Mercurial > hg > svgui
view layer/TimeValueLayer.cpp @ 576:a4ba6c96b66d
* Make text labels in time instant layer more apparent (use drawVisibleText)
* Fix bug that caused time-instants in segmentation mode to come up white when zoomed far out
author | Chris Cannam |
---|---|
date | Mon, 25 Oct 2010 21:52:38 +0200 |
parents | 5bcfc5606528 |
children | f4960f8ce798 |
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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 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. */ #include "TimeValueLayer.h" #include "data/model/Model.h" #include "base/RealTime.h" #include "base/Profiler.h" #include "base/LogRange.h" #include "base/RangeMapper.h" #include "ColourDatabase.h" #include "view/View.h" #include "data/model/SparseTimeValueModel.h" #include "data/model/Labeller.h" #include "widgets/ItemEditDialog.h" #include "widgets/ListInputDialog.h" #include "ColourMapper.h" #include <QPainter> #include <QPainterPath> #include <QMouseEvent> #include <QRegExp> #include <QTextStream> #include <QMessageBox> #include <QInputDialog> #include <iostream> #include <cmath> //#define DEBUG_TIME_VALUE_LAYER 1 TimeValueLayer::TimeValueLayer() : SingleColourLayer(), m_model(0), m_editing(false), m_originalPoint(0, 0.0, tr("New Point")), m_editingPoint(0, 0.0, tr("New Point")), m_editingCommand(0), m_colourMap(0), m_plotStyle(PlotConnectedPoints), m_verticalScale(AutoAlignScale), m_drawSegmentDivisions(true), m_derivative(false), m_scaleMinimum(0), m_scaleMaximum(0) { } void TimeValueLayer::setModel(SparseTimeValueModel *model) { if (m_model == model) return; m_model = model; connectSignals(m_model); m_scaleMinimum = 0; m_scaleMaximum = 0; if (m_model && m_model->getRDFTypeURI().endsWith("Segment")) { setPlotStyle(PlotSegmentation); } if (m_model && m_model->getRDFTypeURI().endsWith("Change")) { setPlotStyle(PlotSegmentation); } #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::setModel(" << model << ")" << std::endl; #endif emit modelReplaced(); } Layer::PropertyList TimeValueLayer::getProperties() const { PropertyList list = SingleColourLayer::getProperties(); list.push_back("Plot Type"); list.push_back("Vertical Scale"); list.push_back("Scale Units"); list.push_back("Draw Segment Division Lines"); list.push_back("Show Derivative"); return list; } QString TimeValueLayer::getPropertyLabel(const PropertyName &name) const { if (name == "Plot Type") return tr("Plot Type"); if (name == "Vertical Scale") return tr("Vertical Scale"); if (name == "Scale Units") return tr("Scale Units"); if (name == "Draw Segment Division Lines") return tr("Draw Segment Division Lines"); if (name == "Show Derivative") return tr("Show Derivative"); return SingleColourLayer::getPropertyLabel(name); } QString TimeValueLayer::getPropertyIconName(const PropertyName &name) const { if (name == "Draw Segment Division Lines") return "lines"; if (name == "Show Derivative") return "derivative"; return ""; } Layer::PropertyType TimeValueLayer::getPropertyType(const PropertyName &name) const { if (name == "Plot Type") return ValueProperty; if (name == "Vertical Scale") return ValueProperty; if (name == "Scale Units") return UnitsProperty; if (name == "Colour" && m_plotStyle == PlotSegmentation) return ValueProperty; if (name == "Draw Segment Division Lines") return ToggleProperty; if (name == "Show Derivative") return ToggleProperty; return SingleColourLayer::getPropertyType(name); } QString TimeValueLayer::getPropertyGroupName(const PropertyName &name) const { if (name == "Vertical Scale" || name == "Scale Units") { return tr("Scale"); } if (name == "Plot Type" || name == "Draw Segment Division Lines" || name == "Show Derivative") { return tr("Plot Type"); } return SingleColourLayer::getPropertyGroupName(name); } int TimeValueLayer::getPropertyRangeAndValue(const PropertyName &name, int *min, int *max, int *deflt) const { int val = 0; if (name == "Colour" && m_plotStyle == PlotSegmentation) { if (min) *min = 0; if (max) *max = ColourMapper::getColourMapCount() - 1; if (deflt) *deflt = 0; val = m_colourMap; } else if (name == "Plot Type") { if (min) *min = 0; if (max) *max = 5; if (deflt) *deflt = int(PlotConnectedPoints); val = int(m_plotStyle); } else if (name == "Vertical Scale") { if (min) *min = 0; if (max) *max = 3; if (deflt) *deflt = int(AutoAlignScale); val = int(m_verticalScale); } else if (name == "Scale Units") { if (deflt) *deflt = 0; if (m_model) { val = UnitDatabase::getInstance()->getUnitId (m_model->getScaleUnits()); } } else if (name == "Draw Segment Division Lines") { if (min) *min = 0; if (max) *max = 0; if (deflt) *deflt = 1; val = (m_drawSegmentDivisions ? 1.0 : 0.0); } else if (name == "Show Derivative") { if (min) *min = 0; if (max) *max = 0; if (deflt) *deflt = 0; val = (m_derivative ? 