/[svn]/linuxsampler/trunk/src/engines/gig/Voice.h

Diff of /linuxsampler/trunk/src/engines/gig/Voice.h

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-revision 242 by schoenebeck,
Wed Sep 15 13:59:08 2004 UTC
+revision 285 by schoenebeck,
Thu Oct 14 21:31:26 2004 UTC
 Line 31
  #include "../../common/RTMath.h"
  #include "../../common/RingBuffer.h"
- #include "../../common/RTELMemoryPool.h"
+ #include "../../common/Pool.h"
  #include "../../drivers/audio/AudioOutputDevice.h"
  #include "../../lib/fileloader/libgig/gig.h"
  #include "../common/BiquadFilter.h"
 Line 92 
 namespace LinuxSampler { namespace gig {
              int          MIDIKey;      ///< MIDI key number of the key that triggered the voice
              uint         KeyGroup;
              DiskThread*  pDiskThread;  ///< Pointer to the disk thread, to be able to order a disk stream and later to delete the stream again
+             RTList<Voice>::Iterator itChildVoice; ///< Points to the next layer voice (if any). This field is currently only used by the voice stealing algorithm.
              // Methods
              Voice();
             ~Voice();
-             void Kill(Event* pKillEvent);
+             void Kill(Pool<Event>::Iterator& itKillEvent);
-             void KillImmediately();
              void Render(uint Samples);
              void Reset();
              void SetOutput(AudioOutputDevice* pAudioOutputDevice);
              void SetEngine(Engine* pEngine);
-             int  Trigger(Event* pNoteOnEvent, int PitchBend, ::gig::Instrument* pInstrument, int iLayer = 0, bool ReleaseTriggerVoice = false);
+             int  Trigger(Pool<Event>::Iterator& itNoteOnEvent, int PitchBend, ::gig::Instrument* pInstrument, int iLayer = 0, bool ReleaseTriggerVoice = false);
-             inline bool IsActive() { return Active; }
+             inline bool IsActive() { return PlaybackState; }
          private:
              // Types
              enum playback_state_t {
-                 playback_state_ram,
+                 playback_state_end  = 0,
-                 playback_state_disk,
+                 playback_state_ram  = 1,
-                 playback_state_end
+                 playback_state_disk = 2
              };
              // Attributes
              gig::Engine*                pEngine;            ///< Pointer to the sampler engine, to be able to access the event lists.
              float                       Volume;             ///< Volume level of the voice
+             float                       PanLeft;
+             float                       PanRight;
              float                       CrossfadeVolume;    ///< Current attenuation level caused by a crossfade (only if a crossfade is defined of course)
              double                      Pos;                ///< Current playback position in sample
              double                      PitchBase;          ///< Basic pitch depth, stays the same for the whole life time of the voice
-Line 122 
 namespace LinuxSampler { namespace gig {
+Line 124 
 namespace LinuxSampler { namespace gig {
              ::gig::Sample*              pSample;            ///< Pointer to the sample to be played back
              ::gig::Region*              pRegion;            ///< Pointer to the articulation information of the respective keyboard region of this voice
              ::gig::DimensionRegion*     pDimRgn;            ///< Pointer to the articulation information of current dimension region of this voice
-             bool                        Active;             ///< If this voice object is currently in usage
              playback_state_t            PlaybackState;      ///< When a sample will be triggered, it will be first played from RAM cache and after a couple of sample points it will switch to disk streaming and at the end of a disk stream we have to add null samples, so the interpolator can do it's work correctly
              bool                        DiskVoice;          ///< If the sample is very short it completely fits into the RAM cache and doesn't need to be streamed from disk, in that case this flag is set to false
              Stream::reference_t         DiskStreamRef;      ///< Reference / link to the disk stream
-Line 146 
 namespace LinuxSampler { namespace gig {
+Line 147 
 namespace LinuxSampler { namespace gig {
              LFO<gig::VCAManipulator>*   pLFO1;              ///< Low Frequency Oscillator 1 (Amplification)
              LFO<gig::VCFCManipulator>*  pLFO2;             ///< Low Frequency Oscillator 2 (Filter cutoff frequency)
              LFO<gig::VCOManipulator>*   pLFO3;              ///< Low Frequency Oscillator 3 (Pitch)
-             Event*                      pTriggerEvent;      ///< First event on the key's list the voice should process (only needed for the first audio fragment in which voice was triggered, after that it will be set to NULL).
