/[svn]/linuxsampler/trunk/src/engines/gig/Voice.cpp
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revision 614 by persson, Mon Jun 6 16:54:20 2005 UTC revision 831 by persson, Sat Jan 28 16:55:30 2006 UTC
# Line 3  Line 3 
3   *   LinuxSampler - modular, streaming capable sampler                     *   *   LinuxSampler - modular, streaming capable sampler                     *
4   *                                                                         *   *                                                                         *
5   *   Copyright (C) 2003, 2004 by Benno Senoner and Christian Schoenebeck   *   *   Copyright (C) 2003, 2004 by Benno Senoner and Christian Schoenebeck   *
6   *   Copyright (C) 2005 Christian Schoenebeck                              *   *   Copyright (C) 2005, 2006 Christian Schoenebeck                        *
7   *                                                                         *   *                                                                         *
8   *   This program is free software; you can redistribute it and/or modify  *   *   This program is free software; you can redistribute it and/or modify  *
9   *   it under the terms of the GNU General Public License as published by  *   *   it under the terms of the GNU General Public License as published by  *
# Line 21  Line 21 
21   *   MA  02111-1307  USA                                                   *   *   MA  02111-1307  USA                                                   *
22   ***************************************************************************/   ***************************************************************************/
23    
 #include "EGADSR.h"  
 #include "Manipulator.h"  
24  #include "../../common/Features.h"  #include "../../common/Features.h"
25  #include "Synthesizer.h"  #include "Synthesizer.h"
26    #include "Profiler.h"
27    
28  #include "Voice.h"  #include "Voice.h"
29    
# Line 32  namespace LinuxSampler { namespace gig { Line 31  namespace LinuxSampler { namespace gig {
31    
32      const float Voice::FILTER_CUTOFF_COEFF(CalculateFilterCutoffCoeff());      const float Voice::FILTER_CUTOFF_COEFF(CalculateFilterCutoffCoeff());
33    
     const int Voice::FILTER_UPDATE_MASK(CalculateFilterUpdateMask());  
   
34      float Voice::CalculateFilterCutoffCoeff() {      float Voice::CalculateFilterCutoffCoeff() {
35          return log(CONFIG_FILTER_CUTOFF_MIN / CONFIG_FILTER_CUTOFF_MAX);          return log(CONFIG_FILTER_CUTOFF_MAX / CONFIG_FILTER_CUTOFF_MIN);
     }  
   
     int Voice::CalculateFilterUpdateMask() {  
         if (CONFIG_FILTER_UPDATE_STEPS <= 0) return 0;  
         int power_of_two;  
         for (power_of_two = 0; 1<<power_of_two < CONFIG_FILTER_UPDATE_STEPS; power_of_two++);  
         return (1 << power_of_two) - 1;  
36      }      }
37    
38      Voice::Voice() {      Voice::Voice() {
39          pEngine     = NULL;          pEngine     = NULL;
40          pDiskThread = NULL;          pDiskThread = NULL;
41          PlaybackState = playback_state_end;          PlaybackState = playback_state_end;
42          pEG1   = NULL;          pLFO1 = new LFOUnsigned(1.0f);  // amplitude EG (0..1 range)
43          pEG2   = NULL;          pLFO2 = new LFOUnsigned(1.0f);  // filter EG (0..1 range)
44          pEG3   = NULL;          pLFO3 = new LFOSigned(1200.0f); // pitch EG (-1200..+1200 range)
         pVCAManipulator  = NULL;  
         pVCFCManipulator = NULL;  
         pVCOManipulator  = NULL;  
         pLFO1  = NULL;  
         pLFO2  = NULL;  
         pLFO3  = NULL;  
45          KeyGroup = 0;          KeyGroup = 0;
46          SynthesisMode = 0; // set all mode bits to 0 first          SynthesisMode = 0; // set all mode bits to 0 first
47          // select synthesis implementation (currently either pure C++ or MMX+SSE(1))          // select synthesis implementation (currently either pure C++ or MMX+SSE(1))
48          #if ARCH_X86          #if CONFIG_ASM && ARCH_X86
49          SYNTHESIS_MODE_SET_IMPLEMENTATION(SynthesisMode, Features::supportsMMX() && Features::supportsSSE());          SYNTHESIS_MODE_SET_IMPLEMENTATION(SynthesisMode, Features::supportsMMX() && Features::supportsSSE());
50          #else          #else
51          SYNTHESIS_MODE_SET_IMPLEMENTATION(SynthesisMode, false);          SYNTHESIS_MODE_SET_IMPLEMENTATION(SynthesisMode, false);
52          #endif          #endif
53          SYNTHESIS_MODE_SET_PROFILING(SynthesisMode, true);          SYNTHESIS_MODE_SET_PROFILING(SynthesisMode, Profiler::isEnabled());
54    
55          FilterLeft.Reset();          finalSynthesisParameters.filterLeft.Reset();
56          FilterRight.Reset();          finalSynthesisParameters.filterRight.Reset();
57      }      }
58    
59      Voice::~Voice() {      Voice::~Voice() {
         if (pEG1)  delete pEG1;  
         if (pEG2)  delete pEG2;  
         if (pEG3)  delete pEG3;  
60          if (pLFO1) delete pLFO1;          if (pLFO1) delete pLFO1;
61          if (pLFO2) delete pLFO2;          if (pLFO2) delete pLFO2;
62          if (pLFO3) delete pLFO3;          if (pLFO3) delete pLFO3;
         if (pVCAManipulator)  delete pVCAManipulator;  
         if (pVCFCManipulator) delete pVCFCManipulator;  
         if (pVCOManipulator)  delete pVCOManipulator;  
63      }      }
64    
65      void Voice::SetEngine(Engine* pEngine) {      void Voice::SetEngine(Engine* pEngine) {
66          this->pEngine = pEngine;          this->pEngine     = pEngine;
   
         // delete old objects  
         if (pEG1) delete pEG1;  
         if (pEG2) delete pEG2;  
         if (pEG3) delete pEG3;  
         if (pVCAManipulator)  delete pVCAManipulator;  
         if (pVCFCManipulator) delete pVCFCManipulator;  
         if (pVCOManipulator)  delete pVCOManipulator;  
         if (pLFO1) delete pLFO1;  
         if (pLFO2) delete pLFO2;  
         if (pLFO3) delete pLFO3;  
   
         // create new ones  
         pEG1   = new EGADSR(pEngine, Event::destination_vca);  
         pEG2   = new EGADSR(pEngine, Event::destination_vcfc);  
         pEG3   = new EGDecay(pEngine, Event::destination_vco);  
         pVCAManipulator  = new VCAManipulator(pEngine);  
         pVCFCManipulator = new VCFCManipulator(pEngine);  
         pVCOManipulator  = new VCOManipulator(pEngine);  
         pLFO1  = new LFO<gig::VCAManipulator>(0.0f, 1.0f, LFO<VCAManipulator>::propagation_top_down, pVCAManipulator, pEngine->pEventPool);  
         pLFO2  = new LFO<gig::VCFCManipulator>(0.0f, 1.0f, LFO<VCFCManipulator>::propagation_top_down, pVCFCManipulator, pEngine->pEventPool);  
         pLFO3  = new LFO<gig::VCOManipulator>(-1200.0f, 1200.0f, LFO<VCOManipulator>::propagation_middle_balanced, pVCOManipulator, pEngine->pEventPool); // +-1 octave (+-1200 cents) max.  
   
