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Sourcecode: ktechlab version File versions

oscilloscopeview.cpp

/***************************************************************************
 *   Copyright (C) 2005 by David Saxton                                    *
 *   david@bluehaze.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 "oscilloscope.h"
#include "oscilloscopedata.h"
#include "oscilloscopeview.h"
#include "probepositioner.h"
#include "simulator.h"

#include <kconfig.h>
#include <kdebug.h>
#include <klocale.h>
#include <kglobal.h>
#include <kpopupmenu.h>
#include <qcheckbox.h>
#include <qcursor.h>
#include <qevent.h>
#include <qlabel.h>
#include <qpainter.h>
#include <qpixmap.h>
#include <qscrollbar.h>
#include <qtimer.h>

#include <algorithm>
#include <cmath>

inline uint64_t min( uint64_t a, uint64_t b)
{
      return a < b ? a : b;
}


OscilloscopeView::OscilloscopeView( QWidget *parent, const char *name)
      : QFrame( parent, name, WNoAutoErase),
      b_needRedraw(true),
      m_pixmap(0),
      m_fps(10),
      m_sliderValueAtClick(-1),
      m_clickOffsetPos(-1),
      m_pSimulator( Simulator::self()),
      m_halfOutputHeight(0.0)
{
      KGlobal::config()->setGroup("Oscilloscope");
      m_fps = KGlobal::config()->readNumEntry( "FPS", 25);

      setBackgroundMode(NoBackground);
      setMouseTracking(true);

      m_updateViewTmr = new QTimer(this);
      connect( m_updateViewTmr, SIGNAL(timeout()), this, SLOT(updateViewTimeout()));
}

OscilloscopeView::~OscilloscopeView()
{
      delete m_pixmap;
}

00065 void OscilloscopeView::updateView()
{
      if(m_updateViewTmr->isActive()) return;

      m_updateViewTmr->start( 1000/m_fps, true);
}

void OscilloscopeView::updateViewTimeout()
{
      b_needRedraw = true;
      repaint(false);
      updateTimeLabel();
}


void OscilloscopeView::updateTimeLabel()
{
      if( hasMouse()) {
            int x = mapFromGlobal( QCursor::pos()).x();
            double time = (double(Oscilloscope::self()->scrollTime()) / LOGIC_UPDATE_RATE) + (x / Oscilloscope::self()->pixelsPerSecond());
            Oscilloscope::self()->timeLabel->setText( QString::number( time, 'f', 6));
      } else Oscilloscope::self()->timeLabel->setText( QString::null);
}


void OscilloscopeView::resizeEvent( QResizeEvent *e)
{
      delete m_pixmap;
      m_pixmap = new QPixmap( e->size());
      b_needRedraw = true;
      QFrame::resizeEvent(e);
}


void OscilloscopeView::mousePressEvent( QMouseEvent *event)
{
      switch ( event->button())
      {
            case Qt::LeftButton:
            {
                  event->accept();
                  m_clickOffsetPos = event->pos().x();
                  m_sliderValueAtClick = Oscilloscope::self()->horizontalScroll->value();
                  setCursor( Qt::SizeAllCursor);
                  return;
            }
            
            case Qt::RightButton:
            {
                  event->accept();
      
                  KPopupMenu fpsMenu;
                  fpsMenu.insertTitle( i18n("Framerate"));
      
                  const int fps[] = { 10, 25, 50, 75, 100 };
      
                  for( uint i=0; i<5; ++i)
                  {
                        const int num = fps[i];
                        fpsMenu.insertItem( i18n("%1 fps").arg(num), num);
                        fpsMenu.setItemChecked( num, num == m_fps);
                  }
      
                  connect( &fpsMenu, SIGNAL(activated(int)), this, SLOT(slotSetFrameRate(int)));
                  fpsMenu.exec( event->globalPos());
                  return;
            }
            
            default:
            {
                  QFrame::mousePressEvent(event);
                  return;
            }
      }
}


void OscilloscopeView::mouseMoveEvent( QMouseEvent *event)
{
      event->accept();
      updateTimeLabel();
      
      if( m_sliderValueAtClick != -1)
      {
            int dx = event->pos().x() - m_clickOffsetPos;
            int dTick = int( dx * Oscilloscope::self()->sliderTicksPerSecond() / Oscilloscope::self()->pixelsPerSecond());
            Oscilloscope::self()->horizontalScroll->setValue( m_sliderValueAtClick - dTick);
      }
}


void OscilloscopeView::mouseReleaseEvent( QMouseEvent *event)
{
      if( m_sliderValueAtClick == -1)
            return QFrame::mouseReleaseEvent(event);
      
      event->accept();
      m_sliderValueAtClick = -1;
      setCursor( Qt::ArrowCursor);
}


void OscilloscopeView::slotSetFrameRate( int fps)
{
      m_fps = fps;
      KGlobal::config()->setGroup("Oscilloscope");
      KGlobal::config()->writeEntry( "FPS", m_fps);
}


