmCluster0;
enum
{
kCalcTransFl = 0x01,
kCalcDurFl = 0x02
};
cmCluster0* cmCluster0Alloc( cmCtx* ctx, cmCluster0* ap, unsigned stateCnt, unsigned binCnt, unsigned flags, cmCluster0DistFunc_t distFunc, void* dstUserPtr );
cmRC_t cmCluster0Free( cmCluster0** pp );
cmRC_t cmCluster0Init( cmCluster0* p, unsigned stateCnt, unsigned binCnt, unsigned flags, cmCluster0DistFunc_t distFunc, void* dstUserPtr );
cmRC_t cmCluster0Final( cmCluster0* p );
cmRC_t cmCluster0Exec( cmCluster0* p, const cmReal_t* v, unsigned vn );
*/
//------------------------------------------------------------------------------------------------------------
typedef struct
{
cmObj obj;
unsigned n;
unsigned m;
unsigned r;
unsigned maxIterCnt;
unsigned convergeCnt;
cmReal_t* V; // V[n,m]
cmReal_t* W; // W[n,r]
cmReal_t* H; // H[r,m]
cmReal_t* tr;
cmReal_t* x;
cmReal_t* t0nm;
cmReal_t* t1nm;
cmReal_t* Wt;
cmReal_t* Ht;
cmReal_t* trm;
unsigned* crm;
cmReal_t* tnr;
unsigned* c0;
unsigned* c1;
unsigned* c0m;
unsigned* c1m;
unsigned* idxV;
} cmNmf_t;
cmNmf_t* cmNmfAlloc( cmCtx* ctx, cmNmf_t* ap, unsigned n, unsigned m, unsigned r, unsigned maxIterCnt, unsigned convergeCnt );
cmRC_t cmNmfFree( cmNmf_t** pp );
cmRC_t cmNmfInit( cmNmf_t* p, unsigned n, unsigned m, unsigned r, unsigned maxIterCnt, unsigned convergeCnt );
cmRC_t cmNmfFinal(cmNmf_t* p );
//
cmRC_t cmNmfExec( cmNmf_t* p, const cmReal_t* v, unsigned cn );
//------------------------------------------------------------------------------------------------------------
enum
{
kBypassModeSdId, // 0 - no effect
kBasicModeSdId, // 1 - fixed thresh
kSpecCentSdId, // 2 - thresh = max magn - (offset * spec_cent)
kAmpEnvSdId, // 3 - thresh = max magn - offset
kBumpSdId,
kModeSdCnt
};
typedef struct
{
cmObj obj;
double srate;
unsigned wndSmpCnt;
unsigned hopFcmt;
unsigned hopSmpCnt;
unsigned procSmpCnt;
cmPvAnl* pva;
cmPvSyn* pvs;
unsigned mode;
double thresh;
double uprSlope;
double lwrSlope;
double offset;
bool invertFl;
double spcBwHz; // spectral centroid bandwidth in Hz
double spcSmArg; // spectral centroid smoothing
double spcMin;
double spcMax;
unsigned spcBinCnt; // count of bins used in the spectral centroid
cmReal_t* hzV; // hzV[spcBinCnt];
cmReal_t spc;
unsigned spcCnt;
cmReal_t spcSum;
cmReal_t spcSqSum;
cmReal_t aeSmMax; // smoothed max bin magn - used by spectral centroid
cmReal_t aeSmOffs; // smoothed offset
cmReal_t ae;
cmReal_t aeMin;
cmReal_t aeMax;
cmReal_t aeUnit;
} cmSpecDist_t;
cmSpecDist_t* cmSpecDistAlloc( cmCtx* ctx,cmSpecDist_t* ap, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopFcmt, unsigned olaWndTypeId );
cmRC_t cmSpecDistFree( cmSpecDist_t** pp );
cmRC_t cmSpecDistInit( cmSpecDist_t* p, unsigned procSmpCnt, double srate, unsigned wndSmpCnt, unsigned hopFcmt, unsigned olaWndTypeId );
cmRC_t cmSpecDistFinal(cmSpecDist_t* p );
cmRC_t cmSpecDistExec( cmSpecDist_t* p, const cmSample_t* sp, unsigned sn );
const cmSample_t* cmSpecDistOut( cmSpecDist_t* p );
//------------------------------------------------------------------------------------------------------------
// Write a binary matrix file in the format acceppted by the octave function readBinFile.m
typedef struct
{
cmObj obj;
cmFileH_t fh;
unsigned rowCnt;
unsigned maxRowEleCnt;
unsigned eleByteCnt;
} cmBinMtxFile_t;
cmBinMtxFile_t* cmBinMtxFileAlloc( cmCtx* ctx, cmBinMtxFile_t* ap, const cmChar_t* fn );
cmRC_t cmBinMtxFileFree( cmBinMtxFile_t** pp );
cmRC_t cmBinMtxFileInit( cmBinMtxFile_t* p, const cmChar_t* fn );
cmRC_t cmBinMtxFileFinal( cmBinMtxFile_t* p );
// Write one row of 'xn' columns to the matrix file.
cmRC_t cmBinMtxFileExecS( cmBinMtxFile_t* p, const cmSample_t* x, unsigned xn );
cmRC_t cmBinMtxFileExecR( cmBinMtxFile_t* p, const cmReal_t* x, unsigned xn );
bool cmBinMtxFileIsValid( cmBinMtxFile_t* p );
// Write a binary matrix file.
// The matrix data is provided as sp[rowCnt,colCnt] or rp[rowCnt,colCnt].
// The matrix is assumed to be in column major order (like all matrices in the cm library)
// Either 'sp' or 'rp' must be given but not both.
// 'ctx' is optional and defaults to NULL.
// If 'ctx' is not provided then 'rpt' must be provided.
// If 'ctx' is provided then 'rpt' is not used.
// See cmAudioFileReadWriteTest() in cmProcTest.c for an example usage.
cmRC_t cmBinMtxFileWrite( const cmChar_t* fn, unsigned rowCnt, unsigned colCnt, const cmSample_t* sp, const cmReal_t* rp, cmCtx* ctx, cmRpt_t* rpt );
// Return the matrix file geometry.
// rowCntPtr,colCntPtr and eleByteCntPtr are optional
cmRC_t cmBinMtxFileSize( cmCtx_t* ctx, const cmChar_t* fn, unsigned* rowCntPtr, unsigned* colCntPtr, unsigned* eleByteCntPtr );
// Fill buf[rowCnt*colCnt*byteEleCnt] buffer from the binary matrix file 'fn'.
// rowCnt,colCnt,eleByteCnt must be exactly the same as the actual file.
// Use cmBinMtxFileSize() to determine the buffer size prior to calling this function.
// colCntV[colCnt] is optional.
cmRC_t cmBinMtxFileRead( cmCtx_t* ctx, const cmChar_t* fn, unsigned rowCnt, unsigned colCnt, unsigned eleByteCnt, void* buf, unsigned* colCntV );
#ifdef __cplusplus
}
#endif
#endif