-#include "audiospectrum.h"
-#include "tools/kiss_fftr.h"
+/***************************************************************************
+ * Copyright (C) 2010 by Simon Andreas Eugster (simon.eu@gmail.com) *
+ * This file is part of kdenlive. See www.kdenlive.org. *
+ * *
+ * 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. *
+ ***************************************************************************/
-#include <QMenu>
-#include <QPainter>
-// Linear interpolation.
-//#include <iostream>
-//#include <fstream>
-bool fileWritten = false;
+#include "audiospectrum.h"
+#include "ffttools.h"
+#include "kiss_fft/tools/kiss_fftr.h"
-AudioSpectrum::AudioSpectrum(Monitor *projMonitor, Monitor *clipMonitor, QWidget *parent) :
- AbstractAudioScopeWidget(projMonitor, clipMonitor, true, parent)
+#include <QMenu>
+#include <QPainter>
+#include <QMouseEvent>
+
+#include <iostream>
+
+// (defined in the header file)
+#ifdef DEBUG_AUDIOSPEC
+#include <QDebug>
+#endif
+
+// (defined in the header file)
+#ifdef DETECT_OVERMODULATION
+#include <limits>
+#include <cmath>
+#endif
+
+// Draw lines instead of single pixels.
+// This is about 25 % faster, especially when enlarging the scope to e.g. 1680x1050 px.
+#define AUDIOSPEC_LINES
+
+#define MIN_DB_VALUE -120
+#define MAX_FREQ_VALUE 96000
+#define MIN_FREQ_VALUE 1000
+#define ALPHA_MOVING_AVG 0.125
+#define MAX_OVM_COLOR 0.7
+
+AudioSpectrum::AudioSpectrum(QWidget *parent) :
+ AbstractAudioScopeWidget(true, parent),
+ m_fftTools(),
+ m_lastFFT(),
+ m_lastFFTLock(1),
+ m_peaks()
+ #ifdef DEBUG_AUDIOSPEC
+ ,m_timeTotal(0)
+ ,m_showTotal(0)
+ #endif
+ ,colorizeFactor(0)
{
ui = new Ui::AudioSpectrum_UI;
ui->setupUi(this);
- m_distance = QSize(65, 30);
- m_dBmin = -120;
- m_dBmax = 0;
- m_freqMax = 10000;
+ m_aResetHz = new QAction(i18n("Reset maximum frequency to sampling rate"), this);
+ m_aTrackMouse = new QAction(i18n("Track mouse"), this);
+ m_aTrackMouse->setCheckable(true);
+ m_aShowMax = new QAction(i18n("Show maximum"), this);
+ m_aShowMax->setCheckable(true);
- m_aLin = new QAction(i18n("Linear scale"), this);
- m_aLin->setCheckable(true);
- m_aLog = new QAction(i18n("Logarithmic scale"), this);
- m_aLog->setCheckable(true);
- m_agScale = new QActionGroup(this);
- m_agScale->addAction(m_aLin);
- m_agScale->addAction(m_aLog);
+ m_menu->addSeparator();
+ m_menu->addAction(m_aResetHz);
+ m_menu->addAction(m_aTrackMouse);
+ m_menu->addAction(m_aShowMax);
+ m_menu->removeAction(m_aRealtime);
- m_menu->addSeparator()->setText(i18n("Scale"));
- m_menu->addAction(m_aLin);
- m_menu->addAction(m_aLog);
ui->windowSize->addItem("256", QVariant(256));
ui->windowSize->addItem("512", QVariant(512));
ui->windowSize->addItem("1024", QVariant(1024));
ui->windowSize->addItem("2048", QVariant(2048));
- m_cfg = kiss_fftr_alloc(ui->windowSize->itemData(ui->windowSize->currentIndex()).toInt(), 0,0,0);
+ ui->windowFunction->addItem(i18n("Rectangular window"), FFTTools::Window_Rect);
+ ui->windowFunction->addItem(i18n("Triangular window"), FFTTools::Window_Triangle);
+ ui->windowFunction->addItem(i18n("Hamming window"), FFTTools::Window_Hamming);
bool b = true;
