src/statistics.cpp - net/nload - Rivoreo Source Code Repositories


 #include "setting.h"
 #include "settingstore.h"
 #include "statistics.h"

 using namespace std;

 void Statistics::insertDataFrame(const DataFrame& dataFrame)
 {
     if(!dataFrame.isValid())
         return;

     m_dataFrames.push_back(dataFrame);

     unsigned int frameCount = m_dataFrames.size();
     if(frameCount < 2)
         return;

     unsigned int averageCount = getAverageWindow();
     unsigned int secondCount = getSecondWindow();

     if(frameCount > averageCount)
     {
         m_dataFrames.erase(m_dataFrames.begin(), m_dataFrames.begin() + (frameCount - averageCount));
         frameCount = averageCount;
     }

     vector<DataFrame>::const_reverse_iterator itFrameSecond = m_dataFrames.rbegin();
     vector<DataFrame>::const_reverse_iterator itFrameAverage = m_dataFrames.rbegin();

     if(frameCount > secondCount)
         itFrameSecond += secondCount;
     else
         itFrameSecond += frameCount - 1;

     if(frameCount > averageCount)
         itFrameAverage += averageCount;
     else
         itFrameAverage += frameCount - 1;

     calculateAverage(*itFrameSecond, m_dataFrames.back(), m_second);
     calculateAverage(*itFrameAverage, m_dataFrames.back(), m_average);

     if(frameCount > 2)
         calculateMinMax(m_second, m_min, m_max);
     else
         m_min = m_max = m_second;
 }

 void Statistics::reset()
 {
     m_second = DataFrame();
     m_average = DataFrame();
     m_min = DataFrame();
     m_max = DataFrame();

     m_dataFrames.clear();
 }

 float Statistics::getUnitFactor(dataUnit unit, long long value)
 {
     float factor = 1.0 / (unit % 2 == 0 ? 8 : 1);

     switch(unit)
     {
         case humanReadableBit:
         case humanReadableByte:
             factor *= 1024 * 1024 * 1024;
             for(int i = 3; i >= 0; --i)
             {
                 if(value * (unit % 2 == 0 ? 8 : 1) >= factor)
                     return factor;

                 factor /= 1024;
             }
             return factor;
         case bit:
         case byte:
             return factor;
         case kiloBit:
         case kiloByte:
             return factor * 1024;
         case megaBit:
         case megaByte:
             return factor * 1024 * 1024;
         case gigaBit:
         case gigaByte:
             return factor * 1024 * 1024 * 1024;
         default: // should never be executed
             return factor;
     }
 }

 string Statistics::getUnitString(dataUnit unit, long long value)
 {
     string description = (unit % 2 == 0 ? "Bit" : "Byte");

     switch(unit)
     {
         case humanReadableBit:
         case humanReadableByte:
             if(value >= 1024 * 1024 * 1024 / (unit % 2 == 0 ? 8 : 1))
                 return 'G' + description;
             if(value >= 1024 * 1024 / (unit % 2 == 0 ? 8 : 1))
                 return 'M' + description;
             if(value >= 1024 / (unit % 2 == 0 ? 8 : 1))
                 return 'k' + description;
             return description;
         case bit:
         case byte:
             return description;
         case kiloBit:
         case kiloByte:
             return 'k' + description;
         case megaBit:
         case megaByte:
             return 'M' + description;
         case gigaBit:
         case gigaByte:
             return 'G' + description;
         default: // should never be executed
             return description;
     }
 }

 void Statistics::calculateAverage(const DataFrame& dataFrameFrom, const DataFrame& dataFrameTo, DataFrame& result)
 {
     float timeSpan = (dataFrameTo.getTimeStampSeconds() + dataFrameTo.getTimeStampMicroseconds() / 1000000.0) -
                      (dataFrameFrom.getTimeStampSeconds() + dataFrameFrom.getTimeStampMicroseconds() / 1000000.0);

     if(timeSpan <= 0)
         return;