67          this->pDiskThread = pEngine->pDiskThread;          this->pDiskThread = pEngine->pDiskThread;
68          dmsg(6,("Voice::SetEngine()\n"));          dmsg(6,("Voice::SetEngine()\n"));
69      }      }
# Line 117  namespace LinuxSampler { namespace gig { Line 72  namespace LinuxSampler { namespace gig {
72       *  Initializes and triggers the voice, a disk stream will be launched if       *  Initializes and triggers the voice, a disk stream will be launched if
73       *  needed.       *  needed.
74       *       *
75       *  @param pEngineChannel       - engine channel on which this voice was ordered       *  @param pEngineChannel - engine channel on which this voice was ordered
76       *  @param itNoteOnEvent        - event that caused triggering of this voice       *  @param itNoteOnEvent  - event that caused triggering of this voice
77       *  @param PitchBend            - MIDI detune factor (-8192 ... +8191)       *  @param PitchBend      - MIDI detune factor (-8192 ... +8191)
78       *  @param pInstrument          - points to the loaded instrument which provides sample wave(s) and articulation data       *  @param pDimRgn        - points to the dimension region which provides sample wave(s) and articulation data
79       *  @param iLayer               - layer number this voice refers to (only if this is a layered sound of course)       *  @param VoiceType      - type of this voice
80       *  @param ReleaseTriggerVoice  - if this new voice is a release trigger voice (optional, default = false)       *  @param iKeyGroup      - a value > 0 defines a key group in which this voice is member of
      *  @param VoiceStealingAllowed - wether the voice is allowed to steal voices for further subvoices  
81       *  @returns 0 on success, a value < 0 if the voice wasn't triggered       *  @returns 0 on success, a value < 0 if the voice wasn't triggered
82       *           (either due to an error or e.g. because no region is       *           (either due to an error or e.g. because no region is
83       *           defined for the given key)       *           defined for the given key)
84       */       */
85      int Voice::Trigger(EngineChannel* pEngineChannel, Pool<Event>::Iterator& itNoteOnEvent, int PitchBend, ::gig::Instrument* pInstrument, int iLayer, bool ReleaseTriggerVoice, bool VoiceStealingAllowed) {      int Voice::Trigger(EngineChannel* pEngineChannel, Pool<Event>::Iterator& itNoteOnEvent, int PitchBend, ::gig::DimensionRegion* pDimRgn, type_t VoiceType, int iKeyGroup) {
86          this->pEngineChannel = pEngineChannel;          this->pEngineChannel = pEngineChannel;
87          if (!pInstrument) {          this->pDimRgn        = pDimRgn;
88             dmsg(1,("voice::trigger: !pInstrument\n"));  
            exit(EXIT_FAILURE);  
         }  
89          #if CONFIG_DEVMODE          #if CONFIG_DEVMODE
90          if (itNoteOnEvent->FragmentPos() > pEngine->MaxSamplesPerCycle) { // just a sanity check for debugging          if (itNoteOnEvent->FragmentPos() > pEngine->MaxSamplesPerCycle) { // just a sanity check for debugging
91              dmsg(1,("Voice::Trigger(): ERROR, TriggerDelay > Totalsamples\n"));              dmsg(1,("Voice::Trigger(): ERROR, TriggerDelay > Totalsamples\n"));
92          }          }
93          #endif // CONFIG_DEVMODE          #endif // CONFIG_DEVMODE
94    
95          Type            = type_normal;          Type            = VoiceType;
96          MIDIKey         = itNoteOnEvent->Param.Note.Key;          MIDIKey         = itNoteOnEvent->Param.Note.Key;
         pRegion         = pInstrument->GetRegion(MIDIKey);  
97          PlaybackState   = playback_state_init; // mark voice as triggered, but no audio rendered yet          PlaybackState   = playback_state_init; // mark voice as triggered, but no audio rendered yet
98          Delay           = itNoteOnEvent->FragmentPos();          Delay           = itNoteOnEvent->FragmentPos();
99          itTriggerEvent  = itNoteOnEvent;          itTriggerEvent  = itNoteOnEvent;
100          itKillEvent     = Pool<Event>::Iterator();          itKillEvent     = Pool<Event>::Iterator();
101            KeyGroup        = iKeyGroup;
102            pSample         = pDimRgn->pSample; // sample won't change until the voice is finished
103    
104          if (!pRegion) {          // calculate volume
105              dmsg(4, ("gig::Voice: No Region defined for MIDI key %d\n", MIDIKey));          const double velocityAttenuation = pDimRgn->GetVelocityAttenuation(itNoteOnEvent->Param.Note.Velocity);
             return -1;  
         }  
106    
107          // only mark the first voice of a layered voice (group) to be in a          Volume = velocityAttenuation / 32768.0f; // we downscale by 32768 to convert from int16 value range to DSP value range (which is -1.0..1.0)
         // key group, so the layered voices won't kill each other  
         KeyGroup = (iLayer == 0 && !ReleaseTriggerVoice) ? pRegion->KeyGroup : 0;  
108    
109          // get current dimension values to select the right dimension region          Volume *= pDimRgn->SampleAttenuation;
         //FIXME: controller values for selecting the dimension region here are currently not sample accurate  
         uint DimValues[8] = { 0 };  
         for (int i = pRegion->Dimensions - 1; i >= 0; i--) {  
             switch (pRegion->pDimensionDefinitions[i].dimension) {  
                 case ::gig::dimension_samplechannel:  
                     DimValues[i] = 0; //TODO: we currently ignore this dimension  
                     break;  
                 case ::gig::dimension_layer:  
                     DimValues[i] = iLayer;  
                     break;  
                 case ::gig::dimension_velocity:  
                     DimValues[i] = itNoteOnEvent->Param.Note.Velocity;  
                     break;  
                 case ::gig::dimension_channelaftertouch:  
                     DimValues[i] = 0; //TODO: we currently ignore this dimension  
                     break;  
                 case ::gig::dimension_releasetrigger:  
                     Type = (ReleaseTriggerVoice) ? type_release_trigger : (!iLayer) ? type_release_trigger_required : type_normal;  
                     DimValues[i] = (uint) ReleaseTriggerVoice;  
                     break;  
                 case ::gig::dimension_keyboard:  
                     DimValues[i] = (uint) pEngineChannel->CurrentKeyDimension;  
                     break;  
                 case ::gig::dimension_roundrobin:  
                     DimValues[i] = (uint) pEngineChannel->pMIDIKeyInfo[MIDIKey].RoundRobinIndex; // incremented for each note on  
                     break;  
                 case ::gig::dimension_random:  
                     pEngine->RandomSeed = pEngine->RandomSeed * 1103515245 + 12345; // classic pseudo random number generator  
                     DimValues[i] = (uint) pEngine->RandomSeed >> (32 - pRegion->pDimensionDefinitions[i].bits); // highest bits are most random  
                     break;  
                 case ::gig::dimension_modwheel:  
                     DimValues[i] = pEngineChannel->ControllerTable[1];  
                     break;  
                 case ::gig::dimension_breath:  
                     DimValues[i] = pEngineChannel->ControllerTable[2];  
                     break;  
                 case ::gig::dimension_foot:  
                     DimValues[i] = pEngineChannel->ControllerTable[4];  
                     break;  
                 case ::gig::dimension_portamentotime:  
                     DimValues[i] = pEngineChannel->ControllerTable[5];  
                     break;  
                 case ::gig::dimension_effect1:  
                     DimValues[i] = pEngineChannel->ControllerTable[12];  
                     break;  
                 case ::gig::dimension_effect2:  
                     DimValues[i] = pEngineChannel->ControllerTable[13];  
                     break;  
                 case ::gig::dimension_genpurpose1:  
                     DimValues[i] = pEngineChannel->ControllerTable[16];  
                     break;  
                 case ::gig::dimension_genpurpose2:  
                     DimValues[i] = pEngineChannel->ControllerTable[17];  
                     break;  
                 case ::gig::dimension_genpurpose3:  
                     DimValues[i] = pEngineChannel->ControllerTable[18];  
                     break;  
                 case ::gig::dimension_genpurpose4:  
                     DimValues[i] = pEngineChannel->ControllerTable[19];  
                     break;  
                 case ::gig::dimension_sustainpedal:  
                     DimValues[i] = pEngineChannel->ControllerTable[64];  
                     break;  
                 case ::gig::dimension_portamento:  
                     DimValues[i] = pEngineChannel->ControllerTable[65];  
                     break;  
                 case ::gig::dimension_sostenutopedal:  
                     DimValues[i] = pEngineChannel->ControllerTable[66];  
                     break;  
                 case ::gig::dimension_softpedal:  
                     DimValues[i] = pEngineChannel->ControllerTable[67];  
                     break;  
                 case ::gig::dimension_genpurpose5:  
                     DimValues[i] = pEngineChannel->ControllerTable[80];  
                     break;  
                 case ::gig::dimension_genpurpose6:  
                     DimValues[i] = pEngineChannel->ControllerTable[81];  
                     break;  
                 case ::gig::dimension_genpurpose7:  
                     DimValues[i] = pEngineChannel->ControllerTable[82];  
                     break;  
                 case ::gig::dimension_genpurpose8:  
                     DimValues[i] = pEngineChannel->ControllerTable[83];  
                     break;  
                 case ::gig::dimension_effect1depth:  
                     DimValues[i] = pEngineChannel->ControllerTable[91];  
                     break;  
                 case ::gig::dimension_effect2depth:  
                     DimValues[i] = pEngineChannel->ControllerTable[92];  
                     break;  
                 case ::gig::dimension_effect3depth:  
                     DimValues[i] = pEngineChannel->ControllerTable[93];  
                     break;  
                 case ::gig::dimension_effect4depth:  
                     DimValues[i] = pEngineChannel->ControllerTable[94];  
                     break;  
                 case ::gig::dimension_effect5depth:  
                     DimValues[i] = pEngineChannel->ControllerTable[95];  
                     break;  
                 case ::gig::dimension_none:  
                     std::cerr << "gig::Voice::Trigger() Error: dimension=none\n" << std::flush;  
                     break;  
                 default:  
                     std::cerr << "gig::Voice::Trigger() Error: Unknown dimension\n" << std::flush;  
             }  
         }  
         pDimRgn = pRegion->GetDimensionRegionByValue(DimValues);  
110    
111          pSample = pDimRgn->pSample; // sample won't change until the voice is finished          // the volume of release triggered samples depends on note length
112          if (!pSample || !pSample->SamplesTotal) return -1; // no need to continue if sample is silent          if (Type == type_release_trigger) {
113                float noteLength = float(pEngine->FrameTime + Delay -
114                                         pEngineChannel->pMIDIKeyInfo[MIDIKey].NoteOnTime) / pEngine->SampleRate;
115                float attenuation = 1 - 0.01053 * (256 >> pDimRgn->ReleaseTriggerDecay) * noteLength;
116                if (attenuation <= 0) return -1;
117                Volume *= attenuation;
118            }
119    
120          // select channel mode (mono or stereo)          // select channel mode (mono or stereo)
121          SYNTHESIS_MODE_SET_CHANNELS(SynthesisMode, pSample->Channels == 2);          SYNTHESIS_MODE_SET_CHANNELS(SynthesisMode, pSample->Channels == 2);
# Line 288  namespace LinuxSampler { namespace gig { Line 136  namespace LinuxSampler { namespace gig {
136                  CrossfadeVolume = 1.0f;                  CrossfadeVolume = 1.0f;
137          }          }
138    
139          PanLeft  = 1.0f - float(RTMath::Max(pDimRgn->Pan, 0)) /  63.0f;          PanLeft  = Engine::PanCurve[64 - pDimRgn->Pan];
140          PanRight = 1.0f - float(RTMath::Min(pDimRgn->Pan, 0)) / -64.0f;          PanRight = Engine::PanCurve[64 + pDimRgn->Pan];
141    
142          Pos = pDimRgn->SampleStartOffset; // offset where we should start playback of sample (0 - 2000 sample points)          finalSynthesisParameters.dPos = pDimRgn->SampleStartOffset; // offset where we should start playback of sample (0 - 2000 sample points)
143            Pos = pDimRgn->SampleStartOffset;
144    
145          // Check if the sample needs disk streaming or is too short for that          // Check if the sample needs disk streaming or is too short for that
146          long cachedsamples = pSample->GetCache().Size / pSample->FrameSize;          long cachedsamples = pSample->GetCache().Size / pSample->FrameSize;
# Line 301  namespace LinuxSampler { namespace gig { Line 150  namespace LinuxSampler { namespace gig {
150              MaxRAMPos = cachedsamples - (pEngine->MaxSamplesPerCycle << CONFIG_MAX_PITCH) / pSample->Channels; //TODO: this calculation is too pessimistic and may better be moved to Render() method, so it calculates MaxRAMPos dependent to the current demand of sample points to be rendered (e.g. in case of JACK)              MaxRAMPos = cachedsamples - (pEngine->MaxSamplesPerCycle << CONFIG_MAX_PITCH) / pSample->Channels; //TODO: this calculation is too pessimistic and may better be moved to Render() method, so it calculates MaxRAMPos dependent to the current demand of sample points to be rendered (e.g. in case of JACK)
151    
152              // check if there's a loop defined which completely fits into the cached (RAM) part of the sample              // check if there's a loop defined which completely fits into the cached (RAM) part of the sample
153              if (pSample->Loops && pSample->LoopEnd <= MaxRAMPos) {              RAMLoop = (pSample->Loops && pSample->LoopEnd <= MaxRAMPos);
                 RAMLoop        = true;  
                 LoopCyclesLeft = pSample->LoopPlayCount;  
             }  
             else RAMLoop = false;  
154    
155              if (pDiskThread->OrderNewStream(&DiskStreamRef, pSample, MaxRAMPos, !RAMLoop) < 0) {              if (pDiskThread->OrderNewStream(&DiskStreamRef, pSample, MaxRAMPos, !RAMLoop) < 0) {
156                  dmsg(1,("Disk stream order failed!\n"));                  dmsg(1,("Disk stream order failed!\n"));
# Line 316  namespace LinuxSampler { namespace gig { Line 161  namespace LinuxSampler { namespace gig {
161          }          }
162          else { // RAM only voice          else { // RAM only voice
163              MaxRAMPos = cachedsamples;              MaxRAMPos = cachedsamples;
164              if (pSample->Loops) {              RAMLoop = (pSample->Loops != 0);
                 RAMLoop        = true;  
                 LoopCyclesLeft = pSample->LoopPlayCount;  
             }  
             else RAMLoop = false;  
165              dmsg(4,("RAM only voice launched (Looping: %s)\n", (RAMLoop) ? "yes" : "no"));              dmsg(4,("RAM only voice launched (Looping: %s)\n", (RAMLoop) ? "yes" : "no"));
166          }          }
167            if (RAMLoop) {
168                loop.uiTotalCycles = pSample->LoopPlayCount;
169                loop.uiCyclesLeft  = pSample->LoopPlayCount;
170                loop.uiStart       = pSample->LoopStart;
171                loop.uiEnd         = pSample->LoopEnd;
172                loop.uiSize        = pSample->LoopSize;
173            }
174    
175          // calculate initial pitch value          // calculate initial pitch value
176          {          {
177              double pitchbasecents = pDimRgn->FineTune + (int) pEngine->ScaleTuning[MIDIKey % 12];              double pitchbasecents = pDimRgn->FineTune + (int) pEngine->ScaleTuning[MIDIKey % 12];
178              if (pDimRgn->PitchTrack) pitchbasecents += (MIDIKey - (int) pDimRgn->UnityNote) * 100;              if (pDimRgn->PitchTrack) pitchbasecents += (MIDIKey - (int) pDimRgn->UnityNote) * 100;
179              this->PitchBase = RTMath::CentsToFreqRatio(pitchbasecents) * (double(pSample->SamplesPerSecond) / double(pEngine->pAudioOutputDevice->SampleRate()));              this->PitchBase = RTMath::CentsToFreqRatio(pitchbasecents) * (double(pSample->SamplesPerSecond) / double(pEngine->SampleRate));
180              this->PitchBend = RTMath::CentsToFreqRatio(((double) PitchBend / 8192.0) * 200.0); // pitchbend wheel +-2 semitones = 200 cents              this->PitchBend = RTMath::CentsToFreqRatio(((double) PitchBend / 8192.0) * 200.0); // pitchbend wheel +-2 semitones = 200 cents
181          }          }
182    
         const double velocityAttenuation = pDimRgn->GetVelocityAttenuation(itNoteOnEvent->Param.Note.Velocity);  
   