- b &= connect(ui->windowSize, SIGNAL(currentIndexChanged(int)), this, SLOT(slotUpdateCfg()));
+ b &= connect(m_aResetHz, SIGNAL(triggered()), this, SLOT(slotResetMaxFreq()));
+ b &= connect(ui->windowFunction, SIGNAL(currentIndexChanged(int)), this, SLOT(forceUpdate()));
+ b &= connect(this, SIGNAL(signalMousePositionChanged()), this, SLOT(forceUpdateHUD()));
Q_ASSERT(b);
- init();
+
+ // Note: These strings are used in both Spectogram and AudioSpectrum. Ideally change both (if necessary) to reduce workload on translators
+ ui->labelFFTSize->setToolTip(i18n("The maximum window size is limited by the number of samples per frame."));
+ ui->windowSize->setToolTip(i18n("A bigger window improves the accuracy at the cost of computational power."));
+ ui->windowFunction->setToolTip(i18n("The rectangular window function is good for signals with equal signal strength (narrow peak), but creates more smearing. See Window function on Wikipedia."));
+
+ AbstractScopeWidget::init();
}
AudioSpectrum::~AudioSpectrum()
{
- free(m_cfg);
- delete m_agScale;
- delete m_aLin;
- delete m_aLog;
+ writeConfig();
+
+ delete m_aResetHz;
+ delete m_aTrackMouse;
+ delete ui;
}
void AudioSpectrum::readConfig()
{
- AbstractAudioScopeWidget::readConfig();
+ AbstractScopeWidget::readConfig();
KSharedConfigPtr config = KGlobal::config();
- KConfigGroup scopeConfig(config, configName());
- QString scale = scopeConfig.readEntry("scale");
- if (scale == "lin") {
- m_aLin->setChecked(true);
+ KConfigGroup scopeConfig(config, AbstractScopeWidget::configName());
+
+ ui->windowSize->setCurrentIndex(scopeConfig.readEntry("windowSize", 0));
+ ui->windowFunction->setCurrentIndex(scopeConfig.readEntry("windowFunction", 0));
+ m_aTrackMouse->setChecked(scopeConfig.readEntry("trackMouse", true));
+ m_aShowMax->setChecked(scopeConfig.readEntry("showMax", true));
+ m_dBmax = scopeConfig.readEntry("dBmax", 0);
+ m_dBmin = scopeConfig.readEntry("dBmin", -70);
+ m_freqMax = scopeConfig.readEntry("freqMax", 0);
+
+ if (m_freqMax == 0) {
+ m_customFreq = false;
+ m_freqMax = 10000;
} else {
- m_aLog->setChecked(true);
+ m_customFreq = true;
}
- ui->windowSize->setCurrentIndex(scopeConfig.readEntry("windowSize", 0));
-
}
void AudioSpectrum::writeConfig()
{
KSharedConfigPtr config = KGlobal::config();
- KConfigGroup scopeConfig(config, configName());
- QString scale;
- if (m_aLin->isChecked()) {
- scale = "lin";
+ KConfigGroup scopeConfig(config, AbstractScopeWidget::configName());
+
+ scopeConfig.writeEntry("windowSize", ui->windowSize->currentIndex());
+ scopeConfig.writeEntry("windowFunction", ui->windowFunction->currentIndex());
+ scopeConfig.writeEntry("trackMouse", m_aTrackMouse->isChecked());
+ scopeConfig.writeEntry("showMax", m_aShowMax->isChecked());
+ scopeConfig.writeEntry("dBmax", m_dBmax);
+ scopeConfig.writeEntry("dBmin", m_dBmin);
+ if (m_customFreq) {
+ scopeConfig.writeEntry("freqMax", m_freqMax);
} else {
- scale = "log";
+ scopeConfig.writeEntry("freqMax", 0);
}
- scopeConfig.writeEntry("scale", scale);
- scopeConfig.writeEntry("windowSize", ui->windowSize->currentIndex());
+
scopeConfig.sync();
}
