libcm/cmProc4.h

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2012-11-15 04:01:05 +00:00
#ifndef cmProc4_h
#define cmProc4_h
#ifdef __cplusplus
extern "C" {
#endif
//( { file_desc:"Processor Library 4" kw:[proclib]}
//)
//( { label:cmEditDist file_desc:"Simplified string alignment function based on Levenshtein edit distance." kw:[proc] }
enum { kEdMinIdx, kEdSubIdx, kEdDelIdx, kEdInsIdx, kEdCnt };
typedef struct
{
unsigned v[kEdCnt];
bool matchFl;
bool transFl;
} ed_val;
typedef struct ed_path_str
{
unsigned code;
unsigned ri;
unsigned ci;
bool matchFl;
bool transFl;
struct ed_path_str* next;
} ed_path;
/*
Backtracking:
m[rn,cn] is organized to indicate the mutation operations
on s0[0:rn-1] or s1[0:cn-1] during backtracking.
Backtracking begins at cell m[rn-1,cn-1] and proceeds
up and left toward m[0,0]. The action to perform during
backtracking is determined by examinging which values
int m[].v[1:3] match m[].v[0].
Match Next Cell
Index Operation Location
----- ------------------------ ------------------------
1 Substitute char s0[ri-1] move diagonally; up-left
2 Delete char s0[ri-1] move up.
3 Delete char s1[ci-1] move left.
(same as inserting blank
into after s[ri-1]
Note that more than one value in m[].v[1:3] may match
m[].v[0]. In this case the candidate solution branches
at this point in the candidate selection processes.
*/
typedef struct
{
const char* s0; // forms rows of m[] - mutate to match s1 - rn=strlen(s0)
const char* s1; // forms columns of m[] - target string - cn=strlen(s1)
unsigned rn; // length of s0 + 1
unsigned cn; // length of s1 + 1
ed_val* m; // m[rn,cn]
unsigned pn; // rn+cn
ed_path* p_mem; // pmem[ 2*pn ];
ed_path* p_avl; // available path record linked list
ed_path* p_cur; // current path linked list
ed_path* p_opt; // p_opt[pn] current best alignment
double s_opt; // score of the current best alignment
} ed_r;
// print the DP matrix ed_r.m[rn,cn].
void ed_print_mtx( ed_r* r );
// Initialize ed_r.
void ed_init( ed_r* r, const char* s0, const char* s1 );
// Fill in the DP matrix.
void ed_calc_mtx( ed_r* r );
// Traverse the possible alignments in the DP matrix and determine the optimal alignment.
void ed_align( ed_r* r );
// Print the optimal alignment p_opt[]
void ed_print_opt( ed_r* r );
// Free resource allocated by ed_init().
void ed_free(ed_r* r);
// Main test function.
void ed_main();
//------------------------------------------------------------------------------------------------------------
//)
//( { label:cmScoreMatch file_desc:"Event oriented local score matching algorithm based on edit distance." kw:[proc] }
enum
{
kSmMinIdx, //
kSmSubIdx, // 'substitute' - may or may not match
kSmDelIdx, // 'delete' - delete a MIDI note
kSmInsIdx, // 'insert' - insert a space in the score
kSmCnt
};
enum
{
kSmMatchFl = 0x01,
kSmTransFl = 0x02,
kSmTruePosFl = 0x04,
kSmFalsePosFl = 0x08,
kSmBarFl = 0x10,
kSmNoteFl = 0x20
};
// Dynamic Programming (DP) matrix element
typedef struct
{
unsigned v[kSmCnt]; // cost for each operation
unsigned flags; // cmSmMatchFl | cmSmTransFl
unsigned scEvtIdx;
} cmScMatchVal_t;
// List record used to track a path through the DP matrix p->m[,]
typedef struct cmScMatchPath_str
{
unsigned code; // kSmXXXIdx
unsigned ri; // matrix row index
unsigned ci; // matrix col index
unsigned flags; // cmSmMatchFl | cmSmTransFl
unsigned locIdx; // p->loc index or cmInvalidIdx
unsigned scEvtIdx; // scScore event index
struct cmScMatchPath_str* next; //
} cmScMatchPath_t;
typedef struct cmScMatchEvt_str
{
unsigned pitch; //
unsigned scEvtIdx; // scScore event index
} cmScMatchEvt_t;
// Score location record.