         Volume = velocityAttenuation / 32768.0f; // we downscale by 32768 to convert from int16 value range to DSP value range (which is -1.0..1.0)  
   
         Volume *= pDimRgn->SampleAttenuation;  
   
183          // the length of the decay and release curves are dependent on the velocity          // the length of the decay and release curves are dependent on the velocity
184          const double velrelease = 1 / pDimRgn->GetVelocityRelease(itNoteOnEvent->Param.Note.Velocity);          const double velrelease = 1 / pDimRgn->GetVelocityRelease(itNoteOnEvent->Param.Note.Velocity);
185    
# Line 362  namespace LinuxSampler { namespace gig { Line 203  namespace LinuxSampler { namespace gig {
203              }              }
204              if (pDimRgn->EG1ControllerInvert) eg1controllervalue = 127 - eg1controllervalue;              if (pDimRgn->EG1ControllerInvert) eg1controllervalue = 127 - eg1controllervalue;
205    
206              // calculate influence of EG1 controller on EG1's parameters (TODO: needs to be fine tuned)              // calculate influence of EG1 controller on EG1's parameters
207              double eg1attack  = (pDimRgn->EG1ControllerAttackInfluence)  ? 0.0001 * (double) (1 << pDimRgn->EG1ControllerAttackInfluence)  * eg1controllervalue : 0.0;              // (eg1attack is different from the others)
208              double eg1decay   = (pDimRgn->EG1ControllerDecayInfluence)   ? 0.0001 * (double) (1 << pDimRgn->EG1ControllerDecayInfluence)   * eg1controllervalue : 0.0;              double eg1attack  = (pDimRgn->EG1ControllerAttackInfluence)  ?
209              double eg1release = (pDimRgn->EG1ControllerReleaseInfluence) ? 0.0001 * (double) (1 << pDimRgn->EG1ControllerReleaseInfluence) * eg1controllervalue : 0.0;                  1 + 0.031 * (double) (pDimRgn->EG1ControllerAttackInfluence == 1 ?
210                                          1 : 1 << pDimRgn->EG1ControllerAttackInfluence) * eg1controllervalue : 1.0;
211              pEG1->Trigger(pDimRgn->EG1PreAttack,              double eg1decay   = (pDimRgn->EG1ControllerDecayInfluence)   ? 1 + 0.00775 * (double) (1 << pDimRgn->EG1ControllerDecayInfluence)   * eg1controllervalue : 1.0;
212                            pDimRgn->EG1Attack + eg1attack,              double eg1release = (pDimRgn->EG1ControllerReleaseInfluence) ? 1 + 0.00775 * (double) (1 << pDimRgn->EG1ControllerReleaseInfluence) * eg1controllervalue : 1.0;
213                            pDimRgn->EG1Hold,  
214                            pSample->LoopStart,              EG1.trigger(pDimRgn->EG1PreAttack,
215                            (pDimRgn->EG1Decay1 + eg1decay) * velrelease,                          pDimRgn->EG1Attack * eg1attack,
216                            (pDimRgn->EG1Decay2 + eg1decay) * velrelease,                          pDimRgn->EG1Hold,
217                            pDimRgn->EG1InfiniteSustain,                          pDimRgn->EG1Decay1 * eg1decay * velrelease,
218                            pDimRgn->EG1Sustain,                          pDimRgn->EG1Decay2 * eg1decay * velrelease,
219                            (pDimRgn->EG1Release + eg1release) * velrelease,                          pDimRgn->EG1InfiniteSustain,
220                            // the SSE synthesis implementation requires                          pDimRgn->EG1Sustain,
221                            // the vca start to be 16 byte aligned                          pDimRgn->EG1Release * eg1release * velrelease,
222                            SYNTHESIS_MODE_GET_IMPLEMENTATION(SynthesisMode) ?                          velocityAttenuation,
223                            Delay & 0xfffffffc : Delay,                          pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
224                            velocityAttenuation);          }
225          }  
226            // setup initial volume in synthesis parameters
227            fFinalVolume = getVolume() * EG1.getLevel();
228            finalSynthesisParameters.fFinalVolumeLeft  = fFinalVolume * PanLeft * pEngineChannel->GlobalPanLeft;
229            finalSynthesisParameters.fFinalVolumeRight = fFinalVolume * PanRight * pEngineChannel->GlobalPanRight;
230    
231    
232          // setup EG 2 (VCF Cutoff EG)          // setup EG 2 (VCF Cutoff EG)
# Line 404  namespace LinuxSampler { namespace gig { Line 249  namespace LinuxSampler { namespace gig {
249              }              }
250              if (pDimRgn->EG2ControllerInvert) eg2controllervalue = 127 - eg2controllervalue;              if (pDimRgn->EG2ControllerInvert) eg2controllervalue = 127 - eg2controllervalue;
251    
252              // calculate influence of EG2 controller on EG2's parameters (TODO: needs to be fine tuned)              // calculate influence of EG2 controller on EG2's parameters
253              double eg2attack  = (pDimRgn->EG2ControllerAttackInfluence)  ? 0.0001 * (double) (1 << pDimRgn->EG2ControllerAttackInfluence)  * eg2controllervalue : 0.0;              double eg2attack  = (pDimRgn->EG2ControllerAttackInfluence)  ? 1 + 0.00775 * (double) (1 << pDimRgn->EG2ControllerAttackInfluence)  * eg2controllervalue : 1.0;
254              double eg2decay   = (pDimRgn->EG2ControllerDecayInfluence)   ? 0.0001 * (double) (1 << pDimRgn->EG2ControllerDecayInfluence)   * eg2controllervalue : 0.0;              double eg2decay   = (pDimRgn->EG2ControllerDecayInfluence)   ? 1 + 0.00775 * (double) (1 << pDimRgn->EG2ControllerDecayInfluence)   * eg2controllervalue : 1.0;
255              double eg2release = (pDimRgn->EG2ControllerReleaseInfluence) ? 0.0001 * (double) (1 << pDimRgn->EG2ControllerReleaseInfluence) * eg2controllervalue : 0.0;              double eg2release = (pDimRgn->EG2ControllerReleaseInfluence) ? 1 + 0.00775 * (double) (1 << pDimRgn->EG2ControllerReleaseInfluence) * eg2controllervalue : 1.0;
256    
257              pEG2->Trigger(pDimRgn->EG2PreAttack,              EG2.trigger(pDimRgn->EG2PreAttack,
258                            pDimRgn->EG2Attack + eg2attack,                          pDimRgn->EG2Attack * eg2attack,
259                            false,                          false,
260                            pSample->LoopStart,                          pDimRgn->EG2Decay1 * eg2decay * velrelease,
261                            (pDimRgn->EG2Decay1 + eg2decay) * velrelease,                          pDimRgn->EG2Decay2 * eg2decay * velrelease,
262                            (pDimRgn->EG2Decay2 + eg2decay) * velrelease,                          pDimRgn->EG2InfiniteSustain,
263                            pDimRgn->EG2InfiniteSustain,                          pDimRgn->EG2Sustain,
264                            pDimRgn->EG2Sustain,                          pDimRgn->EG2Release * eg2release * velrelease,
265                            (pDimRgn->EG2Release + eg2release) * velrelease,                          velocityAttenuation,
266                            Delay,                          pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
                           velocityAttenuation);  
267          }          }
268    
269    
270          // setup EG 3 (VCO EG)          // setup EG 3 (VCO EG)
271          {          {
272            double eg3depth = RTMath::CentsToFreqRatio(pDimRgn->EG3Depth);              // if portamento mode is on, we dedicate EG3 purely for portamento, otherwise if portamento is off we do as told by the patch
273            pEG3->Trigger(eg3depth, pDimRgn->EG3Attack, Delay);              bool  bPortamento = pEngineChannel->PortamentoMode && pEngineChannel->PortamentoPos >= 0.0f;
274                float eg3depth = (bPortamento)
275                                     ? RTMath::CentsToFreqRatio((pEngineChannel->PortamentoPos - (float) MIDIKey) * 100)
276                                     : RTMath::CentsToFreqRatio(pDimRgn->EG3Depth);
277                float eg3time = (bPortamento)
278                                    ? pEngineChannel->PortamentoTime
279                                    : pDimRgn->EG3Attack;
280                EG3.trigger(eg3depth, eg3time, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
281                dmsg(5,("PortamentoPos=%f, depth=%f, time=%f\n", pEngineChannel->PortamentoPos, eg3depth, eg3time));
282          }          }
283    
284    
# Line 437  namespace LinuxSampler { namespace gig { Line 289  namespace LinuxSampler { namespace gig {
289                  case ::gig::lfo1_ctrl_internal:                  case ::gig::lfo1_ctrl_internal:
290                      lfo1_internal_depth  = pDimRgn->LFO1InternalDepth;                      lfo1_internal_depth  = pDimRgn->LFO1InternalDepth;
291                      pLFO1->ExtController = 0; // no external controller                      pLFO1->ExtController = 0; // no external controller
292                        bLFO1Enabled         = (lfo1_internal_depth > 0);
293                      break;                      break;
294                  case ::gig::lfo1_ctrl_modwheel:                  case ::gig::lfo1_ctrl_modwheel:
295                      lfo1_internal_depth  = 0;                      lfo1_internal_depth  = 0;
296                      pLFO1->ExtController = 1; // MIDI controller 1                      pLFO1->ExtController = 1; // MIDI controller 1
297                        bLFO1Enabled         = (pDimRgn->LFO1ControlDepth > 0);
298                      break;                      break;
299                  case ::gig::lfo1_ctrl_breath:                  case ::gig::lfo1_ctrl_breath:
300                      lfo1_internal_depth  = 0;                      lfo1_internal_depth  = 0;
301                      pLFO1->ExtController = 2; // MIDI controller 2                      pLFO1->ExtController = 2; // MIDI controller 2
302                        bLFO1Enabled         = (pDimRgn->LFO1ControlDepth > 0);
303                      break;                      break;
304                  case ::gig::lfo1_ctrl_internal_modwheel:                  case ::gig::lfo1_ctrl_internal_modwheel:
305                      lfo1_internal_depth  = pDimRgn->LFO1InternalDepth;                      lfo1_internal_depth  = pDimRgn->LFO1InternalDepth;
306                      pLFO1->ExtController = 1; // MIDI controller 1                      pLFO1->ExtController = 1; // MIDI controller 1
307                        bLFO1Enabled         = (lfo1_internal_depth > 0 || pDimRgn->LFO1ControlDepth > 0);
308                      break;                      break;
309                  case ::gig::lfo1_ctrl_internal_breath:                  case ::gig::lfo1_ctrl_internal_breath:
310                      lfo1_internal_depth  = pDimRgn->LFO1InternalDepth;                      lfo1_internal_depth  = pDimRgn->LFO1InternalDepth;
311                      pLFO1->ExtController = 2; // MIDI controller 2                      pLFO1->ExtController = 2; // MIDI controller 2
312                        bLFO1Enabled         = (lfo1_internal_depth > 0 || pDimRgn->LFO1ControlDepth > 0);
313                      break;                      break;
314                  default:                  default:
315                      lfo1_internal_depth  = 0;                      lfo1_internal_depth  = 0;
316                      pLFO1->ExtController = 0; // no external controller                      pLFO1->ExtController = 0; // no external controller
317                        bLFO1Enabled         = false;
318              }              }
319              pLFO1->Trigger(pDimRgn->LFO1Frequency,              if (bLFO1Enabled) pLFO1->trigger(pDimRgn->LFO1Frequency,
320                            lfo1_internal_depth,                                               start_level_max,
321                            pDimRgn->LFO1ControlDepth,                                               lfo1_internal_depth,
322                            pEngineChannel->ControllerTable[pLFO1->ExtController],                                               pDimRgn->LFO1ControlDepth,
323                            pDimRgn->LFO1FlipPhase,                                               pDimRgn->LFO1FlipPhase,
324                            pEngine->SampleRate,                                               pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
                           Delay);  
325          }          }
326    
327    
# Line 475  namespace LinuxSampler { namespace gig { Line 332  namespace LinuxSampler { namespace gig {
332                  case ::gig::lfo2_ctrl_internal:                  case ::gig::lfo2_ctrl_internal:
333                      lfo2_internal_depth  = pDimRgn->LFO2InternalDepth;                      lfo2_internal_depth  = pDimRgn->LFO2InternalDepth;
334                      pLFO2->ExtController = 0; // no external controller                      pLFO2->ExtController = 0; // no external controller
335                        bLFO2Enabled         = (lfo2_internal_depth > 0);
336                      break;                      break;
337                  case ::gig::lfo2_ctrl_modwheel:                  case ::gig::lfo2_ctrl_modwheel:
338                      lfo2_internal_depth  = 0;                      lfo2_internal_depth  = 0;
339                      pLFO2->ExtController = 1; // MIDI controller 1                      pLFO2->ExtController = 1; // MIDI controller 1
340                        bLFO2Enabled         = (pDimRgn->LFO2ControlDepth > 0);
341                      break;                      break;
342                  case ::gig::lfo2_ctrl_foot:                  case ::gig::lfo2_ctrl_foot:
343                      lfo2_internal_depth  = 0;                      lfo2_internal_depth  = 0;
344                      pLFO2->ExtController = 4; // MIDI controller 4                      pLFO2->ExtController = 4; // MIDI controller 4
345                        bLFO2Enabled         = (pDimRgn->LFO2ControlDepth > 0);
346                      break;                      break;
347                  case ::gig::lfo2_ctrl_internal_modwheel:                  case ::gig::lfo2_ctrl_internal_modwheel:
348                      lfo2_internal_depth  = pDimRgn->LFO2InternalDepth;                      lfo2_internal_depth  = pDimRgn->LFO2InternalDepth;
349                      pLFO2->ExtController = 1; // MIDI controller 1                      pLFO2->ExtController = 1; // MIDI controller 1
350                        bLFO2Enabled         = (lfo2_internal_depth > 0 || pDimRgn->LFO2ControlDepth > 0);
351                      break;                      break;
352                  case ::gig::lfo2_ctrl_internal_foot:                  case ::gig::lfo2_ctrl_internal_foot:
353                      lfo2_internal_depth  = pDimRgn->LFO2InternalDepth;                      lfo2_internal_depth  = pDimRgn->LFO2InternalDepth;
354                      pLFO2->ExtController = 4; // MIDI controller 4                      pLFO2->ExtController = 4; // MIDI controller 4
355                        bLFO2Enabled         = (lfo2_internal_depth > 0 || pDimRgn->LFO2ControlDepth > 0);
356                      break;                      break;
357                  default:                  default:
358                      lfo2_internal_depth  = 0;                      lfo2_internal_depth  = 0;
359                      pLFO2->ExtController = 0; // no external controller                      pLFO2->ExtController = 0; // no external controller
360                        bLFO2Enabled         = false;
361              }              }
362              pLFO2->Trigger(pDimRgn->LFO2Frequency,              if (bLFO2Enabled) pLFO2->trigger(pDimRgn->LFO2Frequency,
363                            lfo2_internal_depth,                                               start_level_max,
364                            pDimRgn->LFO2ControlDepth,                                               lfo2_internal_depth,
365                            pEngineChannel->ControllerTable[pLFO2->ExtController],                                               pDimRgn->LFO2ControlDepth,
366                            pDimRgn->LFO2FlipPhase,                                               pDimRgn->LFO2FlipPhase,
367                            pEngine->SampleRate,                                               pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
                           Delay);  
368          }          }
369    
370    
# Line 513  namespace LinuxSampler { namespace gig { Line 375  namespace LinuxSampler { namespace gig {
375                  case ::gig::lfo3_ctrl_internal:                  case ::gig::lfo3_ctrl_internal:
376                      lfo3_internal_depth  = pDimRgn->LFO3InternalDepth;                      lfo3_internal_depth  = pDimRgn->LFO3InternalDepth;
377                      pLFO3->ExtController = 0; // no external controller                      pLFO3->ExtController = 0; // no external controller
378                        bLFO3Enabled         = (lfo3_internal_depth > 0);
379                      break;                      break;
380                  case ::gig::lfo3_ctrl_modwheel:                  case ::gig::lfo3_ctrl_modwheel:
381                      lfo3_internal_depth  = 0;                      lfo3_internal_depth  = 0;
382                      pLFO3->ExtController = 1; // MIDI controller 1                      pLFO3->ExtController = 1; // MIDI controller 1
383                        bLFO3Enabled         = (pDimRgn->LFO3ControlDepth > 0);
384                      break;                      break;
385                  case ::gig::lfo3_ctrl_aftertouch:                  case ::gig::lfo3_ctrl_aftertouch:
386                      lfo3_internal_depth  = 0;                      lfo3_internal_depth  = 0;
387                      pLFO3->ExtController = 0; // TODO: aftertouch not implemented yet                      pLFO3->ExtController = 0; // TODO: aftertouch not implemented yet
388                        bLFO3Enabled         = false; // see TODO comment in line above
389                      break;                      break;
390                  case ::gig::lfo3_ctrl_internal_modwheel:                  case ::gig::lfo3_ctrl_internal_modwheel:
391                      lfo3_internal_depth  = pDimRgn->LFO3InternalDepth;                      lfo3_internal_depth  = pDimRgn->LFO3InternalDepth;
392                      pLFO3->ExtController = 1; // MIDI controller 1                      pLFO3->ExtController = 1; // MIDI controller 1
393                        bLFO3Enabled         = (lfo3_internal_depth > 0 || pDimRgn->LFO3ControlDepth > 0);
394                      break;                      break;
395                  case ::gig::lfo3_ctrl_internal_aftertouch:                  case ::gig::lfo3_ctrl_internal_aftertouch:
396                      lfo3_internal_depth  = pDimRgn->LFO3InternalDepth;                      lfo3_internal_depth  = pDimRgn->LFO3InternalDepth;
397                      pLFO1->ExtController = 0; // TODO: aftertouch not implemented yet                      pLFO1->ExtController = 0; // TODO: aftertouch not implemented yet
398                        bLFO3Enabled         = (lfo3_internal_depth > 0 /*|| pDimRgn->LFO3ControlDepth > 0*/); // see TODO comment in line above
399                      break;                      break;
400                  default:                  default:
401                      lfo3_internal_depth  = 0;                      lfo3_internal_depth  = 0;
402                      pLFO3->ExtController = 0; // no external controller                      pLFO3->ExtController = 0; // no external controller
403                        bLFO3Enabled         = false;
404              }              }
405              pLFO3->Trigger(pDimRgn->LFO3Frequency,              if (bLFO3Enabled) pLFO3->trigger(pDimRgn->LFO3Frequency,
406                            lfo3_internal_depth,                                               start_level_mid,
407                            pDimRgn->LFO3ControlDepth,                                               lfo3_internal_depth,
408                            pEngineChannel->ControllerTable[pLFO3->ExtController],                                               pDimRgn->LFO3ControlDepth,
409                            false,                                               false,
410                            pEngine->SampleRate,                                               pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
                           Delay);  
411          }          }
412    
413    
# Line 613  namespace LinuxSampler { namespace gig { Line 480  namespace LinuxSampler { namespace gig {
480              #endif // CONFIG_OVERRIDE_RESONANCE_CTRL              #endif // CONFIG_OVERRIDE_RESONANCE_CTRL
481    
482              #ifndef CONFIG_OVERRIDE_FILTER_TYPE              #ifndef CONFIG_OVERRIDE_FILTER_TYPE
483              FilterLeft.SetType(pDimRgn->VCFType);              finalSynthesisParameters.filterLeft.SetType(pDimRgn->VCFType);
484              FilterRight.SetType(pDimRgn->VCFType);              finalSynthesisParameters.filterRight.SetType(pDimRgn->VCFType);
485              #else // override filter type              #else // override filter type
486              FilterLeft.SetType(CONFIG_OVERRIDE_FILTER_TYPE);              FilterLeft.SetType(CONFIG_OVERRIDE_FILTER_TYPE);
487              FilterRight.SetType(CONFIG_OVERRIDE_FILTER_TYPE);              FilterRight.SetType(CONFIG_OVERRIDE_FILTER_TYPE);
# Line 624  namespace LinuxSampler { namespace gig { Line 491  namespace LinuxSampler { namespace gig {
491              VCFResonanceCtrl.value = pEngineChannel->ControllerTable[VCFResonanceCtrl.controller];              VCFResonanceCtrl.value = pEngineChannel->ControllerTable[VCFResonanceCtrl.controller];
492    
493              // calculate cutoff frequency              // calculate cutoff frequency
494              float cutoff = (!VCFCutoffCtrl.controller)              float cutoff = pDimRgn->GetVelocityCutoff(itNoteOnEvent->Param.Note.Velocity);
                 ? exp((float) (127 - itNoteOnEvent->Param.Note.Velocity) * (float) pDimRgn->VCFVelocityScale * 6.2E-5f * FILTER_CUTOFF_COEFF) * CONFIG_FILTER_CUTOFF_MAX  
                 : exp((float) VCFCutoffCtrl.value * 0.00787402f * FILTER_CUTOFF_COEFF) * CONFIG_FILTER_CUTOFF_MAX;  
   
