XYPlot.cc
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/*
* XYPlot.cc
*
* Created on: 29 oct. 2013
* Author: CS
*/
#include <fstream>
#include <iomanip>
#include <boost/lexical_cast.hpp>
#include <boost/algorithm/string.hpp>
#include "XYPlot.hh"
#include "ParamsNode.hh"
#include "AxesNode.hh"
#include "PlotLogger.hh"
#include "PlotOutput.hh"
#include "TimeUtil.hh"
#include "ParamMgr.hh"
#include "AxisLegendManager.hh"
using namespace AMDA::Parameters;
using namespace AMDA::Info;
namespace plot {
XYPlot::XYPlot(AMDA::Parameters::ParameterManager& manager,
boost::shared_ptr<Panel> panel) :
PanelPlotOutput(manager, panel), _isIsotropic(false) {
}
XYPlot::~XYPlot() {
}
/**
* @overload PanelPlotOutput::preparePlotArea()
*/
void XYPlot::preparePlotArea(double startTime, double stopTime, int intervalIndex) {
// for test, dump plot properties
const char* lBuildType=getenv("BUILD_TYPE");
if(lBuildType && std::string(lBuildType) == "Debug") {
std::ofstream out("xyPlot.txt");
dump(out);
out.close();
}
// Configure range of series and color.
configureSeriesAxis();
configureAxisLegend();
// Configure params legend
configureParamsLegend(startTime,stopTime,intervalIndex);
// If panel title is empty, replace it with start and end date.
if (_panel->getTitle()->_text.empty() || _panel->_updateTitleOnNextInterval) {
//Title must be updated during the next interval plot
_panel->_updateTitleOnNextInterval = true;
// Set start date and end date.
std::string lTimeFormat("%H:%M %d/%m/%y");
long int lStartTime = static_cast<long int>(startTime);
tm * lStartTimeTm = gmtime(&lStartTime);
char lStartTimeChr[80];
// Format date.
strftime(lStartTimeChr, 80, lTimeFormat.c_str(), lStartTimeTm);
long int lStopTime = static_cast<long int>(stopTime);
tm * lStopTimeTm = gmtime(&lStopTime);
char lStopTimeChr[80];
// Format date.
strftime(lStopTimeChr, 80, lTimeFormat.c_str(), lStopTimeTm);
std::string titleText = std::string(lStartTimeChr) + " - " + std::string(lStopTimeChr);
_panel->setTitleText(titleText.c_str());
}
PanelPlotOutput::preparePlotArea(startTime,stopTime,intervalIndex);
}
void XYPlot::createParameters(std::list<std::string>& usedParametersId_)
{
for (ParameterAxesList::iterator it = _parameterAxesList.begin();
it != _parameterAxesList.end(); ++it)
{
std::map<AMDA::Common::ParameterIndexComponent, SeriesProperties>::iterator ity;
AMDA::Parameters::ParameterSPtr originalYParam =
_parameterManager.getParameter(it->_originalParamId);
double samplingYValue = 0.;
double samplingXValue = 0.;
for (ity = it->getYSeriePropertiesMap().begin(); ity != it->getYSeriePropertiesMap().end();
++ity)
{
XSeriesProperties& xSerie = getSerieOnXAxis(ity->second.getXAxisId());
ParameterAxes& xparameter = getParameterAxeOnXAxis(ity->second.getXAxisId());
ParameterAxes* colorSerieParameterAxes = getParameterAxesByColorSerieId(ity->second.getColorSerieId());
AMDA::Parameters::ParameterSPtr originalColorParam;
if (colorSerieParameterAxes != NULL)
originalColorParam = _parameterManager.getParameter(colorSerieParameterAxes->_originalParamId);
AMDA::Parameters::ParameterSPtr usedXParam;
AMDA::Parameters::ParameterSPtr usedYParam;
AMDA::Parameters::ParameterSPtr originalXParam = _parameterManager.getParameter(xparameter._originalParamId);;
if (!ity->second.getComputeExpression().empty())
{
if (samplingXValue == 0.)
samplingXValue = getSamplingInTreeParameter(originalXParam);
double correctedSamplingValue = getCorrectedSamplingValue(ity->second.getMaxResolution(), samplingXValue);
if (abs(samplingXValue - correctedSamplingValue) > 1.)