     result.setTotalDataIn((dataFrameTo.getTotalDataIn() - dataFrameFrom.getTotalDataIn()) / timeSpan);
     result.setTotalDataOut((dataFrameTo.getTotalDataOut() - dataFrameFrom.getTotalDataOut()) / timeSpan);
     result.setTotalPacketsIn((dataFrameTo.getTotalPacketsIn() - dataFrameFrom.getTotalPacketsIn()) / timeSpan);
     result.setTotalPacketsOut((dataFrameTo.getTotalPacketsOut() - dataFrameFrom.getTotalPacketsOut()) / timeSpan);
     result.setTotalErrorsIn((dataFrameTo.getTotalErrorsIn() - dataFrameFrom.getTotalErrorsIn()) / timeSpan);
     result.setTotalErrorsOut((dataFrameTo.getTotalErrorsOut() - dataFrameFrom.getTotalErrorsOut()) / timeSpan);
     result.setTotalDropsIn((dataFrameTo.getTotalDropsIn() - dataFrameFrom.getTotalDropsIn()) / timeSpan);
     result.setTotalDropsOut((dataFrameTo.getTotalDropsOut() - dataFrameFrom.getTotalDropsOut()) / timeSpan);
 }

 void Statistics::calculateMinMax(const DataFrame& dataFrame, DataFrame& min, DataFrame& max)
 {
     if(dataFrame.getTotalDataIn() < min.getTotalDataIn())
         min.setTotalDataIn(dataFrame.getTotalDataIn());
     if(dataFrame.getTotalDataIn() > max.getTotalDataIn())
         max.setTotalDataIn(dataFrame.getTotalDataIn());
     if(dataFrame.getTotalDataOut() < min.getTotalDataOut())
         min.setTotalDataOut(dataFrame.getTotalDataOut());
     if(dataFrame.getTotalDataOut() > max.getTotalDataOut())
         max.setTotalDataOut(dataFrame.getTotalDataOut());

     if(dataFrame.getTotalPacketsIn() < min.getTotalPacketsIn())
         min.setTotalPacketsIn(dataFrame.getTotalPacketsIn());
     if(dataFrame.getTotalPacketsIn() > max.getTotalPacketsIn())
         max.setTotalPacketsIn(dataFrame.getTotalPacketsIn());
     if(dataFrame.getTotalPacketsOut() < min.getTotalPacketsOut())
         min.setTotalPacketsOut(dataFrame.getTotalPacketsOut());
     if(dataFrame.getTotalPacketsOut() > max.getTotalPacketsOut())
         max.setTotalPacketsOut(dataFrame.getTotalPacketsOut());

     if(dataFrame.getTotalErrorsIn() < min.getTotalErrorsIn())
         min.setTotalErrorsIn(dataFrame.getTotalErrorsIn());
     if(dataFrame.getTotalErrorsIn() > max.getTotalErrorsIn())
         max.setTotalErrorsIn(dataFrame.getTotalErrorsIn());
     if(dataFrame.getTotalErrorsOut() < min.getTotalErrorsOut())
         min.setTotalErrorsOut(dataFrame.getTotalErrorsOut());
     if(dataFrame.getTotalErrorsOut() > max.getTotalErrorsOut())
         max.setTotalErrorsOut(dataFrame.getTotalErrorsOut());

     if(dataFrame.getTotalDropsIn() < min.getTotalDropsIn())
         min.setTotalDropsIn(dataFrame.getTotalDropsIn());
     if(dataFrame.getTotalDropsIn() > max.getTotalDropsIn())
         max.setTotalDropsIn(dataFrame.getTotalDropsIn());
     if(dataFrame.getTotalDropsOut() < min.getTotalDropsOut())
         min.setTotalDropsOut(dataFrame.getTotalDropsOut());
     if(dataFrame.getTotalDropsOut() > max.getTotalDropsOut())
         max.setTotalDropsOut(dataFrame.getTotalDropsOut());
 }

 unsigned int Statistics::getAverageWindow()
 {
     unsigned int sleepInterval = SettingStore::get("sleep_interval");
     unsigned int averageWindow = SettingStore::get("average_window");

     return 1000.0 / sleepInterval * averageWindow;
 }

 unsigned int Statistics::getSecondWindow()
 {
     unsigned int sleepInterval = SettingStore::get("sleep_interval");
     unsigned int secondWindow = 1000.0 / sleepInterval;

     return secondWindow > 0 ? secondWindow : 1;
 }

	#include "setting.h"
	#include "settingstore.h"
	#include "statistics.h"

	using namespace std;

	void Statistics::insertDataFrame(const DataFrame& dataFrame)
	{
	if(!dataFrame.isValid())
	return;

	m_dataFrames.push_back(dataFrame);

	unsigned int frameCount = m_dataFrames.size();
	if(frameCount < 2)
	return;

	unsigned int averageCount = getAverageWindow();
	unsigned int secondCount = getSecondWindow();

