/*
 * HistoPlot.cc
 *
 *  Created on: 29 oct. 2013
 *      Author: CS
 */

#include <fstream>
#include <iomanip>
#include <boost/lexical_cast.hpp>
#include <boost/algorithm/string.hpp>

#include "HistoPlot.hh"
#include "ParamsNode.hh"
#include "AxesNode.hh"
#include "Axis.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 {

HistoPlot::HistoPlot(AMDA::Parameters::ParameterManager& manager,
		boost::shared_ptr<Panel> panel) :
		PanelPlotOutput(manager, panel){

}

/**
 * @overload PanelPlotOutput::preparePlotArea()
 */
void HistoPlot::preparePlotArea(double startTime, double stopTime, int intervalIndex, std::vector<std::string>* ttNames) {
	// for test, dump plot properties
	const char* lBuildType=getenv("BUILD_TYPE");
	if(lBuildType && std::string(lBuildType) == "Debug") {
		std::ofstream out("HistoPlot.txt");
		dump(out);
		out.close();
	}

	// Configure range of series and color.
	configureSeriesAxis(startTime,stopTime);
	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("%Y/%m/%d %H:%M:%S");

		long int lStartTime = static_cast<long int>(startTime);
		tm * lStartTimeTm = gmtime(&lStartTime);
		char lStartTimeChr[80];

		// Format date.
		strftime(lStartTimeChr, 80, lTimeFormat.c_str(), lStartTimeTm);
		std::string lStartTimeStr= lStartTimeChr;
		lStartTimeStr += '.'+std::to_string(startTime -lStartTime ).substr(2,3);

		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 lStopTimeStr= lStopTimeChr;
		lStopTimeStr += '.'+std::to_string(stopTime -lStopTime ).substr(2,3);
		std::string titleText = lStartTimeStr + " - " + lStopTimeStr;

		if(_panel->_page->_superposeMode){

			std::string superposedModeText = "Events from ";
			if (ttNames != nullptr) {
				// Iterate through the vector's elements using the pointer
				for (const std::string& name : *ttNames) {
					if (name == ttNames->back() && ttNames->size()>1)
						superposedModeText +=" and '"+name+"' in "+titleText;
					else if (ttNames->size()==1)
						superposedModeText +=" '"+name+"' in "+titleText;
					else if (name == ttNames->at(ttNames->size()-2) && ttNames->size()>1)
						superposedModeText += "'"+name+"'";
					else
						superposedModeText += "'"+name+"',";
				}
			}

			_panel->setTitleText(superposedModeText.c_str());
		}
		else{
			_panel->setTitleText(titleText.c_str());
		}
	}

	PanelPlotOutput::preparePlotArea(startTime,stopTime,intervalIndex, ttNames);
}

void HistoPlot::createParameters(std::list<std::string>& usedParametersId_)
{

	for (ParameterAxesList::iterator it = _parameterAxesList.begin();
				it != _parameterAxesList.end(); ++it)
	{
		AMDA::Parameters::ParameterSPtr usedXParam;
		AMDA::Parameters::ParameterSPtr usedYParam;
		AMDA::Parameters::ParameterSPtr usedColorParam;

		for (auto pHistogramProperties : it->getHistogramSeriesPropertiesList())
		{
			if(pHistogramProperties != nullptr){
				if(pHistogramProperties->getHistogramType() == "histogram1d"){
					AMDA::Parameters::ParameterSPtr originalXParam = _parameterManager.getParameter(it->_originalParamId);
					if(!pHistogramProperties->getHistotypeProperties().getParamId().empty()) {
						AMDA::Parameters::ParameterSPtr originalYParam =_parameterManager.getParameter(pHistogramProperties->getHistotypeProperties().getParamId());
						usedYParam = createSampledParameterUnderReferenceParameter(originalYParam, originalXParam);
						if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
							usedParametersId_.push_back(usedYParam->getId());
						pHistogramProperties->getHistotypeProperties().setParamId(usedYParam->getId());
					}
					
					if (std::find (usedParametersId_.begin(),usedParametersId_.end(),originalXParam->getId()) == usedParametersId_.end())
									usedParametersId_.push_back(originalXParam->getId());
					pHistogramProperties->setParamId(originalXParam->getId());
					pHistogramProperties->setZAxis(false);
				}
				else if(pHistogramProperties->getHistogramType() == "histogram2d"){
					AMDA::Parameters::ParameterSPtr originalYParam = _parameterManager.getParameter(it->_originalParamId);
					ParameterAxes* xSerieParameterAxes = getParameterAxesByXSerieId(pHistogramProperties->getXId());
					XSeriesProperties& xSerie = xSerieParameterAxes->getXSeriePropertiesById(pHistogramProperties->getXId());
					AMDA::Parameters::ParameterSPtr originalXSerieParam = _parameterManager.getParameter(xSerieParameterAxes->_originalParamId);
					AMDA::Parameters::ParameterSPtr originalColorParam;

