engines/sfz/SfzSignalUnitRack.cpp

/***************************************************************************
 *                                                                         *
 *   LinuxSampler - modular, streaming capable sampler                     *
 *                                                                         *
 *   Copyright (C) 2011 Grigor Iliev                                       *
 *                                                                         *
 *   This program is free software; you can redistribute it and/or modify  *
 *   it under the terms of the GNU General Public License as published by  *
 *   the Free Software Foundation; either version 2 of the License, or     *
 *   (at your option) any later version.                                   *
 *                                                                         *
 *   This program is distributed in the hope that it will be useful,       *
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of        *
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 *   GNU General Public License for more details.                          *
 *                                                                         *
 *   You should have received a copy of the GNU General Public License     *
 *   along with this program; if not, write to the Free Software           *
 *   Foundation, Inc., 59 Temple Place, Suite 330, Boston,                 *
 *   MA  02111-1307  USA                                                   *
 ***************************************************************************/

#include "SfzSignalUnitRack.h"
#include "Voice.h"
#include <SF.h>

namespace LinuxSampler { namespace sfz {
    
    SfzSignalUnit::SfzSignalUnit(SfzSignalUnitRack* rack): SignalUnit(rack), pVoice(rack->pVoice) {
        
    }
    
    double SfzSignalUnit::GetSampleRate() {
        return pVoice->GetSampleRate() / CONFIG_DEFAULT_SUBFRAGMENT_SIZE;
    }
    
    
    void EGv1Unit::Trigger() {
        ::sfz::Region* const pRegion = pVoice->pRegion;
        
        // the length of the decay and release curves are dependent on the velocity
        const double velrelease = 1 / pVoice->GetVelocityRelease(pVoice->MIDIVelocity);

        // set the delay trigger
        uiDelayTrigger = (pRegion->ampeg_delay + pRegion->ampeg_vel2delay * velrelease) * GetSampleRate();
        
        EG.trigger(uint(pRegion->ampeg_start * 10),
                   std::max(0.0, pRegion->ampeg_attack + pRegion->ampeg_vel2attack * velrelease),
                   std::max(0.0, pRegion->ampeg_hold + pRegion->ampeg_vel2hold * velrelease),
                   std::max(0.0, pRegion->ampeg_decay + pRegion->ampeg_vel2decay * velrelease),
                   uint(std::min(std::max(0.0, 10 * (pRegion->ampeg_sustain + pRegion->ampeg_vel2sustain * velrelease)), 1000.0)),
                   std::max(0.0, pRegion->ampeg_release + pRegion->ampeg_vel2release * velrelease),
                   GetSampleRate());
    }
    
    
    void EGv2Unit::Trigger() {
        EG.trigger(*pEGInfo, GetSampleRate(), pVoice->MIDIVelocity);
    }
    
    
    void PitchEGUnit::Trigger() {
        ::sfz::Region* const pRegion = pVoice->pRegion;
        depth = pRegion->pitcheg_depth;
        
        // the length of the decay and release curves are dependent on the velocity
        const double velrelease = 1 / pVoice->GetVelocityRelease(pVoice->MIDIVelocity);

        // set the delay trigger
        uiDelayTrigger = (pRegion->pitcheg_delay + pRegion->pitcheg_vel2delay * velrelease) * GetSampleRate();
        
        EG.trigger(uint(pRegion->pitcheg_start * 10),
                   std::max(0.0, pRegion->pitcheg_attack + pRegion->pitcheg_vel2attack * velrelease),
                   std::max(0.0, pRegion->pitcheg_hold + pRegion->pitcheg_vel2hold * velrelease),
                   std::max(0.0, pRegion->pitcheg_decay + pRegion->pitcheg_vel2decay * velrelease),
                   uint(std::min(std::max(0.0, 10 * (pRegion->pitcheg_sustain + pRegion->pitcheg_vel2sustain * velrelease)), 1000.0)),
                   std::max(0.0, pRegion->pitcheg_release + pRegion->pitcheg_vel2release * velrelease),
                   GetSampleRate());
    }
    

    void LFOUnit::Increment() {
        if (DelayStage()) return;
        
        SignalUnit::Increment();
        