{
//create resampling parameter for xparam
usedXParam = createSampledParameter(originalXParam, correctedSamplingValue);
}
else
{
usedXParam = originalXParam;
}
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedXParam->getId());
std::string expr = ity->second.getComputeExpression();
boost::replace_all(expr, OrbitParamComponentName, usedXParam->getId());
//create parameter from expression
usedYParam = _parameterManager.getParameterFromExpression(expr, usedXParam->getGapThreshold());
if (usedYParam == nullptr)
{
LOG4CXX_ERROR(gLogger, "XYPlot::createParameters - Cannot create parameter from expression " << expr);
continue;
}
AMDA::Info::ParamInfoSPtr paramYInfo = AMDA::Info::ParamMgr::getInstance()->getParamInfoFromId(usedYParam->getId(),true);
AMDA::Info::ParamInfoSPtr paramXInfo = AMDA::Info::ParamMgr::getInstance()->getParamInfoFromId(originalXParam->getInfoId(),true);
if (paramYInfo != nullptr)
{
paramYInfo->setShortName(ity->second.getComputeExpressionName());
if (paramXInfo != nullptr)
{
paramYInfo->setUnits(paramXInfo->getUnits());
paramYInfo->setCoordinatesSystem(paramXInfo->getCoordinatesSystem());
}
}
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedYParam->getId());
//link serie to this resampled parameter
ity->second.setParamId(usedYParam->getId());
xSerie.addParamId(usedYParam->getId(), usedXParam->getId());
if (originalColorParam != nullptr)
{
AMDA::Parameters::ParameterSPtr usedColorParam = createSampledParameterUnderReferenceParameter(originalColorParam, usedYParam);
//Add used color parameter to parameters list
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedColorParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedColorParam->getId());
//link this color parameter to the y serie
ity->second.setColorParamId(usedColorParam->getId());
//link the used parameter to the color serie
colorSerieParameterAxes->getColorSeriePropertiesById(ity->second.getColorSerieId()).addParamId(usedYParam->getId(), usedColorParam->getId());
//activate the Z Axis
ity->second.setZAxis(true);
}
usedYParam.reset();
continue;
}
if (samplingYValue == 0.)
samplingYValue = getSamplingInTreeParameter(originalYParam);
samplingXValue = getSamplingInTreeParameter(originalXParam);
switch (ity->second.getResamplingProperties().getType())
{
case ResamplingType::MANUAL :
{
LOG4CXX_DEBUG(gLogger, "XYPlot::createSeriesParameters - ResamplingType::MANUAL");
//create resampling parameters for xparam
usedXParam = createSampledParameter(originalXParam, ity->second.getResamplingProperties().getValue());
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedXParam->getId());
if (originalXParam == originalYParam)
{
//same original parameter => re-use xparam
usedYParam = usedXParam;
}
else
{
//create resampling parameters for xparam
usedYParam = createSampledParameter(originalYParam, ity->second.getResamplingProperties().getValue());
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedYParam->getId());
}
}
break;
case ResamplingType::AUTO :
case ResamplingType::XPARAM :
{
LOG4CXX_DEBUG(gLogger, "XYPlot::createSeriesParameters - ResamplingType::XPARAM");
double correctedSamplingValue = getCorrectedSamplingValue(ity->second.getMaxResolution(), samplingXValue);
if (abs(samplingXValue - correctedSamplingValue) > 1.)
{
//create resampling parameter for xparam
usedXParam = createSampledParameter(originalXParam, correctedSamplingValue);
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedXParam->getId());
if (originalXParam == originalYParam)
{
//same original parameter => re-use xparam
usedYParam = usedXParam;
}
else
{
//create resampling parameter for yparam
usedYParam = createSampledParameter(originalYParam, correctedSamplingValue);
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedYParam->getId());
}
}
else
{
//get original parameter for xparam
usedXParam = originalXParam;
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedXParam->getId());
if (originalXParam == originalYParam)
{
//same original parameter => re-use xparam
usedYParam = usedXParam;
}
else
{
//create resampled parameter under times of xparam for yparam
usedYParam = createSampledParameterUnderReferenceParameter(originalYParam, originalXParam);
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedYParam->getId());
}
}
}
break;
case ResamplingType::YPARAM :
LOG4CXX_DEBUG(gLogger, "XYPlot::createSeriesParameters - ResamplingType::YPARAM");
double correctedSamplingValue = getCorrectedSamplingValue(ity->second.getMaxResolution(), samplingYValue);
if (abs(samplingYValue - correctedSamplingValue) > 1.)
{
//create resampling parameter for xparam
usedXParam = createSampledParameter(originalXParam, correctedSamplingValue);
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedXParam->getId());
if (originalXParam == originalYParam)
{
//same original parameter => re-use xparam
usedYParam = usedXParam;
}
else
{
//create resampling parameter for yparam
usedYParam = createSampledParameter(originalYParam, correctedSamplingValue);
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedYParam->getId());
}
}
else
{
//get original parameter for yparam
usedYParam = originalYParam;
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedYParam->getId());
if (originalXParam == originalYParam)
{
//same original parameter => re-use yparam
usedXParam = usedYParam;
}
else
{
//create resampled parameter under times of yparam for cparam
usedXParam = createSampledParameterUnderReferenceParameter(originalXParam, originalYParam);
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedXParam->getId());
}
}
break;
}
//link serie to this resampled parameter
ity->second.setParamId(usedYParam->getId());
xSerie.addParamId(usedYParam->getId(), usedXParam->getId());
if (originalColorParam != nullptr)
{
AMDA::Parameters::ParameterSPtr usedColorParam = createSampledParameterUnderReferenceParameter(originalColorParam, usedYParam);
//Add used color parameter to parameters list
if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedColorParam->getId()) == usedParametersId_.end())
usedParametersId_.push_back(usedColorParam->getId());
//link this color parameter to the y serie
ity->second.setColorParamId(usedColorParam->getId());
//link the used parameter to the color serie
colorSerieParameterAxes->getColorSeriePropertiesById(ity->second.getColorSerieId()).addParamId(usedYParam->getId(), usedColorParam->getId());
//activate the Z Axis
ity->second.setZAxis(true);
}
}
}
}
/**
* Gets parameter that is it-self or a component on xAxis.