-QString AudioSpectrum::widgetName() const { return QString("audiospectrum"); }
-
+QString AudioSpectrum::widgetName() const { return QString("AudioSpectrum"); }
bool AudioSpectrum::isBackgroundDependingOnInput() const { return false; }
bool AudioSpectrum::isScopeDependingOnInput() const { return true; }
bool AudioSpectrum::isHUDDependingOnInput() const { return false; }
QImage AudioSpectrum::renderBackground(uint) { return QImage(); }
-QImage AudioSpectrum::renderScope(uint, const QVector<int16_t> audioFrame, const int freq, const int num_channels, const int num_samples)
+
+QImage AudioSpectrum::renderAudioScope(uint, const QVector<int16_t> audioFrame, const int freq, const int num_channels,
+ const int num_samples, const int)
{
- if (audioFrame.size() > 63) {
- m_freqMax = freq / 2;
+ if (
+ audioFrame.size() > 63
+ && m_innerScopeRect.width() > 0 && m_innerScopeRect.height() > 0 // <= 0 if widget is too small (resized by user)
+ ) {
+ if (!m_customFreq) {
+ m_freqMax = freq / 2;
+ }
QTime start = QTime::currentTime();
- bool customCfg = false;
- kiss_fftr_cfg myCfg = m_cfg;
+
+#ifdef DETECT_OVERMODULATION
+ bool overmodulated = false;
+ int overmodulateCount = 0;
+
+ for (int i = 0; i < audioFrame.size(); i++) {
+ if (
+ audioFrame[i] == std::numeric_limits<int16_t>::max()
+ || audioFrame[i] == std::numeric_limits<int16_t>::min()) {
+ overmodulateCount++;
+ if (overmodulateCount > 3) {
+ overmodulated = true;
+ break;
+ }
+ }
+ }
+ if (overmodulated) {
+ colorizeFactor = 1;
+ } else {
+ if (colorizeFactor > 0) {
+ colorizeFactor -= .08;
+ if (colorizeFactor < 0) {
+ colorizeFactor = 0;
+ }
+ }
+ }
+#endif
+
+
+ // Determine the window size to use. It should be
+ // * not bigger than the number of samples actually available
+ // * divisible by 2
int fftWindow = ui->windowSize->itemData(ui->windowSize->currentIndex()).toInt();
if (fftWindow > num_samples) {
fftWindow = num_samples;
- customCfg = true;
}
if ((fftWindow & 1) == 1) {
fftWindow--;
- customCfg = true;
- }
- if (customCfg) {
- myCfg = kiss_fftr_alloc(fftWindow, 0,0,0);
}
- float data[fftWindow];
- float freqSpectrum[fftWindow/2];
+ // Show the window size used, for information
+ ui->labelFFTSizeNumber->setText(QVariant(fftWindow).toString());
- int16_t maxSig = 0;
- for (int i = 0; i < fftWindow; i++) {
- if (audioFrame.data()[i*num_channels] > maxSig) {
- maxSig = audioFrame.data()[i*num_channels];
- }
- }
- qDebug() << "Max audio signal is " << maxSig;
- // The resulting FFT vector is only half as long
- kiss_fft_cpx freqData[fftWindow/2];
+ // Get the spectral power distribution of the input samples,
+ // using the given window size and function
+ float freqSpectrum[fftWindow/2];
+ FFTTools::WindowType windowType = (FFTTools::WindowType) ui->windowFunction->itemData(ui->windowFunction->currentIndex()).toInt();
+ m_fftTools.fftNormalized(audioFrame, 0, num_channels, freqSpectrum, windowType, fftWindow, 0);
- // Copy the first channel's audio into a vector for the FFT display
- // (only one channel handled at the moment)
- for (int i = 0; i < fftWindow; i++) {
- // Normalize signals to [0,1] to get correct dB values later on
- data[i] = (float) audioFrame.data()[i*num_channels] / 32767.0f;