        Level = lfo.render();
    }
    
    void LFOUnit::Trigger() {
        //reset
        Level = 0;
        
        // set the delay trigger
        uiDelayTrigger = pLfoInfo->delay * GetSampleRate();
    }
    
    void LFOv1Unit::Trigger() {
        LFOUnit::Trigger();
        
        lfo.trigger (
            pLfoInfo->freq,
            start_level_mid,
            1, 0, false, GetSampleRate()
        );
        lfo.update(0);
    }
    
    void LFOv2Unit::Trigger() {
        LFOUnit::Trigger();
        
        lfo.trigger (
            pLfoInfo->freq,
            start_level_mid,
            1, 0, false, GetSampleRate()
        );
        lfo.update(0);
    }
    
    void AmpLFOUnit::Trigger() {
        ::sfz::Region* const pRegion = pVoice->pRegion;
        pLfoInfo->delay = pRegion->amplfo_delay;
        pLfoInfo->freq = pRegion->amplfo_freq;
        pLfoInfo->volume = pRegion->amplfo_depth;
        
        LFOv1Unit::Trigger();
    }
    
    void PitchLFOUnit::Trigger() {
        ::sfz::Region* const pRegion = pVoice->pRegion;
        pLfoInfo->delay = pRegion->pitchlfo_delay;
        pLfoInfo->freq = pRegion->pitchlfo_freq;
        pLfoInfo->pitch = pRegion->pitchlfo_depth;
        
        LFOv1Unit::Trigger();
    }
    
    void FilLFOUnit::Trigger() {
        ::sfz::Region* const pRegion = pVoice->pRegion;
        pLfoInfo->delay = pRegion->fillfo_delay;
        pLfoInfo->freq = pRegion->fillfo_freq;
        pLfoInfo->cutoff = pRegion->fillfo_depth;
        
        LFOv1Unit::Trigger();
    }


    EndpointUnit::EndpointUnit(SfzSignalUnitRack* rack): EndpointSignalUnit(rack) {
        
    }
    
    SfzSignalUnitRack* const EndpointUnit::GetRack() {
        return static_cast<SfzSignalUnitRack* const>(pRack);
    }
    
    void EndpointUnit::Trigger() {
        
    }
    
    bool EndpointUnit::Active() {
        if (GetRack()->suVolEG.Active()) return true;
        
        bool b = false;
        for (int i = 0; i < GetRack()->volEGs.size(); i++) {
            if (GetRack()->volEGs[i]->Active()) { b = true; break; }
        }
        
        return b;
    }
    
    float EndpointUnit::GetVolume() {
        float vol = GetRack()->suVolEG.Active() ? GetRack()->suVolEG.GetLevel() : 0;
        
        for (int i = 0; i < GetRack()->volEGs.size(); i++) {
            EGv2Unit* eg = GetRack()->volEGs[i];
            if (!eg->Active()) continue;
            vol += eg->GetLevel() * (eg->pEGInfo->amplitude / 100.0f);
        }
        
        AmpLFOUnit* u = &(GetRack()->suAmpLFO);
        vol *= u->Active() ? ::sf2::ToRatio((u->GetLevel() * u->pLfoInfo->volume) * 10.0) : 1;
        
        return vol;
    }
    
    float EndpointUnit::GetFilterCutoff() {
        float val;
        
        FilLFOUnit* u = &(GetRack()->suFilLFO);
        val = u->Active() ? RTMath::CentsToFreqRatioUnlimited(u->GetLevel() * u->pLfoInfo->cutoff) : 1;
        
        for (int i = 0; i < GetRack()->filLFOs.size(); i++) {
            LFOv2Unit* lfo = GetRack()->filLFOs[i];
            if (!lfo->Active()) continue;
            
            float f = lfo->GetLevel() * lfo->pLfoInfo->cutoff;
            val *= RTMath::CentsToFreqRatioUnlimited(f);
        }
        
        return val;
    }
    
    float EndpointUnit::GetPitch() {
        double p;
        EGv1Unit* u = &(GetRack()->suPitchEG);
        p = u->Active() ? RTMath::CentsToFreqRatioUnlimited(u->GetLevel() * u->depth) : 1;
        