*/
ParameterAxes& XYPlot::getParameterAxeOnXAxis(const std::string& xAxisId) {
for (ParameterAxesList::iterator it = _parameterAxesList.begin();
it != _parameterAxesList.end(); ++it) {
std::map<AMDA::Common::ParameterIndexComponent, XSeriesProperties>::const_iterator itx;
for (itx = it->getXSeriePropertiesMap().begin();
itx != it->getXSeriePropertiesMap().end(); ++itx) {
if (itx->second.getAxisId() == xAxisId) {
return *it;
}
}
}
// xseries not found, not expected ... stop process
std::stringstream lError;
lError << "XYPlot::getSerieOnXAxis : no parameter for xAxis of id "
<< xAxisId;
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
/**
* Gets x serie configured on a given x axis id.
*/
XSeriesProperties& XYPlot::getSerieOnXAxis(const std::string& axisId_) {
for (ParameterAxesList::iterator paramAxeIt = _parameterAxesList.begin();
paramAxeIt != _parameterAxesList.end(); ++paramAxeIt) {
try {
XSeriesProperties& props = getSerieOnXAxisfromParameter(axisId_, *paramAxeIt);
// if not found, exception is raised
// if found, return serie
return props;
}
catch(PanelPlotOutputException& ex){
// nop
}
}
// xseries not found, not expected ... stop process
std::stringstream lError;
lError << "XYPlot::getSerieOnXAxis : no parameter for xAxis of id " << axisId_;
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
/**
* Gets x serie from a parameter configured on a given x axis id.
* @throw PanelPlotOutputException if not found
*/
XSeriesProperties& XYPlot::getSerieOnXAxisfromParameter(const std::string& axisId_,
ParameterAxes& parameter_) {
std::map<AMDA::Common::ParameterIndexComponent, XSeriesProperties>::iterator itx;
for (itx = parameter_.getXSeriePropertiesMap().begin();
itx != parameter_.getXSeriePropertiesMap().end(); ++itx) {
if (itx->second.getAxisId() == axisId_) {
return itx->second;
}
}
// xseries not found, not expected ... stop process
std::stringstream lError;
lError
<< "XYPlot::getXSeriefromParameter : no parameter for xAxis of id "
<< axisId_;
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
/*
* Dumps properties for test.
*/
void XYPlot::dump(std::ostream& out_){
PanelPlotOutput::dump(out_);
out_ << "isotropic=" << std::boolalpha << _isIsotropic;
}
void XYPlot::calculatePlotArea(Bounds& bounds_) {
PanelPlotOutput::calculatePlotArea(bounds_);
if (_isIsotropic) {
// Get bounds of panel
Bounds lPanelBounds(_panel->getBoundsInPlPage());
// Parse each parameter to define size of axis.
double lHorizontalAxisGap = 0;
Range lHorizontalRange;
double lVerticalAxisGap = 0;
Range lVerticalRange;
SeriesProperties lSeriesProperties;
boost::shared_ptr<Axis> lYAxis;
boost::shared_ptr<Axis> lXAxis;
for (auto param: _parameterAxesList) {
// Get Y axis
for (auto index: param.getYSerieIndexList(_pParameterValues)) {
lSeriesProperties = param.getYSeriePropertiesAt(index);
lYAxis = _panel->getAxis(lSeriesProperties.getYAxisId());
if (lYAxis.get() == nullptr) {
std::stringstream lError;
lError << "XYPlot::calculatePlotArea" << ": Y axis with id '" << lSeriesProperties.getYAxisId() << "' not found.";
BOOST_THROW_EXCEPTION(PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
lVerticalRange = lYAxis->getRange();
// Get gap for this parameter data
if (lVerticalRange.isSet()) {
double lTmpVerticalAxisGap = fabs(lVerticalRange.getMin() - lVerticalRange.getMax());
// We get the maximum gap in case where there are several parameter to draw on Y axis(axes).
lVerticalAxisGap = std::max(lVerticalAxisGap, lTmpVerticalAxisGap);
}
}
// Get X axis.
for (auto lXSeries: param.getXSeriePropertiesMap()) {
lXAxis = _panel->getAxis(lXSeries.second.getAxisId());
if (lXAxis.get() == nullptr) {
std::stringstream lError;
lError << "XYPlot::calculatePlotArea" << ": X axis with id '" << lSeriesProperties.getXAxisId() << "' not found.";
BOOST_THROW_EXCEPTION(PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
lHorizontalRange = lXAxis->getRange();
// Get gap for this parameter data
if (lHorizontalRange.isSet()) {
double lTmpHorizontalAxisGap = fabs(lHorizontalRange.getMin() - lHorizontalRange.getMax());
lHorizontalAxisGap = std::max(lHorizontalAxisGap, lTmpHorizontalAxisGap);
}
}
// If one of gap is 0 do nothing (gap of range can't be 0).
if ((lVerticalAxisGap == 0) || (lHorizontalAxisGap == 0))
continue;
double lRequestedRatio = lVerticalAxisGap / lHorizontalAxisGap;
double lPlotAreaRatio = bounds_._height / bounds_._width;
double pageWidth = std::get < 1 > (_panel->_page->getSize());
double pageHeight = std::get < 0 > (_panel->_page->getSize());
double lPageRatio = 0;
// Page width and height doesn't depend on orientation...