- }
- // Calculate the Fast Fourier Transform for the input data
- kiss_fftr(m_cfg, data, freqData);
+ // Store the current FFT window (for the HUD) and run the interpolation
+ // for easy pixel-based dB value access
+ QVector<float> dbMap;
+ m_lastFFTLock.acquire();
+ m_lastFFT = QVector<float>(fftWindow/2);
+ memcpy(m_lastFFT.data(), &(freqSpectrum[0]), fftWindow/2 * sizeof(float));
- float val;
- // Get the minimum and the maximum value of the Fourier transformed (for scaling)
- for (int i = 0; i < fftWindow/2; i++) {
- if (m_aLog->isChecked()) {
- // Logarithmic scale: 20 * log ( 2 * magnitude / N )
- // with N = FFT size (after FFT, 1/2 window size)
- val = 20*log(pow(pow(fabs(freqData[i].r),2) + pow(fabs(freqData[i].i),2), .5)/((float)fftWindow/2.0f))/log(10);
- } else {
- // sqrt(r² + i²)
- val = pow(pow(fabs(freqData[i].r),2) + pow(fabs(freqData[i].i),2), .5);
- }
- freqSpectrum[i] = val;
- // qDebug() << val;
- }
+ uint right = ((float) m_freqMax)/(m_freq/2) * (m_lastFFT.size() - 1);
+ dbMap = FFTTools::interpolatePeakPreserving(m_lastFFT, m_innerScopeRect.width(), 0, right, -180);
+ m_lastFFTLock.release();
+#ifdef DEBUG_AUDIOSPEC
+ QTime drawTime = QTime::currentTime();
+#endif
// Draw the spectrum
- QImage spectrum(scopeRect().size(), QImage::Format_ARGB32);
+ QImage spectrum(m_scopeRect.size(), QImage::Format_ARGB32);
spectrum.fill(qRgba(0,0,0,0));
- uint w = scopeRect().size().width();
- uint h = scopeRect().size().height();
- float x;
- for (uint i = 0; i < w; i++) {
+ const uint w = m_innerScopeRect.width();
+ const uint h = m_innerScopeRect.height();
+ const uint leftDist = m_innerScopeRect.left() - m_scopeRect.left();
+ const uint topDist = m_innerScopeRect.top() - m_scopeRect.top();
+ QColor spectrumColor(AbstractScopeWidget::colDarkWhite);
+ int yMax;
+
+#ifdef DETECT_OVERMODULATION
+ if (colorizeFactor > 0) {
+ QColor col = AbstractScopeWidget::colHighlightDark;
+ QColor spec = spectrumColor;
+ float f = std::sin(M_PI_2 * colorizeFactor);
+ spectrumColor = QColor(
+ (int) (f * col.red() + (1-f) * spec.red()),
+ (int) (f * col.green() + (1-f) * spec.green()),
+ (int) (f * col.blue() + (1-f) * spec.blue()),
+ spec.alpha()
+ );
+ // Limit the maximum colorization for non-overmodulated frames to better
+ // recognize consecutively overmodulated frames
+ if (colorizeFactor > MAX_OVM_COLOR) {
+ colorizeFactor = MAX_OVM_COLOR;
+ }
+ }
+#endif
- x = i/((float) w) * fftWindow/2;
+#ifdef AUDIOSPEC_LINES
+ QPainter davinci(&spectrum);
+ davinci.setPen(QPen(QBrush(spectrumColor.rgba()), 1, Qt::SolidLine));
+#endif
- // Use linear interpolation in order to get smoother display
- if (i == 0 || i == w-1) {
- val = freqSpectrum[i];
- } else {
- // Use floor(x)+1 instead of ceil(x) as floor(x) == ceil(x) is possible.
- val = (floor(x)+1 - x)*freqSpectrum[(int) floor(x)] + (x-floor(x))*freqSpectrum[(int) floor(x)+1];
+ for (uint i = 0; i < w; i++) {
+ yMax = (dbMap[i] - m_dBmin) / (m_dBmax-m_dBmin) * (h-1);
+ if (yMax < 0) {
+ yMax = 0;
+ } else if (yMax >= (int)h) {
+ yMax = h-1;
}
-
- // freqSpectrum values range from 0 to -inf as they are relative dB values.