        PitchLFOUnit* u2 = &(GetRack()->suPitchLFO);
        p *= u2->Active() ? RTMath::CentsToFreqRatioUnlimited(u2->GetLevel() * u2->pLfoInfo->pitch) : 1;
        
        return p;
    }
    
    float EndpointUnit::GetResonance() {
         float val = 0;
        
        for (int i = 0; i < GetRack()->resLFOs.size(); i++) {
            LFOv2Unit* lfo = GetRack()->resLFOs[i];
            if (!lfo->Active()) continue;
            
            val += lfo->GetLevel() * lfo->pLfoInfo->resonance;
        }
        
        return val;
    }
    
    float EndpointUnit::GetPan() {
        float pan = 0;
        
        for (int i = 0; i < GetRack()->panLFOs.size(); i++) {
            LFOv2Unit* lfo = GetRack()->panLFOs[i];
            if (!lfo->Active()) continue;
            
            pan += lfo->GetLevel() * lfo->pLfoInfo->pan;
        }
        
        if(pan < -100) return -100;
        if(pan >  100) return  100;
        
        return pan;
    }
    
    
    SfzSignalUnitRack::SfzSignalUnitRack(Voice* voice)
        : SignalUnitRack(MaxUnitCount), pVoice(voice), suEndpoint(this), suVolEG(this), suPitchEG(this),
        EGs(maxEgCount), volEGs(maxEgCount), pitchEGs(maxEgCount),
        suAmpLFO(this), suPitchLFO(this), suFilLFO(this),
        LFOs(maxLfoCount), filLFOs(maxLfoCount), resLFOs(maxLfoCount), panLFOs(maxLfoCount)
    {
        suEndpoint.pVoice = suVolEG.pVoice = suPitchEG.pVoice = voice;
        suAmpLFO.pVoice = suPitchLFO.pVoice = suFilLFO.pVoice = voice;
        
        for (int i = 0; i < EGs.capacity(); i++) {
            EGs[i] = new EGv2Unit(this);
            EGs[i]->pVoice = voice;
        }
        
        for (int i = 0; i < LFOs.capacity(); i++) {
            LFOs[i] = new LFOv2Unit(this);
            LFOs[i]->pVoice = voice;
        }
    }
    
    SfzSignalUnitRack::~SfzSignalUnitRack() {
        for (int i = 0; i < EGs.capacity(); i++) {
            delete EGs[i]; EGs[i] = NULL;
        }
        
        for (int i = 0; i < LFOs.capacity(); i++) {
            delete LFOs[i]; LFOs[i] = NULL;
        }
    }
    
    void SfzSignalUnitRack::Trigger() {
        EGs.clear();
        volEGs.clear();
        pitchEGs.clear();
        
        LFOs.clear();
        filLFOs.clear();
        resLFOs.clear();
        panLFOs.clear();
        
        ::sfz::Region* const pRegion = pVoice->pRegion;
        
        for (int i = 0; i < pRegion->eg.size(); i++) {
            if (pRegion->eg[i].node.size() == 0) continue;
            
            if(EGs.size() < EGs.capacity()) {
                EGv2Unit eg(this);
                eg.pEGInfo = &(pRegion->eg[i]);
                EGs.increment()->Copy(eg);
            } else { std::cerr << "Maximum number of EGs reached!" << std::endl; break; }
            
            if (pRegion->eg[i].amplitude > 0) {
                if(volEGs.size() < volEGs.capacity()) volEGs.add(EGs[EGs.size() - 1]);
                else std::cerr << "Maximum number of EGs reached!" << std::endl;
            }
        }
        
        if (pRegion->ampeg_sustain == -1) {
            if (volEGs.size() > 0) pRegion->ampeg_sustain = 0;
            else pRegion->ampeg_sustain = 100;
        }
        