// so we computes page ratio depending on orientation...
if (_panel->_page->_orientation == PlotCommon::Orientation::LANDSCAPE)
lPageRatio = pageWidth / pageHeight;
else
lPageRatio = pageHeight / pageWidth;
// Calculate width of plot area to keep uniformity of the two scale (axes).
double lPlotAreaIsoW = ((bounds_._height * lPageRatio) / lRequestedRatio);
// Calculate height of plot area to keep uniformity of the two scale (axes).
double lPlotAreaIsoH = ((bounds_._width / lPageRatio) * lRequestedRatio);
// When ratio is lower than 1. it signifies that plot area width is bigger than height.
// So reduce width.
// The upper condition is only valid if new width is purely lower than current plot area width.
// Otherwise we must modify height.
if ( ((lPlotAreaRatio < 1.) && (lPlotAreaIsoW < bounds_._width)) ||
((lPlotAreaRatio > 1.) && (lPlotAreaIsoH > bounds_._height))) {
// Calculate X min bounds of plot area if it can be centered.
double lPlotAreaIsoX = ((lPanelBounds._width - lPlotAreaIsoW) / 2.) + lPanelBounds._x;
// Check if plot area can be centered.
if (lPlotAreaIsoX > bounds_._x) {
bounds_._x = lPlotAreaIsoX;
} else {
bounds_._x += (bounds_._width - lPlotAreaIsoW) / 2.;
}
bounds_._width = lPlotAreaIsoW;
} else {
// Calculate Y min bounds of plot area if it can be centered.
double lPlotAreaIsoY = ((lPanelBounds._height - lPlotAreaIsoH) / 2.) + lPanelBounds._y;
// Check if plot area can be centered.
if (lPlotAreaIsoY > bounds_._y) {
bounds_._y = lPlotAreaIsoY;
} else {
bounds_._y += (bounds_._height - lPlotAreaIsoH) / 2.;
}
bounds_._height = lPlotAreaIsoH;
}
}
}
}
std::string XYPlot::formatDateTime (double dateTime, const std::string &format) {
long int lTime = static_cast<long int>(dateTime);
tm * lTimeTm = gmtime(&lTime);
// Format date.
char timeBuf[80];
strftime (timeBuf, sizeof (timeBuf), format.c_str(), lTimeTm);
return std::string(timeBuf);
}
void XYPlot::drawTimeTicks(SeriesProperties& pSeries, AMDA::Common::ParameterIndexComponent pParamIndex,
double* timeValues, int nbTimeValues) {
LOG4CXX_DEBUG(gLogger, "XYPlot::drawTimeTicks");
TimeTickProperties ttProps = pSeries.getTimeTickProperties();
// Draw Time ticks if required !
if ((ttProps.getStep().compare("0") == 0) && (ttProps.getNumber() == 0))
return;
// Get parameter sampling, data, start time and end time
ParameterAxes& xParameter = getParameterAxeOnXAxis(pSeries.getXAxisId());
std::string paramId = pSeries.getParamId();
XSeriesProperties& xSerie = getSerieOnXAxisfromParameter(pSeries.getXAxisId(), xParameter);
ParameterData& xData = (*_pParameterValues)[xSerie.getXParamIds()[paramId]];
ParameterData& yData = (*_pParameterValues)[paramId];
double startTime = timeValues[0];
double stopTime = timeValues[nbTimeValues-1];
double totalDuration = stopTime - startTime;
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks totalDuration " << totalDuration);
// Compute x and y coordinates for major and minor time ticks
int nbTotMajor = 0;
int nbTotMinor = 0;
int nbMinorPerMajor = ttProps.getMinor();
if (ttProps.getStep().compare("0") != 0)
{
double deltaMajorTick, deltaMinorTick;
if (ttProps.getStep().compare("auto") == 0) {
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks auto");
deltaMajorTick = TimeAxis::computeAutoMajorTickSpace (startTime, stopTime);
}
else {
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks time step");
deltaMajorTick = DD_Time2Double (ttProps.getStep().c_str());
}
nbTotMajor = (int) (totalDuration / deltaMajorTick) + 1;
deltaMinorTick = deltaMajorTick / (nbMinorPerMajor + 1);
// Update totalDuration & stopTime depending on the nbMinorPerMajor value
if (nbMinorPerMajor == 0) {
nbTotMinor = 0;
totalDuration = (nbTotMajor - 1) * deltaMajorTick;
stopTime = startTime + totalDuration;
}
else {
nbTotMinor = (nbTotMajor-1) * nbMinorPerMajor;
nbTotMinor += (int) ((totalDuration - (nbTotMajor - 1) * deltaMajorTick) / deltaMinorTick);
totalDuration = (nbTotMajor + nbTotMinor - 1) * deltaMinorTick;
stopTime = startTime + totalDuration;
}
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks totalDuration " << totalDuration);
}
