#ifndef cwDspTransforms_h #define cwDspTransforms_h namespace cw { namespace dsp { //--------------------------------------------------------------------------------------------------------------------------------- // compressor // namespace compressor { enum { kAtkCompId, kRlsCompId }; typedef struct { real_t srate; // system sample rate unsigned procSmpCnt; // samples per exec cycle real_t inGain; // input gain real_t threshDb; // threshold in dB (max:100 min:0) real_t ratio_num; // numerator of the ratio unsigned atkSmp; // time to reduce the signal by 10.0 db unsigned rlsSmp; // time to increase the signal by 10.0 db real_t outGain; // makeup gain bool bypassFl; // bypass enable sample_t* rmsWnd; // rmsWnd[rmsWndAllocCnt] unsigned rmsWndAllocCnt; // unsigned rmsWndCnt; // current RMS window size (rmsWndCnt must be <= rmsWndAllocCnt) unsigned rmsWndIdx; // next RMS window input index unsigned state; // env. state real_t rmsDb; // current incoming signal RMS (max:100 min:0) real_t gain; // current compressor gain real_t timeConstDb; // the atk/rls will incr/decr by 'timeConstDb' per atkMs/rlsMs. real_t pkDb; // real_t accumDb; // } obj_t; rc_t create( obj_t*& p, real_t srate, unsigned procSmpCnt, real_t inGain, real_t rmsWndMaxMs, real_t rmsWndMs, real_t threshDb, real_t ratio, real_t atkMs, real_t rlsMs, real_t outGain, bool bypassFl ); rc_t destroy( obj_t*& pp ); rc_t exec( obj_t* p, const sample_t* x, sample_t* y, unsigned n ); void set_attack_ms( obj_t* p, real_t ms ); void set_release_ms( obj_t* p, real_t ms ); void set_thresh_db( obj_t* p, real_t thresh ); void set_rms_wnd_ms( obj_t* p, real_t ms ); } namespace limiter { typedef struct { unsigned procSmpCnt; real_t igain; // applied before thresholding real_t thresh; // linear (0.0-1.0) threshold. real_t ogain; // applied after thresholding bool bypassFl; } obj_t; rc_t create( obj_t*& p, real_t srate, unsigned procSmpCnt, real_t thresh, real_t igain, real_t ogain, bool bypassFl ); rc_t destroy( obj_t*& pp ); rc_t exec( obj_t* p, const sample_t* x, sample_t* y, unsigned n ); } namespace dc_filter { typedef struct { real_t d[2]; // real_t b[1]; // real_t a[1]; // a[dn] feedback coeff's real_t b0; // feedforward coeff 0 bool bypassFl; real_t gain; } obj_t; rc_t create( obj_t*& p, real_t srate, unsigned procSmpCnt, real_t gain, bool bypassFl ); rc_t destroy( obj_t*& pp ); rc_t exec( obj_t* p, const sample_t* x, sample_t* y, unsigned n ); rc_t set( obj_t* p, real_t gain, bool bypassFl ); } namespace recorder { typedef struct { real_t srate; // unsigned maxFrameN; // unsigned chN; // channel count unsigned frameIdx; // next frame to write sample_t* buf; // [ [maxFrameN] [maxFrameN] ] } obj_t; // ch0 ch1 rc_t create( obj_t*& pRef, real_t srate, real_t max_secs, unsigned chN ); rc_t destroy( obj_t*& pRef); rc_t exec( obj_t* p, const sample_t* buf, unsigned chN, unsigned frameN ); rc_t exec( obj_t* p, const sample_t* chA[], unsigned chN, unsigned frameN ); rc_t write( obj_t* p, const char* fname ); } namespace audio_meter { typedef struct { unsigned maxWndMs; unsigned maxWndSmpN; unsigned wndSmpN; sample_t* wndV; real_t srate; real_t peakThreshDb; real_t outLin; real_t outDb; bool peakFl; bool clipFl; unsigned peakCnt; unsigned clipCnt; unsigned wi; } obj_t; rc_t create( obj_t*& p, real_t srate, real_t maxWndMs, real_t wndMs, real_t peakThreshDb ); rc_t destroy( obj_t*& pp ); rc_t exec( obj_t* p, const sample_t* x, unsigned n ); void reset( obj_t* p ); void set_window_ms( obj_t* p, real_t wndMs ); } } } #endif