        // LFO
        for (int i = 0; i < pRegion->lfos.size(); i++) {
            if (pRegion->lfos[i].freq == -1) continue; // Not initialized
            
            if(LFOs.size() < LFOs.capacity()) {
                LFOv2Unit lfo(this);
                lfo.pLfoInfo = &(pRegion->lfos[i]);
                LFOs.increment()->Copy(lfo);
            } else { std::cerr << "Maximum number of LFOs reached!" << std::endl; break; }
            
            if (pRegion->lfos[i].cutoff != 0) {
                if(filLFOs.size() < filLFOs.capacity()) filLFOs.add(LFOs[LFOs.size() - 1]);
                else std::cerr << "Maximum number of LFOs reached!" << std::endl;
            }
            
            if (pRegion->lfos[i].resonance != 0) {
                if(resLFOs.size() < resLFOs.capacity()) resLFOs.add(LFOs[LFOs.size() - 1]);
                else std::cerr << "Maximum number of LFOs reached!" << std::endl;
            }
            
            if (pRegion->lfos[i].pan != 0) {
                if(panLFOs.size() < panLFOs.capacity()) panLFOs.add(LFOs[LFOs.size() - 1]);
                else std::cerr << "Maximum number of LFOs reached!" << std::endl;
            }
        }
        
        Units.clear();
        
        Units.add(&suVolEG);
        Units.add(&suPitchEG);
        Units.add(&suPitchLFO);
        Units.add(&suAmpLFO);
        Units.add(&suFilLFO);
        
        for (int i = 0; i < EGs.size(); i++) {
            Units.add(EGs[i]);
        }
        
        for (int i = 0; i < LFOs.size(); i++) {
            Units.add(LFOs[i]);
        }
        
        Units.add(&suEndpoint);
        
        SignalUnitRack::Trigger();
    }
    
    EndpointSignalUnit* SfzSignalUnitRack::GetEndpointUnit() {
        return &suEndpoint;
    }
    
    void SfzSignalUnitRack::EnterFadeOutStage() {
        suVolEG.EG.enterFadeOutStage();
        
        for (int i = 0; i < volEGs.size(); i++) {
            volEGs[i]->EG.enterFadeOutStage();
        }
    }
    