1.0 : 0.0); } else { val = SingleColourLayer::getPropertyRangeAndValue(name, min, max, deflt); } return val; } QString TimeValueLayer::getPropertyValueLabel(const PropertyName &name, int value) const { if (name == "Colour" && m_plotStyle == PlotSegmentation) { return ColourMapper::getColourMapName(value); } else if (name == "Plot Type") { switch (value) { default: case 0: return tr("Points"); case 1: return tr("Stems"); case 2: return tr("Connected Points"); case 3: return tr("Lines"); case 4: return tr("Curve"); case 5: return tr("Segmentation"); } } else if (name == "Vertical Scale") { switch (value) { default: case 0: return tr("Auto-Align"); case 1: return tr("Linear"); case 2: return tr("Log"); case 3: return tr("+/-1"); } } return SingleColourLayer::getPropertyValueLabel(name, value); } void TimeValueLayer::setProperty(const PropertyName &name, int value) { if (name == "Colour" && m_plotStyle == PlotSegmentation) { setFillColourMap(value); } else if (name == "Plot Type") { setPlotStyle(PlotStyle(value)); } else if (name == "Vertical Scale") { setVerticalScale(VerticalScale(value)); } else if (name == "Scale Units") { if (m_model) { m_model->setScaleUnits (UnitDatabase::getInstance()->getUnitById(value)); emit modelChanged(); } } else if (name == "Draw Segment Division Lines") { setDrawSegmentDivisions(value > 0.5); } else if (name == "Show Derivative") { setShowDerivative(value > 0.5); } else { SingleColourLayer::setProperty(name, value); } } void TimeValueLayer::setFillColourMap(int map) { if (m_colourMap == map) return; m_colourMap = map; emit layerParametersChanged(); } void TimeValueLayer::setPlotStyle(PlotStyle style) { if (m_plotStyle == style) return; bool colourTypeChanged = (style == PlotSegmentation || m_plotStyle == PlotSegmentation); m_plotStyle = style; if (colourTypeChanged) { emit layerParameterRangesChanged(); } emit layerParametersChanged(); } void TimeValueLayer::setVerticalScale(VerticalScale scale) { if (m_verticalScale == scale) return; m_verticalScale = scale; emit layerParametersChanged(); } void TimeValueLayer::setDrawSegmentDivisions(bool draw) { if (m_drawSegmentDivisions == draw) return; m_drawSegmentDivisions = draw; emit layerParametersChanged(); } void TimeValueLayer::setShowDerivative(bool show) { if (m_derivative == show) return; m_derivative = show; emit layerParametersChanged(); } bool TimeValueLayer::isLayerScrollable(const View *v) const { // We don't illuminate sections in the line or curve modes, so // they're always scrollable if (m_plotStyle == PlotLines || m_plotStyle == PlotCurve) return true; QPoint discard; return !v->shouldIlluminateLocalFeatures(this, discard); } bool TimeValueLayer::getValueExtents(float &min, float &max, bool &logarithmic, QString &unit) const { if (!m_model) return false; min = m_model->getValueMinimum(); max = m_model->getValueMaximum(); logarithmic = (m_verticalScale == LogScale); unit = m_model->getScaleUnits(); if (m_derivative) { max = std::max(fabsf(min), fabsf(max)); min = -max; } return true; } bool TimeValueLayer::getDisplayExtents(float &min, float &max) const { if (!m_model || shouldAutoAlign()) return false; if (m_scaleMinimum == m_scaleMaximum) { min = m_model->getValueMinimum(); max = m_model->getValueMaximum(); } else { min = m_scaleMinimum; max = m_scaleMaximum; } if (m_derivative) { max = std::max(fabsf(min), fabsf(max)); min = -max; } #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::getDisplayExtents: min = " << min << ", max = " << max << std::endl; #endif return true; } bool TimeValueLayer::setDisplayExtents(float min, float max) { if (!m_model) return false; if (min == max) { if (min == 0.f) { max = 1.f; } else { max = min * 1.0001; } } m_scaleMinimum = min; m_scaleMaximum = max; #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::setDisplayExtents: min = " << min << ", max = " << max << std::endl; #endif emit layerParametersChanged(); return true; } int TimeValueLayer::getVerticalZoomSteps(int &defaultStep) const { if (shouldAutoAlign()) return 0; if (!m_model) return 0; defaultStep = 0; return 100; } int TimeValueLayer::getCurrentVerticalZoomStep() const { if (shouldAutoAlign()) return 0; if (!m_model) return 0; RangeMapper *mapper = getNewVerticalZoomRangeMapper(); if (!mapper) return 0; float dmin, dmax; getDisplayExtents(dmin, dmax); int nr = mapper->getPositionForValue(dmax - dmin); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::getCurrentVerticalZoomStep: dmin = " << dmin << ", dmax = " << dmax << ", nr = " << nr << std::endl; #endif delete mapper; return 100 - nr; } void TimeValueLayer::setVerticalZoomStep(int step) { if (shouldAutoAlign()) return; if (!m_model) return; RangeMapper *mapper = getNewVerticalZoomRangeMapper(); if (!mapper) return; float min, max; bool logarithmic; QString unit; getValueExtents(min, max, logarithmic, unit); float dmin, dmax; getDisplayExtents(dmin, dmax); float newdist = mapper->getValueForPosition(100 - step); float newmin, newmax; if (logarithmic) { // see SpectrogramLayer::setVerticalZoomStep newmax = (newdist + sqrtf(newdist*newdist + 4*dmin*dmax)) / 2; newmin = newmax - newdist; #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "newmin = " << newmin << ", newmax = " << newmax << std::endl; #endif } else { float dmid = (dmax + dmin) / 2; newmin = dmid - newdist / 2; newmax = dmid + newdist / 2; } if (newmin < min) { newmax += (min - newmin); newmin = min; } if (newmax > max) { newmax = max; } #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::setVerticalZoomStep: " << step << ": " << newmin << " -> " << newmax << " (range " << newdist << ")" << std::endl; #endif setDisplayExtents(newmin, newmax); } RangeMapper * TimeValueLayer::getNewVerticalZoomRangeMapper() const { if (!m_model) return 0; RangeMapper *mapper; float min, max; bool logarithmic; QString unit; getValueExtents(min, max, logarithmic, unit); if (min == max) return 0; if (logarithmic) { mapper = new LogRangeMapper(0, 100, min, max, unit); } else { mapper = new LinearRangeMapper(0, 100, min, max, unit); } return mapper; } SparseTimeValueModel::PointList TimeValueLayer::getLocalPoints(View *v, int x) const { if (!m_model) return SparseTimeValueModel::PointList(); long frame = v->getFrameForX(x); SparseTimeValueModel::PointList onPoints = m_model->getPoints(frame); if (!onPoints.empty()) { return onPoints; } SparseTimeValueModel::PointList prevPoints = m_model->getPreviousPoints(frame); SparseTimeValueModel::PointList nextPoints = m_model->getNextPoints(frame); SparseTimeValueModel::PointList usePoints = prevPoints; if (prevPoints.empty()) { usePoints = nextPoints; } else if (long(prevPoints.begin()->frame) < v->getStartFrame() && !(nextPoints.begin()->frame > v->getEndFrame())) { usePoints = nextPoints; } else if (nextPoints.begin()->frame - frame < frame - prevPoints.begin()->frame) { usePoints = nextPoints; } if (!usePoints.empty()) { int fuzz = 2; int px = v->getXForFrame(usePoints.begin()->frame); if ((px > x && px - x > fuzz) || (px < x && x - px > fuzz + 1)) { usePoints.clear(); } } return usePoints; } QString TimeValueLayer::getLabelPreceding(size_t frame) const { if (!m_model) return ""; SparseTimeValueModel::PointList points = m_model->getPreviousPoints(frame); for (SparseTimeValueModel::PointList::const_iterator i = points.begin(); i != points.end(); ++i) { if (i->label != "") return i->label; } return ""; } QString TimeValueLayer::getFeatureDescription(View *v, QPoint &pos) const { int x = pos.x(); if (!m_model || !m_model->getSampleRate()) return ""; SparseTimeValueModel::PointList points = getLocalPoints(v, x); if (points.empty()) { if (!m_model->isReady()) { return tr("In progress"); } else { return tr("No local points"); } } long useFrame = points.begin()->frame; RealTime rt = RealTime::frame2RealTime(useFrame, m_model->getSampleRate()); QString text; QString unit = m_model->getScaleUnits(); if (unit != "") unit = " " + unit; if (points.begin()->label == "") { text = QString(tr("Time:\t%1\nValue:\t%2%3\nNo label")) .arg(rt.toText(true).c_str()) .arg(points.begin()->value) .arg(unit); } else { text = QString(tr("Time:\t%1\nValue:\t%2%3\nLabel:\t%4")) .arg(rt.toText(true).c_str()) .arg(points.begin()->value) .arg(unit) .arg(points.begin()->label); } pos = QPoint(v->getXForFrame(useFrame), getYForValue(v, points.begin()->value)); return text; } bool TimeValueLayer::snapToFeatureFrame(View *v, int &frame, size_t &resolution, SnapType snap) const { if (!m_model) { return Layer::snapToFeatureFrame(v, frame, resolution, snap); } resolution = m_model->getResolution(); SparseTimeValueModel::PointList points; if (snap == SnapNeighbouring) { points = getLocalPoints(v, v->getXForFrame(frame)); if (points.empty()) return false; frame = points.begin()->frame; return true; } points = m_model->getPoints(frame, frame); int snapped = frame; bool found = false; for (SparseTimeValueModel::PointList::const_iterator i = points.begin(); i != points.end(); ++i) { if (snap == SnapRight) { if (i->frame > frame) { snapped = i->frame; found = true; break; } } else if (snap == SnapLeft) { if (i->frame <= frame) { snapped = i->frame; found = true; // don't break, as the next may be better } else { break; } } else { // nearest SparseTimeValueModel::PointList::const_iterator j = i; ++j; if (j == points.end()) { snapped = i->frame; found = true; break; } else if (j->frame >= frame) { if (j->frame - frame < frame - i->frame) { snapped = j->frame; } else { snapped = i->frame; } found = true; break; } } } frame = snapped; return found; } bool TimeValueLayer::snapToSimilarFeature(View *v, int &frame, size_t &resolution, SnapType snap) const { if (!m_model) { return Layer::snapToSimilarFeature(v, frame, resolution, snap); } resolution = m_model->getResolution(); const SparseTimeValueModel::PointList &points = m_model->getPoints(); SparseTimeValueModel::PointList close = m_model->getPoints(frame, frame); SparseTimeValueModel::PointList::const_iterator i; int matchframe = frame; float matchvalue = 0.f; for (i = close.begin(); i != close.end(); ++i) { if (i->frame > frame) break; matchvalue = i->value; matchframe = i->frame; } int snapped = frame; bool found = false; bool distant = false; float epsilon = 0.0001; i = close.begin(); // Scan through the close points first, then the more distant ones // if no suitable close one is found while (i != points.end()) { if (i == close.end()) { i = points.begin(); distant = true; } if (snap == SnapRight) { if (i->frame > matchframe && fabsf(i->value - matchvalue) < epsilon) { snapped = i->frame; found = true; break; } } else if (snap == SnapLeft) { if (i->frame < matchframe) { if (fabsf(i->value - matchvalue) < epsilon) { snapped = i->frame; found = true; // don't break, as the next may be better } } else if (found || distant) { break; } } else { // no other snap types supported } ++i; } frame = snapped; return found; } void TimeValueLayer::getScaleExtents(View *v, float &min, float &max, bool &log) const { min = 0.0; max = 0.0; log = false; if (shouldAutoAlign()) { if (!v->getValueExtents(m_model->getScaleUnits(), min, max, log)) { min = m_model->getValueMinimum(); max = m_model->getValueMaximum(); } else if (log) { LogRange::mapRange(min, max); } } else if (m_verticalScale == PlusMinusOneScale) { min = -1.0; max = 1.0; } else { getDisplayExtents(min, max); if (m_verticalScale == LogScale) { LogRange::mapRange(min, max); log = true; } } if (max == min) max = min + 1.0; } int TimeValueLayer::getYForValue(View *v, float val) const { float min = 0.0, max = 0.0; bool logarithmic = false; int h = v->height(); getScaleExtents(v, min, max, logarithmic); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "getYForValue(" << val << "): min " << min << ", max " << max << ", log " << logarithmic << std::endl; #endif if (logarithmic) { val = LogRange::map(val); } return int(h - ((val - min) * h) / (max - min)); } float TimeValueLayer::getValueForY(View *v, int y) const { float min = 0.0, max = 0.0; bool logarithmic = false; int h = v->height(); getScaleExtents(v, min, max, logarithmic); float val = min + (float(h - y) * float(max - min)) / h; if (logarithmic) { val = LogRange::map(val); } return val; } bool TimeValueLayer::shouldAutoAlign() const { if (!m_model) return false; QString unit = m_model->getScaleUnits(); return (m_verticalScale == AutoAlignScale && unit != ""); } QColor TimeValueLayer::getColourForValue(View *v, float val) const { float min, max; bool log; getScaleExtents(v, min, max, log); if (min > max) std::swap(min, max); if (max == min) max = min + 1; if (log) { val = LogRange::map(val); } #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::getColourForValue: min " << min << ", max " << max << ", log " << log << ", value " << val << std::endl; #endif QColor solid = ColourMapper(m_colourMap, min, max).map(val); return QColor(solid.red(), solid.green(), solid.blue(), 120); } int TimeValueLayer::getDefaultColourHint(bool darkbg, bool &impose) { impose = false; return ColourDatabase::getInstance()->getColourIndex (QString(darkbg ? "Bright Green" : "Green")); } void TimeValueLayer::paint(View *v, QPainter &paint, QRect rect) const { if (!m_model || !m_model->isOK()) return; int sampleRate = m_model->getSampleRate(); if (!sampleRate) return; paint.setRenderHint(QPainter::Antialiasing, false); // Profiler profiler("TimeValueLayer::paint", true); int x0 = rect.left(), x1 = rect.right(); long frame0 = v->getFrameForX(x0); long frame1 = v->getFrameForX(x1); if (m_derivative) --frame0; SparseTimeValueModel::PointList points(m_model->getPoints (frame0, frame1)); if (points.empty()) return; paint.setPen(getBaseQColor()); QColor brushColour(getBaseQColor()); brushColour.setAlpha(80); paint.setBrush(brushColour); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::paint: resolution is " << m_model->getResolution() << " frames" << std::endl; #endif float min = m_model->getValueMinimum(); float max = m_model->getValueMaximum(); if (max == min) max = min + 1.0; int origin = int(nearbyint(v->height() - (-min * v->height()) / (max - min))); QPoint localPos; long illuminateFrame = -1; if (v->shouldIlluminateLocalFeatures(this, localPos)) { SparseTimeValueModel::PointList localPoints = getLocalPoints(v, localPos.x()); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer: " << localPoints.size() << " local points" << std::endl; #endif if (!localPoints.empty()) illuminateFrame = localPoints.begin()->frame; } int w = v->getXForFrame(frame0 + m_model->getResolution()) - v->getXForFrame(frame0); paint.save(); QPainterPath path; int pointCount = 0; int textY = 0; if (m_plotStyle == PlotSegmentation) { textY = v->getTextLabelHeight(this, paint); } else { int originY = getYForValue(v, 0.f); if (originY > 0 && originY < v->height()) { paint.save(); paint.setPen(getPartialShades(v)[1]); paint.drawLine(x0, originY, x1, originY); paint.restore(); } } for (SparseTimeValueModel::PointList::const_iterator i = points.begin(); i != points.end(); ++i) { if (m_derivative && i == points.begin()) continue; const SparseTimeValueModel::Point &p(*i); float value = p.value; if (m_derivative) { SparseTimeValueModel::PointList::const_iterator j = i; --j; value -= j->value; } int x = v->getXForFrame(p.frame); int y = getYForValue(v, value); if (m_plotStyle != PlotSegmentation) { textY = y - paint.fontMetrics().height() + paint.fontMetrics().ascent(); if (textY < paint.fontMetrics().ascent() + 1) { textY = paint.fontMetrics().ascent() + 1; } } bool haveNext = false; int nx = v->getXForFrame(v->getModelsEndFrame()); int ny = y; SparseTimeValueModel::PointList::const_iterator j = i; ++j; if (j != points.end()) { const SparseTimeValueModel::Point &q(*j); float nvalue = q.value; if (m_derivative) nvalue -= p.value; nx = v->getXForFrame(q.frame); ny = getYForValue(v, nvalue); haveNext = true; } // std::cout << "frame = " << p.frame << ", x = " << x << ", haveNext = " << haveNext // << ", nx = " << nx << std::endl; if (w < 1) w = 