/[svn]/linuxsampler/trunk/src/engines/common/AbstractVoice.h
ViewVC logotype

Contents of /linuxsampler/trunk/src/engines/common/AbstractVoice.h

Parent Directory Parent Directory | Revision Log Revision Log


Revision 3561 - (show annotations) (download) (as text)
Fri Aug 23 11:44:00 2019 UTC (4 years, 7 months ago) by schoenebeck
File MIME type: text/x-c++hdr
File size: 18716 byte(s)
NKSP: Added standard units support for numbers and final "!" operator:

* NKSP strictness: Variable names, function names and preprocessor condition
  names must start with a regular character (a-z or A-Z); starting them with
  a digit or underscore is no longer allowed.

* NKSP parser fix: equal comparison operator "=" and not equal comparison
  operator "#" must only accept integer operands.

* NKSP language: Implemented support for standard units like Hertz, seconds,
  Bel including support for metric unit prefixes; so one can now e.g.
  conveniently use numbers in scripts like "5us" meaning "5 microseconds",
  or e.g. "12kHz" meaning "12 kilo Hertz", or e.g. "-14mdB" meaning
  "minus 14 Millidecibel", or e.g. "28c" meaning "28 cents" (for tuning).

* NKSP language: Introduced "final" operator "!" which is specifically
  intended for synthesis parameter values to denote that the synthesis
  parameter value is intended to be the "final" value for that synthesis
  parameter that should explicitly be used by the engine and thus causing
  the sampler engine to ignore all other modulation sources for the same
  synthesis parameter (like e.g. LFO, EG); by simply prefixing a value,
  variable or formula with this new "!" operator the expression is marked as
  being "final".

* Bumped version (2.1.1.svn4).