             // calculate resonance  
             float resonance = (float) VCFResonanceCtrl.value * 0.00787f;   // 0.0..1.0  
495              if (pDimRgn->VCFKeyboardTracking) {              if (pDimRgn->VCFKeyboardTracking) {
496                  resonance += (float) (itNoteOnEvent->Param.Note.Key - pDimRgn->VCFKeyboardTrackingBreakpoint) * 0.00787f;                  cutoff *= exp((itNoteOnEvent->Param.Note.Key - pDimRgn->VCFKeyboardTrackingBreakpoint) * 0.057762265f); // (ln(2) / 12)
497              }              }
498              Constrain(resonance, 0.0, 1.0); // correct resonance if outside allowed value range (0.0..1.0)              CutoffBase = cutoff;
499    
500              VCFCutoffCtrl.fvalue    = cutoff - CONFIG_FILTER_CUTOFF_MIN;              int cvalue;
501              VCFResonanceCtrl.fvalue = resonance;              if (VCFCutoffCtrl.controller) {
502                    cvalue = pEngineChannel->ControllerTable[VCFCutoffCtrl.controller];
503                    if (pDimRgn->VCFCutoffControllerInvert) cvalue = 127 - cvalue;
504                    // VCFVelocityScale in this case means Minimum cutoff
505                    if (cvalue < pDimRgn->VCFVelocityScale) cvalue = pDimRgn->VCFVelocityScale;
506                }
507                else {
508                    cvalue = pDimRgn->VCFCutoff;
509                }
510                cutoff *= float(cvalue) * 0.00787402f; // (1 / 127)
511                if (cutoff > 1.0) cutoff = 1.0;
512                cutoff = (cutoff < 0.5 ? cutoff * 4826 - 1 : cutoff * 5715 - 449);
513                if (cutoff < 1.0) cutoff = 1.0;
514    
515              FilterUpdateCounter = -1;              // calculate resonance
516                float resonance = (float) (VCFResonanceCtrl.controller ? VCFResonanceCtrl.value : pDimRgn->VCFResonance) * 0.00787f; // 0.0..1.0
517    
518                VCFCutoffCtrl.fvalue    = cutoff - 1.0;
519                VCFResonanceCtrl.fvalue = resonance;
520          }          }
521          else {          else {
522              VCFCutoffCtrl.controller    = 0;              VCFCutoffCtrl.controller    = 0;
# Line 662  namespace LinuxSampler { namespace gig { Line 540  namespace LinuxSampler { namespace gig {
540      void Voice::Render(uint Samples) {      void Voice::Render(uint Samples) {
541    
542          // select default values for synthesis mode bits          // select default values for synthesis mode bits
         SYNTHESIS_MODE_SET_INTERPOLATE(SynthesisMode, (PitchBase * PitchBend) != 1.0f);  
         SYNTHESIS_MODE_SET_CONSTPITCH(SynthesisMode, true);  
543          SYNTHESIS_MODE_SET_LOOP(SynthesisMode, false);          SYNTHESIS_MODE_SET_LOOP(SynthesisMode, false);
544    
         // Reset the synthesis parameter matrix  
   
         pEngine->ResetSynthesisParameters(Event::destination_vca, this->Volume * this->CrossfadeVolume * pEngineChannel->GlobalVolume);  
         pEngine->ResetSynthesisParameters(Event::destination_vco, this->PitchBase);  
         pEngine->ResetSynthesisParameters(Event::destination_vcfc, VCFCutoffCtrl.fvalue);  
         pEngine->ResetSynthesisParameters(Event::destination_vcfr, VCFResonanceCtrl.fvalue);  
   
         // Apply events to the synthesis parameter matrix  
         ProcessEvents(Samples);  
   
         // Let all modulators write their parameter changes to the synthesis parameter matrix for the current audio fragment  
         pEG1->Process(Samples, pEngineChannel->pMIDIKeyInfo[MIDIKey].pEvents, itTriggerEvent, this->Pos, this->PitchBase * this->PitchBend, itKillEvent);  
         pEG2->Process(Samples, pEngineChannel->pMIDIKeyInfo[MIDIKey].pEvents, itTriggerEvent, this->Pos, this->PitchBase * this->PitchBend);  
         if (pEG3->Process(Samples)) { // if pitch EG is active  
             SYNTHESIS_MODE_SET_INTERPOLATE(SynthesisMode, true);  
             SYNTHESIS_MODE_SET_CONSTPITCH(SynthesisMode, false);  
         }  
         pLFO1->Process(Samples);  
         pLFO2->Process(Samples);  
         if (pLFO3->Process(Samples)) { // if pitch LFO modulation is active  
             SYNTHESIS_MODE_SET_INTERPOLATE(SynthesisMode, true);  
             SYNTHESIS_MODE_SET_CONSTPITCH(SynthesisMode, false);  
         }  
   
         if (SYNTHESIS_MODE_GET_FILTER(SynthesisMode))  
             CalculateBiquadParameters(Samples); // calculate the final biquad filter parameters  
   