1; paint.setPen(getBaseQColor()); if (m_plotStyle == PlotSegmentation) { paint.setPen(getForegroundQColor(v)); paint.setBrush(getColourForValue(v, value)); } else if (m_plotStyle == PlotLines || m_plotStyle == PlotCurve) { paint.setBrush(Qt::NoBrush); } else { paint.setBrush(brushColour); } if (m_plotStyle == PlotStems) { /* paint.setPen(brushColour); if (y < origin - 1) { paint.drawRect(x + w/2, y + 1, 1, origin - y); } else if (y > origin + 1) { paint.drawRect(x + w/2, origin, 1, y - origin - 1); } */ paint.setPen(getBaseQColor()); if (y < origin - 1) { paint.drawLine(x + w/2, y + 1, x + w/2, origin); } else if (y > origin + 1) { paint.drawLine(x + w/2, origin, x + w/2, y - 1); } } if (illuminateFrame == p.frame) { //!!! aside from the problem of choosing a colour, it'd be //better to save the highlighted rects and draw them at //the end perhaps //!!! not equipped to illuminate the right section in line //or curve mode if (m_plotStyle != PlotCurve && m_plotStyle != PlotLines) { paint.setPen(getForegroundQColor(v)); } } if (m_plotStyle != PlotLines && m_plotStyle != PlotCurve && m_plotStyle != PlotSegmentation) { if (m_plotStyle != PlotStems || w > 1) { paint.drawRect(x, y - 1, w, 2); } } if (m_plotStyle == PlotConnectedPoints || m_plotStyle == PlotLines || m_plotStyle == PlotCurve) { if (haveNext) { if (m_plotStyle == PlotConnectedPoints) { paint.save(); paint.setPen(brushColour); paint.drawLine(x + w, y, nx, ny); paint.restore(); } else if (m_plotStyle == PlotLines) { if (pointCount == 0) { path.moveTo(x + w/2, y); } ++pointCount; // paint.drawLine(x + w/2, y, nx + w/2, ny); path.lineTo(nx + w/2, ny); } else { float x0 = x + float(w)/2; float x1 = nx + float(w)/2; float y0 = y; float y1 = ny; if (pointCount == 0) { path.moveTo((x0 + x1) / 2, (y0 + y1) / 2); } ++pointCount; if (nx - x > 5) { path.cubicTo(x0, y0, x0, y0, (x0 + x1) / 2, (y0 + y1) / 2); // // or // path.quadTo(x0, y0, (x0 + x1) / 2, (y0 + y1) / 2); } else { path.lineTo((x0 + x1) / 2, (y0 + y1) / 2); } } } } if (m_plotStyle == PlotSegmentation) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "drawing rect" << std::endl; #endif if (nx <= x) continue; paint.setPen(QPen(getForegroundQColor(v), 2)); if (illuminateFrame != p.frame) { if (!m_drawSegmentDivisions || nx < x + 5 || x >= v->width() - 1) { paint.setPen(Qt::NoPen); } } paint.drawRect(x, -1, nx - x, v->height() + 1); } if (p.label != "") { if (!haveNext || nx > x + 6 + paint.fontMetrics().width(p.label)) { v->drawVisibleText(paint, x + 5, textY, p.label, View::OutlinedText); // paint.drawText(x + 5, textY, p.label); } } } if ((m_plotStyle == PlotCurve || m_plotStyle == PlotLines) && !path.isEmpty()) { paint.setRenderHint(QPainter::Antialiasing, pointCount <= v->width()); paint.drawPath(path); } paint.restore(); // looks like save/restore doesn't deal with this: paint.setRenderHint(QPainter::Antialiasing, false); } int TimeValueLayer::getVerticalScaleWidth(View *, QPainter &paint) const { int w = paint.fontMetrics().width("-000.000"); if (m_plotStyle == PlotSegmentation) return w + 20; else return w + 10; } void TimeValueLayer::paintVerticalScale(View *v, QPainter &paint, QRect) const { if (!m_model) return; int h = v->height(); int n = 10; float min, max; bool logarithmic; getScaleExtents(v, min, max, logarithmic); if (m_plotStyle == PlotSegmentation) { QString unit; getValueExtents(min, max, logarithmic, unit); if (logarithmic) { LogRange::mapRange(min, max); } } float val = min; float inc = (max - val) / n; char buffer[40]; int w = getVerticalScaleWidth(v, paint); int tx = 5; int boxx = 5, boxy = 5; if (m_model->getScaleUnits() != "") { boxy += paint.fontMetrics().height(); } int boxw = 10, boxh = h - boxy - 5; if (m_plotStyle == PlotSegmentation) { tx += boxx + boxw; paint.drawRect(boxx, boxy, boxw, boxh); } if (m_plotStyle == PlotSegmentation) { paint.save(); for (int y = 0; y < boxh; ++y) { float val = ((boxh - y) * (max - min)) / boxh + min; if (logarithmic) { paint.setPen(getColourForValue(v, LogRange::unmap(val))); } else { paint.setPen(getColourForValue(v, val)); } paint.drawLine(boxx + 1, y + boxy + 1, boxx + boxw, y + boxy + 1); } paint.restore(); } float round = 1.f; int dp = 0; if (inc > 0) { int prec = trunc(log10f(inc)); prec -= 1; if (prec < 0) dp = -prec; round = powf(10.f, prec); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "inc = " << inc << ", round = " << round << std::endl; #endif } int prevy = -1; for (int i = 0; i < n; ++i) { int y, ty; bool drawText = true; float dispval = val; if (m_plotStyle == PlotSegmentation) { y = boxy + int(boxh - ((val - min) * boxh) / (max - min)); ty = y; } else { if (i == n-1 && v->height() < paint.fontMetrics().height() * (n*2)) { if (m_model->getScaleUnits() != "") drawText = false; } dispval = lrintf(val / round) * round; #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "val = " << val << ", dispval = " << dispval << std::endl; #endif if (logarithmic) { y = getYForValue(v, LogRange::unmap(dispval)); } else { y = getYForValue(v, dispval); } ty = y - paint.fontMetrics().height() + paint.fontMetrics().ascent() + 2; if (prevy >= 0 && (prevy - y) < paint.fontMetrics().height()) { val += inc; continue; } } if (logarithmic) { sprintf(buffer, "%.