typedef struct
{
unsigned evtCnt; // count of score events at this location (i.e. a chord will have more than one event at a given location)
cmScMatchEvt_t* evtV; // evtV[evtCnt]
unsigned scLocIdx; // scH score location index
int barNumb; // bar number of this location
} cmScMatchLoc_t;
typedef struct
{
unsigned mni; // unique identifier for this MIDI note - used to recognize when the cmScMatcher backtracks.
unsigned muid; // MIDI file event msg unique id (See cmMidiTrackMsg_t.uid)
unsigned smpIdx; // time stamp of this event
unsigned pitch; // MIDI note pitch
unsigned vel; // " " velocity
unsigned locIdx; // location assoc'd with this MIDI evt (cmInvalidIdx if not a matching or non-matching 'substitute')
unsigned scEvtIdx; // cmScore event index assoc'd with this event
} cmScMatchMidi_t;
typedef struct
{
cmObj obj; //
cmScH_t scH; // cmScore handle
unsigned locN; //
cmScMatchLoc_t* loc; // loc[locN]
unsigned mrn; // max m[] row count (midi)
unsigned rn; // cur m[] row count
unsigned mcn; // max m[] column count (score)
unsigned cn; // cur m[] column count
unsigned mmn; // max length of midiBuf[] (mrn-1)
unsigned msn; // max length of score window (mcn-1)
cmScMatchVal_t* m; // m[mrn,mcn] DP matrix
unsigned pn; // mrn+mcn
cmScMatchPath_t* p_mem; // pmem[ 2*pn ] - path memory
cmScMatchPath_t* p_avl; // available path record linked list
cmScMatchPath_t* p_cur; // current path linked list
cmScMatchPath_t* p_opt; // p_opt[pn] - current best alignment as a linked list
double opt_cost; // last p_opt cost set by cmScMatchExec()
} cmScMatch;
/*
1) This matcher cannot handle multiple instances of the same pitch occuring
at the same 'location'.
2) Because each note of a chord is spread out over multiple locations, and
there is no way to indicate that a note in the chord is already 'in-use'.
If a MIDI note which is part of the chord is repeated, in error, it will
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appear to be correct (a positive match will be assigned to
the second (and possible successive notes)).
*/
cmScMatch* cmScMatchAlloc( cmCtx* c, cmScMatch* p, cmScH_t scH, unsigned maxScWndN, unsigned maxMidiWndN );
cmRC_t cmScMatchFree( cmScMatch** pp );
cmRC_t cmScMatchInit( cmScMatch* p, cmScH_t scH, unsigned maxScWndN, unsigned maxMidiWndN );
cmRC_t cmScMatchFinal( cmScMatch* p );
// Locate the position in p->loc[locIdx:locIdx+locN-1] which bests
// matches midiV[midiN].
// The result of this function is to update p_opt[]
// The optimal path p_opt[] will only be updated if the edit_cost associated 'midiV[midiN]'.
// with the best match is less than 'min_cost'.
// Set 'min_cost' to DBL_MAX to force p_opt[] to be updated.
// Returns cmEofRC if locIdx + locN > p->locN - note that this is not
// necessarily an error.
cmRC_t cmScMatchExec( cmScMatch* p, unsigned locIdx, unsigned locN, const cmScMatchMidi_t* midiV, unsigned midiN, double min_cost );
//------------------------------------------------------------------------------------------------------------
//)
//( { label:cmScoreMatcher file_desc:"MIDI score following algorithm based cmScoreMatch." kw:[proc] }
typedef struct
{
unsigned locIdx; // index into cmScMatch_t.loc[]
unsigned scEvtIdx; // score event index
unsigned mni; // index of the performed MIDI event associated with this score location
unsigned smpIdx; // sample time index of performed MIDI event
unsigned muid; // MIDI file event msg unique id (See cmMidiTrackMsg_t.uid)
unsigned pitch; // performed pitch
unsigned vel; // performed velocity
unsigned flags; // smTruePosFl | smFalsePosFl
} cmScMatcherResult_t;
struct cmScMatcher_str;
typedef void (*cmScMatcherCb_t)( struct cmScMatcher_str* p, void* arg, cmScMatcherResult_t* rp );
typedef struct cmScMatcher_str
{
cmObj obj;
cmScMatcherCb_t cbFunc;
void* cbArg;
cmScMatch* mp;
unsigned mn;
cmScMatchMidi_t* midiBuf; // midiBuf[mn]
cmScMatcherResult_t* res; // res[rn]
unsigned rn; // length of res[] (set to 2*score event count)
unsigned ri; // next avail res[] recd.