}} // namespace LinuxSampler::sfz
1	/***************************************************************************
2	* *
3	* LinuxSampler - modular, streaming capable sampler *
4	* *
5	* Copyright (C) 2011 Grigor Iliev *
6	* *
7	* This program is free software; you can redistribute it and/or modify *
8	* it under the terms of the GNU General Public License as published by *
9	* the Free Software Foundation; either version 2 of the License, or *
10	* (at your option) any later version. *
11	* *
12	* This program is distributed in the hope that it will be useful, *
13	* but WITHOUT ANY WARRANTY; without even the implied warranty of *
14	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
15	* GNU General Public License for more details. *
16	* *
17	* You should have received a copy of the GNU General Public License *
18	* along with this program; if not, write to the Free Software *
19	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, *
20	* MA 02111-1307 USA *
21	***************************************************************************/
22
23	#include "SfzSignalUnitRack.h"
24	#include "Voice.h"
25	#include <SF.h>
26
27	namespace LinuxSampler { namespace sfz {
28
29	SfzSignalUnit::SfzSignalUnit(SfzSignalUnitRack* rack): SignalUnit(rack), pVoice(rack->pVoice) {
30
31	}
32
33	double SfzSignalUnit::GetSampleRate() {
34	return pVoice->GetSampleRate() / CONFIG_DEFAULT_SUBFRAGMENT_SIZE;
35	}
36
37
38	void EGv1Unit::Trigger() {
39	::sfz::Region* const pRegion = pVoice->pRegion;
40
41	// the length of the decay and release curves are dependent on the velocity
42	const double velrelease = 1 / pVoice->GetVelocityRelease(pVoice->MIDIVelocity);
43
44	// set the delay trigger
45	uiDelayTrigger = (pRegion->ampeg_delay + pRegion->ampeg_vel2delay * velrelease) * GetSampleRate();
46
47	EG.trigger(uint(pRegion->ampeg_start * 10),
48	std::max(0.0, pRegion->ampeg_attack + pRegion->ampeg_vel2attack * velrelease),
49	std::max(0.0, pRegion->ampeg_hold + pRegion->ampeg_vel2hold * velrelease),
50	std::max(0.0, pRegion->ampeg_decay + pRegion->ampeg_vel2decay * velrelease),
51	uint(std::min(std::max(0.0, 10 * (pRegion->ampeg_sustain + pRegion->ampeg_vel2sustain * velrelease)), 1000.0)),
52	std::max(0.0, pRegion->ampeg_release + pRegion->ampeg_vel2release * velrelease),
53	GetSampleRate());
54	}
55
56
57	void EGv2Unit::Trigger() {
58	EG.trigger(*pEGInfo, GetSampleRate(), pVoice->MIDIVelocity);
59	}
60
61
62	void PitchEGUnit::Trigger() {
63	::sfz::Region* const pRegion = pVoice->pRegion;
64	depth = pRegion->pitcheg_depth;
65
66	// the length of the decay and release curves are dependent on the velocity
67	const double velrelease = 1 / pVoice->GetVelocityRelease(pVoice->MIDIVelocity);
68
69	// set the delay trigger
70	uiDelayTrigger = (pRegion->pitcheg_delay + pRegion->pitcheg_vel2delay * velrelease) * GetSampleRate();
71
72	EG.trigger(uint(pRegion->pitcheg_start * 10),
73	std::max(0.0, pRegion->pitcheg_attack + pRegion->pitcheg_vel2attack * velrelease),
74	std::max(0.0, pRegion->pitcheg_hold + pRegion->pitcheg_vel2hold * velrelease),
75	std::max(0.0, pRegion->pitcheg_decay + pRegion->pitcheg_vel2decay * velrelease),
76	uint(std::min(std::max(0.0, 10 * (pRegion->pitcheg_sustain + pRegion->pitcheg_vel2sustain * velrelease)), 1000.0)),
77	std::max(0.0, pRegion->pitcheg_release + pRegion->pitcheg_vel2release * velrelease),
78	GetSampleRate());
79	}
80
81
82	void LFOUnit::Increment() {
83	if (DelayStage()) return;
84
85	SignalUnit::Increment();
86
87	Level = lfo.render();
88	}
89
90	void LFOUnit::Trigger() {
91	//reset
92	Level = 0;
93
94	// set the delay trigger
95	uiDelayTrigger = pLfoInfo->delay * GetSampleRate();