else if (ttProps.getNumber() != 0) {
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks step number");
nbTotMajor = ttProps.getNumber();
nbTotMinor = (nbTotMajor-1) * nbMinorPerMajor;
}
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks nbMajor " << nbTotMajor);
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks nbMinor " << nbTotMinor);
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks deltaMajorDuration " << deltaMajorTick);
// Build & compute graduation
double *majorX, *majorY, *minorX, *minorY, *tickLabel;
majorX = new double [nbTotMajor];
majorY = new double [nbTotMajor];
minorX = new double [nbTotMinor];
minorY = new double [nbTotMinor];
tickLabel = new double [nbTotMajor];
int nbGrad = nbTotMajor + nbTotMinor;
int curMajorGrad = 0;
int curMinorGrad = 0;
//XSeriesProperties& xSerie = getSerieOnXAxisfromParameter(pSeries.getXAxisId(), xParameter);
for (int grad=0; grad<nbGrad; grad++) {
double curTime = startTime + grad * (totalDuration / (nbGrad - 1));
// Compute major graduation pos & Record tick label (based on date)
if ((grad%(nbMinorPerMajor+1)) == 0) {
tickLabel [curMajorGrad] = curTime;
majorX [curMajorGrad] = xData.getInterpolatedValue (curTime, xSerie.getIndex());
majorY [curMajorGrad] = yData.getInterpolatedValue (curTime, pParamIndex);
curMajorGrad++;
}
// Compute minor graduation pos
else {
minorX [curMinorGrad] = xData.getInterpolatedValue (curTime, xSerie.getIndex());
minorY [curMinorGrad] = yData.getInterpolatedValue (curTime, pParamIndex);
curMinorGrad++;
}
}
// Draw first time tick major symbol, other time tick major Symbols and minor time ticks symbols
PlWindow lPlWindow = PlWindow(_panel->getAxis(pSeries.getXAxisId())->getRange().getMin(), _panel->getAxis(pSeries.getXAxisId())->getRange().getMax(),
_panel->getAxis(pSeries.getYAxisId())->getRange().getMin(), _panel->getAxis(pSeries.getYAxisId())->getRange().getMax());
_pls->wind(std::get<0>(lPlWindow), std::get<1>(lPlWindow), std::get<2>(lPlWindow), std::get<3>(lPlWindow));
if (nbTotMajor != 0) {
drawSymbols(
ttProps.getFirstSymbol().getType(),
ttProps.getFirstSymbol().getSize(), 1.,
ttProps.getFirstSymbol().getColor(),
1, majorX, majorY);
drawSymbols(
ttProps.getSymbol().getType(),
ttProps.getSymbol().getSize(), 1.,
ttProps.getSymbol().getColor(),
nbTotMajor-1, &majorX[1], &majorY[1]);
}
if (nbTotMinor != 0) {
drawSymbols(
ttProps.getSymbol().getType(),
ttProps.getSymbol().getSize(), 0.5,
ttProps.getSymbol().getColor(),
nbTotMinor, minorX, minorY);
}
// Draw text Label for major tick by building a list of textPlots
if (nbTotMajor != 0) {
TextPlots textPlots;
TextPlot baseTextPlot;
baseTextPlot._color = ttProps.getColor();
baseTextPlot.setFont(ttProps.getFont());
std::string computedTimeFormat = getPlTimeFormat (std::string("hh:mm"), startTime, stopTime, nbTotMajor);
// LOG4CXX_DEBUG(gLogger, "drawTimeTicks computedTimeFormat" << computedTimeFormat);
Range lYRange = getYAxisRange (pSeries, _panel->getAxis(pSeries.getYAxisId()));
double deltaX = 0; // (lXRange.getMax () - lXRange.getMin ()) / 80;
double deltaY = (lYRange.getMax () - lYRange.getMin ()) / 80;
for (int g=0; g<nbTotMajor; g++) {
if (isNAN(majorX[g]) || isNAN(majorY[g]))
continue;
boost::shared_ptr<TextPlot> textPlot (new TextPlot (baseTextPlot));
textPlot->_x = boost::lexical_cast<std::string>(majorX [g] + deltaX);
textPlot->_y = boost::lexical_cast<std::string>(majorY [g] + deltaY);
textPlot->_text = formatDateTime (tickLabel [g], computedTimeFormat);
textPlots.push_back (textPlot);
}
// Draw textPlots for major graduations
drawTextPlots (_panel->getAxis(pSeries.getXAxisId()), _panel->getAxis(pSeries.getYAxisId()), lPlWindow, textPlots);
}
// Free major & minor graduations positions
delete [] majorX;
delete [] majorY;
delete [] minorX;
delete [] minorY;
delete [] tickLabel;
}
void XYPlot::drawSeries(double startDate, double stopDate, int intervalIndex, std::string pParamId,
SeriesProperties& pSeries, AMDA::Common::ParameterIndexComponent pParamIndex,
ParameterAxes& param, bool moreThanOneSerieForAxis) {
// This will configure window, draw axes (if needed) and legend of axes.