545          switch (this->PlaybackState) {          switch (this->PlaybackState) {
546    
547              case playback_state_init:              case playback_state_init:
# Line 707  namespace LinuxSampler { namespace gig { Line 556  namespace LinuxSampler { namespace gig {
556    
557                      if (DiskVoice) {                      if (DiskVoice) {
558                          // check if we reached the allowed limit of the sample RAM cache                          // check if we reached the allowed limit of the sample RAM cache
559                          if (Pos > MaxRAMPos) {                          if (finalSynthesisParameters.dPos > MaxRAMPos) {
560                              dmsg(5,("Voice: switching to disk playback (Pos=%f)\n", Pos));                              dmsg(5,("Voice: switching to disk playback (Pos=%f)\n", finalSynthesisParameters.dPos));
561                              this->PlaybackState = playback_state_disk;                              this->PlaybackState = playback_state_disk;
562                          }                          }
563                      }                      } else if (finalSynthesisParameters.dPos >= pSample->GetCache().Size / pSample->FrameSize) {
                     else if (Pos >= pSample->GetCache().Size / pSample->FrameSize) {  
564                          this->PlaybackState = playback_state_end;                          this->PlaybackState = playback_state_end;
565                      }                      }
566                  }                  }
# Line 727  namespace LinuxSampler { namespace gig { Line 575  namespace LinuxSampler { namespace gig {
575                              KillImmediately();                              KillImmediately();
576                              return;                              return;
577                          }                          }
578                          DiskStreamRef.pStream->IncrementReadPos(pSample->Channels * (int(Pos) - MaxRAMPos));                          DiskStreamRef.pStream->IncrementReadPos(pSample->Channels * (int(finalSynthesisParameters.dPos) - MaxRAMPos));
579                          Pos -= int(Pos);                          finalSynthesisParameters.dPos -= int(finalSynthesisParameters.dPos);
580                          RealSampleWordsLeftToRead = -1; // -1 means no silence has been added yet                          RealSampleWordsLeftToRead = -1; // -1 means no silence has been added yet
581                      }                      }
582    
# Line 749  namespace LinuxSampler { namespace gig { Line 597  namespace LinuxSampler { namespace gig {
597                      // render current audio fragment                      // render current audio fragment
598                      Synthesize(Samples, ptr, Delay);                      Synthesize(Samples, ptr, Delay);
599    
600                      const int iPos = (int) Pos;                      const int iPos = (int) finalSynthesisParameters.dPos;
601                      const int readSampleWords = iPos * pSample->Channels; // amount of sample words actually been read                      const int readSampleWords = iPos * pSample->Channels; // amount of sample words actually been read
602                      DiskStreamRef.pStream->IncrementReadPos(readSampleWords);                      DiskStreamRef.pStream->IncrementReadPos(readSampleWords);
603                      Pos -= iPos; // just keep fractional part of Pos                      finalSynthesisParameters.dPos -= iPos; // just keep fractional part of playback position
604    
605                      // change state of voice to 'end' if we really reached the end of the sample data                      // change state of voice to 'end' if we really reached the end of the sample data
606                      if (RealSampleWordsLeftToRead >= 0) {                      if (RealSampleWordsLeftToRead >= 0) {
# Line 767  namespace LinuxSampler { namespace gig { Line 615  namespace LinuxSampler { namespace gig {
615                  break;                  break;
616          }          }
617    
         // Reset synthesis event lists (except VCO, as VCO events apply channel wide currently)  
         pEngineChannel->pSynthesisEvents[Event::destination_vca]->clear();  
         pEngineChannel->pSynthesisEvents[Event::destination_vcfc]->clear();  
         pEngineChannel->pSynthesisEvents[Event::destination_vcfr]->clear();  
   
618          // Reset delay          // Reset delay
619          Delay = 0;          Delay = 0;
620    
621          itTriggerEvent = Pool<Event>::Iterator();          itTriggerEvent = Pool<Event>::Iterator();
622    
623          // If sample stream or release stage finished, kill the voice          // If sample stream or release stage finished, kill the voice
624          if (PlaybackState == playback_state_end || pEG1->GetStage() == EGADSR::stage_end) KillImmediately();          if (PlaybackState == playback_state_end || EG1.getSegmentType() == EGADSR::segment_end) KillImmediately();
625      }      }
626    
627      /**      /**
# Line 786  namespace LinuxSampler { namespace gig { Line 629  namespace LinuxSampler { namespace gig {
629       *  suspended / not running.       *  suspended / not running.
630       */       */
631      void Voice::Reset() {      void Voice::Reset() {
632          pLFO1->Reset();          finalSynthesisParameters.filterLeft.Reset();
633          pLFO2->Reset();          finalSynthesisParameters.filterRight.Reset();
         pLFO3->Reset();  
         FilterLeft.Reset();  
         FilterRight.Reset();  
634          DiskStreamRef.pStream = NULL;          DiskStreamRef.pStream = NULL;
635          DiskStreamRef.hStream = 0;          DiskStreamRef.hStream = 0;
636          DiskStreamRef.State   = Stream::state_unused;          DiskStreamRef.State   = Stream::state_unused;
# Line 801  namespace LinuxSampler { namespace gig { Line 641  namespace LinuxSampler { namespace gig {
641      }      }
642    
643      /**      /**
644       *  Process the control change event lists of the engine for the current       * Process given list of MIDI note on, note off and sustain pedal events
645       *  audio fragment. Event values will be applied to the synthesis parameter       * for the given time.
      *  matrix.  
646       *       *
647       *  @param Samples - number of samples to be rendered in this audio fragment cycle       * @param itEvent - iterator pointing to the next event to be processed
648         * @param End     - youngest time stamp where processing should be stopped
649       */       */
650      void Voice::ProcessEvents(uint Samples) {      void Voice::processTransitionEvents(RTList<Event>::Iterator& itEvent, uint End) {
651            for (; itEvent && itEvent->FragmentPos() <= End; ++itEvent) {
652          // dispatch control change events              if (itEvent->Type == Event::type_release) {
653          RTList<Event>::Iterator itCCEvent = pEngineChannel->pCCEvents->first();                  EG1.update(EGADSR::event_release, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
654          if (Delay) { // skip events that happened before this voice was triggered                  EG2.update(EGADSR::event_release, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
655              while (itCCEvent && itCCEvent->FragmentPos() <= Delay) ++itCCEvent;              } else if (itEvent->Type == Event::type_cancel_release) {
656                    EG1.update(EGADSR::event_cancel_release, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
657                    EG2.update(EGADSR::event_cancel_release, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
658                }
659          }          }
660          while (itCCEvent) {      }
661              if (itCCEvent->Param.CC.Controller) { // if valid MIDI controller  
662                  if (itCCEvent->Param.CC.Controller == VCFCutoffCtrl.controller) {      /**
663                      *pEngineChannel->pSynthesisEvents[Event::destination_vcfc]->allocAppend() = *itCCEvent;       * Process given list of MIDI control change and pitch bend events for
664                  }       * the given time.
665                  if (itCCEvent->Param.CC.Controller == VCFResonanceCtrl.controller) {       *
666                      *pEngineChannel->pSynthesisEvents[Event::destination_vcfr]->allocAppend() = *itCCEvent;       * @param itEvent - iterator pointing to the next event to be processed
667         * @param End     - youngest time stamp where processing should be stopped
668         */
669        void Voice::processCCEvents(RTList<Event>::Iterator& itEvent, uint End) {
670            for (; itEvent && itEvent->FragmentPos() <= End; ++itEvent) {
671                if (itEvent->Type == Event::type_control_change &&
672                    itEvent->Param.CC.Controller) { // if (valid) MIDI control change event
673                    if (itEvent->Param.CC.Controller == VCFCutoffCtrl.controller) {
674                        processCutoffEvent(itEvent);
675                    }
676                    if (itEvent->Param.CC.Controller == VCFResonanceCtrl.controller) {
677                        processResonanceEvent(itEvent);
678                  }                  }
679                  if (itCCEvent->Param.CC.Controller == pLFO1->ExtController) {                  if (itEvent->Param.CC.Controller == pLFO1->ExtController) {
680                      pLFO1->SendEvent(itCCEvent);                      pLFO1->update(itEvent->Param.CC.Value);
681                  }                  }
682                  if (itCCEvent->Param.CC.Controller == pLFO2->ExtController) {                  if (itEvent->Param.CC.Controller == pLFO2->ExtController) {
683                      pLFO2->SendEvent(itCCEvent);                      pLFO2->update(itEvent->Param.CC.Value);
684                  }                  }
685                  if (itCCEvent->Param.CC.Controller == pLFO3->ExtController) {                  if (itEvent->Param.CC.Controller == pLFO3->ExtController) {
686                      pLFO3->SendEvent(itCCEvent);                      pLFO3->update(itEvent->Param.CC.Value);
687                  }                  }
688                  if (pDimRgn->AttenuationController.type == ::gig::attenuation_ctrl_t::type_controlchange &&                  if (pDimRgn->AttenuationController.type == ::gig::attenuation_ctrl_t::type_controlchange &&
689                      itCCEvent->Param.CC.Controller == pDimRgn->AttenuationController.controller_number) { // if crossfade event                      itEvent->Param.CC.Controller == pDimRgn->AttenuationController.controller_number) {
690                      *pEngineChannel->pSynthesisEvents[Event::destination_vca]->allocAppend() = *itCCEvent;                      processCrossFadeEvent(itEvent);
691                  }                  }
692                } else if (itEvent->Type == Event::type_pitchbend) { // if pitch bend event
693                    processPitchEvent(itEvent);
694              }              }
   
