Mercurial > hg > svcore
view base/RangeMapper.h @ 1385:b061b9f8fca5
Debug notes, tidying
author | Chris Cannam |
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date | Thu, 23 Feb 2017 09:22:56 +0000 |
parents | 35387a99c236 |
children | bd73a689c8af |
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/* -*- 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 QMUL. 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 _RANGE_MAPPER_H_ #define _RANGE_MAPPER_H_ #include <QString> #include "Debug.h" #include <map> class RangeMapper { public: virtual ~RangeMapper() { } /** * Return the position that maps to the given value, rounding to * the nearest position and clamping to the minimum and maximum * extents of the mapper's positional range. */ virtual int getPositionForValue(double value) const = 0; /** * Return the position that maps to the given value, rounding to * the nearest position, without clamping. That is, whatever * mapping function is in use will be projected even outside the * minimum and maximum extents of the mapper's positional * range. (The mapping outside that range is not guaranteed to be * exact, except if the mapper is a linear one.) */ virtual int getPositionForValueUnclamped(double value) const = 0; /** * Return the value mapped from the given position, clamping to * the minimum and maximum extents of the mapper's value range. */ virtual double getValueForPosition(int position) const = 0; /** * Return the value mapped from the given position, without * clamping. That is, whatever mapping function is in use will be * projected even outside the minimum and maximum extents of the * mapper's value range. (The mapping outside that range is not * guaranteed to be exact, except if the mapper is a linear one.) */ virtual double getValueForPositionUnclamped(int position) const = 0; /** * Get the unit of the mapper's value range. */ virtual QString getUnit() const { return ""; } /** * The mapper may optionally provide special labels for one or * more individual positions (such as the minimum position, the * default, or indeed all positions). These should be used in any * display context in preference to just showing the numerical * value for the position. If a position has such a label, return * it here. */ virtual QString getLabel(int /* position */) const { return ""; } }; class LinearRangeMapper : public RangeMapper { public: /** * Map values in range minval->maxval linearly into integer range * minpos->maxpos. minval and minpos must be less than maxval and * maxpos respectively. If inverted is true, the range will be * mapped "backwards" (minval to maxpos and maxval to minpos). */ LinearRangeMapper(int minpos, int maxpos, double minval, double maxval, QString unit = "", bool inverted = false, std::map<int, QString> labels = {}); virtual int getPositionForValue(double value) const; virtual int getPositionForValueUnclamped(double value) const; virtual double getValueForPosition(int position) const; virtual double getValueForPositionUnclamped(int position) const; virtual QString getUnit() const { return m_unit; } virtual QString getLabel(int position) const; protected: int m_minpos; int m_maxpos; double m_minval; double m_maxval; QString m_unit; bool m_inverted; std::map<int, QString> m_labels; }; class LogRangeMapper : public RangeMapper { public: /** * Map values in range minval->maxval into integer range * minpos->maxpos such that logs of the values are mapped * linearly. minval must be greater than zero, and minval and * minpos must be less than maxval and maxpos respectively. If * inverted is true, the range will be mapped "backwards" (minval * to maxpos and maxval to minpos). */ LogRangeMapper(int minpos, int maxpos, double minval, double maxval, QString m_unit = "", bool inverted = false); static void convertRatioMinLog(double ratio, double minlog, int minpos, int maxpos, double &minval, double &maxval); static void convertMinMax(int minpos, int maxpos, double minval, double maxval, double &ratio, double &minlog); virtual int getPositionForValue(double value) const; virtual int getPositionForValueUnclamped(double value) const; virtual double getValueForPosition(int position) const; virtual double getValueForPositionUnclamped(int position) const; virtual QString getUnit() const { return m_unit; } protected: int m_minpos; int m_maxpos; double m_ratio; double m_minlog; double m_maxlog; QString m_unit; bool m_inverted; }; class InterpolatingRangeMapper : public RangeMapper { public: typedef std::map<double, int> CoordMap; /** * Given a series of (value, position) coordinate mappings, * construct a range mapper that maps arbitrary values, in the * range between minimum and maximum of the provided values, onto * coordinates using linear interpolation between the supplied * points. * *!!! todo: Cubic -- more generally useful than linear interpolation *!!! todo: inverted flag * * The set of provided mappings must contain at least two * coordinates. * * It is expected that the values and positions in the coordinate * mappings will both be monotonically increasing (i.e. no * inflections in the mapping curve). Behaviour is undefined if * this is not the case. */ InterpolatingRangeMapper(CoordMap pointMappings, QString unit); virtual int getPositionForValue(double value) const; virtual int getPositionForValueUnclamped(double value) const; virtual double getValueForPosition(int position) const; virtual double getValueForPositionUnclamped(int position) const; virtual QString getUnit() const { return m_unit; } protected: CoordMap m_mappings; std::map<int, double> m_reverse; QString m_unit; template <typename T> double interpolate(T *mapping, double v) const; }; class AutoRangeMapper : public RangeMapper { public: enum MappingType { Interpolating, StraightLine, Logarithmic, }; typedef std::map<double, int> CoordMap; /** * Given a series of (value, position) coordinate mappings, * construct a range mapper that maps arbitrary values, in the * range between minimum and maximum of the provided values, onto * coordinates. * * The mapping used may be * * Interpolating -- an InterpolatingRangeMapper will be used * * StraightLine -- a LinearRangeMapper from the minimum to * maximum value coordinates will be used, ignoring all other * supplied coordinate mappings * * Logarithmic -- a LogRangeMapper from the minimum to * maximum value coordinates will be used, ignoring all other * supplied coordinate mappings * * The mapping will be chosen automatically by looking at the * supplied coordinates. If the supplied coordinates fall on a * straight line, a StraightLine mapping will be used; if they * fall on a log curve, a Logarithmic mapping will be used; * otherwise an Interpolating mapping will be used. * *!!! todo: inverted flag * * The set of provided mappings must contain at least two * coordinates, or at least three if the points are not supposed * to be in a straight line. * * It is expected that the values and positions in the coordinate * mappings will both be monotonically increasing (i.e. no * inflections in the mapping curve). Behaviour is undefined if * this is not the case. */ AutoRangeMapper(CoordMap pointMappings, QString unit); ~AutoRangeMapper(); /** * Return the mapping type in use. */ MappingType getType() const { return m_type; } virtual int getPositionForValue(double value) const; virtual int getPositionForValueUnclamped(double value) const; virtual double getValueForPosition(int position) const; virtual double getValueForPositionUnclamped(int position) const; virtual QString getUnit() const { return m_unit; } protected: MappingType m_type; CoordMap m_mappings; QString m_unit; RangeMapper *m_mapper; MappingType chooseMappingTypeFor(const CoordMap &); }; #endif