LOG4CXX_DEBUG(gLogger, "XYPlot::drawSeries");
PanelPlotOutput::drawSeries(startDate, stopDate, intervalIndex, pParamId, pSeries, pParamIndex, param, moreThanOneSerieForAxis);
//get x serie values
double* lXData = NULL;
double* lXTime = NULL;
int nbXValues = 0;
if (!getXComputedValuesFromSerieAndInterval(startDate, stopDate, pSeries,
&lXData, &lXTime, nbXValues))
{
LOG4CXX_DEBUG(gLogger, "XYPlot::drawSeries - Cannot get computed values for x serie");
return;
}
//get y serie values
double* lYData = NULL;
double* lYTime = NULL;
int nbYValues = 0;
if (!getComputedValuesFromSerieAndInterval(startDate, stopDate, pSeries,
pParamIndex, &lYData, &lYTime, nbYValues))
{
LOG4CXX_DEBUG(gLogger, "XYPlot::drawSeries - Cannot get computed values for y serie");
return;
}
double *coloredComputedValues = NULL;
double *coloredTimeValues = NULL;
//get colored value if needed
if (!pSeries.getColorParamId().empty() && (_panel->getColorAxis() != nullptr))
{
int nbColoredValues;
if (!getColoredComputedValuesFromSerieAndInterval(startDate, stopDate, pSeries,
&coloredComputedValues, &coloredTimeValues, nbColoredValues))
{
LOG4CXX_DEBUG(gLogger, "XYPlot::drawSeries - Cannot get computed values for colored parameter");
return;
}
}
PlWindow lPlWindow = PlWindow(_panel->getAxis(pSeries.getXAxisId())->getRange().getMin(), _panel->getAxis(pSeries.getXAxisId())->getRange().getMax(),
_panel->getAxis(pSeries.getYAxisId())->getRange().getMin(), _panel->getAxis(pSeries.getYAxisId())->getRange().getMax());
_pls->wind(std::get<0>(lPlWindow), std::get<1>(lPlWindow),
std::get<2>(lPlWindow), std::get<3>(lPlWindow));
//draw serie
Color lineColor = getSerieLineColor(pSeries, moreThanOneSerieForAxis);
Color symbolColor = getSerieSymbolColor(pSeries, lineColor);
drawSymbols(
pSeries.getSymbolProperties().getType(),
pSeries.getSymbolProperties().getSize(), 1.,
symbolColor,
nbYValues, lXData, lYData, coloredComputedValues);
drawLines(
pSeries.getLineProperties().getType(),
pSeries.getLineProperties().getStyle(),
pSeries.getLineProperties().getWidth(),
lineColor,
nbYValues, lXData, lYData, coloredComputedValues);
// Draw eventual Time ticks
drawTimeTicks(pSeries, pParamIndex, lYTime, nbYValues);
//draw interval
drawSerieInterval(pSeries,lXData,lYData,lYTime,nbYValues,intervalIndex);
//add serie to param legend
addSerieToParamsLegend(pSeries,pParamIndex,param._originalParamId, lineColor,symbolColor,startDate, stopDate, intervalIndex);
delete[] lXData;
delete[] lYData;
if (coloredComputedValues != NULL)
delete[] coloredComputedValues;
}
/**
* Draws Curve
*/
void XYPlot::drawCurvePlot(CurvePlot &curvePlot)
{
if (curvePlot.isDrawn())
return;
LOG4CXX_DEBUG(gLogger, "XYPlot::drawCurvePlot");
//retrieve associated y serie properties
for (ParameterAxesList::iterator it = _parameterAxesList.begin();
it != _parameterAxesList.end(); ++it)
{
std::map<AMDA::Common::ParameterIndexComponent, SeriesProperties>::iterator ity;
for (ity = it->getYSeriePropertiesMap().begin(); ity != it->getYSeriePropertiesMap().end();
++ity)
{
if (curvePlot._serieId == ity->second.getId())
{
//get curve points
int resolution = ity->second.getMaxResolution();
if (resolution <= 0)
resolution = 100;
CurveFunctionWriter::CurvePointList pointList = curvePlot.getPointList(resolution);
if (pointList.empty()) {
return; //nothing to plot
}
//prepare data in relation to axis of the associated serie
double xData[pointList.size()];
double yData[pointList.size()];
double xMin = DBL_MAX;
double xMax = -DBL_MAX;
double yMin = DBL_MAX;
double yMax = -DBL_MAX;
int i = 0;
for (auto point : pointList)
{
xData[i] = point.x;
xMin = std::min(xMin,point.x);
xMax = std::max(xMax,point.x);
yData[i] = point.y;
yMin = std::min(yMin,point.y);
yMax = std::max(yMax,point.y);
++i;
}
boost::shared_ptr<Axis> lXAxis(_panel->getAxis(ity->second.getXAxisId()));
if ((lXAxis == nullptr))
{
std::stringstream lError;
lError << "XYPlot::drawCurvePlot : cannot retrieve X Axis";
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
double* lXData = _panel->getAxis(ity->second.getXAxisId())->getComputedValues(
xData,
pointList.size(), xMin, xMax);
if(lXData == NULL)
{
std::stringstream lError;
lError << "XYPlot::drawCurvePlot : no value for x, check the request x parameter definition";
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
boost::shared_ptr<Axis> lYAxis(_panel->getAxis(ity->second.getYAxisId()));
if ((lYAxis == nullptr))
{
std::stringstream lError;
lError << "XYPlot::drawCurvePlot : cannot retrieve Y Axis";
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
double* lYData = _panel->getAxis(ity->second.getYAxisId())->getComputedValues(
yData,
pointList.size(), yMin, yMax);
if(lYData == NULL)
{
std::stringstream lError;
lError << "XYPlot::drawCurvePlot : no value for y, check the request y parameter definition";
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
Range lXRange = lXAxis->getRange();
Range lYRange = lYAxis->getRange();
PlWindow lPlWindow = PlWindow(lXRange.getMin(), lXRange.getMax(), lYRange.getMin(), lYRange.getMax());
_pls->wind(std::get<0>(lPlWindow), std::get<1>(lPlWindow), std::get<2>(lPlWindow), std::get<3>(lPlWindow));
//draw the curve
drawLines(
LineType::LINE,
curvePlot._style,
curvePlot._width,
curvePlot._color,
pointList.size(), lXData, lYData);
curvePlot.setDrawn(true);
//delete data
delete [] lXData;
delete [] lYData;
return;
}
}
}
//cannot retrieve the associted y serie => exception
std::stringstream lError;
lError << "XYPlot::drawCurvePlots : y serie with id " << curvePlot._serieId << " not found.";
BOOST_THROW_EXCEPTION(PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
void XYPlot::configureSeriesAxis() {
// map<X/YAxisId, automaticRange>
std::map<std::string, Range> lAxisRangeMap;
Range lColorAxeRange;
boost::shared_ptr<ColorAxis> lZAxis = _panel->getColorAxis();
SeriesProperties lSeriesProperties;
// Parse each parameter to define on which axis to draw series.