+             Pool<Event>::Iterator       itTriggerEvent;      ///< First event on the key's list the voice should process (only needed for the first audio fragment in which voice was triggered, after that it will be set to NULL).
-             Event*                      pKillEvent;         ///< Event which caused this voice to be killed
+             Pool<Event>::Iterator       itKillEvent;         ///< Event which caused this voice to be killed
              // Static Methods
              static float CalculateFilterCutoffCoeff();
              static int   CalculateFilterUpdateMask();
              // Methods
+             void        KillImmediately();
              void        ProcessEvents(uint Samples);
              #if ENABLE_FILTER
              void        CalculateBiquadParameters(uint Samples);
              #endif // ENABLE_FILTER
-             void        Interpolate(uint Samples, sample_t* pSrc, uint Skip);
+             void        InterpolateNoLoop(uint Samples, sample_t* pSrc, uint Skip);
              void        InterpolateAndLoop(uint Samples, sample_t* pSrc, uint Skip);
-             inline void InterpolateOneStep_Stereo(sample_t* pSrc, int& i, float& effective_volume, float& pitch, biquad_param_t& bq_base, biquad_param_t& bq_main) {
+             inline void InterpolateMono(sample_t* pSrc, int& i) {
+                 InterpolateOneStep_Mono(pSrc, i,
+                                         pEngine->pSynthesisParameters[Event::destination_vca][i] * PanLeft,
+                                         pEngine->pSynthesisParameters[Event::destination_vca][i] * PanRight,
+                                         pEngine->pSynthesisParameters[Event::destination_vco][i],
+                                         pEngine->pBasicFilterParameters[i],
+                                         pEngine->pMainFilterParameters[i]);
+             }
+             inline void InterpolateStereo(sample_t* pSrc, int& i) {
+                 InterpolateOneStep_Stereo(pSrc, i,
+                                           pEngine->pSynthesisParameters[Event::destination_vca][i] * PanLeft,
+                                           pEngine->pSynthesisParameters[Event::destination_vca][i] * PanRight,
+                                           pEngine->pSynthesisParameters[Event::destination_vco][i],
+                                           pEngine->pBasicFilterParameters[i],
+                                           pEngine->pMainFilterParameters[i]);
+             }
+             inline void InterpolateOneStep_Stereo(sample_t* pSrc, int& i, float volume_left, float volume_right, float& pitch, biquad_param_t& bq_base, biquad_param_t& bq_main) {
                  int   pos_int   = RTMath::DoubleToInt(this->Pos);  // integer position
                  float pos_fract = this->Pos - pos_int;             // fractional part of position
                  pos_int <<= 1;
-Line 168 
 namespace LinuxSampler { namespace gig {
+Line 189 
 namespace LinuxSampler { namespace gig {
                  #if USE_LINEAR_INTERPOLATION
                      #if ENABLE_FILTER
                          // left channel
-                         pEngine->pOutputLeft[i]    += this->FilterLeft.Apply(&bq_base, &bq_main, effective_volume * (pSrc[pos_int]   + pos_fract * (pSrc[pos_int+2] - pSrc[pos_int])));
+                         pEngine->pOutputLeft[i]    += this->FilterLeft.Apply(&bq_base, &bq_main, volume_left * (pSrc[pos_int]   + pos_fract * (pSrc[pos_int+2] - pSrc[pos_int])));
                          // right channel
-                         pEngine->pOutputRight[i++] += this->FilterRight.Apply(&bq_base, &bq_main, effective_volume * (pSrc[pos_int+1] + pos_fract * (pSrc[pos_int+3] - pSrc[pos_int+1])));
+                         pEngine->pOutputRight[i++] += this->FilterRight.Apply(&bq_base, &bq_main, volume_right * (pSrc[pos_int+1] + pos_fract * (pSrc[pos_int+3] - pSrc[pos_int+1])));
                      #else // no filter
                          // left channel
-                         pEngine->pOutputLeft[i]    += effective_volume * (pSrc[pos_int]   + pos_fract * (pSrc[pos_int+2] - pSrc[pos_int]));
+                         pEngine->pOutputLeft[i]    += volume_left * (pSrc[pos_int]   + pos_fract * (pSrc[pos_int+2] - pSrc[pos_int]));
                          // right channel
-                         pEngine->pOutputRight[i++] += effective_volume * (pSrc[pos_int+1] + pos_fract * (pSrc[pos_int+3] - pSrc[pos_int+1]));