1 /***************************************************************************
2 * *
3 * LinuxSampler - modular, streaming capable sampler *
4 * *
5 * Copyright (C) 2003,2004 by Benno Senoner and Christian Schoenebeck *
6 * Copyright (C) 2005-2008 Christian Schoenebeck *
7 * Copyright (C) 2009-2012 Christian Schoenebeck and Grigor Iliev *
8 * *
9 * This program is free software; you can redistribute it and/or modify *
10 * it under the terms of the GNU General Public License as published by *
11 * the Free Software Foundation; either version 2 of the License, or *
12 * (at your option) any later version. *
13 * *
14 * This program is distributed in the hope that it will be useful, *
15 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
16 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
17 * GNU General Public License for more details. *
18 * *
19 * You should have received a copy of the GNU General Public License *
20 * along with this program; if not, write to the Free Software *
21 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, *
22 * MA 02111-1307 USA *
23 ***************************************************************************/
24
25 #ifndef __LS_ABSTRACTVOICE_H__
26 #define __LS_ABSTRACTVOICE_H__
27
28 #include "Voice.h"
29
30 #include "../../common/global_private.h"
31 #include "../AbstractEngineChannel.h"
32 #include "LFOBase.h"
33 #include "Fade.h"
34 #include "../EngineBase.h"
35 #include "EG.h"
36 #include "../gig/EGADSR.h"
37 #include "../gig/EGDecay.h"
38 #include "../gig/SmoothVolume.h"
39 #include "../gig/Synthesizer.h"
40 #include "../gig/Profiler.h"
41 #include "SignalUnitRack.h"
42
43 // include the appropriate (unsigned) triangle LFO implementation
44 #if CONFIG_UNSIGNED_TRIANG_ALGO == INT_MATH_SOLUTION
45 # include "LFOTriangleIntMath.h"
46 #elif CONFIG_UNSIGNED_TRIANG_ALGO == INT_ABS_MATH_SOLUTION
47 # include "LFOTriangleIntAbsMath.h"
48 #elif CONFIG_UNSIGNED_TRIANG_ALGO == DI_HARMONIC_SOLUTION
49 # include "LFOTriangleDiHarmonic.h"
50 #else
51 # error "Unknown or no (unsigned) triangle LFO implementation selected!"
52 #endif
53
54 // include the appropriate (signed) triangle LFO implementation
55 #if CONFIG_SIGNED_TRIANG_ALGO == INT_MATH_SOLUTION
56 # include "LFOTriangleIntMath.h"
57 #elif CONFIG_SIGNED_TRIANG_ALGO == INT_ABS_MATH_SOLUTION
58 # include "LFOTriangleIntAbsMath.h"
59 #elif CONFIG_SIGNED_TRIANG_ALGO == DI_HARMONIC_SOLUTION
60 # include "LFOTriangleDiHarmonic.h"
61 #else
62 # error "Unknown or no (signed) triangle LFO implementation selected!"
63 #endif
64
65 namespace LinuxSampler {
66
67 #if CONFIG_UNSIGNED_TRIANG_ALGO == INT_MATH_SOLUTION
68 typedef LFOTriangleIntMath<range_unsigned> LFOUnsigned;
69 #elif CONFIG_UNSIGNED_TRIANG_ALGO == INT_ABS_MATH_SOLUTION
70 typedef LFOTriangleIntAbsMath<range_unsigned> LFOUnsigned;
71 #elif CONFIG_UNSIGNED_TRIANG_ALGO == DI_HARMONIC_SOLUTION
72 typedef LFOTriangleDiHarmonic<range_unsigned> LFOUnsigned;
73 #endif
74
75 #if CONFIG_SIGNED_TRIANG_ALGO == INT_MATH_SOLUTION
76 typedef LFOTriangleIntMath<range_signed> LFOSigned;
77 #elif CONFIG_SIGNED_TRIANG_ALGO == INT_ABS_MATH_SOLUTION
78 typedef LFOTriangleIntAbsMath<range_signed> LFOSigned;
79 #elif CONFIG_SIGNED_TRIANG_ALGO == DI_HARMONIC_SOLUTION
80 typedef LFOTriangleDiHarmonic<range_signed> LFOSigned;
81 #endif
82
83 class AbstractVoice : public Voice {
84 public:
85 type_t Type; ///< Voice Type (bit field, a voice may have several types)
86 NoteBase* pNote; ///< Note this voice belongs to and was caused by.
87 int MIDIPan; ///< the current MIDI pan value plus the value from RegionInfo
88
89 SignalUnitRack* const pSignalUnitRack;
90
91 AbstractVoice(SignalUnitRack* pRack);
92 virtual ~AbstractVoice();
93
94 inline bool IsActive() { return PlaybackState; }
95 inline bool IsStealable() { return !itKillEvent && PlaybackState >= playback_state_ram; }
96
97 virtual void Reset();