- qDebug() << val << "/" << (1 - (val - m_dBmax)/(m_dBmin-m_dBmax));
- for (uint y = 0; y < h*(1 - (val - m_dBmax)/(m_dBmin-m_dBmax)) && y < h; y++) {
- spectrum.setPixel(i, h-y-1, qRgba(225, 182, 255, 255));
+#ifdef AUDIOSPEC_LINES
+ davinci.drawLine(leftDist + i, topDist + h-1, leftDist + i, topDist + h-1 - yMax);
+#else
+ for (int y = 0; y < yMax && y < (int)h; y++) {
+ spectrum.setPixel(leftDist + i, topDist + h-y-1, spectrumColor.rgba());
}
+#endif
}
- emit signalScopeRenderingFinished(start.elapsed(), 1);
-
- /*
- if (!fileWritten || true) {
- std::ofstream mFile;
- mFile.open("/tmp/freq.m");
- if (!mFile) {
- qDebug() << "Opening file failed.";
+ // Calculate the peak values. Use the new value if it is bigger, otherwise adapt to lower
+ // values using the Moving Average formula
+ if (m_aShowMax->isChecked()) {
+ davinci.setPen(QPen(QBrush(AbstractScopeWidget::colHighlightLight), 2));
+ if (m_peaks.size() != fftWindow/2) {
+ m_peaks = QVector<float>(m_lastFFT);
} else {
- mFile << "val = [ ";
-
- for (int sample = 0; sample < 256; sample++) {
- mFile << data[sample] << " ";
+ for (int i = 0; i < fftWindow/2; i++) {
+ if (m_lastFFT[i] > m_peaks[i]) {
+ m_peaks[i] = m_lastFFT[i];
+ } else {
+ m_peaks[i] = ALPHA_MOVING_AVG * m_lastFFT[i] + (1-ALPHA_MOVING_AVG) * m_peaks[i];
+ }
}
- mFile << " ];\n";
-
- mFile << "freq = [ ";
- for (int sample = 0; sample < 256; sample++) {
- mFile << freqData[sample].r << "+" << freqData[sample].i << "*i ";
+ }
+ int prev = 0;
+ m_peakMap = FFTTools::interpolatePeakPreserving(m_peaks, m_innerScopeRect.width(), 0, right, -180);
+ for (uint i = 0; i < w; i++) {
+ yMax = (m_peakMap[i] - m_dBmin) / (m_dBmax-m_dBmin) * (h-1);
+ if (yMax < 0) {
+ yMax = 0;
+ } else if (yMax >= (int)h) {
+ yMax = h-1;
}
- mFile << " ];\n";
- mFile.close();
- fileWritten = true;
- qDebug() << "File written.";
+ davinci.drawLine(leftDist + i-1, topDist + h-prev-1, leftDist + i, topDist + h-yMax-1);
+ spectrum.setPixel(leftDist + i, topDist + h-yMax-1, AbstractScopeWidget::colHighlightLight.rgba());
+ prev = yMax;
}
- } else {
- qDebug() << "File already written.";
}
- */
- if (customCfg) {
- free(myCfg);
- }
+#ifdef DEBUG_AUDIOSPEC
+ m_showTotal++;
+ m_timeTotal += drawTime.elapsed();
+ qDebug() << widgetName() << " took " << drawTime.elapsed() << " ms for drawing. Average: " << ((float)m_timeTotal/m_showTotal) ;
+#endif
+
+ emit signalScopeRenderingFinished(start.elapsed(), 1);
+
return spectrum;
} else {
{
QTime start = QTime::currentTime();
- const QRect rect = scopeRect();
- // Minimum distance between two lines
- const uint minDistY = 30;
- const uint minDistX = 40;
- const uint textDist = 5;
- const uint dbDiff = ceil((float)minDistY/rect.height() * (m_dBmax-m_dBmin));
+ if (m_innerScopeRect.height() > 0 && m_innerScopeRect.width() > 0) { // May be below 0 if widget is too small