96	}
97
98	void LFOv1Unit::Trigger() {
99	LFOUnit::Trigger();
100
101	lfo.trigger (
102	pLfoInfo->freq,
103	start_level_mid,
104	1, 0, false, GetSampleRate()
105	);
106	lfo.update(0);
107	}
108
109	void LFOv2Unit::Trigger() {
110	LFOUnit::Trigger();
111
112	lfo.trigger (
113	pLfoInfo->freq,
114	start_level_mid,
115	1, 0, false, GetSampleRate()
116	);
117	lfo.update(0);
118	}
119
120	void AmpLFOUnit::Trigger() {
121	::sfz::Region* const pRegion = pVoice->pRegion;
122	pLfoInfo->delay = pRegion->amplfo_delay;
123	pLfoInfo->freq = pRegion->amplfo_freq;
124	pLfoInfo->volume = pRegion->amplfo_depth;
125
126	LFOv1Unit::Trigger();
127	}
128
129	void PitchLFOUnit::Trigger() {
130	::sfz::Region* const pRegion = pVoice->pRegion;
131	pLfoInfo->delay = pRegion->pitchlfo_delay;
132	pLfoInfo->freq = pRegion->pitchlfo_freq;
133	pLfoInfo->pitch = pRegion->pitchlfo_depth;
134
135	LFOv1Unit::Trigger();
136	}
137
138	void FilLFOUnit::Trigger() {
139	::sfz::Region* const pRegion = pVoice->pRegion;
140	pLfoInfo->delay = pRegion->fillfo_delay;
141	pLfoInfo->freq = pRegion->fillfo_freq;
142	pLfoInfo->cutoff = pRegion->fillfo_depth;
143
144	LFOv1Unit::Trigger();
145	}
146
147
148	EndpointUnit::EndpointUnit(SfzSignalUnitRack* rack): EndpointSignalUnit(rack) {
149
150	}
151
152	SfzSignalUnitRack* const EndpointUnit::GetRack() {
153	return static_cast<SfzSignalUnitRack* const>(pRack);
154	}
155
156	void EndpointUnit::Trigger() {
157
158	}
159
160	bool EndpointUnit::Active() {
161	if (GetRack()->suVolEG.Active()) return true;
162
163	bool b = false;
164	for (int i = 0; i < GetRack()->volEGs.size(); i++) {
165	if (GetRack()->volEGs[i]->Active()) { b = true; break; }
166	}
167
168	return b;
169	}
170
171	float EndpointUnit::GetVolume() {
172	float vol = GetRack()->suVolEG.Active() ? GetRack()->suVolEG.GetLevel() : 0;
173
174	for (int i = 0; i < GetRack()->volEGs.size(); i++) {
175	EGv2Unit* eg = GetRack()->volEGs[i];
176	if (!eg->Active()) continue;
177	vol += eg->GetLevel() * (eg->pEGInfo->amplitude / 100.0f);
178	}
179
180	AmpLFOUnit* u = &(GetRack()->suAmpLFO);
181	vol = u->Active() ? ::sf2::ToRatio((u->GetLevel() u->pLfoInfo->volume) * 10.0) : 1;
182
183	return vol;
184	}
185
186	float EndpointUnit::GetFilterCutoff() {
187	float val;
188
189	FilLFOUnit* u = &(GetRack()->suFilLFO);
190	val = u->Active() ? RTMath::CentsToFreqRatioUnlimited(u->GetLevel() * u->pLfoInfo->cutoff) : 1;
191
192	for (int i = 0; i < GetRack()->filLFOs.size(); i++) {
193	LFOv2Unit* lfo = GetRack()->filLFOs[i];
194	if (!lfo->Active()) continue;
195
196	float f = lfo->GetLevel() * lfo->pLfoInfo->cutoff;
197	val *= RTMath::CentsToFreqRatioUnlimited(f);
198	}
199
200	return val;
201	}
202
203	float EndpointUnit::GetPitch() {
204	double p;
205	EGv1Unit* u = &(GetRack()->suPitchEG);
206	p = u->Active() ? RTMath::CentsToFreqRatioUnlimited(u->GetLevel() * u->depth) : 1;
207
208	PitchLFOUnit* u2 = &(GetRack()->suPitchLFO);
209	p = u2->Active() ? RTMath::CentsToFreqRatioUnlimited(u2->GetLevel() u2->pLfoInfo->pitch) : 1;
210
211	return p;
212	}
213
214	float EndpointUnit::GetResonance() {
215	float val = 0;
216
217	for (int i = 0; i < GetRack()->resLFOs.size(); i++) {
218	LFOv2Unit* lfo = GetRack()->resLFOs[i];
219	if (!lfo->Active()) continue;
220
221	val += lfo->GetLevel() * lfo->pLfoInfo->resonance;
222	}
223
224	return val;
225	}
226
227	float EndpointUnit::GetPan() {
228	float pan = 0;
229
230	for (int i = 0; i < GetRack()->panLFOs.size(); i++) {
231	LFOv2Unit* lfo = GetRack()->panLFOs[i];
232	if (!lfo->Active()) continue;
233
234	pan += lfo->GetLevel() * lfo->pLfoInfo->pan;
235	}
236
237	if(pan < -100) return -100;