for (auto param: _parameterAxesList) {
// Configure range of X axis.
for (auto lXSeries: param.getXSeriePropertiesMap()) {
boost::shared_ptr<Axis> lXAxis = _panel->getAxis(lXSeries.second.getAxisId());
if (lXAxis.get() == nullptr) {
std::stringstream lError;
lError << "XYPlot::configureSeriesAxis" << ": X axis with id '" << lSeriesProperties.getXAxisId() << "' not found.";
BOOST_THROW_EXCEPTION(PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
lXAxis->_used = true;
Range lXRange(lXAxis->getRange());
// If user didn't set a range, calculate range automatically (based on parameters values).
if (!lXRange.isSet()) {
Range lEstimatedRange(lAxisRangeMap[lXAxis->_id]);
// for each paramId get min and max value.
for (auto paramId: lXSeries.second.getXParamIds()) {
ParameterData& xData = (*_pParameterValues)[lXSeries.second.getXParamIds()[paramId.first]];
Range lRangeSampling(xData.getMin(lXSeries.first), xData.getMax(lXSeries.first));
if (!lEstimatedRange.isSet()) {
lEstimatedRange = lRangeSampling;
} else {
lEstimatedRange.setMin(std::min(lEstimatedRange.getMin(), lRangeSampling.getMin()));
lEstimatedRange.setMax(std::max(lEstimatedRange.getMax(), lRangeSampling.getMax()));
}
}
lAxisRangeMap[lXAxis->_id] = lEstimatedRange;
}
}
// Get number of series to draw
// For each "Y" index of parameter identify on which axis series must be drawn.
// Also configure X axis for range.
for (auto index: param.getYSerieIndexList(_pParameterValues)) {
lSeriesProperties = param.getYSeriePropertiesAt(index);
boost::shared_ptr<Axis> lYAxis = _panel->getAxis(lSeriesProperties.getYAxisId());
if (lYAxis.get() == nullptr) {
std::stringstream lError;
lError << "XYPlot::configureSeriesAxis" << ": Y axis with id '" << lSeriesProperties.getYAxisId() << "' not found.";
BOOST_THROW_EXCEPTION(PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
lYAxis->_used = true;
// Configure range for Y axis.
Range lYRange(lYAxis->getRange());
// If range status for this axis is set by the user do not update range "automatically".
if (isnan(lYRange.getMin()) && isnan(lYRange.getMax())) {
ParameterData& yData = (*_pParameterValues)[lSeriesProperties.getParamId()];
Range lEstimatedRange(lAxisRangeMap[lYAxis->_id]);
Range lParamIndexRange(
yData.getMin(index), yData.getMax(index));
if (isnan(lEstimatedRange.getMin()) && isnan(lEstimatedRange.getMax())) {
lEstimatedRange.setMin(lParamIndexRange.getMin());
lEstimatedRange.setMax(lParamIndexRange.getMax());
} else {
lEstimatedRange.setMin(std::min(lEstimatedRange.getMin(), lParamIndexRange.getMin()));
lEstimatedRange.setMax(std::max(lEstimatedRange.getMax(), lParamIndexRange.getMax()));
}
lEstimatedRange._extend = lYRange._extend;
lAxisRangeMap[lYAxis->_id] = lEstimatedRange;
}
// Set ZAxis range if a color param is defined for this serie
if (lZAxis != nullptr)
{
if (!lSeriesProperties.getColorParamId().empty())
{
lZAxis->_used = true;
Range lRange(lZAxis->getRange());
ParameterAxes* colorSerieParameterAxes = getParameterAxesByColorSerieId(lSeriesProperties.getColorSerieId());
if (colorSerieParameterAxes == NULL)
continue;
ColorSeriesProperties& colorSerieProp = colorSerieParameterAxes->getColorSeriePropertiesById(lSeriesProperties.getColorSerieId());
// If range status for this axis is set by the user do not update range "automatically".
if (isnan(lRange.getMin()) && isnan(lRange.getMax())) {
Range lEstimatedRange(lColorAxeRange);
Range lParamIndexRange(
(*_pParameterValues)[lSeriesProperties.getColorParamId()].getMin(
colorSerieProp.getIndex()),
(*_pParameterValues)[lSeriesProperties.getColorParamId()].getMax(
colorSerieProp.getIndex()));
if (isnan(lEstimatedRange.getMin()) && isnan(lEstimatedRange.getMax())) {
lEstimatedRange.setMin(lParamIndexRange.getMin());
lEstimatedRange.setMax(lParamIndexRange.getMax());
} else {
lEstimatedRange.setMin(std::min(lEstimatedRange.getMin(), lParamIndexRange.getMin()));
lEstimatedRange.setMax(std::max(lEstimatedRange.getMax(), lParamIndexRange.getMax()));
}
lEstimatedRange._extend = lRange._extend;
lColorAxeRange = lEstimatedRange;
}
}
}
}
}
// Update range of axis.
