annotate audioio/AudioCallbackPlaySource.h @ 3:e764bbf2b090 last-cc-copyright

* Move the current DenseThreeDimensionalModel to EditableDenseThreeDimensionalModel (wow!), and make DTDM an abstract base * Move FFTFuzzyAdapter to FFTModel as a new subclass of DTDM
author Chris Cannam
date Mon, 31 Jul 2006 17:05:18 +0000
parents cd5d7ff8ef38
children ee967635c728
rev   line source
Chris@0 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
Chris@0 2
Chris@0 3 /*
Chris@0 4 Sonic Visualiser
Chris@0 5 An audio file viewer and annotation editor.
Chris@0 6 Centre for Digital Music, Queen Mary, University of London.
Chris@0 7 This file copyright 2006 Chris Cannam.
Chris@0 8
Chris@0 9 This program is free software; you can redistribute it and/or
Chris@0 10 modify it under the terms of the GNU General Public License as
Chris@0 11 published by the Free Software Foundation; either version 2 of the
Chris@0 12 License, or (at your option) any later version. See the file
Chris@0 13 COPYING included with this distribution for more information.
Chris@0 14 */
Chris@0 15
Chris@0 16 #ifndef _AUDIO_CALLBACK_PLAY_SOURCE_H_
Chris@0 17 #define _AUDIO_CALLBACK_PLAY_SOURCE_H_
Chris@0 18
Chris@0 19 #include "base/RingBuffer.h"
Chris@0 20 #include "base/AudioPlaySource.h"
Chris@0 21 #include "base/Scavenger.h"
Chris@0 22
Chris@0 23 #include <QObject>
Chris@0 24 #include <QMutex>
Chris@0 25 #include <QWaitCondition>
Chris@0 26
Chris@0 27 #include "base/Thread.h"
Chris@0 28
Chris@0 29 #include <samplerate.h>
Chris@0 30
Chris@0 31 #include <set>
Chris@0 32 #include <map>
Chris@0 33
Chris@0 34 class Model;
Chris@0 35 class ViewManager;
Chris@0 36 class AudioGenerator;
Chris@0 37 class PlayParameters;
Chris@0 38 class IntegerTimeStretcher;
Chris@0 39
Chris@0 40 /**
Chris@0 41 * AudioCallbackPlaySource manages audio data supply to callback-based
Chris@0 42 * audio APIs such as JACK or CoreAudio. It maintains one ring buffer
Chris@0 43 * per channel, filled during playback by a non-realtime thread, and
Chris@0 44 * provides a method for a realtime thread to pick up the latest
Chris@0 45 * available sample data from these buffers.
Chris@0 46 */
Chris@0 47 class AudioCallbackPlaySource : public virtual QObject,
Chris@0 48 public AudioPlaySource
Chris@0 49 {
Chris@0 50 Q_OBJECT
Chris@0 51
Chris@0 52 public:
Chris@0 53 AudioCallbackPlaySource(ViewManager *);
Chris@0 54 virtual ~AudioCallbackPlaySource();
Chris@0 55
Chris@0 56 /**
Chris@0 57 * Add a data model to be played from. The source can mix
Chris@0 58 * playback from a number of sources including dense and sparse
Chris@0 59 * models. The models must match in sample rate, but they don't
Chris@0 60 * have to have identical numbers of channels.
Chris@0 61 */
Chris@0 62 virtual void addModel(Model *model);
Chris@0 63
Chris@0 64 /**
Chris@0 65 * Remove a model.
Chris@0 66 */
Chris@0 67 virtual void removeModel(Model *model);
Chris@0 68
Chris@0 69 /**
Chris@0 70 * Remove all models. (Silence will ensue.)
Chris@0 71 */
Chris@0 72 virtual void clearModels();
Chris@0 73
Chris@0 74 /**
Chris@0 75 * Start making data available in the ring buffers for playback,
Chris@0 76 * from the given frame. If playback is already under way, reseek
Chris@0 77 * to the given frame and continue.
Chris@0 78 */
Chris@0 79 virtual void play(size_t startFrame);
Chris@0 80
Chris@0 81 /**
Chris@0 82 * Stop playback and ensure that no more data is returned.
Chris@0 83 */
Chris@0 84 virtual void stop();
Chris@0 85
Chris@0 86 /**
Chris@0 87 * Return whether playback is currently supposed to be happening.
Chris@0 88 */
Chris@0 89 virtual bool isPlaying() const { return m_playing; }
Chris@0 90
Chris@0 91 /**
Chris@0 92 * Return the frame number that is currently expected to be coming
Chris@0 93 * out of the speakers. (i.e. compensating for playback latency.)
Chris@0 94 */
Chris@0 95 virtual size_t getCurrentPlayingFrame();
Chris@0 96
Chris@0 97 /**
Chris@0 98 * Set the block size of the target audio device. This should
Chris@0 99 * be called by the target class.