238	if(pan > 100) return 100;
239
240	return pan;
241	}
242
243
244	SfzSignalUnitRack::SfzSignalUnitRack(Voice* voice)
245	: SignalUnitRack(MaxUnitCount), pVoice(voice), suEndpoint(this), suVolEG(this), suPitchEG(this),
246	EGs(maxEgCount), volEGs(maxEgCount), pitchEGs(maxEgCount),
247	suAmpLFO(this), suPitchLFO(this), suFilLFO(this),
248	LFOs(maxLfoCount), filLFOs(maxLfoCount), resLFOs(maxLfoCount), panLFOs(maxLfoCount)
249	{
250	suEndpoint.pVoice = suVolEG.pVoice = suPitchEG.pVoice = voice;
251	suAmpLFO.pVoice = suPitchLFO.pVoice = suFilLFO.pVoice = voice;
252
253	for (int i = 0; i < EGs.capacity(); i++) {
254	EGs[i] = new EGv2Unit(this);
255	EGs[i]->pVoice = voice;
256	}
257
258	for (int i = 0; i < LFOs.capacity(); i++) {
259	LFOs[i] = new LFOv2Unit(this);
260	LFOs[i]->pVoice = voice;
261	}
262	}
263
264	SfzSignalUnitRack::~SfzSignalUnitRack() {
265	for (int i = 0; i < EGs.capacity(); i++) {
266	delete EGs[i]; EGs[i] = NULL;
267	}
268
269	for (int i = 0; i < LFOs.capacity(); i++) {
270	delete LFOs[i]; LFOs[i] = NULL;
271	}
272	}
273
274	void SfzSignalUnitRack::Trigger() {
275	EGs.clear();
276	volEGs.clear();
277	pitchEGs.clear();
278
279	LFOs.clear();
280	filLFOs.clear();
281	resLFOs.clear();
282	panLFOs.clear();
283
284	::sfz::Region* const pRegion = pVoice->pRegion;
285
286	for (int i = 0; i < pRegion->eg.size(); i++) {
287	if (pRegion->eg[i].node.size() == 0) continue;
288
289	if(EGs.size() < EGs.capacity()) {
290	EGv2Unit eg(this);
291	eg.pEGInfo = &(pRegion->eg[i]);
292	EGs.increment()->Copy(eg);
293	} else { std::cerr << "Maximum number of EGs reached!" << std::endl; break; }
294
295	if (pRegion->eg[i].amplitude > 0) {
296	if(volEGs.size() < volEGs.capacity()) volEGs.add(EGs[EGs.size() - 1]);
297	else std::cerr << "Maximum number of EGs reached!" << std::endl;
298	}
299	}
300
301	if (pRegion->ampeg_sustain == -1) {
302	if (volEGs.size() > 0) pRegion->ampeg_sustain = 0;
303	else pRegion->ampeg_sustain = 100;
304	}
305
306	// LFO
307	for (int i = 0; i < pRegion->lfos.size(); i++) {
308	if (pRegion->lfos[i].freq == -1) continue; // Not initialized
309
310	if(LFOs.size() < LFOs.capacity()) {
311	LFOv2Unit lfo(this);
312	lfo.pLfoInfo = &(pRegion->lfos[i]);
313	LFOs.increment()->Copy(lfo);
314	} else { std::cerr << "Maximum number of LFOs reached!" << std::endl; break; }
315
316	if (pRegion->lfos[i].cutoff != 0) {
317	if(filLFOs.size() < filLFOs.capacity()) filLFOs.add(LFOs[LFOs.size() - 1]);
318	else std::cerr << "Maximum number of LFOs reached!" << std::endl;
319	}
320
321	if (pRegion->lfos[i].resonance != 0) {
322	if(resLFOs.size() < resLFOs.capacity()) resLFOs.add(LFOs[LFOs.size() - 1]);
323	else std::cerr << "Maximum number of LFOs reached!" << std::endl;
324	}
325
326	if (pRegion->lfos[i].pan != 0) {
327	if(panLFOs.size() < panLFOs.capacity()) panLFOs.add(LFOs[LFOs.size() - 1]);
328	else std::cerr << "Maximum number of LFOs reached!" << std::endl;
329	}
330	}
331
332	Units.clear();
333
334	Units.add(&suVolEG);
335	Units.add(&suPitchEG);
336	Units.add(&suPitchLFO);
337	Units.add(&suAmpLFO);
338	Units.add(&suFilLFO);
339
340	for (int i = 0; i < EGs.size(); i++) {
341	Units.add(EGs[i]);
342	}
343
344	for (int i = 0; i < LFOs.size(); i++) {
345	Units.add(LFOs[i]);
346	}
347
348	Units.add(&suEndpoint);
349
350	SignalUnitRack::Trigger();
351	}
352
353	EndpointSignalUnit* SfzSignalUnitRack::GetEndpointUnit() {
354	return &suEndpoint;
355	}
356
357	void SfzSignalUnitRack::EnterFadeOutStage() {
358	suVolEG.EG.enterFadeOutStage();
359
360	for (int i = 0; i < volEGs.size(); i++) {
361	volEGs[i]->EG.enterFadeOutStage();
362	}
363	}
364
365	}} // namespace LinuxSampler::sfz