98
99 virtual int Trigger (
100 AbstractEngineChannel* pEngineChannel,
101 Pool<Event>::Iterator& itNoteOnEvent,
102 int PitchBend,
103 type_t VoiceType,
104 int iKeyGroup
105 );
106
107 /** Invoked when the voice is freed - gone from active to inactive. */
108 virtual void VoiceFreed() { }
109
110 virtual void Synthesize(uint Samples, sample_t* pSrc, uint Skip);
111
112 virtual release_trigger_t GetReleaseTriggerFlags() = 0;
113
114 uint GetSampleRate() { return GetEngine()->SampleRate; }
115
116 uint8_t GetControllerValue(uint8_t Controller) {
117 return (Controller > 128) ? 0 : pEngineChannel->ControllerTable[Controller];
118 }
119
120 /// Keyboard key on which this voice should listen to transitional events (i.e. note-off events to release the voice).
121 inline uint8_t HostKey() const { return pNote->hostKey; }
122 /// Keyboard key which the voice should use for calculating any synthesis relevant parameters (i.e. pitch).
123 inline uint8_t MIDIKey() const { return pNote->cause.Param.Note.Key; }
124 /// MIDI note-on velocity value which the voice should use for calculating any synthesis relevant parameters (i.e. amplitude).
125 inline uint8_t MIDIVelocity() const { return pNote->cause.Param.Note.Velocity; }
126
127 void processCCEvents(RTList<Event>::Iterator& itEvent, uint End);
128 void processPitchEvent(RTList<Event>::Iterator& itEvent);
129 void processResonanceEvent(RTList<Event>::Iterator& itEvent);
130 void processTransitionEvents(RTList<Event>::Iterator& itEvent, uint End);
131 void processGroupEvents(RTList<Event>::Iterator& itEvent, uint End);
132 void UpdatePortamentoPos(Pool<Event>::Iterator& itNoteOffEvent);
133 void Kill(Pool<Event>::Iterator& itKillEvent);
134 void CreateEq();
135 void onScaleTuningChanged();
136
137 bool Orphan; ///< true if this voice is playing a sample from an instrument that is unloaded. When the voice dies, the sample (and dimension region) will be handed back to the instrument resource manager.
138 playback_state_t PlaybackState; ///< When a sample will be triggered, it will be first played from RAM cache and after a couple of sample points it will switch to disk streaming and at the end of a disk stream we have to add null samples, so the interpolator can do it's work correctly
139 Stream::reference_t DiskStreamRef; ///< Reference / link to the disk stream
140
141 template<class TV, class TRR, class TR, class TD, class TIM, class TI> friend class EngineBase;
142
143 #if CONFIG_DEVMODE
144 public:
145 #else
146 protected:
147 #endif
148 SampleInfo SmplInfo;
149 RegionInfo RgnInfo;
150 InstrumentInfo InstrInfo;
151 AbstractEngineChannel* pEngineChannel;
152
153 double Pos; ///< Current playback position in sample
154 PitchInfo Pitch;
155 Fade NotePitch; ///< Updated by calls to built-in instrument script function change_tune() (defaults to 1.0, that is neutral).
156 float CutoffBase; ///< Cutoff frequency before control change, EG and LFO are applied
157 float VolumeLeft; ///< Left channel volume. This factor is calculated when the voice is triggered and doesn't change after that.
158 float VolumeRight; ///< Right channel volume. This factor is calculated when the voice is triggered and doesn't change after that.
159 Fade NotePan[2]; ///< Updated by calls to built-in instrument script function change_pan() (defaults to 1.0, that is neutral, index 0 for left pan, index 1 for right).
160 NoteBase::Norm NoteCutoff; ///< Updated by calls to built-in instrument script function change_cutoff() (defaults to 1.0, that is neutral).
161 NoteBase::Norm NoteResonance; ///< Updated by calls to built-in instrument script function change_reso() (defaults to 1.0, that is neutral).
162 gig::SmoothVolume CrossfadeSmoother; ///< Crossfade volume, updated by crossfade CC events
163 gig::SmoothVolume VolumeSmoother; ///< Volume, updated by CC 7 (volume) events
