DigitalAxis.cc
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/*
* DigitalAxis.cc
*
* Created on: 3 déc. 2013
* Author: CS
*/
#include "DigitalAxis.hh"
#include "PlotLogger.hh"
#include "PanelPlotOutputException.hh"
#include <sstream>
#include <iomanip>
#include <iostream>
#include "plplot/plplotP.h"
namespace plot {
const int DigitalAxis::MAX_DIGIT_NUMBER = 3;
const int DigitalAxis::STANDARD_FORMAT_PRECISION = 1;
const int DigitalAxis::LOG_CONSTANT = 1000000;
std::string DigitalAxis::getPlotOpt() {
std::string options = Axis::getPlotOpt();
// Remove m or n plplot option if tickmark not visible
// This will prevent plplot to draw any tickmark
if (_showTickMark == false) {
size_t pos;
if ((pos = options.find("m")) != std::string::npos) {
options.replace(pos, 1, "");
}
if ((pos = options.find("n")) != std::string::npos) {
options.replace(pos, 1, "");
}
}
if (_scale == Scale::LOGARITHMIC) {
options += "l";
} else if (getFormat() == Format::SCIENTIFIC) {
// Check format to use for label
options += "of";
} else {
options += "f";
}
return options;
}
Range DigitalAxis::getRange() {
Range lRange = Axis::getRange();
try {
if (_scale == Scale::LOGARITHMIC) {
double min;
if (lRange.getMin() <= 0) {
min = log10(lRange.getMax() / LOG_CONSTANT);
} else {
min = log10(lRange.getMin());
}
double max;
if (lRange.getMax() <= 0) {
max = log10(lRange.getMin() / LOG_CONSTANT);
} else {
max = log10(lRange.getMax());
}
lRange.setMin(min);
lRange.setMax(max);
if (lRange._extend) {
return extendRange(lRange);
} else {
return lRange;
}
} else {
if (lRange._extend) {
return extendRange(lRange);
} else {
return lRange;
}
}
} catch (std::exception& e) {
// negative value for log ... stop process
std::stringstream lError;
lError << "DigitalAxis::getRange : range min and max have to be positive value (" << e.what() << ")";
BOOST_THROW_EXCEPTION(
PanelPlotOutputException() << AMDA::ex_msg(lError.str()));
}
}
DigitalAxis::Format DigitalAxis::getFormat() {
double lMin = pow(10, -MAX_DIGIT_NUMBER);
double lMax = pow(10, MAX_DIGIT_NUMBER);
double lDesiredMin = std::abs(getRange().getMin());
double lDesiredMax = std::abs(getRange().getMax());
// If maximum range doesn't include desired range,
// label need to be formatted.
if ( (lDesiredMin != 0 && (lDesiredMin <= lMin || lDesiredMin >= lMax)) ||
(lDesiredMax != 0 && (lDesiredMax <= lMin || lDesiredMax >= lMax)) ) {
return DigitalAxis::Format::SCIENTIFIC;
} else {
return DigitalAxis::Format::STANDARD;
}
}
std::pair<int, int> DigitalAxis::getTickMarkSize() {
// If tickmarks are not visible return a null size
if (_showTickMark == false) {
return std::pair<int , int> (0,0);
}
std::pair<int, int> tickMarkSize(0, getTickMarkLines());
// If TickMark width is fixed, return it !
if (_fixedTickMarkWidth != -1) {
tickMarkSize.first = _fixedTickMarkWidth;
return tickMarkSize;
}
Range lRange(getRange());
if (_scale == Scale::LOGARITHMIC) {
tickMarkSize.first = 3;
} else if (getFormat() == Format::SCIENTIFIC){
// (i.e. 1.3e⁴)
_scientific_format_precision = computeScientificFormatPrecision(lRange.getMin(), lRange.getMax());
tickMarkSize.first = _scientific_format_precision + 4 + (lRange.getMin() < 0 ? 1 : 0);
} else {
double dMinFloor = floor(fabs(lRange.getMin()));
double dMaxFloor = floor(fabs(lRange.getMax()));
// Check that min and max for is not null to avoid log10(0) !