// returns a % b
static double lld_modulus( int64_t a, double b)
{
      return double(a) - int64_t(a/b)*b;
}


void OscilloscopeView::paintEvent( QPaintEvent *e)
{
      QRect r = e->rect();
      
      if(b_needRedraw)
      {
            updateOutputHeight();
            const double pixelsPerSecond = Oscilloscope::self()->pixelsPerSecond();
            
            QPainter p;
            m_pixmap->fill( paletteBackgroundColor());
            p.begin(m_pixmap);
            p.setClipRegion(e->region());
            
            //BEGIN Draw vertical marker lines
            const double divisions = 5.0;
            const double min_sep = 10.0;
            
            double spacing = pixelsPerSecond/(std::pow( divisions, std::floor(std::log(pixelsPerSecond/min_sep)/std::log(divisions))));
            
            // Pixels offset is the number of pixels that the view is scrolled along
            const int64_t pixelsOffset = int64_t(Oscilloscope::self()->scrollTime()*pixelsPerSecond/LOGIC_UPDATE_RATE);
            double linesOffset = - lld_modulus( pixelsOffset, spacing);
            
            int blackness = 256 - int(184.0 * spacing / (min_sep*divisions*divisions));
            p.setPen( QColor( blackness, blackness, blackness));
            
            for( double i = linesOffset; i <= frameRect().width(); i += spacing)
                  p.drawLine( int(i), 1, int(i), frameRect().height()-2);
            
            
            
            spacing *= divisions;
            linesOffset = - lld_modulus( pixelsOffset, spacing);
            
            blackness = 256 - int(184.0 * spacing / (min_sep*divisions*divisions));
            p.setPen( QColor( blackness, blackness, blackness));
            
            for( double i = linesOffset; i <= frameRect().width(); i += spacing)
                  p.drawLine( int(i), 1, int(i), frameRect().height()-2);
            
            
            
            spacing *= divisions;
            linesOffset = - lld_modulus( pixelsOffset, spacing);
            
            blackness = 256 - int(184.0);
            p.setPen( QColor( blackness, blackness, blackness));
            
            for( double i = linesOffset; i <= frameRect().width(); i += spacing)
                  p.drawLine( int(i), 1, int(i), frameRect().height()-2);
            //END Draw vertical marker lines
            
            drawLogicData(p);
            drawFloatingData(p);
            
            p.setPen(Qt::black);
            p.drawRect( frameRect());
            
            b_needRedraw = false;
      }
      
      bitBlt( this, r.x(), r.y(), m_pixmap, r.x(), r.y(), r.width(), r.height());
}


void OscilloscopeView::updateOutputHeight()
{
      m_halfOutputHeight = int((Oscilloscope::self()->probePositioner->probeOutputHeight() - (probeArrowWidth/Oscilloscope::self()->numberOfProbes()))/2)-1;
}


void OscilloscopeView::drawLogicData( QPainter & p)
{
      const double pixelsPerSecond = Oscilloscope::self()->pixelsPerSecond();
      
      const LogicProbeDataMap::iterator end = Oscilloscope::self()->m_logicProbeDataMap.end();
      for( LogicProbeDataMap::iterator it = Oscilloscope::self()->m_logicProbeDataMap.begin(); it != end; ++it)
      {
            // When searching for the next logic value to display, we look along
            // until there is a recorded point which is at least one pixel along
            // If we are zoomed out far, there might be thousands of data points
            // between each pixel. It is time consuming searching for the next point
            // to display one at a time, so we record the average number of data points
            // between pixels ( = deltaAt / totalDeltaAt)
            int64_t deltaAt = 1;
            int totalDeltaAt = 1;
            
            LogicProbeData * probe = it.data();

            vector<LogicDataPoint> *data = probe->m_data;
            if(!data->size()) continue;
            
            const int midHeight = Oscilloscope::self()->probePositioner->probePosition(probe);
            const int64_t timeOffset = Oscilloscope::self()->scrollTime();
            
            // Draw the horizontal line indicating the midpoint of our output
            p.setPen( QColor( 228, 228, 228));
            p.drawLine( 0, midHeight, width(), midHeight);
            
            // Set the pen colour according to the colour the user has selected for the probe
            p.setPen( probe->color());
            