					if(pHistogramProperties->getHistotypeProperties().getParamId() != ""){
						originalColorParam = _parameterManager.getParameter(pHistogramProperties->getHistotypeProperties().getParamId());
					}

					getUsedParameters(originalXSerieParam,originalYParam,originalColorParam,pHistogramProperties->getResamplingProperties(),-1,
										usedXParam,usedYParam,usedColorParam );

					if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedXParam->getId()) == usedParametersId_.end())
								usedParametersId_.push_back(usedXParam->getId());

					if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedYParam->getId()) == usedParametersId_.end())
									usedParametersId_.push_back(usedYParam->getId());

					if (originalColorParam != nullptr)
					{
						if (std::find (usedParametersId_.begin(),usedParametersId_.end(),usedColorParam->getId()) == usedParametersId_.end())
							usedParametersId_.push_back(usedColorParam->getId());

						pHistogramProperties->getHistotypeProperties().setParamId(usedColorParam->getId());
						
					}
					pHistogramProperties->setZAxis(true);
					//link serie to this resampled parameter
					pHistogramProperties->setParamId(usedYParam->getId());
					xSerie.setParamId(usedXParam->getId());
				}
			}
		}
    }
}

void HistoPlot::getUsedParameters(AMDA::Parameters::ParameterSPtr originalXParam_,AMDA::Parameters::ParameterSPtr originalYParam_,
								AMDA::Parameters::ParameterSPtr originalZParam_, ResamplingProperties &resamplingProperties_,
								int /*maxResolution_*/,AMDA::Parameters::ParameterSPtr &usedXParam_,
								AMDA::Parameters::ParameterSPtr &usedYParam_,AMDA::Parameters::ParameterSPtr &usedZParam_)
{
	switch (resamplingProperties_.getType())
	{
	case ResamplingType::MANUAL :
		{
			LOG4CXX_ERROR(gLogger, "HistoPlot::getUsedParameters - ResamplingType::MANUAL not available");
		}
		break;
	case ResamplingType::AUTO   :
	case ResamplingType::XPARAM :
		LOG4CXX_DEBUG(gLogger, "HistoPlot::getUsedParameters - ResamplingType::XPARAM");
		//get original parameter for xparam
		usedXParam_ = originalXParam_;
		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_);
		}
		break;
	case ResamplingType::YPARAM :
		LOG4CXX_DEBUG(gLogger, "HistoPlot::getUsedParameters - ResamplingType::YPARAM");
		//get original parameter for yparam
		usedYParam_ = originalYParam_;
		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_);
		}
		break;
	}
	if (originalZParam_ != nullptr)
	{
		usedZParam_ = createSampledParameterUnderReferenceParameter(originalZParam_, usedYParam_);
	}
}

void HistoPlot::configureSeriesAxis(double startDate, double stopDate) {
	// map<X/YAxisId, automaticRange>
	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) {

		for (auto pHistogramProperties : param.getHistogramSeriesPropertiesList())
		{
			if(pHistogramProperties != nullptr){ 

					boost::shared_ptr<Axis> lXAxis = _panel->getAxis(pHistogramProperties->getXAxisId());
					boost::shared_ptr<Axis> lYAxis = _panel->getAxis(pHistogramProperties->getYAxisId());
					lXAxis->_used = true; lYAxis->_used = true;

				if(pHistogramProperties->getHistogramType() == "histogram1d"){
					
					std::vector<std::pair<double,double>> grid;
					double xBinSize = 0;

					// Call histo1DUtils to get yMin/yMax and send these to PanelPlotOutput::drawHistogram to draw the y axis
					histo1DUtils(startDate, stopDate,*pHistogramProperties.get(), grid, xBinSize);
				}

				else if(pHistogramProperties->getHistogramType() == "histogram2d"){
					lZAxis->_used = true;
					if(_panel->_page->_superposeMode){
						_globalStartTime = startDate;
						_globalStopTime = stopDate;
					}
				}
			}
		}
	}

	if (lZAxis != nullptr && lColorAxeRange.isSet())
		lZAxis->setRange(lColorAxeRange);
}

void HistoPlot::configureAxisLegend () {
	// Y axis
	AxisLegendManager::configureYAxisLegendForSeries(this);

	// X axis
	AxisLegendManager::configureXAxisLegendForSeries(this);

	// Z axis
	AxisLegendManager::configureColorAxisLegendForSeries(this);