if ((dMinFloor == 0) && (dMaxFloor == 0)) {
char buf1 [64], buf2 [64];
sprintf (buf1,"%.3f", lRange.getMin());
sprintf (buf2,"%.3f", lRange.getMax());
tickMarkSize.first = std::max(strlen (buf1), strlen (buf2));
} else {
int iMinFloor = log10 (dMinFloor) + 1;
int iMaxFloor = log10 (dMaxFloor) + 1;
double rangeSize = lRange.getMin() - lRange.getMax();
int precision = abs(floor(log10(fabs(rangeSize))));
tickMarkSize.first = precision + std::max(iMinFloor, iMaxFloor) + 1;
if (lRange.getMin() < 0 || lRange.getMax() < 0) {
tickMarkSize.first += 1;
}
}
}
return tickMarkSize;
}
/**
* @overrides Axis::getComputedValues
*/
double* DigitalAxis::getComputedValues(double* originalValues_, int size_, double min, double max) {
double *computedValues = new double [size_];
// Duplicates data
memcpy (computedValues, originalValues_, size_ * sizeof (double));
// Need to filter min max values ?
if ((std::isnan(min) == false) || (std::isnan(max) == false)) {
for (int i = 0; i < size_; ++i) {
if ((originalValues_[i] < min) || (originalValues_[i] > max)) {
computedValues [i] = nan("");
}
}
}
// if scale is logarithmic, just calculate log for each value
if ((_scale == Scale::LOGARITHMIC) && !_isZAxis) {
for (int i = 0; i < size_; ++i) {
if (computedValues[i] <= 0) {
computedValues [i] = log10(std::max(min, max) / DigitalAxis::LOG_CONSTANT);
LOG4CXX_WARN(gLogger, "Negative value found, no log calculated");
} else {
computedValues [i] = log10(computedValues[i]);
}
}
}
return computedValues;
}
void generateDigitalLabel(PLINT /*axis*/, PLFLT value, char *label, PLINT length, PLPointer data) {
DigitalAxis *pAxis = (DigitalAxis *)data;
double min = pAxis->getRange().getMin();
double max = pAxis->getRange().getMax();
getDigitalLabel(value, pAxis->getScientificFormatPrecision(), label, length,min,max);
}
void generateNoDigitalLabel(PLINT /*axis*/, PLFLT /*value*/, char *label, PLINT /*length*/, PLPointer /*data*/) {
// Builds an empty Time label
label [0] = 0;
}
int computeScientificFormatPrecision(double min, double max) {
int precision = 1;
int lMinExp = floor(log10(fabs(min)));
int lMaxExp = floor(log10(fabs(max)));
if (lMaxExp != lMinExp) {
return precision;
}
PLFLT tick = 0;
PLINT nsubt = 0;
pldtik( min, max, &tick, &nsubt, false);
double v = tick / pow(10, lMinExp);
precision = ceil(fabs(log10(v)));
return precision;
}
void getDigitalLabel(double value, int precision, char* label, int length, double /*min*/, double /*max*/) {
//int relativePrecision = floor(log10(fabs((max-min))));
if(value != 0){
int lExp = floor(log10(fabs(value)));
double lValue = value / pow(10, lExp);
if (lExp == 0 )
snprintf( label, length, "%.*f", precision, lValue);
// BRE - Regression in ThirdPart.ReLease3.SprinT1.UserStory32 => deactivate this fix define for #11199
//else if(fabs(2*relativePrecision) < fabs(lExp)){
// std::stringstream lStrValue;
// lStrValue << 0;
// snprintf( label, length, "%s", lStrValue.str().c_str());
//}
else
snprintf( label, length, "%.*fe#u%i#d", precision, lValue, lExp);
}
else {
std::stringstream lStrValue;
lStrValue << value;
snprintf( label, length, "%s", lStrValue.str().c_str());
}
}
} /* namespace plot */