Mercurial > hg > svgui
view layer/WaveformLayer.cpp @ 1367:f5566f7271fe waverevision
Rework waveform renderer to use smooth paths, aiming to get near-pixel-identical results when zoomed out far enough for a single path not to be relevant
author | Chris Cannam |
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date | Wed, 31 Oct 2018 15:06:32 +0000 |
parents | c2a3ac0a6688 |
children | ca9a36a5ab76 |
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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 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 "WaveformLayer.h" #include "base/AudioLevel.h" #include "view/View.h" #include "base/Profiler.h" #include "base/RangeMapper.h" #include "base/Strings.h" #include "ColourDatabase.h" #include "PaintAssistant.h" #include "data/model/WaveformOversampler.h" #include <QPainter> #include <QPixmap> #include <QTextStream> #include <iostream> #include <cmath> //#define DEBUG_WAVEFORM_PAINT 1 //#define DEBUG_WAVEFORM_PAINT_BY_PIXEL 1 using std::vector; WaveformLayer::WaveformLayer() : SingleColourLayer(), m_model(0), m_gain(1.0f), m_autoNormalize(false), m_showMeans(true), m_channelMode(SeparateChannels), m_channel(-1), m_scale(LinearScale), m_middleLineHeight(0.5), m_aggressive(false), m_cache(0), m_cacheValid(false) { } WaveformLayer::~WaveformLayer() { delete m_cache; } void WaveformLayer::setModel(const RangeSummarisableTimeValueModel *model) { bool channelsChanged = false; if (m_channel == -1) { if (!m_model) { if (model) { channelsChanged = true; } } else { if (model && m_model->getChannelCount() != model->getChannelCount()) { channelsChanged = true; } } } m_model = model; m_cacheValid = false; if (!m_model || !m_model->isOK()) return; connectSignals(m_model); emit modelReplaced(); if (channelsChanged) emit layerParametersChanged(); } Layer::PropertyList WaveformLayer::getProperties() const { PropertyList list = SingleColourLayer::getProperties(); list.push_back("Scale"); list.push_back("Gain"); list.push_back("Normalize Visible Area"); if (m_model && m_model->getChannelCount() > 1 && m_channel == -1) { list.push_back("Channels"); } return list; } QString WaveformLayer::getPropertyLabel(const PropertyName &name) const { if (name == "Scale") return tr("Scale"); if (name == "Gain") return tr("Gain"); if (name == "Normalize Visible Area") return tr("Normalize Visible Area"); if (name == "Channels") return tr("Channels"); return SingleColourLayer::getPropertyLabel(name); } QString WaveformLayer::getPropertyIconName(const PropertyName &name) const { if (name == "Normalize Visible Area") return "normalise"; return ""; } Layer::PropertyType WaveformLayer::getPropertyType(const PropertyName &name) const { if (name == "Gain") return RangeProperty; if (name == "Normalize Visible Area") return ToggleProperty; if (name == "Channels") return ValueProperty; if (name == "Scale") return ValueProperty; return SingleColourLayer::getPropertyType(name); } QString WaveformLayer::getPropertyGroupName(const PropertyName &name) const { if (name == "Gain" || name == "Normalize Visible Area" || name == "Scale") return tr("Scale"); return QString(); } int WaveformLayer::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; val = int(lrint(log10(m_gain) * 20.0)); if (val < *min) val = *min; if (val > *max) val = *max; } else if (name == "Normalize Visible Area") { val = (m_autoNormalize ? 1 : 0); *deflt = 0; } else if (name == "Channels") { *min = 0; *max = 2; *deflt = 0; if (m_channelMode == MixChannels) val = 1; else if (m_channelMode == MergeChannels) val = 2; else val = 0; } else if (name == "Scale") { *min = 0; *max = 2; *deflt = 0; val = (int)m_scale; } else { val = SingleColourLayer::getPropertyRangeAndValue(name, min, max, deflt); } return val; } QString WaveformLayer::getPropertyValueLabel(const PropertyName &name, int value) const { if (name == "Scale") { switch (value) { default: case 0: return tr("Linear"); case 1: return tr("Meter"); case 2: return tr("dB"); } } if (name == "Channels") { switch (value) { default: case 0: return tr("Separate"); case 1: return tr("Mean"); case 2: return tr("Butterfly"); } } return SingleColourLayer::getPropertyValueLabel(name, value); } RangeMapper * WaveformLayer::getNewPropertyRangeMapper(const PropertyName &name) const { if (name == "Gain") { return new LinearRangeMapper(-50, 50, -25, 25, tr("dB")); } return 0; } void WaveformLayer::setProperty(const PropertyName &name, int value) { if (name == "Gain") { setGain(float(pow(10, float(value)/20.0))); } else if (name == "Normalize Visible Area") { setAutoNormalize(value ? true : false); } else if (name == "Channels") { if (value == 1) setChannelMode(MixChannels); else if (value == 2) setChannelMode(MergeChannels); else setChannelMode(SeparateChannels); } else if (name == "Scale") { switch (value) { default: case 0: setScale(LinearScale); break; case 1: setScale(MeterScale); break; case 2: setScale(dBScale); break; } } else { SingleColourLayer::setProperty(name, value); } } void WaveformLayer::setGain(float gain) { if (m_gain == gain) return; m_gain = gain; m_cacheValid = false; emit layerParametersChanged(); emit verticalZoomChanged(); } void WaveformLayer::setAutoNormalize(bool autoNormalize) { if (m_autoNormalize == autoNormalize) return; m_autoNormalize = autoNormalize; m_cacheValid = false; emit layerParametersChanged(); } void WaveformLayer::setShowMeans(bool showMeans) { if (m_showMeans == showMeans) return; m_showMeans = showMeans; m_cacheValid = false; emit layerParametersChanged(); } void WaveformLayer::setChannelMode(ChannelMode channelMode) { if (m_channelMode == channelMode) return; m_channelMode = channelMode; m_cacheValid = false; emit layerParametersChanged(); } void WaveformLayer::setChannel(int channel) { // SVDEBUG << "WaveformLayer::setChannel(" << channel << ")" << endl; if (m_channel == channel) return; m_channel = channel; m_cacheValid = false; emit layerParametersChanged(); } void WaveformLayer::setScale(Scale scale) { if (m_scale == scale) return; m_scale = scale; m_cacheValid = false; emit layerParametersChanged(); } void WaveformLayer::setMiddleLineHeight(double height) { if (m_middleLineHeight == height) return; m_middleLineHeight = height; m_cacheValid = false; emit layerParametersChanged(); } void WaveformLayer::setAggressiveCacheing(bool aggressive) { if (m_aggressive == aggressive) return; m_aggressive = aggressive; m_cacheValid = false; emit layerParametersChanged(); } int WaveformLayer::getCompletion(LayerGeometryProvider *) const { int completion = 100; if (!m_model || !m_model->isOK()) return completion; if (m_model->isReady(&completion)) return 100; return completion; } bool WaveformLayer::getValueExtents(double &min, double &max, bool &, QString &unit) const { if (m_scale == LinearScale) { min = 0.0; max = 1.0; unit = "V"; } else if (m_scale == MeterScale) { return false; //!!! } else { min = AudioLevel::multiplier_to_dB(0.0); max = AudioLevel::multiplier_to_dB(1.0); unit = "dB"; } return true; } double WaveformLayer::dBscale(double sample, int m) const { if (sample < 0.0) return dBscale(-sample, m); double dB = AudioLevel::multiplier_to_dB(sample); if (dB < -50.0) return 0; if (dB > 0.0) return m; return ((dB + 50.0) * m) / 50.0; } int WaveformLayer::getChannelArrangement(int &min, int &max, bool &merging, bool &mixing) const { if (!m_model || !m_model->isOK()) return 0; int channels = m_model->getChannelCount(); if (channels == 0) return 0; int rawChannels = channels; if (m_channel == -1) { min = 0; if (m_channelMode == MergeChannels || m_channelMode == MixChannels) { max = 0; channels = 1; } else { max = channels - 1; } } else { min = m_channel; max = m_channel; rawChannels = 1; channels = 1; } merging = (m_channelMode == MergeChannels && rawChannels > 1); mixing = (m_channelMode == MixChannels && rawChannels > 1); // SVDEBUG << "WaveformLayer::getChannelArrangement: min " << min << ", max " << max << ", merging " << merging << ", channels " << channels << endl; return channels; } bool WaveformLayer::isLayerScrollable(const LayerGeometryProvider *) const { return !m_autoNormalize; } static float meterdbs[] = { -40, -30, -20, -15, -10, -5, -3, -2, -1, -0.5, 0 }; bool WaveformLayer::getSourceFramesForX(LayerGeometryProvider *v, int x, int modelZoomLevel, sv_frame_t &f0, sv_frame_t &f1) const { sv_frame_t viewFrame = v->getFrameForX(x); if (viewFrame < 0) { f0 = 0; f1 = 0; return false; } f0 = viewFrame; f0 = f0 / modelZoomLevel; f0 = f0 * modelZoomLevel; if (v->getZoomLevel().zone == ZoomLevel::PixelsPerFrame) { f1 = f0 + 1; } else { viewFrame = v->getFrameForX(x + 1); f1 = viewFrame; f1 = f1 / modelZoomLevel; f1 = f1 * modelZoomLevel; } return (f0 < m_model->getEndFrame()); } float WaveformLayer::getNormalizeGain(LayerGeometryProvider *v, int channel) const { sv_frame_t startFrame = v->getStartFrame(); sv_frame_t endFrame = v->getEndFrame(); sv_frame_t modelStart = m_model->getStartFrame(); sv_frame_t modelEnd = m_model->getEndFrame(); sv_frame_t rangeStart, rangeEnd; if (startFrame < modelStart) rangeStart = modelStart; else rangeStart = startFrame; if (endFrame < 0) rangeEnd = 0; else if (endFrame > modelEnd) rangeEnd = modelEnd; else rangeEnd = endFrame; if (rangeEnd < rangeStart) rangeEnd = rangeStart; RangeSummarisableTimeValueModel::Range range = m_model->getSummary(channel, rangeStart, rangeEnd - rangeStart); int minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; (void)getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (mergingChannels || mixingChannels) { RangeSummarisableTimeValueModel::Range otherRange = m_model->getSummary(1, rangeStart, rangeEnd - rangeStart); range.setMax(std::max(range.max(), otherRange.max())); range.setMin(std::min(range.min(), otherRange.min())); range.setAbsmean(std::min(range.absmean(), otherRange.absmean())); } return float(1.0 / std::max(fabs(range.max()), fabs(range.min()))); } void WaveformLayer::paint(LayerGeometryProvider *v, QPainter &viewPainter, QRect rect) const { if (!m_model || !m_model->isOK()) { return; } ZoomLevel zoomLevel = v->getZoomLevel(); #ifdef DEBUG_WAVEFORM_PAINT Profiler profiler("WaveformLayer::paint", true); SVCERR << "WaveformLayer::paint (" << rect.x() << "," << rect.y() << ") [" << rect.width() << "x" << rect.height() << "]: zoom " << zoomLevel << endl; #endif int channels = 0, minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; channels = getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (channels == 0) return; int w = v->getPaintWidth(); int h = v->getPaintHeight(); QPainter *paint; if (m_aggressive) { #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "WaveformLayer::paint: aggressive is true" << endl; #endif using namespace std::rel_ops; if (m_cacheValid && (zoomLevel != m_cacheZoomLevel)) { m_cacheValid = false; } if (!m_cache || m_cache->width() != w || m_cache->height() != h) { #ifdef DEBUG_WAVEFORM_PAINT if (m_cache) { SVCERR << "WaveformLayer::paint: cache size " << m_cache->width() << "x" << m_cache->height() << " differs from view size " << w << "x" << h << ": regenerating aggressive cache" << endl; } #endif delete m_cache; m_cache = new QPixmap(w, h); m_cacheValid = false; } if (m_cacheValid) { viewPainter.drawPixmap(rect, *m_cache, rect); return; } paint = new QPainter(m_cache); paint->setPen(Qt::NoPen); paint->setBrush(getBackgroundQColor(v)); paint->drawRect(rect); paint->setPen(getForegroundQColor(v)); paint->setBrush(Qt::NoBrush); } else { paint = &viewPainter; } paint->setRenderHint(QPainter::Antialiasing, true); if (m_middleLineHeight != 0.5) { paint->save(); double space = m_middleLineHeight * 2; if (space > 1.0) space = 2.0 - space; double yt = h * (m_middleLineHeight - space/2); paint->translate(QPointF(0, yt)); paint->scale(1.0, space); } int x0 = 0, x1 = w - 1; x0 = rect.left(); x1 = rect.right(); if (x0 > 0) { rect.adjust(-1, 0, 0, 0); x0 = rect.left(); } if (x1 < w) { rect.adjust(0, 0, 1, 0); x1 = rect.right(); } // Our zoom level may differ from that at which the underlying // model has its blocks. // Each pixel within our visible range must always draw from // exactly the same set of underlying audio frames, no matter what // the range being drawn is. And that set of underlying frames // must remain the same when we scroll one or more pixels left or // right. int desiredBlockSize = 1; if (zoomLevel.zone == ZoomLevel::FramesPerPixel) { desiredBlockSize = zoomLevel.level; } int blockSize = m_model->getSummaryBlockSize(desiredBlockSize); sv_frame_t frame0; sv_frame_t frame1; sv_frame_t spare; getSourceFramesForX(v, x0, blockSize, frame0, spare); getSourceFramesForX(v, x1, blockSize, spare, frame1); #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "Painting waveform from " << frame0 << " to " << frame1 << " (" << (x1-x0+1) << " pixels at zoom " << zoomLevel << " and model zoom " << blockSize << ")" << endl; #endif m_effectiveGains.clear(); while ((int)m_effectiveGains.size() <= maxChannel) { m_effectiveGains.push_back(m_gain); } if (m_autoNormalize) { for (int ch = minChannel; ch <= maxChannel; ++ch) { m_effectiveGains[ch] = getNormalizeGain(v, ch); } } RangeVec ranges; if (v->getZoomLevel().zone == ZoomLevel::FramesPerPixel) { getSummaryRanges(minChannel, maxChannel, mixingChannels || mergingChannels, frame0, frame1, blockSize, ranges); } else { getOversampledRanges(minChannel, maxChannel, mixingChannels || mergingChannels, frame0, frame1, v->getZoomLevel().level, ranges); } if (!ranges.empty()) { for (int ch = minChannel; ch <= maxChannel; ++ch) { paintChannel(v, paint, rect, ch, ranges, blockSize, frame0, frame1); } } if (m_middleLineHeight != 0.5) { paint->restore(); } if (m_aggressive) { if (m_model->isReady() && rect == v->getPaintRect()) { m_cacheValid = true; m_cacheZoomLevel = zoomLevel; } paint->end(); delete paint; viewPainter.drawPixmap(rect, *m_cache, rect); } } void WaveformLayer::getSummaryRanges(int minChannel, int maxChannel, bool mixingOrMerging, sv_frame_t frame0, sv_frame_t frame1, int blockSize, RangeVec &ranges) const { for (int ch = minChannel; ch <= maxChannel; ++ch) { ranges.push_back({}); m_model->getSummaries(ch, frame0, frame1 - frame0, ranges[ch - minChannel], blockSize); #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "channel " << ch << ": " << ranges[ch - minChannel].size() << " ranges from " << frame0 << " to " << frame1 << " at zoom level " << blockSize << endl; #endif } if (mixingOrMerging) { if (minChannel != 0 || maxChannel != 0) { throw std::logic_error("Internal error: min & max channels should be 0 when merging or mixing all channels"); } else if (m_model->getChannelCount() > 1) { ranges.push_back({}); m_model->getSummaries (1, frame0, frame1 - frame0, ranges[1], blockSize); } } } void WaveformLayer::getOversampledRanges(int minChannel, int maxChannel, bool mixingOrMerging, sv_frame_t frame0, sv_frame_t frame1, int oversampleBy, RangeVec &ranges) const { if (mixingOrMerging) { if (minChannel != 0 || maxChannel != 0) { throw std::logic_error("Internal error: min & max channels should be 0 when merging or mixing all channels"); } if (m_model->getChannelCount() > 1) { // call back on self for the individual channels with // mixingOrMerging false getOversampledRanges (0, 1, false, frame0, frame1, oversampleBy, ranges); return; } } // These frame values, tail length, etc variables are at the model // sample rate, not the oversampled rate sv_frame_t tail = 16; sv_frame_t startFrame = m_model->getStartFrame(); sv_frame_t endFrame = m_model->getEndFrame(); sv_frame_t rf0 = frame0 - tail; if (rf0 < startFrame) { rf0 = 0; } sv_frame_t rf1 = frame1 + tail; if (rf1 >= endFrame) { rf1 = endFrame - 1; } if (rf1 <= rf0) { SVCERR << "WARNING: getOversampledRanges: rf1 (" << rf1 << ") <= rf0 (" << rf0 << ")" << endl; return; } for (int ch = minChannel; ch <= maxChannel; ++ch) { floatvec_t oversampled = WaveformOversampler::getOversampledData (m_model, ch, frame0, frame1 - frame0, oversampleBy); RangeSummarisableTimeValueModel::RangeBlock rr; for (float v: oversampled) { RangeSummarisableTimeValueModel::Range r; r.sample(v); rr.push_back(r); } ranges.push_back(rr); #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "getOversampledRanges: " << frame0 << " -> " << frame1 << " (" << frame1 - frame0 << "-frame range) at ratio " << oversampleBy << " with tail " << tail << " -> got " << oversampled.size() << " oversampled values for channel " << ch << ", from which returning " << rr.size() << " ranges" << endl; #endif } return; } void WaveformLayer::paintChannel(LayerGeometryProvider *v, QPainter *paint, QRect rect, int ch, const RangeVec &ranges, int blockSize, sv_frame_t frame0, sv_frame_t frame1) const { int x0 = rect.left(); int y0 = rect.top(); int x1 = rect.right(); int y1 = rect.bottom(); int h = v->getPaintHeight(); int channels = 0, minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; channels = getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (channels == 0) return; QColor baseColour = getBaseQColor(); QColor midColour = baseColour; if (midColour == Qt::black) { midColour = Qt::gray; } else if (v->hasLightBackground()) { midColour = midColour.light(150); } else { midColour = midColour.light(50); } double gain = m_effectiveGains[ch]; int m = (h / channels) / 2; int my = m + (((ch - minChannel) * h) / channels); #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "ch = " << ch << ", channels = " << channels << ", m = " << m << ", my = " << my << ", h = " << h << endl; #endif if (my - m > y1 || my + m < y0) return; if ((m_scale == dBScale || m_scale == MeterScale) && m_channelMode != MergeChannels) { m = (h / channels); my = m + (((ch - minChannel) * h) / channels); } // Horizontal axis along middle paint->setPen(QPen(midColour, 