- QImage hud(AbstractAudioScopeWidget::rect().size(), QImage::Format_ARGB32);
- hud.fill(qRgba(0,0,0,0));
+ // Minimum distance between two lines
+ const uint minDistY = 30;
+ const uint minDistX = 40;
+ const uint textDistX = 10;
+ const uint textDistY = 25;
+ const uint topDist = m_innerScopeRect.top() - m_scopeRect.top();
+ const uint leftDist = m_innerScopeRect.left() - m_scopeRect.left();
+ const uint dbDiff = ceil((float)minDistY/m_innerScopeRect.height() * (m_dBmax-m_dBmin));
+ const int mouseX = m_mousePos.x() - m_innerScopeRect.left();
+ const int mouseY = m_mousePos.y() - m_innerScopeRect.top();
- QPainter davinci(&hud);
- davinci.setPen(AbstractAudioScopeWidget::penLight);
- int y;
- for (int db = -dbDiff; db > m_dBmin; db -= dbDiff) {
- y = rect.height() * ((float)db)/(m_dBmin - m_dBmax);
- davinci.drawLine(0, y, rect.width()-1, y);
- davinci.drawText(rect.width() + textDist, y + 8, i18n("%1 dB", db));
- }
+ QImage hud(m_scopeRect.size(), QImage::Format_ARGB32);
+ hud.fill(qRgba(0,0,0,0));
+
+ QPainter davinci(&hud);
+ davinci.setPen(AbstractScopeWidget::penLight);
+
+ int y;
+ for (int db = -dbDiff; db > m_dBmin; db -= dbDiff) {
+ y = topDist + m_innerScopeRect.height() * ((float)db)/(m_dBmin - m_dBmax);
+ if (y-topDist > m_innerScopeRect.height()-minDistY+10) {
+ // Abort here, there is still a line left for min dB to paint which needs some room.
+ break;
+ }
+ davinci.drawLine(leftDist, y, leftDist + m_innerScopeRect.width()-1, y);
+ davinci.drawText(leftDist + m_innerScopeRect.width() + textDistX, y + 6, i18n("%1 dB", m_dBmax + db));
+ }
+ davinci.drawLine(leftDist, topDist, leftDist + m_innerScopeRect.width()-1, topDist);
+ davinci.drawText(leftDist + m_innerScopeRect.width() + textDistX, topDist+6, i18n("%1 dB", m_dBmax));
+ davinci.drawLine(leftDist, topDist+m_innerScopeRect.height()-1, leftDist + m_innerScopeRect.width()-1, topDist+m_innerScopeRect.height()-1);
+ davinci.drawText(leftDist + m_innerScopeRect.width() + textDistX, topDist+m_innerScopeRect.height()+6, i18n("%1 dB", m_dBmin));
+
+ const uint hzDiff = ceil( ((float)minDistX)/m_innerScopeRect.width() * m_freqMax / 1000 ) * 1000;
+ int x = 0;
+ const int rightBorder = leftDist + m_innerScopeRect.width()-1;
+ y = topDist + m_innerScopeRect.height() + textDistY;
+ for (int hz = 0; x <= rightBorder; hz += hzDiff) {
+ davinci.setPen(AbstractScopeWidget::penLighter);
+ x = leftDist + m_innerScopeRect.width() * ((float)hz)/m_freqMax;
+
+ if (x <= rightBorder) {
+ davinci.drawLine(x, topDist, x, topDist + m_innerScopeRect.height()+6);
+ }
+ if (hz < m_freqMax && x+textDistY < leftDist + m_innerScopeRect.width()) {
+ davinci.drawText(x-4, y, QVariant(hz/1000).toString());
+ } else {
+ x = leftDist + m_innerScopeRect.width();
+ davinci.drawLine(x, topDist, x, topDist + m_innerScopeRect.height()+6);
