Mercurial > hg > svgui
view layer/SpectrogramLayer.h @ 69:6dad2724f3aa
* Ensure plugin parameters for a transform are saved in the .sv file and
restored in case the plugin has to be run again
* Make plugin dialog offer options for mixdown/single-channel use if the
file has more than one channels but the plugin only accepts one
* Fix incorrect samplerate playback for second file loaded if its samplerate
differed from first
* Add Zoom to Fit and Select Visible Range menu options, split out Import
Audio into main model and secondary model options
* Add stubs for cut, copy and paste operations (not implemented yet)
author | Chris Cannam |
---|---|
date | Thu, 30 Mar 2006 13:18:11 +0000 |
parents | 705f05ab42e3 |
children | 72fa239a4880 |
line wrap: on
line source
/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* Sonic Visualiser An audio file viewer and annotation editor. Centre for Digital Music, Queen Mary, University of London. This file copyright 2006 Chris Cannam. 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. See the file COPYING included with this distribution for more information. */ #ifndef _SPECTROGRAM_LAYER_H_ #define _SPECTROGRAM_LAYER_H_ #include "base/Layer.h" #include "base/Window.h" #include "model/PowerOfSqrtTwoZoomConstraint.h" #include "model/DenseTimeValueModel.h" #include <QThread> #include <QMutex> #include <QWaitCondition> #include <fftw3.h> #include <stdint.h> class View; class QPainter; class QImage; class QPixmap; class QTimer; class RealTime; /** * SpectrogramLayer represents waveform data (obtained from a * DenseTimeValueModel) in spectrogram form. */ class SpectrogramLayer : public Layer, public PowerOfSqrtTwoZoomConstraint { Q_OBJECT public: enum Configuration { FullRangeDb, MelodicRange, MelodicPeaks }; SpectrogramLayer(Configuration = FullRangeDb); ~SpectrogramLayer(); virtual const ZoomConstraint *getZoomConstraint() const { return this; } virtual const Model *getModel() const { return m_model; } virtual void paint(View *v, QPainter &paint, QRect rect) const; virtual int getVerticalScaleWidth(View *v, QPainter &) const; virtual void paintVerticalScale(View *v, QPainter &paint, QRect rect) const; virtual QString getFeatureDescription(View *v, QPoint &) const; virtual bool snapToFeatureFrame(View *v, int &frame, size_t &resolution, SnapType snap) const; void setModel(const DenseTimeValueModel *model); virtual PropertyList getProperties() const; virtual PropertyType getPropertyType(const PropertyName &) const; virtual QString getPropertyGroupName(const PropertyName &) const; virtual int getPropertyRangeAndValue(const PropertyName &, int *min, int *max) const; virtual QString getPropertyValueLabel(const PropertyName &, int value) const; virtual void setProperty(const PropertyName &, int value); /** * Specify the channel to use from the source model. * A value of -1 means to mix all available channels. * The default is channel 0. */ void setChannel(int); int getChannel() const; void setWindowSize(size_t); size_t getWindowSize() const; void setWindowOverlap(size_t percent); size_t getWindowOverlap() const; void setWindowType(WindowType type); WindowType getWindowType() const; /** * Set the gain multiplier for sample values in this view prior to * FFT calculation. * * The default is 1.0. */ void setGain(float gain); float getGain() const; /** * Set the threshold for sample values to be shown in the FFT, * in voltage units. * * The default is 0.0. */ void setThreshold(float threshold); float getThreshold() const; void setMinFrequency(size_t); size_t getMinFrequency() const; void setMaxFrequency(size_t); // 0 -> no maximum size_t getMaxFrequency() const; enum ColourScale { LinearColourScale, MeterColourScale, dBColourScale, PhaseColourScale }; /** * Specify the scale for sample levels. See WaveformLayer for * details of meter and dB scaling. The default is dBColourScale. */ void setColourScale(ColourScale); ColourScale getColourScale() const; enum FrequencyScale { LinearFrequencyScale, LogFrequencyScale }; /** * Specify the scale for the y axis. */ void setFrequencyScale(FrequencyScale); FrequencyScale getFrequencyScale() const; enum BinDisplay { AllBins, PeakBins, PeakFrequencies }; /** * Specify the processing of frequency bins for the y axis. */ void setBinDisplay(BinDisplay); BinDisplay getBinDisplay() const; void setNormalizeColumns(bool n); bool getNormalizeColumns() const; enum ColourScheme { DefaultColours, WhiteOnBlack, BlackOnWhite, RedOnBlue, YellowOnBlack, Rainbow }; void setColourScheme(ColourScheme scheme); ColourScheme getColourScheme() const; /** * Specify the colourmap rotation for the colour scale. */ void setColourRotation(int); int getColourRotation() const; virtual VerticalPosition getPreferredFrameCountPosition() const { return PositionTop; } virtual bool isLayerOpaque() const { return true; } float getYForFrequency(View *v, float frequency) const; float getFrequencyForY(View *v, int y) const; virtual int getCompletion() const; virtual QString toXmlString(QString indent = "", QString extraAttributes = "") const; void setProperties(const QXmlAttributes &attributes); virtual void setLayerDormant(const View *v, bool dormant); protected slots: void cacheInvalid(); void cacheInvalid(size_t startFrame, size_t endFrame); void fillTimerTimedOut(); protected: const DenseTimeValueModel *m_model; // I do not own this int