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.value();
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);
}
}
void ScopeScreenView::drawContents(QPainter * p)
{
QRect cr = contentsRect();
for(int i =1; i < m_intervalsX; i++)
{
int x = cr.left() + cr.width()*i/m_intervalsX;
p->drawLine(x, cr.top(), x, cr.bottom());
}
const int ticksPerScreen = m_intervalsX * m_ticksPerIntervalX;
const double pixelsPerTick = cr.width()/double(ticksPerScreen);
const double ticksPerPixel = m_intervalsX * m_ticksPerIntervalX / cr.width();
//draw the current time
int curTimeX = ((Simulator::self()->time() + m_offsetX) % (ticksPerScreen)) * pixelsPerTick;
//kDebug() << curTimeX <<endl;
p->drawLine(curTimeX, cr.top(), curTimeX, cr.bottom());
//the following is liberally borrowed from OscilloscopeView::drawFloatingData
const FloatingProbeDataMap::iterator end = Oscilloscope::self()->m_floatingProbeDataMap.end();
for ( FloatingProbeDataMap::iterator it = Oscilloscope::self()->m_floatingProbeDataMap.begin(); it != end; ++it )
{
FloatingProbeData * probe = it.value();
StoredData<float> * data = &(probe->m_data);
if ( data->allocatedUpTo() == 0 )
continue;
bool logarithmic = probe->scaling() == FloatingProbeData::Logarithmic;
double lowerAbsValue = probe->lowerAbsValue();
double sf = ((cr.height()/Oscilloscope::self()->numberOfProbes())/2) / (logarithmic ? log(probe->upperAbsValue()/lowerAbsValue) : probe->upperAbsValue());
const int midHeight = Oscilloscope::self()->probePositioner->probePosition(probe);
//const int midHeight = cr.top() + cr.height()/2;
//const llong timeOffset = Oscilloscope::self()->scrollTime();
const llong timeOffset = Simulator::self()->time() - (FADESPEED * m_intervalsX * m_ticksPerIntervalX);
// 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() );
llong at = probe->findPos(timeOffset);
const llong maxAt = probe->insertPos();
llong prevTime = probe->toTime(at);
double v = data->dataAt((at>0)?at:0);
int prevY = int(midHeight - (logarithmic ? ( (v>0) ? log(v/lowerAbsValue) : -log(-v/lowerAbsValue) ) : v) * sf);
int prevX = (int((prevTime - timeOffset)*pixelsPerTick) + curTimeX) % cr.width();
while ( at < maxAt-1 )
{
at++;
ullong nextTime = probe->toTime(at);
double v = data->dataAt((at>0)?at:0);
int nextY = int(midHeight - (logarithmic ? ( (v>0) ? log(v/lowerAbsValue) : -log(-v/lowerAbsValue) ) : v) * sf);
int nextX = (int((nextTime - timeOffset)*pixelsPerTick) + curTimeX) % cr.width();
if(nextX < prevX)
{
prevX = 0;
}
//kDebug() <<at<<" "<<nextX<<" "<<nextY<<" "<<nextTime<<endl;
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 < curTimeX )
// p->drawLine( prevX, prevY, curTimeX, prevY );
}
//and this was liberally borrowed from OscilloscopeView::DrawLogicData
{
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 )
llong deltaAt = 1;
int totalDeltaAt = 1;
LogicProbeData * probe = it.value();
StoredData<LogicDataPoint> * data = &(probe->m_data);
if ( data->allocatedUpTo() == 0 )
continue;
const int midHeight = Oscilloscope::self()->probePositioner->probePosition(probe);
const llong timeOffset = Simulator::self()->time() - (FADESPEED * m_intervalsX * m_ticksPerIntervalX);//Oscilloscope::self()->scrollTime();
const int halfOutputHeight = ((cr.height()/Oscilloscope::self()->numberOfProbes())/2);
// 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 = ticksPerPixel;//int(LOGIC_UPDATE_RATE/pixelsPerSecond);
llong at = probe->findPos(timeOffset);
const llong maxAt = probe->insertPos();
llong prevTime = data->dataAt(at).time;
int prevX = (int((prevTime - timeOffset)*pixelsPerTick) + curTimeX) % cr.width();
bool prevHigh = data->dataAt(at).value;
int prevY = midHeight + int(prevHigh ? -halfOutputHeight : +halfOutputHeight);
while ( at < maxAt )
{
// Search for the next pos which will show up at our zoom level
llong previousAt = at;
llong dAt = deltaAt / totalDeltaAt;
while ( (dAt > 1) && (at < maxAt) && ( (llong(data->dataAt(at).time) - prevTime) != minTimeStep ) )
{
// Search forwards until we overshoot
while ( at < maxAt && ( llong(data->dataAt(at).time) - prevTime ) < minTimeStep )
at += dAt;
dAt /= 2;
// Search backwards until we undershoot
while ( (at < maxAt) && ( llong(data->dataAt(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) && ( llong(data->dataAt(at).time) - prevTime ) < minTimeStep) )
at++;
if ( at >= maxAt )
break;
// Update the average values
deltaAt += at - previousAt;
totalDeltaAt++;
bool nextHigh = data->dataAt(at).value;
if ( nextHigh == prevHigh )
continue;
llong nextTime = data->dataAt(at).time;
int nextX = (int((nextTime - timeOffset)*pixelsPerTick) + curTimeX) % cr.width();
int nextY = midHeight + int(nextHigh ? -halfOutputHeight : +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 );
}
}
}