*g", dp < 2 ? 2 : dp, LogRange::unmap(dispval)); } else { sprintf(buffer, "%.*f", dp, dispval); } QString label = QString(buffer); if (m_plotStyle != PlotSegmentation) { paint.drawLine(w - 5, y, w, y); } else { paint.drawLine(boxx + boxw - boxw/3, y, boxx + boxw, y); } if (drawText) { if (m_plotStyle != PlotSegmentation) { paint.drawText(tx + w - paint.fontMetrics().width(label) - 8, ty, label); } else { paint.drawText(tx, ty, label); } } prevy = y; val += inc; } if (m_model->getScaleUnits() != "") { paint.drawText(5, 5 + paint.fontMetrics().ascent(), m_model->getScaleUnits()); } } void TimeValueLayer::drawStart(View *v, QMouseEvent *e) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::drawStart(" << e->x() << "," << e->y() << ")" << std::endl; #endif if (!m_model) return; long frame = v->getFrameForX(e->x()); long resolution = m_model->getResolution(); if (frame < 0) frame = 0; frame = (frame / resolution) * resolution; float value = getValueForY(v, e->y()); bool havePoint = false; SparseTimeValueModel::PointList points = getLocalPoints(v, e->x()); if (!points.empty()) { for (SparseTimeValueModel::PointList::iterator i = points.begin(); i != points.end(); ++i) { if (((i->frame / resolution) * resolution) != frame) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "ignoring out-of-range frame at " << i->frame << std::endl; #endif continue; } m_editingPoint = *i; havePoint = true; } } if (!havePoint) { m_editingPoint = SparseTimeValueModel::Point (frame, value, tr("New Point")); } m_originalPoint = m_editingPoint; if (m_editingCommand) finish(m_editingCommand); m_editingCommand = new SparseTimeValueModel::EditCommand(m_model, tr("Draw Point")); if (!havePoint) { m_editingCommand->addPoint(m_editingPoint); } m_editing = true; } void TimeValueLayer::drawDrag(View *v, QMouseEvent *e) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::drawDrag(" << e->x() << "," << e->y() << ")" << std::endl; #endif if (!m_model || !m_editing) return; long frame = v->getFrameForX(e->x()); long resolution = m_model->getResolution(); if (frame < 0) frame = 0; frame = (frame / resolution) * resolution; float value = getValueForY(v, e->y()); SparseTimeValueModel::PointList points = getLocalPoints(v, e->x()); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << points.size() << " points" << std::endl; #endif bool havePoint = false; if (!points.empty()) { for (SparseTimeValueModel::PointList::iterator i = points.begin(); i != points.end(); ++i) { if (i->frame == m_editingPoint.frame && i->value == m_editingPoint.value) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "ignoring current editing point at " << i->frame << ", " << i->value << std::endl; #endif continue; } if (((i->frame / resolution) * resolution) != frame) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "ignoring out-of-range frame at " << i->frame << std::endl; #endif continue; } #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "adjusting to new point at " << i->frame << ", " << i->value << std::endl; #endif m_editingPoint = *i; m_originalPoint = m_editingPoint; m_editingCommand->deletePoint(m_editingPoint); havePoint = true; } } if (!havePoint) { if (frame == m_editingPoint.frame) { m_editingCommand->deletePoint(m_editingPoint); } } // m_editingCommand->deletePoint(m_editingPoint); m_editingPoint.frame = frame; m_editingPoint.value = value; m_editingCommand->addPoint(m_editingPoint); } void TimeValueLayer::drawEnd(View *, QMouseEvent *) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::drawEnd" << std::endl; #endif if (!m_model || !m_editing) return; finish(m_editingCommand); m_editingCommand = 0; m_editing = false; } void TimeValueLayer::eraseStart(View *v, QMouseEvent *e) { if (!m_model) return; SparseTimeValueModel::PointList points = getLocalPoints(v, e->x()); if (points.empty()) return; m_editingPoint = *points.begin(); if (m_editingCommand) { finish(m_editingCommand); m_editingCommand = 0; } m_editing = true; } void TimeValueLayer::eraseDrag(View *v, QMouseEvent *e) { } void TimeValueLayer::eraseEnd(View *v, QMouseEvent *e) { if (!m_model || !m_editing) return; m_editing = false; SparseTimeValueModel::PointList points = getLocalPoints(v, e->x()); if (points.empty()) return; if (points.begin()->frame != m_editingPoint.frame || points.begin()->value != m_editingPoint.value) return; m_editingCommand = new SparseTimeValueModel::EditCommand (m_model, tr("Erase Point")); m_editingCommand->deletePoint(m_editingPoint); finish(m_editingCommand); m_editingCommand = 0; m_editing = false; } void TimeValueLayer::editStart(View *v, QMouseEvent *e) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::editStart(" << e->x() << "," << e->y() << ")" << std::endl; #endif if (!m_model) return; SparseTimeValueModel::PointList points = getLocalPoints(v, e->x()); if (points.empty()) return; m_editingPoint = *points.begin(); m_originalPoint = m_editingPoint; if (m_editingCommand) { finish(m_editingCommand); m_editingCommand = 0; } m_editing = true; } void TimeValueLayer::editDrag(View *v, QMouseEvent *e) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::editDrag(" << e->x() << "," << e->y() << ")" << std::endl; #endif