m_channel; size_t m_windowSize; WindowType m_windowType; size_t m_windowOverlap; float m_gain; float m_threshold; int m_colourRotation; size_t m_minFrequency; size_t m_maxFrequency; ColourScale m_colourScale; ColourScheme m_colourScheme; FrequencyScale m_frequencyScale; BinDisplay m_binDisplay; bool m_normalizeColumns; // At the moment we cache one unsigned char per bin for the // magnitude -- which is nothing like precise enough to allow us // to subsequently adjust gain etc without recalculating the // cached values -- plus optionally one unsigned char per bin for // phase-adjusted frequency. // To speed up redrawing after parameter changes, we would like to // cache magnitude in a way that can have gain applied afterwards // and can determine whether something is a peak or not, and also // cache phase rather than only phase-adjusted frequency so that // we don't have to recalculate if switching between phase and // magnitude displays. // This implies probably 16 bits for a normalized magnitude (in // dB?) and at most 16 bits for phase. 16 or 32 bits per bin // instead of 8 or 16. // Each column's magnitudes are expected to be stored normalized // to [0,1] with respect to the column, so the normalization // factor should be calculated before all values in a column, and // set appropriately. class Cache { public: Cache(); // of size zero, call resize() before using ~Cache(); size_t getWidth() const { return m_width; } size_t getHeight() const { return m_height; } void resize(size_t width, size_t height); void reset(); // zero-fill or 1-fill as appropriate without changing size float getMagnitudeAt(size_t x, size_t y) const { return getNormalizedMagnitudeAt(x, y) * m_factor[x]; } float getNormalizedMagnitudeAt(size_t x, size_t y) const { return float(m_magnitude[x][y]) / 65535.0; } float getPhaseAt(size_t x, size_t y) const { int16_t i = (int16_t)m_phase[x][y]; return (float(i) / 32767.0) * M_PI; } bool isLocalPeak(size_t x, size_t y) const { if (y > 0 && m_magnitude[x][y] < m_magnitude[x][y-1]) return false; if (y < m_height-1 && m_magnitude[x][y] < m_magnitude[x][y+1]) return false; return true; } bool isOverThreshold(size_t x, size_t y, float threshold) const { if (threshold == 0.0) return true; return getMagnitudeAt(x, y) > threshold; } void setNormalizationFactor(size_t x, float factor) { if (x < m_width) m_factor[x] = factor; } void setMagnitudeAt(size_t x, size_t y, float mag) { // norm factor must already be set setNormalizedMagnitudeAt(x, y, mag / m_factor[x]); } void setNormalizedMagnitudeAt(size_t x, size_t y, float norm) { if (x < m_width && y < m_height) { m_magnitude[x][y] = uint16_t(norm * 65535.0); } } void setPhaseAt(size_t x, size_t y, float phase) { // phase in range -pi -> pi if (x < m_width && y < m_height) { m_phase[x][y] = uint16_t(int16_t((phase * 32767) / M_PI)); } } QColor getColour(unsigned char index) const { return m_colours[index]; } void setColour(unsigned char index, QColor colour) { m_colours[index] = colour; } private: size_t m_width; size_t m_height; uint16_t **m_magnitude; uint16_t **m_phase; float *m_factor; QColor m_colours[256]; void resize(uint16_t **&, size_t, size_t); }; enum { NO_VALUE = 0 }; // colour index for unused pixels Cache *m_cache; bool m_cacheInvalid; class CacheFillThread : public QThread { public: CacheFillThread(SpectrogramLayer &layer) : m_layer(layer), m_fillExtent(0) { } size_t getFillExtent() const { return m_fillExtent; } size_t getFillCompletion() const { return m_fillCompletion; } virtual void run(); protected: SpectrogramLayer &m_layer; size_t m_fillExtent; size_t m_fillCompletion; }; void fillCache(); mutable QPixmap *m_pixmapCache; mutable bool m_pixmapCacheInvalid; mutable long m_pixmapCacheStartFrame; mutable size_t m_pixmapCacheZoomLevel; QWaitCondition m_condition; mutable QMutex m_mutex; CacheFillThread *m_fillThread; QTimer *m_updateTimer; mutable size_t m_candidateFillStartFrame; size_t m_lastFillExtent; bool m_exiting; void setCacheColourmap(); void rotateCacheColourmap(int distance); void fillCacheColumn(int column, double *inputBuffer, fftw_complex *outputBuffer, fftw_plan plan, size_t windowSize, size_t windowIncrement, const Window<double> &windower) const; static float calculateFrequency(size_t bin, size_t windowSize, size_t windowIncrement, size_t sampleRate, float previousPhase, float currentPhase, bool &steadyState); unsigned char getDisplayValue(float input) const; float getInputForDisplayValue(unsigned char uc) const; int getColourScaleWidth(QPainter &) const; float getEffectiveMinFrequency() const; float getEffectiveMaxFrequency() const; struct LayerRange { long startFrame; int zoomLevel; size_t modelStart; size_t modelEnd; }; bool getXBinRange(View *v, int x, float &windowMin, float &windowMax) const; bool getYBinRange(View *v, int y, float &freqBinMin, float &freqBinMax) const; bool getYBinSourceRange(View *v, int y, float &freqMin, float &freqMax) const; bool getAdjustedYBinSourceRange(View *v, int x, int y, float &freqMin, float &freqMax, float &adjFreqMin, float &adjFreqMax) const; bool getXBinSourceRange(View *v, int x, RealTime &timeMin, RealTime &timeMax) const; bool getXYBinSourceRange(View *v, int x, int y, float &min, float &max, float &phaseMin, float &phaseMax) const; size_t getWindowIncrement() const { return m_windowSize - m_windowSize * m_windowOverlap / 100; } }; #endif