             ++itCCEvent;  
695          }          }
696        }
697    
698        void Voice::processPitchEvent(RTList<Event>::Iterator& itEvent) {
699            const float pitch = RTMath::CentsToFreqRatio(((double) itEvent->Param.Pitch.Pitch / 8192.0) * 200.0); // +-two semitones = +-200 cents
700            finalSynthesisParameters.fFinalPitch *= pitch;
701            PitchBend = pitch;
702        }
703    
704          // process pitch events      void Voice::processCrossFadeEvent(RTList<Event>::Iterator& itEvent) {
705          {          CrossfadeVolume = CrossfadeAttenuation(itEvent->Param.CC.Value);
706              RTList<Event>* pVCOEventList = pEngineChannel->pSynthesisEvents[Event::destination_vco];          fFinalVolume = getVolume();
707              RTList<Event>::Iterator itVCOEvent = pVCOEventList->first();      }
             if (Delay) { // skip events that happened before this voice was triggered  
                 while (itVCOEvent && itVCOEvent->FragmentPos() <= Delay) ++itVCOEvent;  
             }  
             // apply old pitchbend value until first pitch event occurs  
             if (this->PitchBend != 1.0) {  
                 uint end = (itVCOEvent) ? itVCOEvent->FragmentPos() : Samples;  
                 for (uint i = Delay; i < end; i++) {  
                     pEngine->pSynthesisParameters[Event::destination_vco][i] *= this->PitchBend;  
                 }  
             }  
             float pitch;  
             while (itVCOEvent) {  
                 RTList<Event>::Iterator itNextVCOEvent = itVCOEvent;  
                 ++itNextVCOEvent;  
   
                 // calculate the influence length of this event (in sample points)  
                 uint end = (itNextVCOEvent) ? itNextVCOEvent->FragmentPos() : Samples;  
   
                 pitch = RTMath::CentsToFreqRatio(((double) itVCOEvent->Param.Pitch.Pitch / 8192.0) * 200.0); // +-two semitones = +-200 cents  
   
                 // apply pitch value to the pitch parameter sequence  
                 for (uint i = itVCOEvent->FragmentPos(); i < end; i++) {  
                     pEngine->pSynthesisParameters[Event::destination_vco][i] *= pitch;  
                 }  
708    
709                  itVCOEvent = itNextVCOEvent;      float Voice::getVolume() {
710              }          #if CONFIG_PROCESS_MUTED_CHANNELS
711              if (!pVCOEventList->isEmpty()) {          return pEngineChannel->GetMute() ? 0 : (Volume * CrossfadeVolume * pEngineChannel->GlobalVolume);
712                  this->PitchBend = pitch;          #else
713                  SYNTHESIS_MODE_SET_INTERPOLATE(SynthesisMode, true);          return Volume * CrossfadeVolume * pEngineChannel->GlobalVolume;
714                  SYNTHESIS_MODE_SET_CONSTPITCH(SynthesisMode, false);          #endif
715              }      }
716    
717        void Voice::processCutoffEvent(RTList<Event>::Iterator& itEvent) {
718            int ccvalue = itEvent->Param.CC.Value;
719            if (VCFCutoffCtrl.value == ccvalue) return;
720            VCFCutoffCtrl.value == ccvalue;
721            if (pDimRgn->VCFCutoffControllerInvert)  ccvalue = 127 - ccvalue;
722            if (ccvalue < pDimRgn->VCFVelocityScale) ccvalue = pDimRgn->VCFVelocityScale;
723            float cutoff = CutoffBase * float(ccvalue) * 0.00787402f; // (1 / 127)
724            if (cutoff > 1.0) cutoff = 1.0;
725            cutoff = (cutoff < 0.5 ? cutoff * 4826 - 1 : cutoff * 5715 - 449);
726            if (cutoff < 1.0) cutoff = 1.0;
727    
728            VCFCutoffCtrl.fvalue = cutoff - 1.0; // needed for initialization of fFinalCutoff next time
729            fFinalCutoff = cutoff;
730        }
731    
732        void Voice::processResonanceEvent(RTList<Event>::Iterator& itEvent) {
733            // convert absolute controller value to differential
734            const int ctrldelta = itEvent->Param.CC.Value - VCFResonanceCtrl.value;
735            VCFResonanceCtrl.value = itEvent->Param.CC.Value;
736            const float resonancedelta = (float) ctrldelta * 0.00787f; // 0.0..1.0
737            fFinalResonance += resonancedelta;
738            // needed for initialization of parameter
739            VCFResonanceCtrl.fvalue = itEvent->Param.CC.Value * 0.00787f;
740        }
741    
742        /**
743         *  Synthesizes the current audio fragment for this voice.
744         *
745         *  @param Samples - number of sample points to be rendered in this audio
746         *                   fragment cycle
747         *  @param pSrc    - pointer to input sample data
748         *  @param Skip    - number of sample points to skip in output buffer
749         */
750        void Voice::Synthesize(uint Samples, sample_t* pSrc, uint Skip) {
751            finalSynthesisParameters.pOutLeft  = &pEngineChannel->pOutputLeft[Skip];
752            finalSynthesisParameters.pOutRight = &pEngineChannel->pOutputRight[Skip];
753            finalSynthesisParameters.pSrc      = pSrc;
754    
755            RTList<Event>::Iterator itCCEvent = pEngineChannel->pEvents->first();
756            RTList<Event>::Iterator itNoteEvent = pEngineChannel->pMIDIKeyInfo[MIDIKey].pEvents->first();
757    
758            if (Skip) { // skip events that happened before this voice was triggered
759                while (itCCEvent && itCCEvent->FragmentPos() <= Skip) ++itCCEvent;
760                while (itNoteEvent && itNoteEvent->FragmentPos() <= Skip) ++itNoteEvent;
761          }          }
762    
763          // process volume / attenuation events (TODO: we only handle and _expect_ crossfade events here ATM !)          uint killPos;
764          {          if (itKillEvent) killPos = RTMath::Min(itKillEvent->FragmentPos(), pEngine->MaxFadeOutPos);
             RTList<Event>* pVCAEventList = pEngineChannel->pSynthesisEvents[Event::destination_vca];  
             RTList<Event>::Iterator itVCAEvent = pVCAEventList->first();  
             if (Delay) { // skip events that happened before this voice was triggered  
                 while (itVCAEvent && itVCAEvent->FragmentPos() <= Delay) ++itVCAEvent;  
             }  
             float crossfadevolume;  
             while (itVCAEvent) {  
                 RTList<Event>::Iterator itNextVCAEvent = itVCAEvent;  
                 ++itNextVCAEvent;  
765    
766                  // calculate the influence length of this event (in sample points)          float fFinalPanLeft = PanLeft * pEngineChannel->GlobalPanLeft;
767                  uint end = (itNextVCAEvent) ? itNextVCAEvent->FragmentPos() : Samples;          float fFinalPanRight = PanRight * pEngineChannel->GlobalPanRight;
768    
769                  crossfadevolume = CrossfadeAttenuation(itVCAEvent->Param.CC.Value);          uint i = Skip;
770            while (i < Samples) {
771                int iSubFragmentEnd = RTMath::Min(i + CONFIG_DEFAULT_SUBFRAGMENT_SIZE, Samples);
772    
773                  float effective_volume = crossfadevolume * this->Volume * pEngineChannel->GlobalVolume;              // initialize all final synthesis parameters
774                finalSynthesisParameters.fFinalPitch = PitchBase * PitchBend;
775                fFinalVolume    = getVolume();
776                fFinalCutoff    = VCFCutoffCtrl.fvalue;
777                fFinalResonance = VCFResonanceCtrl.fvalue;
778    
779                  // apply volume value to the volume parameter sequence              // process MIDI control change and pitchbend events for this subfragment
780                  for (uint i = itVCAEvent->FragmentPos(); i < end; i++) {              processCCEvents(itCCEvent, iSubFragmentEnd);
                     pEngine->pSynthesisParameters[Event::destination_vca][i] = effective_volume;  
                 }  
781    
782                  itVCAEvent = itNextVCAEvent;              // process transition events (note on, note off & sustain pedal)
783              }              processTransitionEvents(itNoteEvent, iSubFragmentEnd);
             if (!pVCAEventList->isEmpty()) this->CrossfadeVolume = crossfadevolume;  
         }  
784    
785          // process filter cutoff events              // if the voice was killed in this subfragment switch EG1 to fade out stage
786          {              if (itKillEvent && killPos <= iSubFragmentEnd) {
787              RTList<Event>* pCutoffEventList = pEngineChannel->pSynthesisEvents[Event::destination_vcfc];                  EG1.enterFadeOutStage();
788              RTList<Event>::Iterator itCutoffEvent = pCutoffEventList->first();                  itKillEvent = Pool<Event>::Iterator();
             if (Delay) { // skip events that happened before this voice was triggered  
                 while (itCutoffEvent && itCutoffEvent->FragmentPos() <= Delay) ++itCutoffEvent;  
789              }              }
             float cutoff;  
             while (itCutoffEvent) {  
                 RTList<Event>::Iterator itNextCutoffEvent = itCutoffEvent;  
                 ++itNextCutoffEvent;  
   
                 // calculate the influence length of this event (in sample points)  
                 uint end = (itNextCutoffEvent) ? itNextCutoffEvent->FragmentPos() : Samples;  
   
                 cutoff = exp((float) itCutoffEvent->Param.CC.Value * 0.00787402f * FILTER_CUTOFF_COEFF) * CONFIG_FILTER_CUTOFF_MAX - CONFIG_FILTER_CUTOFF_MIN;  
   