if (!m_model || !m_editing) return; long frame = v->getFrameForX(e->x()); if (frame < 0) frame = 0; frame = frame / m_model->getResolution() * m_model->getResolution(); float value = getValueForY(v, e->y()); if (!m_editingCommand) { m_editingCommand = new SparseTimeValueModel::EditCommand(m_model, tr("Drag Point")); } m_editingCommand->deletePoint(m_editingPoint); m_editingPoint.frame = frame; m_editingPoint.value = value; m_editingCommand->addPoint(m_editingPoint); } void TimeValueLayer::editEnd(View *, QMouseEvent *) { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "TimeValueLayer::editEnd" << std::endl; #endif if (!m_model || !m_editing) return; if (m_editingCommand) { QString newName = m_editingCommand->getName(); if (m_editingPoint.frame != m_originalPoint.frame) { if (m_editingPoint.value != m_originalPoint.value) { newName = tr("Edit Point"); } else { newName = tr("Relocate Point"); } } else { newName = tr("Change Point Value"); } m_editingCommand->setName(newName); finish(m_editingCommand); } m_editingCommand = 0; m_editing = false; } bool TimeValueLayer::editOpen(View *v, QMouseEvent *e) { if (!m_model) return false; SparseTimeValueModel::PointList points = getLocalPoints(v, e->x()); if (points.empty()) return false; SparseTimeValueModel::Point point = *points.begin(); ItemEditDialog *dialog = new ItemEditDialog (m_model->getSampleRate(), ItemEditDialog::ShowTime | ItemEditDialog::ShowValue | ItemEditDialog::ShowText, m_model->getScaleUnits()); dialog->setFrameTime(point.frame); dialog->setValue(point.value); dialog->setText(point.label); if (dialog->exec() == QDialog::Accepted) { SparseTimeValueModel::Point newPoint = point; newPoint.frame = dialog->getFrameTime(); newPoint.value = dialog->getValue(); newPoint.label = dialog->getText(); SparseTimeValueModel::EditCommand *command = new SparseTimeValueModel::EditCommand(m_model, tr("Edit Point")); command->deletePoint(point); command->addPoint(newPoint); finish(command); } delete dialog; return true; } void TimeValueLayer::moveSelection(Selection s, size_t newStartFrame) { if (!m_model) return; SparseTimeValueModel::EditCommand *command = new SparseTimeValueModel::EditCommand(m_model, tr("Drag Selection")); SparseTimeValueModel::PointList points = m_model->getPoints(s.getStartFrame(), s.getEndFrame()); for (SparseTimeValueModel::PointList::iterator i = points.begin(); i != points.end(); ++i) { if (s.contains(i->frame)) { SparseTimeValueModel::Point newPoint(*i); newPoint.frame = i->frame + newStartFrame - s.getStartFrame(); command->deletePoint(*i); command->addPoint(newPoint); } } finish(command); } void TimeValueLayer::resizeSelection(Selection s, Selection newSize) { if (!m_model) return; SparseTimeValueModel::EditCommand *command = new SparseTimeValueModel::EditCommand(m_model, tr("Resize Selection")); SparseTimeValueModel::PointList points = m_model->getPoints(s.getStartFrame(), s.getEndFrame()); double ratio = double(newSize.getEndFrame() - newSize.getStartFrame()) / double(s.getEndFrame() - s.getStartFrame()); for (SparseTimeValueModel::PointList::iterator i = points.begin(); i != points.end(); ++i) { if (s.contains(i->frame)) { double target = i->frame; target = newSize.getStartFrame() + double(target - s.getStartFrame()) * ratio; SparseTimeValueModel::Point newPoint(*i); newPoint.frame = lrint(target); command->deletePoint(*i); command->addPoint(newPoint); } } finish(command); } void TimeValueLayer::deleteSelection(Selection s) { if (!m_model) return; SparseTimeValueModel::EditCommand *command = new SparseTimeValueModel::EditCommand(m_model, tr("Delete Selected Points")); SparseTimeValueModel::PointList points = m_model->getPoints(s.getStartFrame(), s.getEndFrame()); for (SparseTimeValueModel::PointList::iterator i = points.begin(); i != points.end(); ++i) { if (s.contains(i->frame)) { command->deletePoint(*i); } } finish(command); } void TimeValueLayer::copy(View *v, Selection s, Clipboard &to) { if (!m_model) return; SparseTimeValueModel::PointList points = m_model->getPoints(s.getStartFrame(), s.getEndFrame()); for (SparseTimeValueModel::PointList::iterator i = points.begin(); i != points.end(); ++i) { if (s.contains(i->frame)) { Clipboard::Point point(i->frame, i->value, i->label); point.setReferenceFrame(alignToReference(v, i->frame)); to.addPoint(point); } } } bool TimeValueLayer::paste(View *v, const Clipboard &from, int frameOffset, bool interactive) { if (!m_model) return false; const Clipboard::PointList &points = from.getPoints(); bool realign = false; if (clipboardHasDifferentAlignment(v, from)) { QMessageBox::StandardButton button = QMessageBox::question(v, tr("Re-align pasted items?"), tr("The items you are pasting came from a layer with different source material from this one. Do you want to re-align them in time, to match the source material for this layer?"), QMessageBox::Yes | QMessageBox::No | QMessageBox::Cancel, QMessageBox::Yes); if (button == QMessageBox::Cancel) { return false; } if (button == QMessageBox::Yes) { realign = true; } } SparseTimeValueModel::EditCommand *command = new SparseTimeValueModel::EditCommand(m_model, tr("Paste")); enum ValueAvailability { UnknownAvailability, NoValues, SomeValues, AllValues }; Labeller::ValueType generation = Labeller::ValueNone; bool haveUsableLabels = false; bool haveExistingItems = !