double s_opt; //
unsigned missCnt; // current count of consecutive trailing non-matches
unsigned ili; // index into loc[] to start scan following reset
unsigned eli; // index into loc[] of the last positive match.
unsigned mni; // current count of MIDI events since the last call to cmScMatcherReset()
unsigned mbi; // index of oldest MIDI event in midiBuf[]; stays at 0 when the buffer is full.
unsigned begSyncLocIdx; // start of score window, in mp->loc[], of best match in previous scan
unsigned initHopCnt; // max window hops during the initial (when the MIDI buffer fills for first time) sync scan
unsigned stepCnt; // count of forward/backward score loc's to examine for a match during cmScMatcherStep().
unsigned maxMissCnt; // max. number of consecutive non-matches during step prior to executing a scan.
unsigned scanCnt; // current count of times a resync-scan was executed during cmScMatcherStep()
bool printFl;
} cmScMatcher;
cmScMatcher* cmScMatcherAlloc(
cmCtx* c, // Program context.
cmScMatcher* p, // Existing cmScMatcher to reallocate or NULL to allocate a new cmScMatcher.
double srate, // System sample rate.
cmScH_t scH, // Score handle. See cmScore.h.
unsigned scWndN, // Length of the scores active search area. ** See Notes.
unsigned midiWndN, // Length of the MIDI active note buffer. ** See Notes.
cmScMatcherCb_t cbFunc, // A cmScMatcherCb_t function to be called to notify the recipient of changes in the score matcher status.
void* cbArg ); // User argument to 'cbFunc'.
// Notes:
// The cmScMatcher maintains an internal cmScMatch object which is used to attempt to find the
// best match between the current MIDI active note buffer and the current score search area.
// 'scWndN' is used to set the cmScMatch 'locN' argument.
// 'midiWndN' sets the length of the MIDI FIFO which is used to match to the score with
// each recceived MIDI note.
// 'midiWndN' must be <= 'scWndN'.
cmRC_t cmScMatcherFree( cmScMatcher** pp );
cmRC_t cmScMatcherInit( cmScMatcher* p, double srate, cmScH_t scH, unsigned scWndN, unsigned midiWndN, cmScMatcherCb_t cbFunc, void* cbArg );
cmRC_t cmScMatcherFinal( cmScMatcher* p );
// 'scLocIdx' is a score index as used by cmScoreLoc(scH) not into p->mp->loc[].
cmRC_t cmScMatcherReset( cmScMatcher* p, unsigned scLocIdx );
// Slide a score window 'hopCnt' times, beginning at 'bli' (an
// index into p->mp->loc[]) looking for the best match to p->midiBuf[].
// The score window contain scWndN (p->mp->mcn-1) score locations.
// Returns the index into p->mp->loc[] of the start of the best
// match score window. The score associated
// with this match is stored in s_opt.
unsigned cmScMatcherScan( cmScMatcher* p, unsigned bli, unsigned hopCnt );
// Step forward/back by p->stepCnt from p->eli.
// p->eli must therefore be valid prior to calling this function.
// If more than p->maxMissCnt consecutive MIDI events are
// missed then automatically run cmScAlignScan().
// Return cmEofRC if the end of the score is encountered.
// Return cmSubSysFailRC if an internal scan resync. failed.
cmRC_t cmScMatcherStep( cmScMatcher* p );
// This function calls cmScMatcherScan() and cmScMatcherStep() internally.
// If 'status' is not kNonMidiMdId then the function returns without changing the
// state of the object. In other words the matcher only recognizes MIDI note-on messages.
// If the MIDI note passed by the call results in a successful match then
// p->eli will be updated to the location in p->mp->loc[] of the latest
// match, the MIDI note in p->midiBuf[] associated with this match
// will be assigned a valid locIdx and scLocIdx values, and *scLocIdxPtr
// will be set with the matched scLocIdx of the match.
// If this call does not result in a successful match *scLocIdxPtr is set
// to cmInvalidIdx.
// 'muid' is the unique id associated with this MIDI event under the circumstances
// that the event came from a MIDI file. See cmMidiFile.h cmMidiTrackMsg_t.uid.
// Return:
// cmOkRC - Continue processing MIDI events.
// cmEofRC - The end of the score was encountered.
// cmInvalidArgRC - scan failed or the object was in an invalid state to attempt a match.
