Mercurial > hg > svgui
view layer/ColourMapper.cpp @ 1245:f0e291fa7b9c
Use Range01 normalisation in Colour 3D Plot. This gives us the same column normalisation behaviour as in 2.5 (better than the Max1 option).
| author | Chris Cannam |
|---|---|
| date | Tue, 28 Feb 2017 14:06:24 +0000 |
| parents | 73d43e410a6b |
| children | 6e724c81f18f |
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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 2006-2016 Chris Cannam and 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. */ #include "ColourMapper.h" #include <iostream> #include <cmath> #include "base/Debug.h" #include <vector> #include <QPainter> using namespace std; static vector<QColor> convertStrings(const vector<QString> &strs) { vector<QColor> converted; for (const auto &s: strs) converted.push_back(QColor(s)); reverse(converted.begin(), converted.end()); return converted; } static vector<QColor> ice = convertStrings({ // Based on ColorBrewer ylGnBu "#ffffff", "#ffff00", "#f7fcf0", "#e0f3db", "#ccebc5", "#a8ddb5", "#7bccc4", "#4eb3d3", "#2b8cbe", "#0868ac", "#084081", "#042040" }); static vector<QColor> cherry = convertStrings({ "#f7f7f7", "#fddbc7", "#f4a582", "#d6604d", "#b2182b", "#dd3497", "#ae017e", "#7a0177", "#49006a" }); static void mapDiscrete(double norm, vector<QColor> &colours, double &r, double &g, double &b) { int n = int(colours.size()); double m = norm * (n-1); if (m >= n-1) { colours[n-1].getRgbF(&r, &g, &b, 0); return; } if (m <= 0) { colours[0].getRgbF(&r, &g, &b, 0); return; } int base(int(floor(m))); double prop0 = (base + 1.0) - m, prop1 = m - base; QColor c0(colours[base]), c1(colours[base+1]); r = c0.redF() * prop0 + c1.redF() * prop1; g = c0.greenF() * prop0 + c1.greenF() * prop1; b = c0.blueF() * prop0 + c1.blueF() * prop1; } ColourMapper::ColourMapper(int map, double min, double max) : m_map(map), m_min(min), m_max(max) { if (m_min == m_max) { cerr << "WARNING: ColourMapper: min == max (== " << m_min << "), adjusting" << endl; m_max = m_min + 1; } } ColourMapper::~ColourMapper() { } int ColourMapper::getColourMapCount() { return 12; } QString ColourMapper::getColourMapName(int n) { if (n >= getColourMapCount()) return QObject::tr("<unknown>"); StandardMap map = (StandardMap)n; switch (map) { case Green: return QObject::tr("Green"); case WhiteOnBlack: return QObject::tr("White on Black"); case BlackOnWhite: return QObject::tr("Black on White"); case Cherry: return QObject::tr("Cherry"); case Wasp: return QObject::tr("Wasp"); case Ice: return QObject::tr("Ice"); case Sunset: return QObject::tr("Sunset"); case FruitSalad: return QObject::tr("Fruit Salad"); case Banded: return QObject::tr("Banded"); case Highlight: return QObject::tr("Highlight"); case Printer: return QObject::tr("Printer"); case HighGain: return QObject::tr("High Gain"); } return QObject::tr("<unknown>"); } QColor ColourMapper::map(double value) const { double norm = (value - m_min) / (m_max - m_min); if (norm < 0.0) norm = 0.0; if (norm > 1.0) norm = 1.0; double h = 0.0, s = 0.0, v = 0.0, r = 0.0, g = 0.0, b = 0.0; bool hsv = true; double blue = 0.6666, pieslice = 0.3333; if (m_map >= getColourMapCount()) return Qt::black; StandardMap map = (StandardMap)m_map; switch (map) { case Green: h = blue - norm * 2.0 * pieslice; s = 0.5f + norm/2.0; v = norm; break; case WhiteOnBlack: r = g = b = norm; hsv = false; break; case BlackOnWhite: r = g = b = 1.0 - norm; hsv = false; break; case Cherry: hsv = false; mapDiscrete(norm, cherry, r, g, b); break; case Wasp: h = 0.15; s = 1.0; v = norm; break; case Sunset: r = (norm - 0.24) * 2.38; if (r > 1.0) r = 1.0; if (r < 0.0) r = 0.0; g = (norm - 0.64) * 2.777; if (g > 1.0) g = 1.0; if (g < 0.0) g = 0.0; b = (3.6f * norm); if (norm > 0.277) b = 2.0 - b; if (b > 1.0) b = 1.0; if (b < 0.0) b = 0.0; hsv = false; break; case FruitSalad: h = blue + (pieslice/6.0) - norm; if (h < 0.0) h += 1.0; s = 1.0; v = 1.0; break; case Banded: if (norm < 0.125) return Qt::darkGreen; else if (norm < 0.25) return Qt::green; else if (norm < 0.375) return Qt::darkBlue; else if (norm < 0.5) return Qt::blue; else if (norm < 0.625) return Qt::darkYellow; else if (norm < 0.75) return Qt::yellow; else if (norm < 0.875) return Qt::darkRed; else return Qt::red; break; case Highlight: if (norm > 0.99) return Qt::white; else return Qt::darkBlue; case Printer: if (norm > 0.8) { r = 1.0; } else if (norm > 0.7) { r = 0.9; } else if (norm > 0.6) { r = 0.8; } else if (norm > 0.5) { r = 0.7; } else if (norm > 0.4) { r = 0.6; } else if (norm > 0.3) { r = 0.5; } else if (norm > 0.2) { r = 0.4; } else { r = 0.0; } r = g = b = 1.0 - r; hsv = false; break; case HighGain: if (norm <= 1.0 / 256.0) { norm = 0.0; } else { norm = 0.1f + (pow(((norm - 0.5) * 2.0), 3.0) + 1.0) / 2.081; } // now as for Sunset r = (norm - 0.24) * 2.38; if (r > 1.0) r = 1.0; if (r < 0.0) r = 0.0; g = (norm - 0.64) * 2.777; if (g > 1.0) g = 1.0; if (g < 0.0) g = 0.0; b = (3.6f * norm); if (norm > 0.277) b = 2.0 - b; if (b > 1.0) b = 1.0; if (b < 0.0) b = 0.0; hsv = false; /* if (r > 1.0) r = 1.0; r = g = b = 1.0 - r; hsv = false; */ break; case Ice: hsv = false; mapDiscrete(norm, ice, r, g, b); } if (hsv) { return QColor::fromHsvF(h, s, v); } else { return QColor::fromRgbF(r, g, b); } } QColor ColourMapper::getContrastingColour() const { if (m_map >= getColourMapCount()) return Qt::white; StandardMap map = (StandardMap)m_map; switch (map) { case Green: return QColor(255, 150, 50); case WhiteOnBlack: return Qt::red; case BlackOnWhite: return Qt::darkGreen; case Cherry: return Qt::green; case Wasp: return QColor::fromHsv(240, 255, 255); case Ice: return Qt::red; case Sunset: return Qt::white; case FruitSalad: return Qt::white; case Banded: return Qt::cyan; case Highlight: return Qt::red; case Printer: return Qt::red; case HighGain: return Qt::red; } return Qt::white; } bool ColourMapper::hasLightBackground() const { if (m_map >= getColourMapCount()) return false; StandardMap map = (StandardMap)m_map; switch (map) { case BlackOnWhite: case Printer: case HighGain: return true; case Green: case Sunset: case WhiteOnBlack: case Cherry: case Wasp: case Ice: case FruitSalad: case Banded: case Highlight: default: return false; } } QPixmap ColourMapper::getExamplePixmap(QSize size) const { QPixmap pmap(size); pmap.fill(Qt::white); QPainter paint(&pmap); int w = size.width(), h = size.height(); int margin = 2; if (w < 4 || h < 4) margin = 0; else if (w < 8 || h < 8) margin = 1; int n = w - margin*2; for (int x = 0; x < n; ++x) { double value = m_min + ((m_max - m_min) * x) / (n-1); QColor colour(map(value)); paint.setPen(colour); paint.drawLine(x + margin, margin, x + margin, h - margin); } return pmap; }