(m_model->isEmpty()); Labeller labeller; labeller.setSampleRate(m_model->getSampleRate()); if (interactive) { ValueAvailability availability = UnknownAvailability; for (Clipboard::PointList::const_iterator i = points.begin(); i != points.end(); ++i) { if (!i->haveFrame()) continue; if (availability == UnknownAvailability) { if (i->haveValue()) availability = AllValues; else availability = NoValues; continue; } if (i->haveValue()) { if (availability == NoValues) { availability = SomeValues; } } else { if (availability == AllValues) { availability = SomeValues; } } if (!haveUsableLabels) { if (i->haveLabel()) { if (i->getLabel().contains(QRegExp("[0-9]"))) { haveUsableLabels = true; } } } if (availability == SomeValues && haveUsableLabels) break; } if (availability == NoValues || availability == SomeValues) { QString text; if (availability == NoValues) { text = tr("The items you are pasting do not have values.\nWhat values do you want to use for these items?"); } else { text = tr("Some of the items you are pasting do not have values.\nWhat values do you want to use for these items?"); } Labeller::TypeNameMap names = labeller.getTypeNames(); QStringList options; std::vector<Labeller::ValueType> genopts; for (Labeller::TypeNameMap::const_iterator i = names.begin(); i != names.end(); ++i) { if (i->first == Labeller::ValueNone) options << tr("Zero for all items"); else options << i->second; genopts.push_back(i->first); } static int prevSelection = 0; bool ok = false; QString selected = ListInputDialog::getItem (0, tr("Choose value calculation"), text, options, prevSelection, &ok); if (!ok) return false; int selection = 0; generation = Labeller::ValueNone; for (QStringList::const_iterator i = options.begin(); i != options.end(); ++i) { if (selected == *i) { generation = genopts[selection]; break; } ++selection; } labeller.setType(generation); if (generation == Labeller::ValueFromCyclicalCounter || generation == Labeller::ValueFromTwoLevelCounter) { int cycleSize = QInputDialog::getInteger (0, tr("Select cycle size"), tr("Cycle size:"), 4, 2, 16, 1); labeller.setCounterCycleSize(cycleSize); } prevSelection = selection; } } SparseTimeValueModel::Point prevPoint(0); for (Clipboard::PointList::const_iterator i = points.begin(); i != points.end(); ++i) { if (!i->haveFrame()) continue; size_t frame = 0; if (!realign) { frame = i->getFrame(); } else { if (i->haveReferenceFrame()) { frame = i->getReferenceFrame(); frame = alignFromReference(v, frame); } else { frame = i->getFrame(); } } SparseTimeValueModel::Point newPoint(frame); if (i->haveLabel()) { newPoint.label = i->getLabel(); } else if (i->haveValue()) { newPoint.label = QString("%1").arg(i->getValue()); } bool usePrev = false; SparseTimeValueModel::Point formerPrevPoint = prevPoint; if (i->haveValue()) { newPoint.value = i->getValue(); } else { #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "Setting value on point at " << newPoint.frame << " from labeller"; if (i == points.begin()) { std::cerr << ", no prev point" << std::endl; } else { std::cerr << ", prev point is at " << prevPoint.frame << std::endl; } #endif labeller.setValue<SparseTimeValueModel::Point> (newPoint, (i == points.begin()) ? 0 : &prevPoint); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "New point value = " << newPoint.value << std::endl; #endif if (labeller.actingOnPrevPoint() && i != points.begin()) { usePrev = true; } } if (usePrev) { command->deletePoint(formerPrevPoint); command->addPoint(prevPoint); } prevPoint = newPoint; command->addPoint(newPoint); } finish(command); return true; } void TimeValueLayer::toXml(QTextStream &stream, QString indent, QString extraAttributes) const { SingleColourLayer::toXml(stream, indent, extraAttributes + QString(" colourMap=\"%1\" plotStyle=\"%2\" verticalScale=\"%3\" scaleMinimum=\"%4\" scaleMaximum=\"%5\" drawDivisions=\"%6\" derivative=\"%7\" ") .arg(m_colourMap) .arg(m_plotStyle) .arg(m_verticalScale) .arg(m_scaleMinimum) .arg(m_scaleMaximum) .arg(m_drawSegmentDivisions ? "true" : "false") .arg(m_derivative ? "true" : "false")); } void TimeValueLayer::setProperties(const QXmlAttributes &attributes) { SingleColourLayer::setProperties(attributes); bool ok, alsoOk; int cmap = attributes.value("colourMap").toInt(&ok); if (ok) setFillColourMap(cmap); PlotStyle style = (PlotStyle) attributes.value("plotStyle").toInt(&ok); if (ok) setPlotStyle(style); VerticalScale scale = (VerticalScale) attributes.value("verticalScale").toInt(&ok); if (ok) setVerticalScale(scale); bool draw = (attributes.value("drawDivisions").trimmed() == "true"); setDrawSegmentDivisions(draw); bool derivative = (attributes.value("derivative").trimmed() == "true"); setShowDerivative(derivative); float min = attributes.value("scaleMinimum").toFloat(&ok); float max = attributes.value("scaleMaximum").toFloat(&alsoOk); #ifdef DEBUG_TIME_VALUE_LAYER std::cerr << "from properties: min = " << min << ", max = " << max << std::endl; #endif if (ok && alsoOk && min != max) setDisplayExtents(min, max); }