Chris@0 100 */
Chris@0 101 void setTargetBlockSize(size_t);
Chris@0 102
Chris@0 103 /**
Chris@0 104 * Get the block size of the target audio device.
Chris@0 105 */
Chris@0 106 size_t getTargetBlockSize() const;
Chris@0 107
Chris@0 108 /**
Chris@0 109 * Set the playback latency of the target audio device, in frames
Chris@0 110 * at the target sample rate. This is the difference between the
Chris@0 111 * frame currently "leaving the speakers" and the last frame (or
Chris@0 112 * highest last frame across all channels) requested via
Chris@0 113 * getSamples(). The default is zero.
Chris@0 114 */
Chris@0 115 void setTargetPlayLatency(size_t);
Chris@0 116
Chris@0 117 /**
Chris@0 118 * Get the playback latency of the target audio device.
Chris@0 119 */
Chris@0 120 size_t getTargetPlayLatency() const;
Chris@0 121
Chris@0 122 /**
Chris@0 123 * Specify that the target audio device has a fixed sample rate
Chris@0 124 * (i.e. cannot accommodate arbitrary sample rates based on the
Chris@0 125 * source). If the target sets this to something other than the
Chris@0 126 * source sample rate, this class will resample automatically to
Chris@0 127 * fit.
Chris@0 128 */
Chris@0 129 void setTargetSampleRate(size_t);
Chris@0 130
Chris@0 131 /**
Chris@0 132 * Return the sample rate set by the target audio device (or the
Chris@0 133 * source sample rate if the target hasn't set one).
Chris@0 134 */
Chris@0 135 virtual size_t getTargetSampleRate() const;
Chris@0 136
Chris@0 137 /**
Chris@0 138 * Set the current output levels for metering (for call from the
Chris@0 139 * target)
Chris@0 140 */
Chris@0 141 void setOutputLevels(float left, float right);
Chris@0 142
Chris@0 143 /**
Chris@0 144 * Return the current (or thereabouts) output levels in the range
Chris@0 145 * 0.0 -> 1.0, for metering purposes.
Chris@0 146 */
Chris@0 147 virtual bool getOutputLevels(float &left, float &right);
Chris@0 148
Chris@0 149 /**
Chris@0 150 * Get the number of channels of audio that in the source models.
Chris@0 151 * This may safely be called from a realtime thread. Returns 0 if
Chris@0 152 * there is no source yet available.
Chris@0 153 */
Chris@0 154 size_t getSourceChannelCount() const;
Chris@0 155
Chris@0 156 /**
Chris@0 157 * Get the number of channels of audio that will be provided
Chris@0 158 * to the play target. This may be more than the source channel
Chris@0 159 * count: for example, a mono source will provide 2 channels
Chris@0 160 * after pan.
Chris@0 161 * This may safely be called from a realtime thread. Returns 0 if
Chris@0 162 * there is no source yet available.
Chris@0 163 */
Chris@0 164 size_t getTargetChannelCount() const;
Chris@0 165
Chris@0 166 /**
Chris@0 167 * Get the actual sample rate of the source material. This may
Chris@0 168 * safely be called from a realtime thread. Returns 0 if there is
Chris@0 169 * no source yet available.
Chris@0 170 */
Chris@0 171 size_t getSourceSampleRate() const;
Chris@0 172
Chris@0 173 /**
Chris@0 174 * Get "count" samples (at the target sample rate) of the mixed
Chris@0 175 * audio data, in all channels. This may safely be called from a
Chris@0 176 * realtime thread.