}

void HistoPlot::histo1DUtils(double startDate, double stopDate, HistogramSeriesProperties &pHistogramProperties,
								std::vector<std::pair<double,double>> &grid, double &xBinSize){
	// Get X, Y  axis.
	boost::shared_ptr<Axis> lXAxis(_panel->getAxis(pHistogramProperties.getXAxisId()));
    boost::shared_ptr<Axis> lYAxis(_panel->getAxis(pHistogramProperties.getYAxisId()));

	Range lXRange = lXAxis->getRange();

	if(std::isnan(lXRange.getMin()) || std::isnan(lXRange.getMax()))
		return;
    Range lYRange = lYAxis->Axis::getRange();
	double yMin = lYRange.getMin() ; 
	double yMax = lYRange.getMax() ;

	unsigned int xBinNumber = pHistogramProperties.getManualProperties().getXBinNumber();

	xBinSize = (lXRange.getMax() - lXRange.getMin())/ xBinNumber;

	ParameterData &xData = (*_pParameterValues)[pHistogramProperties.getParamId()];
	

    int xStartIndex = 0;
	int xNbValues = 0;
	
	xData.getIntervalBounds(startDate, stopDate, xStartIndex, xNbValues);	
    double* xValues =nullptr;
	double* yValues =nullptr;

	if(lXAxis->_scale==Axis::Scale::LOGARITHMIC)
		xValues =  lXAxis->getComputedValues(xData.getValues(pHistogramProperties.getIndex(), xStartIndex),xNbValues,exp10(lXRange.getMin()), exp10(lXRange.getMax()));
	else
		xValues = xData.getValues(pHistogramProperties.getIndex(), xStartIndex);

	

	if(!pHistogramProperties.getHistotypeProperties().getParamId().empty()){
		ParameterData &yData = (*_pParameterValues)[pHistogramProperties.getHistotypeProperties().getParamId()];
		int yStartIndex = 0;	
		int yNbValues = 0;

		xData.getIntervalBounds(startDate, stopDate, yStartIndex, yNbValues);
		yValues = yData.getValues(pHistogramProperties.getHistotypeProperties().getIndex(), yStartIndex);
	}
	pHistogramProperties.getHistotypeProperties().getHisto1DFunction()->apply(pHistogramProperties.getHistotypeProperties().getHisto1DFunction(),grid,xValues,yValues,xNbValues,lXRange, xBinSize, 
													(lYAxis->_scale==Axis::Scale::LOGARITHMIC) ,yMin, yMax);
	


	if(lXAxis->_scale==Axis::Scale::LOGARITHMIC)
		free(xValues);
	
	if(!std::isnan(yMin))
		lYRange.setMin(yMin);
	if(!std::isnan(yMax))
		lYRange.setMax(yMax);
	lYRange._extend = lYAxis->isExtended();
	lYAxis->setRange(lYRange);
}

void HistoPlot::drawHistogram(double startDate, double stopDate, std::string pParamId, 
								HistogramSeriesProperties &pHistogramProperties){
	
	if(pHistogramProperties.getHistogramType() == "histogram1d"){
		if(_panel->_page->_superposeMode && pHistogramProperties.isPlotted())
			return;

		std::vector<std::pair<double,double>> grid;
		Color color = pHistogramProperties.getColor();
		double xBinSize = 0;
		boost::shared_ptr<Axis> lYAxis(_panel->getAxis(pHistogramProperties.getYAxisId()));
		Range lYRange = lYAxis->getRange();

		histo1DUtils(startDate, stopDate,pHistogramProperties, grid, xBinSize);
		
		PanelPlotOutput::drawHistogram(startDate,stopDate,pParamId, pHistogramProperties);
		PanelPlotOutput::drawHistogramBoxes(grid,color,xBinSize, lYRange.getMin(), pHistogramProperties.getManualProperties().hasStairs());
		pHistogramProperties.setPlotted(true);

	}
	else {
		if(_panel->_page->_superposeMode && pHistogramProperties.isPlotted())
			return;

		if(_panel->_page->_superposeMode){
			startDate= _globalStartTime;
			stopDate = _globalStopTime;
		}
		// Get X, Y and Z axis.
		boost::shared_ptr<Axis> lXAxis(_panel->getAxis(pHistogramProperties.getXAxisId()));
		boost::shared_ptr<Axis> lYAxis(_panel->getAxis(pHistogramProperties.getYAxisId()));
		//boost::shared_ptr<Axis> lZAxis(_panel->getAxis(pHistogramProperties.getZAxisId()));
		boost::shared_ptr<ColorAxis> lZAxis = _panel->getColorAxis();

		Range lXRange = lXAxis->getRange();
		Range lYRange = lYAxis->getRange();
		Range lZRange = lZAxis->getRequestedRange();
		

		Color minValColor = lZAxis->getMinValColor();
		Color maxValColor = lZAxis->getMaxValColor();