0)); paint->drawLine(x0, my, x1, my); paintChannelScaleGuides(v, paint, rect, ch); int rangeix = ch - minChannel; #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "paint channel " << ch << ": frame0 = " << frame0 << ", frame1 = " << frame1 << ", blockSize = " << blockSize << ", have " << ranges.size() << " range blocks of which ours is index " << rangeix << " with " << ranges[rangeix].size() << " ranges in it" << endl; #else (void)frame1; // not actually used #endif QPainterPath waveformPath; QPainterPath meanPath; QPainterPath clipPath; vector<QPointF> individualSamplePoints; bool firstPoint = true; for (int x = x0; x <= x1; ++x) { sv_frame_t f0, f1; sv_frame_t i0, i1; bool showIndividualSample = false; if (v->getZoomLevel().zone == ZoomLevel::FramesPerPixel) { if (!getSourceFramesForX(v, x, blockSize, f0, f1)) { continue; } f1 = f1 - 1; i0 = (f0 - frame0) / blockSize; i1 = (f1 - frame0) / blockSize; } else { int oversampleBy = v->getZoomLevel().level; f0 = f1 = v->getFrameForX(x); int xf0 = v->getXForFrame(f0); showIndividualSample = (x == xf0); i0 = i1 = (f0 - frame0) * oversampleBy + (x - xf0); } if (f0 < frame0) { SVCERR << "ERROR: WaveformLayer::paint: pixel " << x << " has f0 = " << f0 << " which is less than range frame0 " << frame0 << " for x0 = " << x0 << endl; continue; } #ifdef DEBUG_WAVEFORM_PAINT_BY_PIXEL SVCERR << "WaveformLayer::paint: pixel " << x << ": i0 " << i0 << " (f " << f0 << "), i1 " << i1 << " (f " << f1 << ")" << endl; #endif if (i1 > i0 + 1) { SVCERR << "WaveformLayer::paint: ERROR: i1 " << i1 << " > i0 " << i0 << " plus one (zoom = " << v->getZoomLevel() << ", model zoom = " << blockSize << ")" << endl; } const auto &r = ranges[rangeix]; RangeSummarisableTimeValueModel::Range range; if (in_range_for(r, i0)) { range = r[i0]; if (i1 > i0 && in_range_for(r, i1)) { range.setMax(std::max(range.max(), r[i1].max())); range.setMin(std::min(range.min(), r[i1].min())); range.setAbsmean((range.absmean() + r[i1].absmean()) / 2); } } else { #ifdef DEBUG_WAVEFORM_PAINT SVCERR << "No (or not enough) ranges for index i0 = " << i0 << " (there are " << r.size() << " range(s))" << endl; #endif continue; } double rangeBottom = 0, rangeTop = 0, meanBottom = 0, meanTop = 0; if (mergingChannels && ranges.size() > 1) { const auto &other = ranges[1]; if (in_range_for(other, i0)) { range.setMax(fabsf(range.max())); range.setMin(-fabsf(other[i0].max())); range.setAbsmean ((range.absmean() + other[i0].absmean()) / 2); if (i1 > i0 && in_range_for(other, i1)) { // let's not concern ourselves about the mean range.setMin(std::min(range.min(), -fabsf(other[i1].max()))); } } } else if (mixingChannels && ranges.size() > 1) { const auto &other = ranges[1]; if (in_range_for(other, i0)) { range.setMax((range.max() + other[i0].max()) / 2); range.setMin((range.min() + other[i0].min()) / 2); range.setAbsmean((range.absmean() + other[i0].absmean()) / 2); } } switch (m_scale) { case LinearScale: rangeBottom = range.min() * gain * m; rangeTop = range.max() * gain * m; meanBottom = range.absmean() * gain * (-m); meanTop = range.absmean() * gain * m; break; case dBScale: if (!mergingChannels) { double db0 = dBscale(range.min() * gain, m); double db1 = dBscale(range.max() * gain, m); rangeTop = std::max(db0, db1); meanTop = std::min(db0, db1); if (mixingChannels) rangeBottom = meanTop; else rangeBottom = dBscale(range.absmean() * gain, m); meanBottom = rangeBottom; } else { rangeBottom = -dBscale(range.min() * gain, m); rangeTop = dBscale(range.max() * gain, m); meanBottom = -dBscale(range.absmean() * gain, m); meanTop = dBscale(range.absmean() * gain, m); } break; case MeterScale: if (!mergingChannels) { double r0 = fabs(AudioLevel::multiplier_to_preview (range.min() * gain, m)); double r1 = fabs(AudioLevel::multiplier_to_preview (range.max() * gain, m)); rangeTop = std::max(r0, r1); meanTop = std::min(r0, r1); if (mixingChannels) rangeBottom = meanTop; else rangeBottom = AudioLevel::multiplier_to_preview (range.absmean() * gain, m); meanBottom = rangeBottom; } else { rangeBottom = -AudioLevel::multiplier_to_preview (range.min() * gain, m); rangeTop = AudioLevel::multiplier_to_preview (range.max() * gain, m); meanBottom = -AudioLevel::multiplier_to_preview (range.absmean() * gain, m); meanTop = AudioLevel::multiplier_to_preview (range.absmean() * gain, m); } break; } rangeBottom = my - rangeBottom; rangeTop = my - rangeTop; meanBottom = my - meanBottom; meanTop = my - meanTop; bool clipped = false; if (rangeTop < my - m) { rangeTop = my - m; } if (rangeTop > my + m) { rangeTop = my + m; } if (rangeBottom < my - m) { rangeBottom = my - m; } if (rangeBottom > my + m) { rangeBottom = my + m; } if (range.max() <= -1.0 || range.max() >= 1.0) { clipped = true; } bool drawMean = m_showMeans; meanTop = meanTop - 0.5; meanBottom = meanBottom + 0.5; if (meanTop <= rangeTop + 1.0) { meanTop = rangeTop + 1.0; } if (meanBottom >= rangeBottom - 1.0 && m_scale == LinearScale) { meanBottom = rangeBottom - 1.0; } if (meanTop > meanBottom - 1.0) { drawMean = false; } #ifdef DEBUG_WAVEFORM_PAINT_BY_PIXEL SVCERR << "range " << rangeBottom << " -> " << rangeTop << ", means " << meanBottom << " -> " << meanTop << ", raw range " << range.min() << " -> " << range.max() << endl; #endif double rangeMiddle = (rangeTop + rangeBottom) / 2.0; bool trivialRange = (fabs(rangeTop - rangeBottom) < 1.0); double px = x + 0.5; if (showIndividualSample) { individualSamplePoints.push_back(QPointF(px, rangeTop)); if (!trivialRange) { // common e.g. in "butterfly" merging mode individualSamplePoints.push_back(QPointF(px, rangeBottom)); } } if (firstPoint) { waveformPath = QPainterPath(QPointF(px, rangeMiddle)); firstPoint = false; } else { waveformPath.lineTo(QPointF(px, rangeMiddle)); } if (!trivialRange) { waveformPath.lineTo(QPointF(px, rangeTop)); waveformPath.lineTo(QPointF(px, rangeBottom)); waveformPath.lineTo(QPointF(px, rangeMiddle)); } if (drawMean) { meanPath.moveTo(QPointF(px, meanBottom)); meanPath.lineTo(QPointF(px, meanTop)); } if (clipped) { if (trivialRange) { clipPath.moveTo(QPointF(px, rangeMiddle)); clipPath.lineTo(QPointF(px+1, rangeMiddle)); } else { clipPath.moveTo(QPointF(px, rangeBottom)); clipPath.lineTo(QPointF(px, rangeTop)); } } } double penWidth = 1.0; if (m_model->isReady()) { paint->setPen(QPen(baseColour, penWidth)); } else { paint->setPen(QPen(midColour, penWidth)); } paint->drawPath(waveformPath); if (!clipPath.isEmpty()) { paint->save(); paint->setPen(QPen(ColourDatabase::getInstance()-> getContrastingColour(m_colour), penWidth)); paint->drawPath(clipPath); paint->restore(); } if (!meanPath.isEmpty()) { paint->save(); paint->setPen(QPen(midColour, penWidth)); paint->drawPath(meanPath); paint->restore(); } if (!individualSamplePoints.empty()) { paint->save(); paint->setPen(QPen(baseColour, penWidth)); double sz = ViewManager::scalePixelSize(2.0); for (QPointF p: individualSamplePoints) { paint->drawRect(QRectF(p.x() - sz/2, p.y() - sz/2, sz, sz)); } paint->restore(); } } void WaveformLayer::paintChannelScaleGuides(LayerGeometryProvider *v, QPainter *paint, QRect rect, int ch) const { int x0 = rect.left(); int x1 = rect.right(); int n = 10; int py = -1; double gain = m_effectiveGains[ch]; if (v->hasLightBackground() && v->getViewManager() && v->getViewManager()->shouldShowScaleGuides()) { paint->setPen(QColor(240, 240, 240)); for (int i = 1; i < n; ++i) { double val = 0.0, nval = 0.0; switch (m_scale) { case LinearScale: val = (i * gain) / n; if (i > 0) nval = -val; break; case MeterScale: val = AudioLevel::dB_to_multiplier(meterdbs[i]) * gain; break; case dBScale: val = AudioLevel::dB_to_multiplier(-(10*n) + i * 10) * gain; break; } if (val < -1.0 || val > 1.0) continue; int y = getYForValue(v, val, ch); if (py >= 0 && abs(y - py) < 10) continue; else py = y; int ny = y; if (nval != 0.0) { ny = getYForValue(v, nval, ch); } paint->drawLine(x0, y, x1, y); if (ny != y) { paint->drawLine(x0, ny, x1, ny); } } } } QString WaveformLayer::getFeatureDescription(LayerGeometryProvider *v, QPoint &pos) const { int x = pos.x(); if (!m_model || !m_model->isOK()) return ""; ZoomLevel zoomLevel = v->getZoomLevel(); int desiredBlockSize = 1; if (zoomLevel.zone == ZoomLevel::FramesPerPixel) { desiredBlockSize = zoomLevel.level; } int blockSize = m_model->getSummaryBlockSize(desiredBlockSize); sv_frame_t f0, f1; if (!getSourceFramesForX(v, x, blockSize, f0, f1)) return ""; QString text; RealTime rt0 = RealTime::frame2RealTime(f0, m_model->getSampleRate()); RealTime rt1 = RealTime::frame2RealTime(f1, m_model->getSampleRate()); if (f1 != f0 + 1 && (rt0.sec != rt1.sec || rt0.msec() != rt1.msec())) { text += tr("Time:\t%1 - %2") .arg(rt0.toText(true).c_str()) .arg(rt1.toText(true).c_str()); } else { text += tr("Time:\t%1") .arg(rt0.toText(true).c_str()); } int channels = 0, minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; channels = getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (channels == 0) return ""; for (int ch = minChannel; ch <= maxChannel; ++ch) { RangeSummarisableTimeValueModel::RangeBlock ranges; m_model->getSummaries(ch, f0, f1 - f0, ranges, blockSize); if (ranges.empty()) continue; RangeSummarisableTimeValueModel::Range range = ranges[0]; QString label = tr("Level:"); if (minChannel != maxChannel) { if (ch == 0) label = tr("Left:"); else if (ch == 1) label = tr("Right:"); else label = tr("Channel %1").arg(ch + 1); } bool singleValue = false; double min, max; if (fabs(range.min()) < 0.01) { min = range.min(); max = range.max(); singleValue = (min == max); } else { int imin = int(lrint(range.min() * 10000)); int imax = int(lrint(range.max() * 10000)); singleValue = (imin == imax); min = double(imin)/10000; max = double(imax)/10000; } int db = int(AudioLevel::multiplier_to_dB(std::max(fabsf(range.min()), fabsf(range.max()))) * 100); if (!singleValue) { text += tr("\n%1\t%2 - %3 (%4 dB peak)") .arg(label).arg(min).arg(max).arg(double(db)/100); } else { text += tr("\n%1\t%2 (%3 dB peak)") .arg(label).arg(min).arg(double(db)/100); } } return text; } int WaveformLayer::getYForValue(const LayerGeometryProvider *v, double value, int channel) const { int channels = 0, minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; channels = getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (channels == 0) return 0; if (maxChannel < minChannel || channel < minChannel) return 0; int h = v->getPaintHeight(); int m = (h / channels) / 2; if ((m_scale == dBScale || m_scale == MeterScale) && m_channelMode != MergeChannels) { m = (h / channels); } int my = m + (((channel - minChannel) * h) / channels); int vy = 0; switch (m_scale) { case LinearScale: vy = int(m * value); break; case MeterScale: vy = AudioLevel::multiplier_to_preview(value, m); break; case dBScale: vy = int(dBscale(value, m)); break; } // SVCERR << "mergingChannels= " << mergingChannels << ", channel = " << channel << ", value = " << value << ", vy = " << vy << endl; return my - vy; } double WaveformLayer::getValueForY(const LayerGeometryProvider *v, int y, int &channel) const { int channels = 0, minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; channels = getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (channels == 0) return 0; if (maxChannel < minChannel) return 0; int h = v->getPaintHeight(); int m = (h / channels) / 2; if ((m_scale == dBScale || m_scale == MeterScale) && m_channelMode != MergeChannels) { m = (h / channels); } channel = (y * channels) / h + minChannel; int my = m + (((channel - minChannel) * h) / channels); int vy = my - y; double value = 0; double thresh = -50.f; switch (m_scale) { case LinearScale: value = double(vy) / m; break; case MeterScale: value = AudioLevel::preview_to_multiplier(vy, m); break; case dBScale: value = (-thresh * double(vy)) / m + thresh; value = AudioLevel::dB_to_multiplier(value); break; } return value / m_gain; } bool WaveformLayer::getYScaleValue(const LayerGeometryProvider *v, int y, double &value, QString &unit) const { int channel; value = getValueForY(v, y, channel); if (m_scale == dBScale || m_scale == MeterScale) { double thresh = -50.f; if (value > 0.0) { value = 10.0 * log10(value); if (value < thresh) value = thresh; } else value = thresh; unit = "dBV"; } else { unit = "V"; } return true; } bool WaveformLayer::getYScaleDifference(const LayerGeometryProvider *v, int y0, int y1, double &diff, QString &unit) const { int c0, c1; double v0 = getValueForY(v, y0, c0); double v1 = getValueForY(v, y1, c1); if (c0 != c1) { // different channels, not comparable diff = 0.0; unit = ""; return false; } if (m_scale == dBScale || m_scale == MeterScale) { double thresh = -50.0; if (v1 == v0) diff = thresh; else { if (v1 > v0) diff = v0 / v1; else diff = v1 / v0; diff = 10.0 * log10(diff); if (diff < thresh) diff = thresh; } unit = "dBV"; } else { diff = fabs(v1 - v0); unit = "V"; } return true; } int WaveformLayer::getVerticalScaleWidth(LayerGeometryProvider *, bool, QPainter &paint) const { if (m_scale == LinearScale) { return paint.fontMetrics().width("0.0") + 13; } else { return std::max(paint.fontMetrics().width(tr("0dB")), paint.fontMetrics().width(Strings::minus_infinity)) + 13; } } void WaveformLayer::paintVerticalScale(LayerGeometryProvider *v, bool, QPainter &paint, QRect rect) const { if (!m_model || !m_model->isOK()) { return; } int channels = 0, minChannel = 0, maxChannel = 0; bool mergingChannels = false, mixingChannels = false; channels = getChannelArrangement(minChannel, maxChannel, mergingChannels, mixingChannels); if (channels == 0) return; int h = rect.height(), w = rect.width(); int textHeight = paint.fontMetrics().height(); int toff = -textHeight/2 + paint.fontMetrics().ascent() + 1; double gain = m_gain; for (int ch = minChannel; ch <= maxChannel; ++ch) { int lastLabelledY = -1; if (ch < (int)m_effectiveGains.size()) gain = m_effectiveGains[ch]; int n = 10; for (int i = 0; i <= n; ++i) { double val = 0.0, nval = 0.0; QString text = ""; switch (m_scale) { case LinearScale: val = (i * gain) / n; text = QString("%1").arg(double(i) / n); if (i == 0) text = "0.0"; else { nval = -val; if (i == n) text = "1.0"; } break; case MeterScale: val = AudioLevel::dB_to_multiplier(meterdbs[i]) * gain; text = QString("%1").arg(meterdbs[i]); if (i == n) text = tr("0dB"); if (i == 0) { text = Strings::minus_infinity; val = 0.0; } break; case dBScale: val = AudioLevel::dB_to_multiplier(-(10*n) + i * 10) * gain; text = QString("%1").arg(-(10*n) + i * 10); if (i == n) text = tr("0dB"); if (i == 0) { text = Strings::minus_infinity; val = 0.0; } break; } if (val < -1.0 || val > 1.0) continue; int y = getYForValue(v, val, ch); int ny = y; if (nval != 0.0) { ny = getYForValue(v, nval, ch); } bool spaceForLabel = (i == 0 || abs(y - lastLabelledY) >= textHeight - 1); if (spaceForLabel) { int tx = 3; if (m_scale != LinearScale) { tx = w - 10 - paint.fontMetrics().width(text); } int ty = y; if (ty < paint.fontMetrics().ascent()) { ty = paint.fontMetrics().ascent(); } else if (ty > h - paint.fontMetrics().descent()) { ty = h - paint.fontMetrics().descent(); } else { ty += toff; } paint.drawText(tx, ty, text); lastLabelledY = ty - toff; if (ny != y) { ty = ny; if (ty < paint.fontMetrics().ascent()) { ty = paint.fontMetrics().ascent(); } else if (ty > h - paint.fontMetrics().descent()) { ty = h - paint.fontMetrics().descent(); } else { ty += toff; } paint.drawText(tx, ty, text); } paint.drawLine(w - 7, y, w, y); if (ny != y) paint.drawLine(w - 7, ny, w, ny); } else { paint.drawLine(w - 4, y, w, y); if (ny != y) paint.drawLine(w - 4, ny, w, ny); } } } } void WaveformLayer::toXml(QTextStream &stream, QString indent, QString extraAttributes) const { QString s; QString colourName, colourSpec, darkbg; ColourDatabase::getInstance()->getStringValues (m_colour, colourName, colourSpec, darkbg); s += QString("gain=\"%1\" " "showMeans=\"%2\" " "greyscale=\"%3\" " "channelMode=\"%4\" " "channel=\"%5\" " "scale=\"%6\" " "middleLineHeight=\"%7\" " "aggressive=\"%8\" " "autoNormalize=\"%9\"") .arg(m_gain) .arg(m_showMeans) .arg(true) // Option removed, but effectively always on, so // retained in the session file for compatibility .arg(m_channelMode) .arg(m_channel) .arg(m_scale) .arg(m_middleLineHeight) .arg(m_aggressive) .arg(m_autoNormalize); SingleColourLayer::toXml(stream, indent, extraAttributes + " " + s); } void WaveformLayer::setProperties(const QXmlAttributes &attributes) { bool ok = false; SingleColourLayer::setProperties(attributes); float gain = attributes.value("gain").toFloat(&ok); if (ok) setGain(gain); bool showMeans = (attributes.value("showMeans") == "1" || attributes.value("showMeans") == "true"); setShowMeans(showMeans); ChannelMode channelMode = (ChannelMode) attributes.value("channelMode").toInt(&ok); if (ok) setChannelMode(channelMode); int channel = attributes.value("channel").toInt(&ok); if (ok) setChannel(channel); Scale scale = (Scale)attributes.value("scale").toInt(&ok); if (ok) setScale(scale); float middleLineHeight = attributes.value("middleLineHeight").toFloat(&ok); if (ok) setMiddleLineHeight(middleLineHeight); bool aggressive = (attributes.value("aggressive") == "1" || attributes.value("aggressive") == "true"); setAggressiveCacheing(aggressive); bool autoNormalize = (attributes.value("autoNormalize") == "1" || attributes.value("autoNormalize") == "true"); setAutoNormalize(autoNormalize); } int WaveformLayer::getVerticalZoomSteps(int &defaultStep) const { defaultStep = 50; return 100; } int WaveformLayer::getCurrentVerticalZoomStep() const { int val = int(lrint(log10(m_gain) * 20.0) + 50); if (val < 0) val = 0; if (val > 100) val = 100; return val; } void WaveformLayer::setVerticalZoomStep(int step) { setGain(powf(10, float(step - 50) / 20.f)); }