+                         pEngine->pOutputRight[i++] += volume_right * (pSrc[pos_int+1] + pos_fract * (pSrc[pos_int+3] - pSrc[pos_int+1]));
                      #endif // ENABLE_FILTER
                  #else // polynomial interpolation
                      // calculate left channel
-Line 187 
 namespace LinuxSampler { namespace gig {
+Line 208 
 namespace LinuxSampler { namespace gig {
                      float b   = 2.0f * x1 + xm1 - (5.0f * x0 + x2) * 0.5f;
                      float c   = (x1 - xm1) * 0.5f;
                      #if ENABLE_FILTER
-                         pEngine->pOutputLeft[i] += this->FilterLeft.Apply(&bq_base, &bq_main, effective_volume * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0));
+                         pEngine->pOutputLeft[i] += this->FilterLeft.Apply(&bq_base, &bq_main, volume_left * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0));
                      #else // no filter
-                         pEngine->pOutputLeft[i] += effective_volume * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0);
+                         pEngine->pOutputLeft[i] += volume_left * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0);
                      #endif // ENABLE_FILTER
                      //calculate right channel
-Line 201 
 namespace LinuxSampler { namespace gig {
+Line 222 
 namespace LinuxSampler { namespace gig {
                      b   = 2.0f * x1 + xm1 - (5.0f * x0 + x2) * 0.5f;
                      c   = (x1 - xm1) * 0.5f;
                      #if ENABLE_FILTER
-                         pEngine->pOutputRight[i++] += this->FilterRight.Apply(&bq_base, &bq_main, effective_volume * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0));
+                         pEngine->pOutputRight[i++] += this->FilterRight.Apply(&bq_base, &bq_main, volume_right * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0));
                      #else // no filter
-                         pEngine->pOutputRight[i++] += effective_volume * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0);
+                         pEngine->pOutputRight[i++] += volume_right * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0);
                      #endif // ENABLE_FILTER
                  #endif // USE_LINEAR_INTERPOLATION
                  this->Pos += pitch;
              }
-             inline void InterpolateOneStep_Mono(sample_t* pSrc, int& i, float& effective_volume, float& pitch,  biquad_param_t& bq_base, biquad_param_t& bq_main) {
+             inline void InterpolateOneStep_Mono(sample_t* pSrc, int& i, float volume_left, float volume_right, float& pitch,  biquad_param_t& bq_base, biquad_param_t& bq_main) {
                  int   pos_int   = RTMath::DoubleToInt(this->Pos);  // integer position
                  float pos_fract = this->Pos - pos_int;             // fractional part of position
                  #if USE_LINEAR_INTERPOLATION
-                     float sample_point  = effective_volume * (pSrc[pos_int] + pos_fract * (pSrc[pos_int+1] - pSrc[pos_int]));
+                     float sample_point  = pSrc[pos_int] + pos_fract * (pSrc[pos_int+1] - pSrc[pos_int]);
                  #else // polynomial interpolation
                      float xm1 = pSrc[pos_int];
                      float x0  = pSrc[pos_int+1];
-Line 224 
 namespace LinuxSampler { namespace gig {
+Line 245 
 namespace LinuxSampler { namespace gig {
                      float a   = (3.0f * (x0 - x1) - xm1 + x2) * 0.5f;
                      float b   = 2.0f * x1 + xm1 - (5.0f * x0 + x2) * 0.5f;
                      float c   = (x1 - xm1) * 0.5f;
-                     float sample_point = effective_volume * ((((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0);
+                     float sample_point =  (((a * pos_fract) + b) * pos_fract + c) * pos_fract + x0;
                  #endif // USE_LINEAR_INTERPOLATION
                  #if ENABLE_FILTER
                      sample_point = this->FilterLeft.Apply(&bq_base, &bq_main, sample_point);
                  #endif // ENABLE_FILTER
-                 pEngine->pOutputLeft[i]    += sample_point;
+                 pEngine->pOutputLeft[i]    += sample_point * volume_left;
-                 pEngine->pOutputRight[i++] += sample_point;
+                 pEngine->pOutputRight[i++] += sample_point * volume_right;
                  this->Pos += pitch;
              }

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