                 // apply cutoff frequency to the cutoff parameter sequence  
                 for (uint i = itCutoffEvent->FragmentPos(); i < end; i++) {  
                     pEngine->pSynthesisParameters[Event::destination_vcfc][i] = cutoff;  
                 }  
790    
791                  itCutoffEvent = itNextCutoffEvent;              // process envelope generators
792                switch (EG1.getSegmentType()) {
793                    case EGADSR::segment_lin:
794                        fFinalVolume *= EG1.processLin();
795                        break;
796                    case EGADSR::segment_exp:
797                        fFinalVolume *= EG1.processExp();
798                        break;
799                    case EGADSR::segment_end:
800                        fFinalVolume *= EG1.getLevel();
801                        break; // noop
802              }              }
803              if (!pCutoffEventList->isEmpty()) VCFCutoffCtrl.fvalue = cutoff; // needed for initialization of parameter matrix next time              switch (EG2.getSegmentType()) {
804          }                  case EGADSR::segment_lin:
805                        fFinalCutoff *= EG2.processLin();
806          // process filter resonance events                      break;
807          {                  case EGADSR::segment_exp:
808              RTList<Event>* pResonanceEventList = pEngineChannel->pSynthesisEvents[Event::destination_vcfr];                      fFinalCutoff *= EG2.processExp();
809              RTList<Event>::Iterator itResonanceEvent = pResonanceEventList->first();                      break;
810              if (Delay) { // skip events that happened before this voice was triggered                  case EGADSR::segment_end:
811                  while (itResonanceEvent && itResonanceEvent->FragmentPos() <= Delay) ++itResonanceEvent;                      fFinalCutoff *= EG2.getLevel();
812                        break; // noop
813              }              }
814              while (itResonanceEvent) {              if (EG3.active()) finalSynthesisParameters.fFinalPitch *= EG3.render();
815                  RTList<Event>::Iterator itNextResonanceEvent = itResonanceEvent;  
816                  ++itNextResonanceEvent;              // process low frequency oscillators
817                if (bLFO1Enabled) fFinalVolume *= pLFO1->render();
818                  // calculate the influence length of this event (in sample points)              if (bLFO2Enabled) fFinalCutoff *= pLFO2->render();
819                  uint end = (itNextResonanceEvent) ? itNextResonanceEvent->FragmentPos() : Samples;              if (bLFO3Enabled) finalSynthesisParameters.fFinalPitch *= RTMath::CentsToFreqRatio(pLFO3->render());
   
                 // convert absolute controller value to differential  
                 int ctrldelta = itResonanceEvent->Param.CC.Value - VCFResonanceCtrl.value;  
                 VCFResonanceCtrl.value = itResonanceEvent->Param.CC.Value;  
   
                 float resonancedelta = (float) ctrldelta * 0.00787f; // 0.0..1.0  
   
                 // apply cutoff frequency to the cutoff parameter sequence  
                 for (uint i = itResonanceEvent->FragmentPos(); i < end; i++) {  
                     pEngine->pSynthesisParameters[Event::destination_vcfr][i] += resonancedelta;  
                 }  
820    
821                  itResonanceEvent = itNextResonanceEvent;              // if filter enabled then update filter coefficients
822                if (SYNTHESIS_MODE_GET_FILTER(SynthesisMode)) {
823                    finalSynthesisParameters.filterLeft.SetParameters(fFinalCutoff + 1.0, fFinalResonance, pEngine->SampleRate);
824                    finalSynthesisParameters.filterRight.SetParameters(fFinalCutoff + 1.0, fFinalResonance, pEngine->SampleRate);
825              }              }
             if (!pResonanceEventList->isEmpty()) VCFResonanceCtrl.fvalue = pResonanceEventList->last()->Param.CC.Value * 0.00787f; // needed for initialization of parameter matrix next time  
         }  
     }  
826    
827      /**              // do we need resampling?
828       * Calculate all necessary, final biquad filter parameters.              const float __PLUS_ONE_CENT  = 1.000577789506554859250142541782224725466f;
829       *              const float __MINUS_ONE_CENT = 0.9994225441413807496009516495583113737666f;
830       * @param Samples - number of samples to be rendered in this audio fragment cycle              const bool bResamplingRequired = !(finalSynthesisParameters.fFinalPitch <= __PLUS_ONE_CENT &&
831       */                                                 finalSynthesisParameters.fFinalPitch >= __MINUS_ONE_CENT);
832      void Voice::CalculateBiquadParameters(uint Samples) {              SYNTHESIS_MODE_SET_INTERPOLATE(SynthesisMode, bResamplingRequired);
833          biquad_param_t bqbase;  
834          biquad_param_t bqmain;              // prepare final synthesis parameters structure
835          float prev_cutoff = pEngine->pSynthesisParameters[Event::destination_vcfc][0];              finalSynthesisParameters.uiToGo            = iSubFragmentEnd - i;
836          float prev_res    = pEngine->pSynthesisParameters[Event::destination_vcfr][0];  #ifdef CONFIG_INTERPOLATE_VOLUME
837          FilterLeft.SetParameters( &bqbase, &bqmain, prev_cutoff + CONFIG_FILTER_CUTOFF_MIN, prev_res, pEngine->SampleRate);              finalSynthesisParameters.fFinalVolumeDeltaLeft  =
838          FilterRight.SetParameters(&bqbase, &bqmain, prev_cutoff + CONFIG_FILTER_CUTOFF_MIN, prev_res, pEngine->SampleRate);                  (fFinalVolume * fFinalPanLeft - finalSynthesisParameters.fFinalVolumeLeft) / finalSynthesisParameters.uiToGo;
839          pEngine->pBasicFilterParameters[0] = bqbase;              finalSynthesisParameters.fFinalVolumeDeltaRight =
840          pEngine->pMainFilterParameters[0]  = bqmain;                  (fFinalVolume * fFinalPanRight - finalSynthesisParameters.fFinalVolumeRight) / finalSynthesisParameters.uiToGo;
841    #else
842          float* bq;              finalSynthesisParameters.fFinalVolumeLeft  = fFinalVolume * fFinalPanLeft;
843          for (int i = 1; i < Samples; i++) {              finalSynthesisParameters.fFinalVolumeRight = fFinalVolume * fFinalPanRight;
844              // recalculate biquad parameters if cutoff or resonance differ from previous sample point  #endif
845              if (!(i & FILTER_UPDATE_MASK)) {              // render audio for one subfragment
846                  if (pEngine->pSynthesisParameters[Event::destination_vcfr][i] != prev_res ||              RunSynthesisFunction(SynthesisMode, &finalSynthesisParameters, &loop);
847                      pEngine->pSynthesisParameters[Event::destination_vcfc][i] != prev_cutoff)  
848                  {              // stop the rendering if volume EG is finished
849                      prev_cutoff = pEngine->pSynthesisParameters[Event::destination_vcfc][i];              if (EG1.getSegmentType() == EGADSR::segment_end) break;
850                      prev_res    = pEngine->pSynthesisParameters[Event::destination_vcfr][i];  
851                      FilterLeft.SetParameters( &bqbase, &bqmain, prev_cutoff + CONFIG_FILTER_CUTOFF_MIN, prev_res, pEngine->SampleRate);              const double newPos = Pos + (iSubFragmentEnd - i) * finalSynthesisParameters.fFinalPitch;
852                      FilterRight.SetParameters(&bqbase, &bqmain, prev_cutoff + CONFIG_FILTER_CUTOFF_MIN, prev_res, pEngine->SampleRate);  
853                // increment envelopes' positions
854                if (EG1.active()) {
855    
856                    // if sample has a loop and loop start has been reached in this subfragment, send a special event to EG1 to let it finish the attack hold stage
857                    if (pSample->Loops && Pos <= pSample->LoopStart && pSample->LoopStart < newPos) {
858                        EG1.update(EGADSR::event_hold_end, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
859                  }                  }
860    
861                    EG1.increment(1);
862                    if (!EG1.toStageEndLeft()) EG1.update(EGADSR::event_stage_end, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
863              }              }
864                if (EG2.active()) {
865                    EG2.increment(1);
866                    if (!EG2.toStageEndLeft()) EG2.update(EGADSR::event_stage_end, pEngine->SampleRate / CONFIG_DEFAULT_SUBFRAGMENT_SIZE);
867                }
868                EG3.increment(1);
869                if (!EG3.toEndLeft()) EG3.update(); // neutralize envelope coefficient if end reached
870    
871              //same as 'pEngine->pBasicFilterParameters[i] = bqbase;'              Pos = newPos;
872              bq    = (float*) &pEngine->pBasicFilterParameters[i];              i = iSubFragmentEnd;
             bq[0] = bqbase.b0;  
             bq[1] = bqbase.b1;  
             bq[2] = bqbase.b2;  
             bq[3] = bqbase.a1;  
             bq[4] = bqbase.a2;  
   
             // same as 'pEngine->pMainFilterParameters[i] = bqmain;'  
             bq    = (float*) &pEngine->pMainFilterParameters[i];  
             bq[0] = bqmain.b0;  
             bq[1] = bqmain.b1;  
             bq[2] = bqmain.b2;  
             bq[3] = bqmain.a1;  
             bq[4] = bqmain.a2;  
873          }          }
874      }      }
875    
876      /**      /** @brief Update current portamento position.
      *  Synthesizes the current audio fragment for this voice.  
877       *       *
878       *  @param Samples - number of sample points to be rendered in this audio       * Will be called when portamento mode is enabled to get the final
879       *                   fragment cycle       * portamento position of this active voice from where the next voice(s)
880       *  @param pSrc    - pointer to input sample data       * might continue to slide on.
881       *  @param Skip    - number of sample points to skip in output buffer       *
882         * @param itNoteOffEvent - event which causes this voice to die soon
883       */       */
884      void Voice::Synthesize(uint Samples, sample_t* pSrc, uint Skip) {      void Voice::UpdatePortamentoPos(Pool<Event>::Iterator& itNoteOffEvent) {
885          RunSynthesisFunction(SynthesisMode, *this, Samples, pSrc, Skip);          const float fFinalEG3Level = EG3.level(itNoteOffEvent->FragmentPos());
886            pEngineChannel->PortamentoPos = (float) MIDIKey + RTMath::FreqRatioToCents(fFinalEG3Level) * 0.01f;
887      }      }
888    
889      /**      /**

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