164 gig::SmoothVolume PanLeftSmoother; ///< Left channel volume, updated by CC 10 (pan) events and change_pan() real-time instrument script calls.
165 gig::SmoothVolume PanRightSmoother; ///< Right channel volume, updated by CC 10 (pan) events and change_pan() real-time instrument script calls.
166 Fade NoteVolume; ///< Note's global volume, updated by change_vol() real-time instrument script calls (defaults to 1.0, that is neutral).
167 bool DiskVoice; ///< If the sample is very short it completely fits into the RAM cache and doesn't need to be streamed from disk, in that case this flag is set to false
168 bool RAMLoop; ///< If this voice has a loop defined which completely fits into the cached RAM part of the sample, in this case we handle the looping within the voice class, else if the loop is located in the disk stream part, we let the disk stream handle the looping
169 unsigned long MaxRAMPos; ///< The upper allowed limit (not actually the end) in the RAM sample cache, after that point it's not safe to chase the interpolator another time over over the current cache position, instead we switch to disk then.
170 uint Delay; ///< Number of sample points the rendering process of this voice should be delayed (jitter correction), will be set to 0 after the first audio fragment cycle
171 EG* pEG1; ///< Envelope Generator 1 (Amplification)
172 EG* pEG2; ///< Envelope Generator 2 (Filter cutoff frequency)
173 gig::EGDecay EG3; ///< Envelope Generator 3 (Pitch) TODO: use common EG instead?
174 midi_ctrl VCFCutoffCtrl;
175 midi_ctrl VCFResonanceCtrl;
176 LFOUnsigned* pLFO1; ///< Low Frequency Oscillator 1 (Amplification)
177 LFOUnsigned* pLFO2; ///< Low Frequency Oscillator 2 (Filter cutoff frequency)
178 LFOSigned* pLFO3; ///< Low Frequency Oscillator 3 (Pitch)
179 bool bLFO1Enabled; ///< Should we use the Amplitude LFO for this voice?
180 bool bLFO2Enabled; ///< Should we use the Filter Cutoff LFO for this voice?
181 bool bLFO3Enabled; ///< Should we use the Pitch LFO for this voice?
182 Pool<Event>::Iterator itTriggerEvent; ///< First event on the key's list the voice should process (only needed for the first audio fragment in which voice was triggered, after that it will be set to NULL).
183 Pool<Event>::Iterator itKillEvent; ///< Event which caused this voice to be killed
184 int SynthesisMode;
185 float fFinalCutoff;
186 float fFinalResonance;
187 gig::SynthesisParam finalSynthesisParameters;
188 gig::Loop loop;
189 RTList<Event>* pGroupEvents; ///< Events directed to an exclusive group
190
191 EqSupport* pEq; ///< Used for per voice equalization
192 bool bEqSupport;
193
194 void PrintEqInfo() {
195 if (!bEqSupport || pEq == NULL) {
196 dmsg(1,("EQ support: no\n"));
197 } else {
198 pEq->PrintInfo();
199 }
200 }
201
202 virtual AbstractEngine* GetEngine() = 0;
203 virtual SampleInfo GetSampleInfo() = 0;
204 virtual RegionInfo GetRegionInfo() = 0;
205 virtual InstrumentInfo GetInstrumentInfo() = 0;
206
207 /**
208 * Most of the important members of the voice are set when the voice
209 * is triggered (like pEngineChannel, pRegion, pSample, etc).
210 * This method is called after these members are set and before
211 * the voice is actually triggered.
212 * Override this method if you need to do some additional
213 * initialization which depends on these members before the voice
214 * is triggered.
215 */
216 virtual void AboutToTrigger() { }
217
218 virtual bool EG1Finished();
219
220 /**
221 * Gets the sample cache size in bytes.
222 */
223 virtual unsigned long GetSampleCacheSize() = 0;
224
225 /**
226 * Because in most cases we cache part of the sample in RAM, if the
227 * offset is too big (will extend beyond the RAM cache if the cache contains
228 * the beginning of the sample) we should cache in the RAM buffer not the
229 * beginning of the sample but a part that starts from the sample offset point.
230 * In that case the current sample position should start from zero (Pos).