            // The smallest time step that will display in our oscilloscope
            const int minTimeStep = int(LOGIC_UPDATE_RATE/pixelsPerSecond);
            
            int64_t at = probe->findPos(timeOffset);
            const int64_t maxAt = probe->m_data->size();
            int64_t prevTime = (*data)[at].time;
            int prevX = (at > 0) ? 0 : int((prevTime - timeOffset)*(pixelsPerSecond/LOGIC_UPDATE_RATE));
            bool prevHigh = (*data)[at].value;
            int prevY = midHeight + int(prevHigh ? -m_halfOutputHeight : +m_halfOutputHeight);

            while ( at < maxAt) {
                  // Search for the next pos which will show up at our zoom level
                  int64_t previousAt = at;
                  int64_t dAt = deltaAt / totalDeltaAt;
                  
                  while ( (dAt > 1) && (at < maxAt) && ( (int64_t((*data)[at].time) - prevTime) != minTimeStep))
                  {
                        // Search forwards until we overshoot
                        while ( at < maxAt && ( int64_t((*data)[at].time) - prevTime) < minTimeStep)
                              at += dAt;
                        dAt /= 2;
                        
                        // Search backwards until we undershoot
                        while ( (at < maxAt) && ( int64_t((*data)[at].time) - prevTime) > minTimeStep)
                        {
                              at -= dAt;
                              if( at < 0)
                                    at = 0;
                        }
                        dAt /= 2;
                  }
                  
                  // Possibly increment the value of at found by one (or more if this is the first go)
                  while ( (previousAt == at) || ((at < maxAt) && ( int64_t((*data)[at].time) - prevTime) < minTimeStep))
                        at++;

                  if( at >= maxAt) break;

                  // Update the average values
                  deltaAt += at - previousAt;
                  totalDeltaAt++;
                  
                  bool nextHigh = (*data)[at].value;
                  if( nextHigh == prevHigh) continue;

                  int64_t nextTime = (*data)[at].time;
                  int nextX = int((nextTime - timeOffset)*(pixelsPerSecond/LOGIC_UPDATE_RATE));
                  int nextY = midHeight + int(nextHigh ? -m_halfOutputHeight : +m_halfOutputHeight);
                  
                  p.drawLine( prevX, prevY, nextX, prevY);
                  p.drawLine( nextX, prevY, nextX, nextY);

                  prevHigh = nextHigh;
                  prevTime = nextTime;
                  prevX = nextX;
                  prevY = nextY;

                  if( nextX > width()) break;
            };
            
            // If we could not draw right to the end; it is because we exceeded
            // maxAt
            if( prevX < width())
                  p.drawLine( prevX, prevY, width(), prevY);
      }
}

#define v_to_y int(midHeight - (logarithmic ? ( (v>0) ? log(v/lowerAbsValue) : -log(-v/lowerAbsValue)) : v) * sf)

void OscilloscopeView::drawFloatingData(QPainter &p)
{
      const double pixelsPerSecond = Oscilloscope::self()->pixelsPerSecond();

      const FloatingProbeDataMap::iterator end = Oscilloscope::self()->m_floatingProbeDataMap.end();
      for(FloatingProbeDataMap::iterator it = Oscilloscope::self()->m_floatingProbeDataMap.begin(); it != end; ++it) {
            FloatingProbeData * probe = it.data();
            vector<float> *data = probe->m_data;

            if(!data->size()) continue;

            bool logarithmic = probe->scaling() == FloatingProbeData::Logarithmic;
            double lowerAbsValue = probe->lowerAbsValue();
            double sf = m_halfOutputHeight / (logarithmic ? log(probe->upperAbsValue()/lowerAbsValue) : probe->upperAbsValue());

            const int midHeight = Oscilloscope::self()->probePositioner->probePosition(probe);
            const int64_t timeOffset = Oscilloscope::self()->scrollTime();

            // Draw the horizontal line indicating the midpoint of our output
            p.setPen( QColor( 228, 228, 228));
            p.drawLine( 0, midHeight, width(), midHeight);

            // Set the pen colour according to the colour the user has selected for the probe
            p.setPen( probe->color());

            int64_t at = probe->findPos(timeOffset);
            const int64_t maxAt = probe->m_data->size();
            if(at > maxAt) at = maxAt;
            int64_t prevTime = probe->toTime(at);

            double v = (*data)[(at>0)?at:0];
            int prevY = v_to_y;
            int prevX = int((prevTime - timeOffset)*(pixelsPerSecond/LOGIC_UPDATE_RATE));

            while ( at < maxAt) {
                  at++;

                  uint64_t nextTime = prevTime + uint64_t(LOGIC_UPDATE_RATE * LINEAR_UPDATE_PERIOD);

                  double v = (*data)[(at>0)?at:0];
                  int nextY = v_to_y;
                  int nextX = int((nextTime - timeOffset)*(pixelsPerSecond/LOGIC_UPDATE_RATE));

                  p.drawLine( prevX, prevY, nextX, nextY);

                  prevTime = nextTime;
                  prevX = nextX;
                  prevY = nextY;

                  if( nextX > width()) break;
            };

            // If we could not draw right to the end; it is because we exceeded
            // maxAt
            if( prevX < width())
                  p.drawLine( prevX, prevY, width(), prevY);
      }
}

#include "oscilloscopeview.moc"

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