+ davinci.drawText(x-10, y, i18n("%1 kHz").arg((double)m_freqMax/1000, 0, 'f', 1));
+ }
+
+ if (hz > 0) {
+ // Draw finer lines between the main lines
+ davinci.setPen(AbstractScopeWidget::penLightDots);
+ for (uint dHz = 3; dHz > 0; dHz--) {
+ x = leftDist + m_innerScopeRect.width() * ((float)hz - dHz * hzDiff/4.0f)/m_freqMax;
+ if (x > rightBorder) {
+ break;
+ }
+ davinci.drawLine(x, topDist, x, topDist + m_innerScopeRect.height()-1);
+ }
+ }
+ }
+
+ if (m_aTrackMouse->isChecked() && m_mouseWithinWidget && mouseX < m_innerScopeRect.width()-1) {
+ davinci.setPen(AbstractScopeWidget::penThin);
+
+ x = leftDist + mouseX;
+
+ float db = 0;
+ float freq = ((float) mouseX)/(m_innerScopeRect.width()-1) * m_freqMax;
+ bool drawDb = false;
+
+ m_lastFFTLock.acquire();
+ // We need to test whether the mouse is inside the widget
+ // because the position could already have changed in the meantime (-> crash)
+ if (m_lastFFT.size() > 0 && mouseX >= 0 && mouseX < m_innerScopeRect.width()) {
+ uint right = ((float) m_freqMax)/(m_freq/2) * (m_lastFFT.size() - 1);
+ QVector<float> dbMap = FFTTools::interpolatePeakPreserving(m_lastFFT, m_innerScopeRect.width(), 0, right, -120);
+
+ db = dbMap[mouseX];
+ y = topDist + m_innerScopeRect.height()-1 - (dbMap[mouseX] - m_dBmin) / (m_dBmax-m_dBmin) * (m_innerScopeRect.height()-1);
+
+ if (y < (int)topDist + m_innerScopeRect.height()-1) {
+ drawDb = true;
+ davinci.drawLine(x, y, leftDist + m_innerScopeRect.width()-1, y);
+ }
+ } else {
+ y = topDist + mouseY;
+ }
+ m_lastFFTLock.release();
+
+ if (y > (int)topDist + mouseY) {
+ y = topDist+ mouseY;
+ }
+ davinci.drawLine(x, y, x, topDist + m_innerScopeRect.height()-1);
+
+ if (drawDb) {
+ QPoint dist(20, -20);
+ QRect rect(
+ leftDist + mouseX + dist.x(),
+ topDist + mouseY + dist.y(),
+ 100,
+ 40
+ );
+ if (rect.right() > (int)leftDist + m_innerScopeRect.width()-1) {
+ // Mirror the rectangle at the y axis to keep it inside the widget
+ rect = QRect(
+ rect.topLeft() - QPoint(rect.width() + 2*dist.x(), 0),
+ rect.size());
+ }
+
+ QRect textRect(
+ rect.topLeft() + QPoint(12, 4),
+ rect.size()
+ );
+
+ davinci.fillRect(rect, AbstractScopeWidget::penBackground.brush());
+ davinci.setPen(AbstractScopeWidget::penLighter);
+ davinci.drawRect(rect);
+ davinci.drawText(textRect, QString(
+ i18n("%1 dB", QString("%1").arg(db, 0, 'f', 2))
+ + "\n"
+ + i18n("%1 kHz", QString("%1").arg(freq/1000, 0, 'f', 2))));
+ }
+
+ }
+ emit signalHUDRenderingFinished(start.elapsed(), 1);
+ return hud;
- qDebug() << "max freq: " << m_freqMax;
- const uint hzDiff = ceil( ((float)minDistX)/rect.width() * m_freqMax / 1000 ) * 1000;
- qDebug() << hzDiff;
- int x;
- for (int hz = hzDiff; hz < m_freqMax; hz += hzDiff) {
- x = rect.width() * ((float)hz)/m_freqMax;
- davinci.drawLine(x, 0, x, rect.height()+4);
- davinci.drawText(x-4, rect.height() + 20, QVariant(hz/1000).toString());
+ } else {