// cmSubSysFailRC - a scan resync failed in cmScMatcherStep().
cmRC_t cmScMatcherExec( cmScMatcher* p, unsigned smpIdx, unsigned muid, unsigned status, cmMidiByte_t d0, cmMidiByte_t d1, unsigned* scLocIdxPtr );
void cmScMatcherPrint( cmScMatcher* p );
//------------------------------------------------------------------------------------------------------------
//)
//( { label:cmScMeas file_desc:"Measure and report some differences between the score and the performance." kw:[proc] }
typedef struct
{
cmScoreSet_t* sp; // ptr to this set in the score
unsigned bsei; // begin score event index
unsigned esei; // end score event index
unsigned bsli; // beg score loc index
unsigned esli; // end score loc index
unsigned bli; //
unsigned eli; //
double value; // DBL_MAX if the value has not yet been set
double tempo; //
double match_cost; // cost of the match to the performance divided by sp->eleCnt
} cmScMeasSet_t;
typedef struct
{
cmObj obj;
double srate; //
cmScMatch* mp; //
unsigned mii; // next avail recd in midiBuf[]
unsigned mn; // length of of midiBuf[] (init. to 2*cmScoreEvtCount())
cmScMatchMidi_t* midiBuf; // midiBuf[mn]
unsigned sn; // length of set[] (init. to cmScoreSetCount())
cmScMeasSet_t* set; // set[sn]
unsigned dn; // length of dynRef[]
unsigned* dynRef; // dynRef[dn]
unsigned nsi; // next set index to fill (this is the set[] we are waiting to complete)
unsigned nsli; // next score location index we are expecting to receive
unsigned vsi; // set[vsi:nsi-1] indicates sets with new values following a call to cmScMeasExec()
unsigned vsli; // vsli:nsli-1 indicates cmScore loc's to check for section triggers following a call to cmScMeasExec()
} cmScMeas;
//
// Notes:
//
// 1) midiBuf[] stores all MIDI notes for the duration of the performance
// it is initialized to 2*score_event_count.
//
// 2) dynRef[] is the gives the MIDI velocity range for each dynamics
// category: pppp-fff
//
// 3) See a cmDspKr.c _cmScFolMatcherCb() for an example of how
// cmScMeas.vsi and cmScMeas.vsli are used to act on the results of
// a call to cmMeasExec().
cmScMeas* cmScMeasAlloc( cmCtx* c, cmScMeas* p, cmScH_t scH, double srate, const unsigned* dynRefArray, unsigned dynRefCnt );
cmRC_t cmScMeasFree( cmScMeas** pp );
cmRC_t cmScMeasInit( cmScMeas* p, cmScH_t scH, double srate, const unsigned* dynRefArray, unsigned dynRefCnt );
cmRC_t cmScMeasFinal( cmScMeas* p );
// Empty MIDI buffer and set the next set nsi and nsli to zero.
cmRC_t cmScMeasReset( cmScMeas* p );
// This function is called for each input MIDI note which is assigned a
// score location by cmScMatcher.
// 'mni' is the MIDI event index which uniquely identifies this MIDI event.
// 'locIdx' is the location index into cmScMatcher.mp->loc[] associated with
// this event.
cmRC_t cmScMeasExec( cmScMeas* p, unsigned mni, unsigned locIdx, unsigned scEvtIdx, unsigned flags, unsigned smpIdx, unsigned pitch, unsigned vel );
//=======================================================================================================================
unsigned cmScAlignScanToTimeLineEvent( cmScMatcher* p, cmTlH_t tlH, cmTlObj_t* top, unsigned endSmpIdx );
// Given a score, a time-line, and a marker on the time line scan the
// entire score looking for the best match between the first 'midiN'
// notes in each marker region and the score.
void cmScAlignScanMarkers( cmRpt_t* rpt, cmTlH_t tlH, cmScH_t scH );
//------------------------------------------------------------------------------------------------------------
//)
//( { label:cmScMod file_desc:"Store and recall parameter information under score follower control." kw:[proc] }
/*
Syntax: <loc> <mod> <var> <type> <params>
<loc> - score location
<mod> - name of the modulator
<var> - variable name
<type> - type of operation
<params>
<min> - set a variable min value
<max> - set a variable max value
<rate> - limit how often a variable is transmitted while it is ramping
<val> - type dependent value - see 'Types' below.
<end> - ending value for a ramping variable
<dur> - determines the length of time to get to the ending value
The value of parameters may be literal numeric values or may refer to
variables by their name.