231 * When the offset fits into RAM buffer or the whole sample is cached
232 * in RAM, Pos should contain the actual offset.
233 * We don't trim the sample because it might have a defined
234 * loop start point before the start point of the playback.
235 */
236 virtual void SetSampleStartOffset();
237
238 /**
239 * Returns the correct amplitude factor for the given \a MIDIKeyVelocity.
240 * All involved parameters (VelocityResponseCurve, VelocityResponseDepth
241 * and VelocityResponseCurveScaling) involved are taken into account to
242 * calculate the amplitude factor. Use this method when a key was
243 * triggered to get the volume with which the sample should be played
244 * back.
245 *
246 * @param MIDIKeyVelocity MIDI velocity value of the triggered key (between 0 and 127)
247 * @returns amplitude factor (between 0.0 and 1.0)
248 */
249 virtual double GetVelocityAttenuation(uint8_t MIDIKeyVelocity) = 0;
250
251 virtual double GetSampleAttenuation() = 0;
252
253 virtual double CalculateVolume(double velocityAttenuation);
254
255 virtual float GetReleaseTriggerAttenuation(float noteLength);
256
257 /**
258 * Get starting crossfade volume level
259 */
260 virtual double CalculateCrossfadeVolume(uint8_t MIDIKeyVelocity) = 0;
261
262 virtual MidiKeyBase* GetMidiKeyInfo(int MIDIKey) = 0;
263
264 virtual int OrderNewStream() = 0;
265
266 virtual PitchInfo CalculatePitchInfo(int PitchBend);
267
268 // TODO: cleanup the interface. The following two methods
269 // are maybe not neccessary after the TriggerEG1 method
270 // was added.
271
272 /**
273 * Get current value of EG1 controller.
274 */
275 virtual double GetEG1ControllerValue(uint8_t MIDIKeyVelocity) = 0;
276
277 /**
278 * Calculate influence of EG1 controller on EG1's parameters.
279 */
280 virtual EGInfo CalculateEG1ControllerInfluence(double eg1ControllerValue) = 0;
281
282 // TODO: cleanup the interface. The velrelase and
283 // velocityAttenuation parameters are perhaps too gig
284 // specific.
285 /**
286 * Trigger the amplitude envelope generator.
287 */
288 virtual void TriggerEG1(const EGInfo& egInfo, double velrelease, double velocityAttenuation, uint sampleRate, uint8_t velocity) = 0;
289
290 /**
291 * Get current value of EG2 controller.
292 */
293 virtual double GetEG2ControllerValue(uint8_t MIDIKeyVelocity) = 0;
294
295 /**
296 * Calculate influence of EG2 controller on EG2's parameters.
297 */
298 virtual EGInfo CalculateEG2ControllerInfluence(double eg2ControllerValue) = 0;
299
300 virtual void TriggerEG2(const EGInfo& egInfo, double velrelease, double velocityAttenuation, uint sampleRate, uint8_t velocity) = 0;
301
302 virtual float CalculateCutoffBase(uint8_t MIDIKeyVelocity) = 0;
303 virtual float CalculateFinalCutoff(float cutoffBase) = 0;
304
305 virtual void InitLFO1() = 0;
306 virtual void InitLFO2() = 0;
307 virtual void InitLFO3() = 0;
308
309 virtual uint8_t GetVCFCutoffCtrl() = 0;
310 virtual uint8_t GetVCFResonanceCtrl() = 0;
311 virtual uint8_t CrossfadeAttenuation(uint8_t& CrossfadeControllerValue) = 0;
312
313 virtual void GetFirstEventOnKey(uint8_t MIDIKey, RTList<Event>::Iterator& itEvent) = 0;
314 virtual void ProcessCCEvent(RTList<Event>::Iterator& itEvent) = 0;
315 virtual void ProcessChannelPressureEvent(RTList<Event>::Iterator& itEvent) = 0;
316 virtual void ProcessPolyphonicKeyPressureEvent(RTList<Event>::Iterator& itEvent) = 0;
317 virtual void ProcessCutoffEvent(RTList<Event>::Iterator& itEvent) = 0;
318 virtual double GetVelocityRelease(uint8_t MIDIKeyVelocity) = 0;
319
320 virtual unsigned long GetNoteOnTime(int MIDIKey) = 0;
321
322 virtual void ProcessGroupEvent(RTList<Event>::Iterator& itEvent) = 0;
323 void EnterReleaseStage();
324
325 virtual int CalculatePan(uint8_t pan) = 0;
326 };
327 } // namespace LinuxSampler
328
329 #endif /* __LS_ABSTRACTVOICE_H__ */

  ViewVC Help
Powered by ViewVC