+#ifdef DEBUG_AUDIOSPEC
+ qDebug() << "Widget is too small for painting inside. Size of inner scope rect is "
+ << m_innerScopeRect.width() << "x" << m_innerScopeRect.height() <<".";
+#endif
+ emit signalHUDRenderingFinished(0, 1);
+ return QImage();
}
- davinci.drawText(rect.width(), rect.height() + 20, "[kHz]");
+}
- emit signalHUDRenderingFinished(start.elapsed(), 1);
- return hud;
+QRect AudioSpectrum::scopeRect()
+{
+ m_scopeRect = QRect(
+ QPoint(
+ 10, // Left
+ ui->verticalSpacer->geometry().top()+6 // Top
+ ),
+ AbstractAudioScopeWidget::rect().bottomRight()
+ );
+ m_innerScopeRect = QRect(
+ QPoint(
+ m_scopeRect.left()+6, // Left
+ m_scopeRect.top()+6 // Top
+ ), QPoint(
+ ui->verticalSpacer->geometry().right()-70,
+ ui->verticalSpacer->geometry().bottom()-40
+ )
+ );
+ return m_scopeRect;
}
-QRect AudioSpectrum::scopeRect() {
- return QRect(QPoint(0, 0), AbstractAudioScopeWidget::rect().size() - m_distance);
+void AudioSpectrum::slotResetMaxFreq()
+{
+ m_customFreq = false;
+ forceUpdateHUD();
+ forceUpdateScope();
}
-void AudioSpectrum::slotUpdateCfg()
+///// EVENTS /////
+
+void AudioSpectrum::handleMouseDrag(const QPoint &movement, const RescaleDirection rescaleDirection, const Qt::KeyboardModifiers rescaleModifiers)
{
- free(m_cfg);
- m_cfg = kiss_fftr_alloc(ui->windowSize->itemData(ui->windowSize->currentIndex()).toInt(), 0,0,0);
+ if (rescaleDirection == North) {
+ // Nort-South direction: Adjust the dB scale
+
+ if ((rescaleModifiers & Qt::ShiftModifier) == 0) {
+
+ // By default adjust the min dB value
+ m_dBmin += movement.y();
+
+ } else {
+
+ // Adjust max dB value if Shift is pressed.
+ m_dBmax += movement.y();
+
+ }
+
+ // Ensure the dB values lie in [-100, 0] (or rather [MIN_DB_VALUE, 0])
+ // 0 is the upper bound, everything below -70 dB is most likely noise
+ if (m_dBmax > 0) {
+ m_dBmax = 0;
+ }
+ if (m_dBmin < MIN_DB_VALUE) {
+ m_dBmin = MIN_DB_VALUE;
+ }
+ // Ensure there is at least 6 dB between the minimum and the maximum value;
+ // lower values hardly make sense
+ if (m_dBmax - m_dBmin < 6) {
+ if ((rescaleModifiers & Qt::ShiftModifier) == 0) {
+ // min was adjusted; Try to adjust the max value to maintain the
+ // minimum dB difference of 6 dB
+ m_dBmax = m_dBmin + 6;
+ if (m_dBmax > 0) {
+ m_dBmax = 0;
+ m_dBmin = -6;
+ }
+ } else {
+ // max was adjusted, adjust min
+ m_dBmin = m_dBmax - 6;
+ if (m_dBmin < MIN_DB_VALUE) {
+ m_dBmin = MIN_DB_VALUE;
+ m_dBmax = MIN_DB_VALUE+6;
+ }
+ }
+ }
+
+ forceUpdateHUD();
+ forceUpdateScope();
+
+ } else if (rescaleDirection == East) {
+ // East-West direction: Adjust the maximum frequency
+ m_freqMax -= 100*movement.x();
+ if (m_freqMax < MIN_FREQ_VALUE) {
+ m_freqMax = MIN_FREQ_VALUE;
+ }
+ if (m_freqMax > MAX_FREQ_VALUE) {
+ m_freqMax = MAX_FREQ_VALUE;
+ }
+ m_customFreq = true;
+
+ forceUpdateHUD();
+ forceUpdateScope();
+ }
}