Types:
set = set <var> to <val> which may be a literal or another variable.
line = ramp from its current value to <val> over <dur> seconds
sline = set <var> to <val> and ramp to <end> over <dur> seconds
post = send a 'post' msg after each transmission (can be used to change the cross-fader after each msg)
*/
enum
{
kInvalidModTId,
kDeclModTId, // declare a variable but do not associate a value with it (allows a variable to be connected to w/o sending a value)
kSetModTId, // set variable to parray[0] at scLocIdx
kLineModTId, // linear ramp variable to parray[0] over parray[1] seconds
kSetLineModTId, // set variable to parray[0] and ramp to parray[1] over parray[2] seconds
kPostModTId, //
};
enum
{
kActiveModFl = 0x01, // this variable is on the 'active' list
kCalcModFl = 0x02 // when this variable is used as a parameter it's value must be calculated rather than used directly.
};
struct cmScModEntry_str;
typedef enum
{
kInvalidModPId,
kLiteralModPId, // this is a literal value
kSymbolModPId //
} cmScModPId_t;
typedef struct cmScModParam_str
{
cmScModPId_t pid; // parameter type: literal or symbol
unsigned symId; // symbol of external and internal variables
double val; // value of literals
} cmScModParam_t;
typedef struct cmScModVar_str
{
unsigned flags; // see kXXXModFl flags above.
unsigned varSymId; // variable name
unsigned outVarId; // output var id
double value; // current value of this variable
double v0; // reserved internal variable
unsigned phase; // cycle phase since activation
double min;
double max;
double rate; // output rate in milliseconds (use
struct cmScModEntry_str* entry; // last entry assoc'd with this value
struct cmScModVar_str* vlink; // p->vlist link
struct cmScModVar_str* alink; // p->alist link
} cmScModVar_t;
// Each entry gives a time tagged location and some parameters
// for an algorthm which is used to set/modulate a value.
typedef struct cmScModEntry_str
{
unsigned scLocIdx; // entry start time
unsigned typeId; // variable type
cmScModParam_t beg; // parameter values
cmScModParam_t end; //
cmScModParam_t dur; //
cmScModParam_t min; // min value for this variable
cmScModParam_t max; // max value for this variable
cmScModParam_t rate; // update rate in milliseconds (DBL_MAX to disable)
cmScModVar_t* varPtr; // target variable
} cmScModEntry_t;
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typedef void (*cmScModCb_t)( void* cbArg, unsigned varSymId, double value, bool postFl );
typedef struct
{
cmObj obj;
cmChar_t* fn; // modulator score file
unsigned modSymId; // modulator name
cmSymTblH_t stH; // symbol table used by this modulator
cmScModCb_t cbFunc; // active value callback function
void* cbArg; // first arg to cbFunc()
unsigned samplesPerCycle; // interval in samples between calls to cmScModulatorExec()
double srate; // system sample rate
cmScModEntry_t* earray; // earray[en] - entry array sorted on ascending cmScModEntry_t.scLocIdx
unsigned en; // count
cmScModVar_t* vlist; // variable list
cmScModVar_t* alist; // active variable list
cmScModVar_t* elist; // last element on the active list
unsigned nei; // next entry index
unsigned outVarCnt; // count of unique vars that are targets of entry recds
bool postFl; // send a 'post' msg after each transmission
} cmScModulator;
cmScModulator* cmScModulatorAlloc( cmCtx* c, cmScModulator* p, cmCtx_t* ctx, cmSymTblH_t stH, double srate, unsigned samplesPerCycle, const cmChar_t* fn, const cmChar_t* modLabel, cmScModCb_t cbFunc, void* cbArg );
cmRC_t cmScModulatorFree( cmScModulator** pp );
cmRC_t cmScModulatorInit( cmScModulator* p, cmCtx_t* ctx, cmSymTblH_t stH, double srate, unsigned samplesPerCycle, const cmChar_t* fn, const cmChar_t* modLabel, cmScModCb_t cbFunc, void* cbArg );
cmRC_t cmScModulatorFinal( cmScModulator* p );
// Return count of variables.
unsigned cmScModulatorOutVarCount( cmScModulator* p );
// Return a pointer to the variable at vlist[idx].
cmScModVar_t* cmScModulatorOutVar( cmScModulator* p, unsigned idx );
cmRC_t cmScModulatorSetValue( cmScModulator* p, unsigned varSymId, double value, double min, double max );
cmRC_t cmScModulatorReset( cmScModulator* p, cmCtx_t* ctx, unsigned scLocIdx );
cmRC_t cmScModulatorExec( cmScModulator* p, unsigned scLocIdx );
cmRC_t cmScModulatorDump( cmScModulator* p );
//------------------------------------------------------------------------------------------------------------
//)
//( { label:cmRecdPlay file_desc:"Record fragments of audio, store them,and play them back at a later time." kw:[proc] }
//
// Record fragments of audio, store them, and play them back at a later time.