Chris@0 177 */
Chris@0 178 size_t getSourceSamples(size_t count, float **buffer);
Chris@0 179
Chris@0 180 void setSlowdownFactor(size_t factor);
Chris@0 181
Chris@0 182 signals:
Chris@0 183 void modelReplaced();
Chris@0 184
Chris@0 185 void playStatusChanged(bool isPlaying);
Chris@0 186
Chris@0 187 void sampleRateMismatch(size_t requested, size_t available, bool willResample);
Chris@0 188
Chris@0 189 protected slots:
Chris@0 190 void selectionChanged();
Chris@0 191 void playLoopModeChanged();
Chris@0 192 void playSelectionModeChanged();
Chris@0 193 void playParametersChanged(PlayParameters *);
Chris@0 194
Chris@0 195 protected:
Chris@0 196 ViewManager *m_viewManager;
Chris@0 197 AudioGenerator *m_audioGenerator;
Chris@0 198
Chris@0 199 class RingBufferVector : public std::vector<RingBuffer<float> *> {
Chris@0 200 public:
Chris@0 201 virtual ~RingBufferVector() {
Chris@0 202 while (!empty()) {
Chris@0 203 delete *begin();
Chris@0 204 erase(begin());
Chris@0 205 }
Chris@0 206 }
Chris@0 207 };
Chris@0 208
Chris@0 209 std::set<Model *> m_models;
Chris@0 210 RingBufferVector *m_readBuffers;
Chris@0 211 RingBufferVector *m_writeBuffers;
Chris@0 212 size_t m_readBufferFill;
Chris@0 213 size_t m_writeBufferFill;
Chris@0 214 Scavenger<RingBufferVector> m_bufferScavenger;
Chris@0 215 size_t m_sourceChannelCount;
Chris@0 216 size_t m_blockSize;
Chris@0 217 size_t m_sourceSampleRate;
Chris@0 218 size_t m_targetSampleRate;
Chris@0 219 size_t m_playLatency;
Chris@0 220 bool m_playing;
Chris@0 221 bool m_exiting;
Chris@0 222 size_t m_lastModelEndFrame;
Chris@0 223 static const size_t m_ringBufferSize;
Chris@0 224 float m_outputLeft;
Chris@0 225 float m_outputRight;
Chris@0 226
Chris@0 227 RingBuffer<float> *getWriteRingBuffer(size_t c) {
Chris@0 228 if (m_writeBuffers && c < m_writeBuffers->size()) {
Chris@0 229 return (*m_writeBuffers)[c];
Chris@0 230 } else {
Chris@0 231 return 0;
Chris@0 232 }
Chris@0 233 }
Chris@0 234
Chris@0 235 RingBuffer<float> *getReadRingBuffer(size_t c) {
Chris@0 236 RingBufferVector *rb = m_readBuffers;
Chris@0 237 if (rb && c < rb->size()) {
Chris@0 238 return (*rb)[c];
Chris@0 239 } else {
Chris@0 240 return 0;
Chris@0 241 }
Chris@0 242 }
Chris@0 243
Chris@0 244 void clearRingBuffers(bool haveLock = false, size_t count = 0);
Chris@0 245 void unifyRingBuffers();
Chris@0 246
Chris@0 247 class TimeStretcherData
Chris@0 248 {
Chris@0 249 public:
Chris@0 250 TimeStretcherData(size_t channels, size_t factor, size_t blockSize);
Chris@0 251 ~TimeStretcherData();
Chris@0 252
Chris@0 253 size_t getFactor() const { return m_factor; }
Chris@0 254 IntegerTimeStretcher *getStretcher(size_t channel);
Chris@0 255 float *getOutputBuffer(size_t channel);
Chris@0 256 float *getInputBuffer();
Chris@0 257
Chris@0 258 void run(size_t channel);
Chris@0 259
Chris@0 260 protected:
Chris@0 261 TimeStretcherData(const TimeStretcherData &); // not provided
Chris@0 262 TimeStretcherData &operator=(const TimeStretcherData &); // not provided
Chris@0 263
Chris@0 264 typedef std::pair<IntegerTimeStretcher *, float *> StretcherBuffer;
Chris@0 265 std::map<size_t, StretcherBuffer> m_stretcher;
Chris@0 266 float *m_stretchInputBuffer;
Chris@0 267 size_t m_factor;
Chris@0 268 size_t m_blockSize;
Chris@0 269 };
Chris@0 270
Chris@0 271 size_t m_slowdownCounter;
Chris@0 272 TimeStretcherData *m_timeStretcher;
Chris@0 273 Scavenger<TimeStretcherData> m_timeStretcherScavenger;
Chris@0 274
Chris@0 275 // Called from fill thread, m_playing true, mutex held
Chris@0 276 // Return true if work done
Chris@0 277 bool fillBuffers();
Chris@0 278
Chris@0 279 // Called from fillBuffers. Return the number of frames written,
Chris@0 280 // which will be count or fewer. Return in the frame argument the
Chris@0 281 // new buffered frame position (which may be earlier than the
Chris@0 282 // frame argument passed in, in the case of looping).
Chris@0 283 size_t mixModels(size_t &frame, size_t count, float **buffers);
Chris@0 284
Chris@0 285 class AudioCallbackPlaySourceFillThread : public Thread
Chris@0 286 {
Chris@0 287 public:
Chris@0 288 AudioCallbackPlaySourceFillThread(AudioCallbackPlaySource &source) :
Chris@0 289 Thread(Thread::NonRTThread),
Chris@0 290 m_source(source) { }
Chris@0 291
Chris@0 292 virtual void run();
Chris@0 293
Chris@0 294 protected:
Chris@0 295 AudioCallbackPlaySource &m_source;
Chris@0 296 };
Chris@0 297
Chris@0 298 QMutex m_mutex;
Chris@0 299 QWaitCondition m_condition;
Chris@0 300 AudioCallbackPlaySourceFillThread *m_fillThread;
Chris@0 301 SRC_STATE *m_converter;
Chris@0 302 };
Chris@0 303
Chris@0 304 #endif
Chris@0 305
Chris@0 306