for (auto lAxis: lAxisRangeMap) {
_panel->getAxis(lAxis.first)->setRange(lAxis.second);
}
if (lZAxis != nullptr && lColorAxeRange.isSet())
lZAxis->setRange(lColorAxeRange);
}
void XYPlot::configureAxisLegend () {
// Y axis
AxisLegendManager::configureYAxisLegendForSeries(this);
// X axis
AxisLegendManager::configureXAxisLegendForSeries(this);
// Z axis
AxisLegendManager::configureColorAxisLegendForSeries(this);
}
/*
* @brief Get computed X values (in relation with the x axis definition) for a serie and a time interval
* Do not forget to delete computedValues !!
* Don't delete timeValues !!
*/
bool XYPlot::getXComputedValuesFromSerieAndInterval(double startDate, double stopDate, SeriesProperties &rSeriesProperties,
double** computedValues, double** timeValues, int& nbValues)
{
LOG4CXX_DEBUG(gLogger, "XYPlot::getXComputedValuesFromSerieAndInterval");
ParameterAxes& xparameter = getParameterAxeOnXAxis(rSeriesProperties.getXAxisId());
XSeriesProperties& xSerie = getSerieOnXAxisfromParameter(
rSeriesProperties.getXAxisId(), xparameter);
//get parameter x data for this serie
ParameterData& xData = (*_pParameterValues)[xSerie.getXParamIds()[rSeriesProperties.getParamId()]];
int startIndex;
double *valuesInterval = xData.getIntervalValues(startDate, stopDate, xSerie.getIndex(),
startIndex, nbValues);
if (valuesInterval == NULL)
{
LOG4CXX_DEBUG(gLogger, "XYPlot::getXComputedValuesFromSerieAndInterval - Cannot find data for the x serie");
return false;
}
//get computed data for interval [startDate, stopDate] in relation with the serie y axis
(*computedValues) = _panel->getAxis(rSeriesProperties.getXAxisId())->getComputedValues(
valuesInterval,
nbValues,
xSerie.getMin(),
xSerie.getMax());
//get time values
(*timeValues) = &xData.getTimes()[startIndex];
return true;
}
/*
* @overload PanelPlotOutput::getSerieParamsLegendString Return the associated params legend to a xy serie
*/
std::string XYPlot::getSerieParamsLegendString(SeriesProperties &rSeriesProperties,
AMDA::Common::ParameterIndexComponent& index, std::string originalParamId)
{
//retrieve x axis properties
ParameterAxes& xparameter = getParameterAxeOnXAxis(rSeriesProperties.getXAxisId());
XSeriesProperties xSerie = getSerieOnXAxisfromParameter(
rSeriesProperties.getXAxisId(), xparameter);
// Retrieve ParamInfo Manager
ParamMgr *piMgr =ParamMgr::getInstance();
// Build parameter text legend depending on the availability of paramInfo
// for Y and X component
//For y component, re-use the text of the PanelPlotOutput
std::stringstream paramLegendText;
paramLegendText << PanelPlotOutput::getSerieParamsLegendString(rSeriesProperties,index,originalParamId);
// Try to retrieve informations from paramInfo for Y componenet
//ParameterSPtr p = _parameterManager.getParameter(rSeriesProperties.getParamId());
paramLegendText << " = f(";
// Try to retrieve informations from paramInfo for X component
ParameterSPtr p = _parameterManager.getParameter(xparameter._originalParamId);
ParamInfoSPtr paramInfo = piMgr->getParamInfoFromId(p->getInfoId());
// Build parameter text legend depending on the availability of paramInfo
if (paramInfo)
{
if ((xSerie.getIndex().getDim1Index() == -1) && (xSerie.getIndex().getDim2Index() == -1))
{
// parameter legend text = short_name
paramLegendText << paramInfo->getShortName();
}
else
{
if (paramInfo->getComponents(xSerie.getIndex()).empty() == false)
// parameter legend text = components at index index]
paramLegendText << paramInfo->getComponents(xSerie.getIndex());
else
{
// parameter legend text = short_name [index]
paramLegendText << paramInfo->getShortName() << "[" << xSerie.getIndex().getDim1Index();
if (xSerie.getIndex().getDim2Index() != -1)
paramLegendText << "," << xSerie.getIndex().getDim2Index();
paramLegendText << "]";
}
}
}
else
{
if ((xSerie.getIndex().getDim1Index() == -1) && (xSerie.getIndex().getDim2Index() == -1))
// parameter legend text = _originalParamId
paramLegendText << xparameter._originalParamId;
else
{
// parameter legend text = _originalParamId [index]
paramLegendText << xparameter._originalParamId << "[" << xSerie.getIndex().getDim1Index();
if (xSerie.getIndex().getDim2Index() != -1)
paramLegendText << "," << xSerie.getIndex().getDim2Index();
paramLegendText << "]";
}
}
paramLegendText << ")";
return paramLegendText.str();
}
} /* namespace plot */