//
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typedef struct cmRecdPlayFrag_str
{
unsigned labelSymId; // this fragments label
cmSample_t** chArray; // record buffer chArray[cmRecdPlay.chCnt][allocCnt]
unsigned allocCnt; // count of samples allocated to each channel
unsigned playIdx; // index of next sample to play
unsigned recdIdx; // index of next sample to receieve audio (count of full samples)
double fadeDbPerSec; // fade rate in dB per second
unsigned fadeSmpIdx;
struct cmRecdPlayFrag_str* rlink; // cmRecdPlay.rlist link
struct cmRecdPlayFrag_str* plink; // cmRecdPlay.plist link
} cmRecdPlayFrag;
typedef struct
{
cmObj obj;
cmRecdPlayFrag* frags; // frags[fragCnt] fragment array
unsigned fragCnt; // count of fragments
double srate; // system sample rate
unsigned chCnt; // count of input and output audio channels
double initFragSecs; // size initial memory allocated to each frag in seconds
unsigned maxLaSmpCnt; // samples allocated to each channel of the look-ahead buffers.
unsigned curLaSmpCnt; // current look-ahead time in samples (curLaSmpCnt<=maxLaSmpCnt)
cmSample_t** laChs; // laChs[chCnt][maxLaSmpCnt] - look-ahead buffers
int laSmpIdx; // next look-ahead buffer index to receive a sample
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cmRecdPlayFrag* plist; // currently playing frags
cmRecdPlayFrag* rlist; // currently recording frags
} cmRecdPlay;
// srate - system sample rate
// fragCnt - total count of samples to record
// chCnt - count of input and output audio channels.
// initFragSecs - amount of memory to pre-allocate for each fragment.
// maxLaSecs - maximum value for curLaSecs
// curLaSecs - current duration of look-ahead buffer
//
// The look-ahead buffer is a circular buffer which hold the previous 'curLaSecs' seconds
// of incoming audio. When recording is enabled with via cmRecdPlayBeginRecord() the
// look ahead buffer is automatically prepended to the fragment.
cmRecdPlay* cmRecdPlayAlloc( cmCtx* c, cmRecdPlay* p, double srate, unsigned fragCnt, unsigned chCnt, double initFragSecs, double maxLaSecs, double curLaSecs );
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cmRC_t cmRecdPlayFree( cmRecdPlay** pp );
cmRC_t cmRecdPlayInit( cmRecdPlay* p, double srate, unsigned flagCnt, unsigned chCnt, double initFragSecs, double maxLaSecs, double curLaSecs );
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cmRC_t cmRecdPlayFinal( cmRecdPlay* p );
cmRC_t cmRecdPlayRegisterFrag( cmRecdPlay* p, unsigned fragIdx, unsigned labelSymId );
cmRC_t cmRecdPlaySetLaSecs( cmRecdPlay* p, double curLaSecs );
// Deactivates all active recorders and players, zeros the look-ahead buffer and
// rewinds all fragment play positions. This function does not clear the audio from
// frabments that have already been recorded.
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cmRC_t cmRecdPlayRewind( cmRecdPlay* p );
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cmRC_t cmRecdPlayBeginRecord( cmRecdPlay* p, unsigned labelSymId );
cmRC_t cmRecdPlayEndRecord( cmRecdPlay* p, unsigned labelSymId );
cmRC_t cmRecdPlayInsertRecord(cmRecdPlay* p, unsigned labelSymId, const cmChar_t* wavFn );
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cmRC_t cmRecdPlayBeginPlay( cmRecdPlay* p, unsigned labelSymId );
cmRC_t cmRecdPlayEndPlay( cmRecdPlay* p, unsigned labelSymId );
// Begin fading out the specified fragment at a rate deteremined by 'dbPerSec'.
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cmRC_t cmRecdPlayBeginFade( cmRecdPlay* p, unsigned labelSymId, double fadeDbPerSec );
cmRC_t cmRecdPlayExec( cmRecdPlay* p, const cmSample_t** iChs, cmSample_t** oChs, unsigned chCnt, unsigned smpCnt );
//)
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#ifdef __cplusplus
}
#endif
#endif