		GridPart grid;
		MatrixGrid matrixGrid;
		int smoothFactor = pHistogramProperties.getHistotypeProperties().getSmoothFactor();

		unsigned int xBinNumber = pHistogramProperties.getManualProperties().getXBinNumber();
		unsigned int yBinNumber = pHistogramProperties.getManualProperties().getYBinNumber();

		

		double xBinSize = (lXRange.getMax() - lXRange.getMin())/ xBinNumber;
		double yBinSize = (lYRange.getMax() - lYRange.getMin())/ yBinNumber;

		//get parameter x data for this serie
		ParameterAxes* xSerieParameterAxes = getParameterAxesByXSerieId(pHistogramProperties.getXId());
		XSeriesProperties& xSerie = xSerieParameterAxes->getXSeriePropertiesById(pHistogramProperties.getXId());

		ParameterData &xData = (*_pParameterValues)[xSerie.getParamId()];
		ParameterData &yData = (*_pParameterValues)[pHistogramProperties.getParamId()];
		ParameterData &zData = (*_pParameterValues)[pHistogramProperties.getHistotypeProperties().getParamId()];


		int xStartIndex;
		int yStartIndex;
		int zStartIndex;
		int xNbValues;
		int yNbValues;
		int zNbValues;
		double zMin = NAN ; 
		double zMax = NAN ;
		
		xData.getIntervalBounds(startDate, stopDate, xStartIndex, xNbValues);
		yData.getIntervalBounds(startDate, stopDate, yStartIndex, yNbValues);
		zData.getIntervalBounds(startDate, stopDate, zStartIndex, zNbValues);

		double* xValues;
		double* yValues;
		double* zValues;
		if(lXAxis->_scale==Axis::Scale::LOGARITHMIC)
			xValues =  lXAxis->getComputedValues(xData.getValues(xSerie.getIndex(), xStartIndex),xNbValues,exp10(lXRange.getMin()), exp10(lXRange.getMax()));
		else
			xValues = xData.getValues(xSerie.getIndex(), xStartIndex);
		if(lYAxis->_scale==Axis::Scale::LOGARITHMIC)
			yValues =  lYAxis->getComputedValues(yData.getValues(pHistogramProperties.getIndex(), yStartIndex),yNbValues,exp10(lYRange.getMin()), exp10(lYRange.getMax()));
		else
			yValues = yData.getValues(pHistogramProperties.getIndex(), yStartIndex);
		
		zValues = zData.getValues(pHistogramProperties.getHistotypeProperties().getIndex(), zStartIndex);

		for (unsigned int i(0); i < xBinNumber; ++i)
		{
			for (unsigned int j(0); j < yBinNumber; ++j)
			{
				grid.x[0] =  lXRange.getMin()+xBinSize*i;
				grid.x[1] = grid.x[0]+xBinSize;
				grid.y[0] = lYRange.getMin() + yBinSize*j;
				grid.y[1] = grid.y[0]+yBinSize;
				grid.value = NAN;
				grid.isColorIndex= false;

				matrixGrid.push_back(grid);
			}
		}

		pHistogramProperties.getHistotypeProperties().getHisto2DFunction()->apply(matrixGrid, xValues, yValues, zValues, xNbValues,lXRange,lYRange,
														xBinNumber, yBinNumber, zMin, zMax, smoothFactor);
		if(lXAxis->_scale==Axis::Scale::LOGARITHMIC)
			free(xValues);
		if(lYAxis->_scale==Axis::Scale::LOGARITHMIC)
			free(yValues);
		
		if(std::isnan(lZRange.getMin()))
			lZRange.setMin(zMin);
		if(std::isnan(lZRange.getMax()))
			lZRange.setMax(zMax);
		
		lZRange._extend = lZAxis->isExtended();
		lZAxis->setRange(lZRange);

		
		PanelPlotOutput::drawHistogram(startDate,stopDate,pParamId, pHistogramProperties);
		PanelPlotOutput::drawMatrix(matrixGrid, zMin, zMax, minValColor,maxValColor, lZAxis->_color._colorMapIndex, false);
		pHistogramProperties.setPlotted(true);
	}
}

void HistoPlot::resetPlot()
{
	for (auto param: _parameterAxesList) {

		for (auto pHistogramProperties : param.getHistogramSeriesPropertiesList())
		{
			if(pHistogramProperties != nullptr){ 

				if(pHistogramProperties->getHistogramType() == "histogram1d"){
					
					pHistogramProperties->getHistotypeProperties().getHisto1DFunction()->resetCache();
				}
				pHistogramProperties->setPlotted(false);
			}
		}
	}
	PanelPlotOutput::resetPlot();
}
}

// Events from 'tt' in TIMEMIN - TIMEMAX