annotate data/model/RangeSummarisableTimeValueModel.h @ 558:1d7ebc05157e

* Some fairly simplistic code to set up layer type properties based on RDF data about feature types (both when running transforms and when importing features from RDF files).
author Chris Cannam
date Thu, 12 Feb 2009 15:26:43 +0000
parents 9c7ebf2cd956
children 8c5b0eec6fe9
rev   line source
Chris@147 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
Chris@147 2
Chris@147 3 /*
Chris@147 4 Sonic Visualiser
Chris@147 5 An audio file viewer and annotation editor.
Chris@147 6 Centre for Digital Music, Queen Mary, University of London.
Chris@297 7 This file copyright 2006-2007 Chris Cannam and QMUL.
Chris@147 8
Chris@147 9 This program is free software; you can redistribute it and/or
Chris@147 10 modify it under the terms of the GNU General Public License as
Chris@147 11 published by the Free Software Foundation; either version 2 of the
Chris@147 12 License, or (at your option) any later version. See the file
Chris@147 13 COPYING included with this distribution for more information.
Chris@147 14 */
Chris@147 15
Chris@147 16 #ifndef _RANGE_SUMMARISABLE_TIME_VALUE_MODEL_H_
Chris@147 17 #define _RANGE_SUMMARISABLE_TIME_VALUE_MODEL_H_
Chris@147 18
Chris@147 19 #include <QObject>
Chris@147 20
Chris@147 21 #include "DenseTimeValueModel.h"
Chris@147 22 #include "base/ZoomConstraint.h"
Chris@147 23
Chris@147 24 /**
Chris@147 25 * Base class for models containing dense two-dimensional data (value
Chris@147 26 * against time) that may be meaningfully represented in a zoomed view
Chris@147 27 * using min/max range summaries. Audio waveform data is an obvious
Chris@147 28 * example: think "peaks and minima" for "ranges".
Chris@147 29 */
Chris@147 30
Chris@179 31 class RangeSummarisableTimeValueModel : public DenseTimeValueModel
Chris@147 32 {
Chris@147 33 Q_OBJECT
Chris@147 34
Chris@147 35 public:
Chris@319 36 RangeSummarisableTimeValueModel() { }
Chris@297 37
Chris@410 38 #define RANGE_USE_SHORT 1
Chris@410 39 #ifdef RANGE_USE_SHORT
Chris@410 40 class Range
Chris@147 41 {
Chris@410 42 public:
Chris@147 43 Range() :
Chris@410 44 m_min(0), m_max(0), m_absmean(0) { }
Chris@147 45 Range(const Range &r) :
Chris@410 46 m_min(r.m_min), m_max(r.m_max), m_absmean(r.m_absmean) { }
Chris@410 47 Range(float min, float max, float absmean)
Chris@410 48 { setMin(min); setMax(max); setAbsmean(absmean); }
Chris@410 49
Chris@410 50 float min() const { return i2f(m_min); }
Chris@410 51 float max() const { return i2f(m_max); }
Chris@410 52 float absmean() const { return i2f(m_absmean); }
Chris@410 53
Chris@410 54 void setMin(float min) { m_min = f2i(min); }
Chris@410 55 void setMax(float max) { m_max = f2i(max); }
Chris@410 56 void setAbsmean(float absmean) { m_absmean = f2i(absmean); }
Chris@410 57
Chris@410 58 private:
Chris@410 59 static inline int16_t f2i(float f) {
Chris@410 60 if (f > 1.f) f = 1.f;
Chris@410 61 if (f < -1.f) f = -1.f;
Chris@410 62 return int16_t(f * 32767.f);
Chris@410 63 }
Chris@410 64 static inline float i2f(int16_t i) {
Chris@410 65 return float(i) / 32767.f;
Chris@410 66 }
Chris@410 67
Chris@410 68 int16_t m_min;
Chris@410 69 int16_t m_max;
Chris@410 70 int16_t m_absmean;
Chris@147 71 };
Chris@410 72 #else
Chris@410 73 class Range
Chris@410 74 {
Chris@410 75 public:
Chris@410 76 Range() :
Chris@410 77 m_min(0.f), m_max(0.f), m_absmean(0.f) { }
Chris@410 78 Range(const Range &r) :
Chris@410 79 m_min(r.m_min), m_max(r.m_max), m_absmean(r.m_absmean) { }
Chris@410 80 Range(float min, float max, float absmean) :
Chris@410 81 m_min(min), m_max(max), m_absmean(absmean) { }
Chris@410 82
Chris@410 83 float min() const { return m_min; }
Chris@410 84 float max() const { return m_max; }
Chris@410 85 float absmean() const { return m_absmean; }
Chris@410 86
Chris@410 87 void setMin(float min) { m_min = min; }
Chris@410 88 void setMax(float max) { m_max = max; }
Chris@410 89 void setAbsmean(float absmean) { m_absmean = absmean; }
Chris@410 90
Chris@410 91 private:
Chris@410 92 float m_min;
Chris@410 93 float m_max;
Chris@410 94 float m_absmean;
Chris@410 95 };
Chris@410 96 #endif
Chris@147 97
Chris@147 98 typedef std::vector<Range> RangeBlock;
Chris@147 99
Chris@147 100 /**
Chris@300 101 * Return ranges from the given start frame, corresponding to the
Chris@300 102 * given number of underlying sample frames, summarised at the
Chris@300 103 * given block size. duration / blockSize ranges should ideally
Chris@300 104 * be returned.
Chris@147 105 *
Chris@147 106 * If the given block size is not supported by this model
Chris@147 107 * (according to its zoom constraint), also modify the blockSize
Chris@147 108 * parameter so as to return the block size that was actually
Chris@147 109 * obtained.
Chris@147 110 */
Chris@300 111 virtual void getSummaries(size_t channel, size_t start, size_t count,
Chris@300 112 RangeBlock &ranges,
Chris@300 113 size_t &blockSize) const = 0;
Chris@147 114
Chris@147 115 /**
Chris@300 116 * Return the range from the given start frame, corresponding to
Chris@300 117 * the given number of underlying sample frames, summarised at a
Chris@300 118 * block size equal to the distance between start and end frames.
Chris@147 119 */
Chris@300 120 virtual Range getSummary(size_t channel, size_t start, size_t count) const = 0;
Chris@345 121
Chris@377 122 virtual size_t getSummaryBlockSize(size_t desired) const = 0;
Chris@377 123
Chris@345 124 QString getTypeName() const { return tr("Range-Summarisable Time-Value"); }
Chris@147 125 };
Chris@147 126
Chris@147 127 #endif
Chris@147 128