Mercurial > hg > svgui
view layer/SliceLayer.cpp @ 1408:c8a6fd3f9dff fix-static-analysis
Use nullptr throughout
| author | Chris Cannam |
|---|---|
| date | Mon, 26 Nov 2018 14:33:54 +0000 |
| parents | 10e768adaee5 |
| children | dbff4b290bf0 |
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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 2006-2007 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 "SliceLayer.h" #include "view/View.h" #include "base/AudioLevel.h" #include "base/RangeMapper.h" #include "base/RealTime.h" #include "ColourMapper.h" #include "ColourDatabase.h" #include "PaintAssistant.h" #include "base/Profiler.h" #include <QPainter> #include <QPainterPath> #include <QTextStream> SliceLayer::SliceLayer() : m_sliceableModel(nullptr), m_binAlignment(BinsSpanScalePoints), m_colourMap(int(ColourMapper::Ice)), m_colourInverted(false), m_energyScale(dBScale), m_samplingMode(SampleMean), m_plotStyle(PlotLines), m_binScale(LinearBins), m_normalize(false), m_threshold(0.0), m_initialThreshold(0.0), m_gain(1.0), m_minbin(0), m_maxbin(0), m_currentf0(0), m_currentf1(0) { } SliceLayer::~SliceLayer() { } void SliceLayer::setSliceableModel(const Model *model) { const DenseThreeDimensionalModel *sliceable = dynamic_cast<const DenseThreeDimensionalModel *>(model); if (model && !sliceable) { cerr << "WARNING: SliceLayer::setSliceableModel(" << model << "): model is not a DenseThreeDimensionalModel" << endl; } if (m_sliceableModel == sliceable) return; m_sliceableModel = sliceable; if (!m_sliceableModel) return; connectSignals(m_sliceableModel); if (m_minbin == 0 && m_maxbin == 0) { m_minbin = 0; m_maxbin = m_sliceableModel->getHeight(); } emit modelReplaced(); emit layerParametersChanged(); } void SliceLayer::sliceableModelReplaced(const Model *orig, const Model *replacement) { SVDEBUG << "SliceLayer::sliceableModelReplaced(" << orig << ", " << replacement << ")" << endl; if (orig == m_sliceableModel) { setSliceableModel (dynamic_cast<const DenseThreeDimensionalModel *>(replacement)); } } void SliceLayer::modelAboutToBeDeleted(Model *m) { SVDEBUG << "SliceLayer::modelAboutToBeDeleted(" << m << ")" << endl; if (m == m_sliceableModel) { setSliceableModel(nullptr); } } QString SliceLayer::getFeatureDescription(LayerGeometryProvider *v, QPoint &p) const { int minbin, maxbin, range; return getFeatureDescriptionAux(v, p, true, minbin, maxbin, range); } QString SliceLayer::getFeatureDescriptionAux(LayerGeometryProvider *v, QPoint &p, bool includeBinDescription, int &minbin, int &maxbin, int &range) const { minbin = 0; maxbin = 0; if (!m_sliceableModel) return ""; if (m_binAlignment == BinsSpanScalePoints) { minbin = int(getBinForX(v, p.x())); maxbin = int(getBinForX(v, p.x() + 1)); } else { minbin = int(getBinForX(v, p.x()) + 0.5); maxbin = int(getBinForX(v, p.x() + 1) + 0.5); } int mh = m_sliceableModel->getHeight(); if (minbin >= mh) minbin = mh - 1; if (maxbin >= mh) maxbin = mh - 1; if (minbin < 0) minbin = 0; if (maxbin < 0) maxbin = 0; sv_samplerate_t sampleRate = m_sliceableModel->getSampleRate(); sv_frame_t f0 = m_currentf0; sv_frame_t f1 = m_currentf1; RealTime rt0 = RealTime::frame2RealTime(f0, sampleRate); RealTime rt1 = RealTime::frame2RealTime(f1, sampleRate); range = int(f1 - f0 + 1); QString rtrangestr = QString("%1 s").arg((rt1 - rt0).toText().c_str()); if (includeBinDescription) { int i0 = minbin - m_minbin; int i1 = maxbin - m_minbin; float minvalue = 0.0; if (in_range_for(m_values, i0)) minvalue = m_values[i0]; float maxvalue = minvalue; if (in_range_for(m_values, i1)) maxvalue = m_values[i1]; if (minvalue > maxvalue) std::swap(minvalue, maxvalue); QString binstr; if (maxbin != minbin) { binstr = tr("%1 - %2").arg(minbin+1).arg(maxbin+1); } else { binstr = QString("%1").arg(minbin+1); } QString valuestr; if (maxvalue != minvalue) { valuestr = tr("%1 - %2").arg(minvalue).arg(maxvalue); } else { valuestr = QString("%1").arg(minvalue); } QString description = tr("Time:\t%1 - %2\nRange:\t%3 samples (%4)\nBin:\t%5\n%6 value:\t%7") .arg(QString::fromStdString(rt0.toText(true))) .arg(QString::fromStdString(rt1.toText(true))) .arg(range) .arg(rtrangestr) .arg(binstr) .arg(m_samplingMode == NearestSample ? tr("First") : m_samplingMode == SampleMean ? tr("Mean") : tr("Peak")) .arg(valuestr); return description; } else { QString description = tr("Time:\t%1 - %2\nRange:\t%3 samples (%4)") .arg(QString::fromStdString(rt0.toText(true))) .arg(QString::fromStdString(rt1.toText(true))) .arg(range) .arg(rtrangestr); return description; } } double SliceLayer::getXForBin(const LayerGeometryProvider *v, double bin) const { return getXForScalePoint(v, bin, m_minbin, m_maxbin); } double SliceLayer::getXForScalePoint(const LayerGeometryProvider *v, double p, double pmin, double pmax) const { double x = 0; int pw = v->getPaintWidth(); int origin = m_xorigins[v->getId()]; int w = pw - origin; if (w < 1) w = 1; if (pmax <= pmin) { pmax = pmin + 1.0; } if (p < pmin) p = pmin; if (p > pmax) p = pmax; if (m_binScale == LinearBins) { x = (w * (p - pmin)) / (pmax - pmin); } else { if (m_binScale == InvertedLogBins) { // stoopid p = pmax - p; } // The 0.8 here is an awkward compromise. Our x-coord is // proportional to log of bin number, with the x-coord "of a // bin" being that of the left edge of the bin range. We can't // start counting bins from 0, as that would give us x = -Inf // and hide the first bin entirely. But if we start from 1, we // are giving a lot of space to the first bin, which in most // display modes won't be used because the "point" location // for that bin is in the middle of it. Yet in some modes // we'll still want it. A compromise is to count our first bin // as "a bit less than 1", so that most of it is visible but a // bit is tactfully cropped at the left edge so it doesn't // take up so much space. const double origin = 0.8; // sometimes we are called with a pmin/pmax range that begins // before 0: in that situation, we shift everything along by // the difference between 0 and pmin before doing any other // calculations double reqdshift = 0.0; if (pmin < 0) reqdshift = -pmin; double pminlog = log10(pmin + reqdshift + origin); double pmaxlog = log10(pmax + reqdshift + origin); double plog = log10(p + reqdshift + origin); x = (w * (plog - pminlog)) / (pmaxlog - pminlog); /* cerr << "getXForScalePoint(" << p << "): pmin = " << pmin << ", pmax = " << pmax << ", w = " << w << ", reqdshift = " << reqdshift << ", pminlog = " << pminlog << ", pmaxlog = " << pmaxlog << ", plog = " << plog << " -> x = " << x << endl; */ if (m_binScale == InvertedLogBins) { // still stoopid x = w - x; } } return x + origin; } double SliceLayer::getBinForX(const LayerGeometryProvider *v, double x) const { return getScalePointForX(v, x, m_minbin, m_maxbin); } double SliceLayer::getScalePointForX(const LayerGeometryProvider *v, double x, double pmin, double pmax) const { double p = 0; int pw = v->getPaintWidth(); int origin = m_xorigins[v->getId()]; int w = pw - origin; if (w < 1) w = 1; x = x - origin; if (x < 0) x = 0; double eps = 1e-10; if (pmax <= pmin) { pmax = pmin + 1.0; } if (m_binScale == LinearBins) { p = pmin + eps + (x * (pmax - pmin)) / w; } else { if (m_binScale == InvertedLogBins) { x = w - x; } // See comments in getXForScalePoint const double origin = 0.8; double reqdshift = 0.0; if (pmin < 0) reqdshift = -pmin; double pminlog = log10(pmin + reqdshift + origin); double pmaxlog = log10(pmax + reqdshift + origin); double plog = pminlog + eps + (x * (pmaxlog - pminlog)) / w; p = pow(10.0, plog) - reqdshift - origin; if (m_binScale == InvertedLogBins) { p = pmax - p; } } return p; } double SliceLayer::getYForValue(const LayerGeometryProvider *v, double value, double &norm) const { norm = 0.0; if (m_yorigins.find(v->getId()) == m_yorigins.end()) return 0; value *= m_gain; int yorigin = m_yorigins[v->getId()]; int h = m_heights[v->getId()]; double thresh = getThresholdDb(); double y = 0.0; if (h <= 0) return y; switch (m_energyScale) { case dBScale: { double db = thresh; if (value > 0.0) db = 10.0 * log10(fabs(value)); if (db < thresh) db = thresh; norm = (db - thresh) / -thresh; y = yorigin - (double(h) * norm); break; } case MeterScale: y = AudioLevel::multiplier_to_preview(value, h); norm = double(y) / double(h); y = yorigin - y; break; case AbsoluteScale: value = fabs(value); #if (__GNUC__ >= 7) __attribute__ ((fallthrough)); #endif case LinearScale: default: norm = (value - m_threshold); if (norm < 0) norm = 0; y = yorigin - (double(h) * norm); break; } return y; } double SliceLayer::getValueForY(const LayerGeometryProvider *v, double y) const { double value = 0.0; if (m_yorigins.find(v->getId()) == m_yorigins.end()) return value; int yorigin = m_yorigins[v->getId()]; int h = m_heights[v->getId()]; double thresh = getThresholdDb(); if (h <= 0) return value; y = yorigin - y; switch (m_energyScale) { case dBScale: { double db = ((y / h) * -thresh) + thresh; value = pow(10.0, db/10.0); break; } case MeterScale: value = AudioLevel::preview_to_multiplier(int(lrint(y)), h); break; case LinearScale: case AbsoluteScale: default: value = y / h + m_threshold; } return value / m_gain; } void SliceLayer::paint(LayerGeometryProvider *v, QPainter &paint, QRect rect) const { if (!m_sliceableModel || !m_sliceableModel->isOK() || !m_sliceableModel->isReady()) return; Profiler profiler("SliceLayer::paint()"); paint.save(); paint.setRenderHint(QPainter::Antialiasing, true); paint.setBrush(Qt::NoBrush); if (v->getViewManager() && v->getViewManager()->shouldShowScaleGuides()) { if (!m_scalePoints.empty()) { paint.setPen(QColor(240, 240, 240)); //!!! and dark background? int ratio = int(round(double(v->getPaintHeight()) / m_scalePaintHeight)); for (int i = 0; i < (int)m_scalePoints.size(); ++i) { paint.drawLine(0, m_scalePoints[i] * ratio, rect.width(), m_scalePoints[i] * ratio); } } } int mh = m_sliceableModel->getHeight(); int bin0 = 0; if (m_maxbin > m_minbin) { mh = m_maxbin - m_minbin; bin0 = m_minbin; } if (m_plotStyle == PlotBlocks) { // Must use actual zero-width pen, too slow otherwise paint.setPen(QPen(getBaseQColor(), 0)); } else { // Similarly, if there are very many bins here, we use a // thinner pen QPen pen; if (mh < 10000) { pen = v->scalePen(QPen(getBaseQColor(), 0.8)); } else { pen = QPen(getBaseQColor(), 1); } paint.setPen(pen); } int xorigin = getVerticalScaleWidth(v, true, paint) + 1; m_xorigins[v->getId()] = xorigin; // for use in getFeatureDescription int yorigin = v->getPaintHeight() - getHorizontalScaleHeight(v, paint) - paint.fontMetrics().height(); int h = yorigin - paint.fontMetrics().height() - 8; m_yorigins[v->getId()] = yorigin; // for getYForValue etc m_heights[v->getId()] = h; if (h <= 0) return; QPainterPath path; int divisor = 0; m_values.clear(); for (int bin = 0; bin < mh; ++bin) { m_values.push_back(0.0); } sv_frame_t f0 = v->getCentreFrame(); int f0x = v->getXForFrame(f0); f0 = v->getFrameForX(f0x); sv_frame_t f1 = v->getFrameForX(f0x + 1); if (f1 > f0) --f1; // cerr << "centre frame " << v->getCentreFrame() << ", x " << f0x << ", f0 " << f0 << ", f1 " << f1 << endl; int res = m_sliceableModel->getResolution(); int col0 = int(f0 / res); int col1 = col0; if (m_samplingMode != NearestSample) col1 = int(f1 / res); f0 = col0 * res; f1 = (col1 + 1) * res - 1; // cerr << "resolution " << res << ", col0 " << col0 << ", col1 " << col1 << ", f0 " << f0 << ", f1 " << f1 << endl; // cerr << "mh = " << mh << endl; m_currentf0 = f0; m_currentf1 = f1; BiasCurve curve; getBiasCurve(curve); int cs = int(curve.size()); for (int col = col0; col <= col1; ++col) { DenseThreeDimensionalModel::Column column = m_sliceableModel->getColumn(col); for (int bin = 0; bin < mh; ++bin) { float value = column[bin0 + bin]; if (bin < cs) value *= curve[bin]; if (m_samplingMode == SamplePeak) { if (value > m_values[bin]) m_values[bin] = value; } else { m_values[bin] += value; } } ++divisor; } float max = 0.0; for (int bin = 0; bin < mh; ++bin) { if (m_samplingMode == SampleMean && divisor > 0) { m_values[bin] /= float(divisor); } if (m_values[bin] > max) max = m_values[bin]; } if (max != 0.0 && m_normalize) { for (int bin = 0; bin < mh; ++bin) { m_values[bin] /= max; } } ColourMapper mapper(m_colourMap, m_colourInverted, 0, 1); double ytop = 0, ybottom = 0; bool firstBinOfPixel = true; QColor prevColour = v->getBackground(); double prevYtop = 0; double xleft = -1, xmiddle = -1, xright = -1; double prevXmiddle = 0; for (int bin = 0; bin < mh; ++bin) { if (m_binAlignment == BinsSpanScalePoints) { if (xright >= 0) xleft = xright; // previous value of else xleft = getXForBin(v, bin0 + bin); xmiddle = getXForBin(v, bin0 + bin + 0.5); xright = getXForBin(v, bin0 + bin + 1); } else { if (xright >= 0) xleft = xright; // previous value of else xleft = getXForBin(v, bin0 + bin - 0.5); xmiddle = getXForBin(v, bin0 + bin); xright = getXForBin(v, bin0 + bin + 0.5); } double value = m_values[bin]; double norm = 0.0; double y = getYForValue(v, value, norm); if (y < ytop || firstBinOfPixel) { ytop = y; } if (y > ybottom || firstBinOfPixel) { ybottom = y; } if (int(xright) != int(xleft) || bin+1 == mh) { if (m_plotStyle == PlotLines) { if (bin == 0) { path.moveTo(xmiddle, y); } else { if (ytop != ybottom) { path.lineTo(xmiddle, ybottom); path.lineTo(xmiddle, ytop); path.moveTo(xmiddle, ybottom); } else { path.lineTo(xmiddle, ytop); } } } else if (m_plotStyle == PlotSteps) { if (bin == 0) { path.moveTo(xleft, y); } else { path.lineTo(xleft, ytop); } path.lineTo(xright, ytop); } else if (m_plotStyle == PlotBlocks) { // work in pixel coords here, as we don't want the // vertical edges to be antialiased path.moveTo(QPoint(int(xleft), int(yorigin))); path.lineTo(QPoint(int(xleft), int(ytop))); path.lineTo(QPoint(int(xright), int(ytop))); path.lineTo(QPoint(int(xright), int(yorigin))); path.lineTo(QPoint(int(xleft), int(yorigin))); } else if (m_plotStyle == PlotFilledBlocks) { QColor c = mapper.map(norm); paint.setPen(Qt::NoPen); // work in pixel coords here, as we don't want the // vertical edges to be antialiased if (xright > xleft + 1) { QVector<QPoint> pp; if (bin > 0) { paint.setBrush(prevColour); pp.clear(); pp << QPoint(int(prevXmiddle), int(yorigin)); pp << QPoint(int(prevXmiddle), int(prevYtop)); pp << QPoint(int((xmiddle + prevXmiddle) / 2), int((ytop + prevYtop) / 2)); pp << QPoint(int((xmiddle + prevXmiddle) / 2), int(yorigin)); paint.drawConvexPolygon(QPolygon(pp)); paint.setBrush(c); pp.clear(); pp << QPoint(int((xmiddle + prevXmiddle) / 2), int(yorigin)); pp << QPoint(int((xmiddle + prevXmiddle) / 2), int((ytop + prevYtop) / 2)); pp << QPoint(int(xmiddle), int(ytop)); pp << QPoint(int(xmiddle), int(yorigin)); paint.drawConvexPolygon(QPolygon(pp)); } prevColour = c; prevYtop = ytop; } else { paint.fillRect(QRect(int(xleft), int(ytop), int(xright) - int(xleft), int(yorigin) - int(ytop)), c); } prevXmiddle = xmiddle; } firstBinOfPixel = true; } else { firstBinOfPixel = false; } } if (m_plotStyle != PlotFilledBlocks) { paint.drawPath(path); } paint.restore(); } int SliceLayer::getVerticalScaleWidth(LayerGeometryProvider *, bool, QPainter &paint) const { int width; if (m_energyScale == LinearScale || m_energyScale == AbsoluteScale) { width = std::max(paint.fontMetrics().width("0.0") + 13, paint.fontMetrics().width("x10-10")); } else { width = std::max(paint.fontMetrics().width(tr("0dB")), paint.fontMetrics().width(tr("-Inf"))) + 13; } return width; } void SliceLayer::paintVerticalScale(LayerGeometryProvider *v, bool, QPainter &paint, QRect rect) const { double thresh = m_threshold; if (m_energyScale != LinearScale && m_energyScale != AbsoluteScale) { thresh = AudioLevel::dB_to_multiplier(getThresholdDb()); } // int h = (rect.height() * 3) / 4; // int y = (rect.height() / 2) - (h / 2); int yorigin = v->getPaintHeight() - getHorizontalScaleHeight(v, paint) - paint.fontMetrics().height(); int h = yorigin - paint.fontMetrics().height() - 8; if (h < 0) return; QRect actual(rect.x(), rect.y() + yorigin - h, rect.width(), h); int mult = 1; PaintAssistant::paintVerticalLevelScale (paint, actual, thresh, 1.0 / m_gain, PaintAssistant::Scale(m_energyScale), mult, const_cast<std::vector<int> *>(&m_scalePoints)); // Ugly hack (but then everything about this scale drawing is a // bit ugly). In pixel-doubling hi-dpi scenarios, the scale is // painted at pixel-doubled resolution but we do explicit // pixel-doubling ourselves when painting the layer content. We // make a note of this here so that we can compare with the // equivalent dimension in the paint method when deciding where to // place scale continuation lines. m_scalePaintHeight = v->getPaintHeight(); if (mult != 1 && mult != 0) { int log = int(lrint(log10(mult))); QString a = tr("x10"); QString b = QString("%1").arg(-log); paint.drawText(3, 8 + paint.fontMetrics().ascent(), a); paint.drawText(3 + paint.fontMetrics().width(a), 3 + paint.fontMetrics().ascent(), b); } } bool SliceLayer::hasLightBackground() const { if (usesSolidColour()) { ColourMapper mapper(m_colourMap, m_colourInverted, 0, 1); return mapper.hasLightBackground(); } else { return SingleColourLayer::hasLightBackground(); } } Layer::PropertyList SliceLayer::getProperties() const { PropertyList list = SingleColourLayer::getProperties(); list.push_back("Bin Scale"); list.push_back("Plot Type"); list.push_back("Scale"); list.push_back("Normalize"); list.push_back("Threshold"); list.push_back("Gain"); return list; } QString SliceLayer::getPropertyLabel(const PropertyName &name) const { if (name == "Plot Type") return tr("Plot Type"); if (name == "Scale") return tr("Scale"); if (name == "Normalize") return tr("Normalize"); if (name == "Threshold") return tr("Threshold"); if (name == "Gain") return tr("Gain"); if (name == "Sampling Mode") return tr("Sampling Mode"); if (name == "Bin Scale") return tr("Bin Scale"); return SingleColourLayer::getPropertyLabel(name); } QString SliceLayer::getPropertyIconName(const PropertyName &name) const { if (name == "Normalize") return "normalise"; return ""; } Layer::PropertyType SliceLayer::getPropertyType(const PropertyName &name) const { if (name == "Gain") return RangeProperty; if (name == "Normalize") return ToggleProperty; if (name == "Threshold") return RangeProperty; if (name == "Plot Type") return ValueProperty; if (name == "Scale") return ValueProperty; if (name == "Sampling Mode") return ValueProperty; if (name == "Bin Scale") return ValueProperty; if (name == "Colour" && usesSolidColour()) return ColourMapProperty; return SingleColourLayer::getPropertyType(name); } QString SliceLayer::getPropertyGroupName(const PropertyName &name) const { if (name == "Scale" || name == "Normalize" || name == "Sampling Mode" || name == "Threshold" || name == "Gain") return tr("Scale"); if (name == "Plot Type" || name == "Bin Scale") return tr("Bins"); return SingleColourLayer::getPropertyGroupName(name); } int SliceLayer::getPropertyRangeAndValue(const PropertyName &name, int *min, int *max, int *deflt) const { int val = 0; int garbage0, garbage1, garbage2; if (!min) min = &garbage0; if (!max) max = &garbage1; if (!deflt) deflt = &garbage2; if (name == "Gain") { *min = -50; *max = 50; *deflt = 0; // cerr << "gain is " << m_gain << ", mode is " << m_samplingMode << endl; val = int(lrint(log10(m_gain) * 20.0)); if (val < *min) val = *min; if (val > *max) val = *max; } else if (name == "Threshold") { *min = -80; *max = 0; *deflt = int(lrint(AudioLevel::multiplier_to_dB(m_initialThreshold))); if (*deflt < *min) *deflt = *min; if (*deflt > *max) *deflt = *max; val = int(lrint(AudioLevel::multiplier_to_dB(m_threshold))); if (val < *min) val = *min; if (val > *max) val = *max; } else if (name == "Normalize") { val = (m_normalize ? 1 : 0); *deflt = 0; } else if (name == "Colour" && usesSolidColour()) { *min = 0; *max = ColourMapper::getColourMapCount() - 1; *deflt = int(ColourMapper::Ice); val = m_colourMap; } else if (name == "Scale") { *min = 0; *max = 3; *deflt = (int)dBScale; val = (int)m_energyScale; } else if (name == "Sampling Mode") { *min = 0; *max = 2; *deflt = (int)SampleMean; val = (int)m_samplingMode; } else if (name == "Plot Type") { *min = 0; *max = 3; *deflt = (int)PlotSteps; val = (int)m_plotStyle; } else if (name == "Bin Scale") { *min = 0; *max = 2; *deflt = (int)LinearBins; // *max = 1; // I don't think we really do want to offer inverted log val = (int)m_binScale; } else { val = SingleColourLayer::getPropertyRangeAndValue(name, min, max, deflt); } return val; } QString SliceLayer::getPropertyValueLabel(const PropertyName &name, int value) const { if (name == "Colour" && usesSolidColour()) { return ColourMapper::getColourMapLabel(value); } if (name == "Scale") { switch (value) { default: case 0: return tr("Linear"); case 1: return tr("Meter"); case 2: return tr("Log"); case 3: return tr("Absolute"); } } if (name == "Sampling Mode") { switch (value) { default: case 0: return tr("Any"); case 1: return tr("Mean"); case 2: return tr("Peak"); } } if (name == "Plot Type") { switch (value) { default: case 0: return tr("Lines"); case 1: return tr("Steps"); case 2: return tr("Blocks"); case 3: return tr("Colours"); } } if (name == "Bin Scale") { switch (value) { default: case 0: return tr("Linear"); case 1: return tr("Log"); case 2: return tr("Rev Log"); } } return SingleColourLayer::getPropertyValueLabel(name, value); } RangeMapper * SliceLayer::getNewPropertyRangeMapper(const PropertyName &name) const { if (name == "Gain") { return new LinearRangeMapper(-50, 50, -25, 25, tr("dB")); } if (name == "Threshold") { return new LinearRangeMapper(-80, 0, -80, 0, tr("dB")); } return SingleColourLayer::getNewPropertyRangeMapper(name); } void SliceLayer::setProperty(const PropertyName &name, int value) { if (name == "Gain") { setGain(powf(10, float(value)/20.0f)); } else if (name == "Threshold") { if (value == -80) setThreshold(0.0f); else setThreshold(float(AudioLevel::dB_to_multiplier(value))); } else if (name == "Colour" && usesSolidColour()) { setFillColourMap(value); } else if (name == "Scale") { switch (value) { default: case 0: setEnergyScale(LinearScale); break; case 1: setEnergyScale(MeterScale); break; case 2: setEnergyScale(dBScale); break; case 3: setEnergyScale(AbsoluteScale); break; } } else if (name == "Plot Type") { setPlotStyle(PlotStyle(value)); } else if (name == "Sampling Mode") { switch (value) { default: case 0: setSamplingMode(NearestSample); break; case 1: setSamplingMode(SampleMean); break; case 2: setSamplingMode(SamplePeak); break; } } else if (name == "Bin Scale") { switch (value) { default: case 0: setBinScale(LinearBins); break; case 1: setBinScale(LogBins); break; case 2: setBinScale(InvertedLogBins); break; } } else if (name == "Normalize") { setNormalize(value ? true : false); } else { SingleColourLayer::setProperty(name, value); } } void SliceLayer::setFillColourMap(int map) { if (m_colourMap == map) return; m_colourMap = map; emit layerParametersChanged(); } void SliceLayer::setEnergyScale(EnergyScale scale) { if (m_energyScale == scale) return; m_energyScale = scale; emit layerParametersChanged(); } void SliceLayer::setSamplingMode(SamplingMode mode) { if (m_samplingMode == mode) return; m_samplingMode = mode; emit layerParametersChanged(); } void SliceLayer::setPlotStyle(PlotStyle style) { if (m_plotStyle == style) return; bool colourTypeChanged = (style == PlotFilledBlocks || m_plotStyle == PlotFilledBlocks); m_plotStyle = style; if (colourTypeChanged) { emit layerParameterRangesChanged(); } emit layerParametersChanged(); } void SliceLayer::setBinScale(BinScale scale) { if (m_binScale == scale) return; m_binScale = scale; emit layerParametersChanged(); } void SliceLayer::setNormalize(bool n) { if (m_normalize == n) return; m_normalize = n; emit layerParametersChanged(); } void SliceLayer::setThreshold(float thresh) { if (m_threshold == thresh) return; m_threshold = thresh; emit layerParametersChanged(); } void SliceLayer::setGain(float gain) { if (m_gain == gain) return; m_gain = gain; emit layerParametersChanged(); } float SliceLayer::getThresholdDb() const { if (m_threshold == 0.0) return -80.f; float db = float(AudioLevel::multiplier_to_dB(m_threshold)); return db; } int SliceLayer::getDefaultColourHint(bool darkbg, bool &impose) { impose = false; return ColourDatabase::getInstance()->getColourIndex (QString(darkbg ? "Bright Blue" : "Blue")); } void SliceLayer::toXml(QTextStream &stream, QString indent, QString extraAttributes) const { QString s; s += QString("energyScale=\"%1\" " "samplingMode=\"%2\" " "plotStyle=\"%3\" " "binScale=\"%4\" " "gain=\"%5\" " "threshold=\"%6\" " "normalize=\"%7\" %8 ") .arg(m_energyScale) .arg(m_samplingMode) .arg(m_plotStyle) .arg(m_binScale) .arg(m_gain) .arg(m_threshold) .arg(m_normalize ? "true" : "false") .arg(QString("minbin=\"%1\" " "maxbin=\"%2\"") .arg(m_minbin) .arg(m_maxbin)); // New-style colour map attribute, by string id rather than by // number s += QString("fillColourMap=\"%1\" ") .arg(ColourMapper::getColourMapId(m_colourMap)); // Old-style colour map attribute s += QString("colourScheme=\"%1\" ") .arg(ColourMapper::getBackwardCompatibilityColourMap(m_colourMap)); SingleColourLayer::toXml(stream, indent, extraAttributes + " " + s); } void SliceLayer::setProperties(const QXmlAttributes &attributes) { bool ok = false; SingleColourLayer::setProperties(attributes); EnergyScale scale = (EnergyScale) attributes.value("energyScale").toInt(&ok); if (ok) setEnergyScale(scale); SamplingMode mode = (SamplingMode) attributes.value("samplingMode").toInt(&ok); if (ok) setSamplingMode(mode); QString colourMapId = attributes.value("fillColourMap"); int colourMap = ColourMapper::getColourMapById(colourMapId); if (colourMap >= 0) { setFillColourMap(colourMap); } else { colourMap = attributes.value("colourScheme").toInt(&ok); if (ok && colourMap < ColourMapper::getColourMapCount()) { setFillColourMap(colourMap); } } PlotStyle s = (PlotStyle) attributes.value("plotStyle").toInt(&ok); if (ok) setPlotStyle(s); BinScale b = (BinScale) attributes.value("binScale").toInt(&ok); if (ok) setBinScale(b); float gain = attributes.value("gain").toFloat(&ok); if (ok) setGain(gain); float threshold = attributes.value("threshold").toFloat(&ok); if (ok) setThreshold(threshold); bool normalize = (attributes.value("normalize").trimmed() == "true"); setNormalize(normalize); bool alsoOk = false; float min = attributes.value("minbin").toFloat(&ok); float max = attributes.value("maxbin").toFloat(&alsoOk); if (ok && alsoOk) setDisplayExtents(min, max); } bool SliceLayer::getValueExtents(double &min, double &max, bool &logarithmic, QString &unit) const { if (!m_sliceableModel) return false; min = 0; max = double(m_sliceableModel->getHeight()); logarithmic = (m_binScale == BinScale::LogBins); unit = ""; return true; } bool SliceLayer::getDisplayExtents(double &min, double &max) const { if (!m_sliceableModel) return false; double hmax = double(m_sliceableModel->getHeight()); min = m_minbin; max = m_maxbin; if (max <= min) { min = 0; max = hmax; } if (min < 0) min = 0; if (max > hmax) max = hmax; return true; } bool SliceLayer::setDisplayExtents(double min, double max) { if (!m_sliceableModel) return false; m_minbin = int(lrint(min)); m_maxbin = int(lrint(max)); if (m_minbin < 0) { m_minbin = 0; } if (m_maxbin < 0) { m_maxbin = 0; } if (m_minbin > m_sliceableModel->getHeight()) { m_minbin = m_sliceableModel->getHeight(); } if (m_maxbin > m_sliceableModel->getHeight()) { m_maxbin = m_sliceableModel->getHeight(); } if (m_maxbin < m_minbin) { m_maxbin = m_minbin; } emit layerParametersChanged(); return true; } int SliceLayer::getVerticalZoomSteps(int &defaultStep) const { if (!m_sliceableModel) return 0; defaultStep = 0; int h = m_sliceableModel->getHeight(); return h; } int SliceLayer::getCurrentVerticalZoomStep() const { if (!m_sliceableModel) return 0; double min, max; getDisplayExtents(min, max); return m_sliceableModel->getHeight() - int(lrint(max - min)); } void SliceLayer::setVerticalZoomStep(int step) { if (!m_sliceableModel) return; // SVDEBUG << "SliceLayer::setVerticalZoomStep(" <<step <<"): before: minbin = " << m_minbin << ", maxbin = " << m_maxbin << endl; int dist = m_sliceableModel->getHeight() - step; if (dist < 1) dist = 1; double centre = m_minbin + (m_maxbin - m_minbin) / 2.0; int minbin = int(lrint(centre - dist/2.0)); int maxbin = minbin + dist; setDisplayExtents(minbin, maxbin); } RangeMapper * SliceLayer::getNewVerticalZoomRangeMapper() const { if (!m_sliceableModel) return nullptr; return new LinearRangeMapper(0, m_sliceableModel->getHeight(), 0, m_sliceableModel->getHeight(), ""); } void SliceLayer::zoomToRegion(const LayerGeometryProvider *v, QRect rect) { double bin0 = getBinForX(v, rect.x()); double bin1 = getBinForX(v, rect.x() + rect.width()); // ignore y for now... SVDEBUG << "SliceLayer::zoomToRegion: zooming to bin range " << bin0 << " -> " << bin1 << endl; setDisplayExtents(floor(bin0), ceil(bin1)); }