	if(frameCount > averageCount)
	{
	m_dataFrames.erase(m_dataFrames.begin(), m_dataFrames.begin() + (frameCount - averageCount));
	frameCount = averageCount;
	}

	vector<DataFrame>::const_reverse_iterator itFrameSecond = m_dataFrames.rbegin();
	vector<DataFrame>::const_reverse_iterator itFrameAverage = m_dataFrames.rbegin();

	if(frameCount > secondCount)
	itFrameSecond += secondCount;
	else
	itFrameSecond += frameCount - 1;

	if(frameCount > averageCount)
	itFrameAverage += averageCount;
	else
	itFrameAverage += frameCount - 1;

	calculateAverage(*itFrameSecond, m_dataFrames.back(), m_second);
	calculateAverage(*itFrameAverage, m_dataFrames.back(), m_average);

	if(frameCount > 2)
	calculateMinMax(m_second, m_min, m_max);
	else
	m_min = m_max = m_second;
	}

	void Statistics::reset()
	{
	m_second = DataFrame();
	m_average = DataFrame();
	m_min = DataFrame();
	m_max = DataFrame();

	m_dataFrames.clear();
	}

	float Statistics::getUnitFactor(dataUnit unit, long long value)
	{
	float factor = 1.0 / (unit % 2 == 0 ? 8 : 1);

	switch(unit)
	{
	case humanReadableBit:
	case humanReadableByte:
	factor = 1024 1024 * 1024;
	for(int i = 3; i >= 0; --i)
	{
	if(value * (unit % 2 == 0 ? 8 : 1) >= factor)
	return factor;

	factor /= 1024;
	}
	return factor;
	case bit:
	case byte:
	return factor;
	case kiloBit:
	case kiloByte:
	return factor * 1024;
	case megaBit:
	case megaByte:
	return factor * 1024 * 1024;
	case gigaBit:
	case gigaByte:
	return factor * 1024 * 1024 * 1024;
	default: // should never be executed
	return factor;
	}
	}

	string Statistics::getUnitString(dataUnit unit, long long value)
	{
	string description = (unit % 2 == 0 ? "Bit" : "Byte");

	switch(unit)
	{
	case humanReadableBit:
	case humanReadableByte:
	if(value >= 1024 * 1024 * 1024 / (unit % 2 == 0 ? 8 : 1))
	return 'G' + description;
	if(value >= 1024 * 1024 / (unit % 2 == 0 ? 8 : 1))
	return 'M' + description;
	if(value >= 1024 / (unit % 2 == 0 ? 8 : 1))
	return 'k' + description;
	return description;
	case bit:
	case byte:
	return description;
	case kiloBit:
	case kiloByte:
	return 'k' + description;
	case megaBit:
	case megaByte:
	return 'M' + description;
	case gigaBit:
	case gigaByte:
	return 'G' + description;
	default: // should never be executed
	return description;
	}
	}

	void Statistics::calculateAverage(const DataFrame& dataFrameFrom, const DataFrame& dataFrameTo, DataFrame& result)
	{
	float timeSpan = (dataFrameTo.getTimeStampSeconds() + dataFrameTo.getTimeStampMicroseconds() / 1000000.0) -
	(dataFrameFrom.getTimeStampSeconds() + dataFrameFrom.getTimeStampMicroseconds() / 1000000.0);

	if(timeSpan <= 0)
	return;

	result.setTotalDataIn((dataFrameTo.getTotalDataIn() - dataFrameFrom.getTotalDataIn()) / timeSpan);
	result.setTotalDataOut((dataFrameTo.getTotalDataOut() - dataFrameFrom.getTotalDataOut()) / timeSpan);
	result.setTotalPacketsIn((dataFrameTo.getTotalPacketsIn() - dataFrameFrom.getTotalPacketsIn()) / timeSpan);
	result.setTotalPacketsOut((dataFrameTo.getTotalPacketsOut() - dataFrameFrom.getTotalPacketsOut()) / timeSpan);
	result.setTotalErrorsIn((dataFrameTo.getTotalErrorsIn() - dataFrameFrom.getTotalErrorsIn()) / timeSpan);
	result.setTotalErrorsOut((dataFrameTo.getTotalErrorsOut() - dataFrameFrom.getTotalErrorsOut()) / timeSpan);
	result.setTotalDropsIn((dataFrameTo.getTotalDropsIn() - dataFrameFrom.getTotalDropsIn()) / timeSpan);
	result.setTotalDropsOut((dataFrameTo.getTotalDropsOut() - dataFrameFrom.getTotalDropsOut()) / timeSpan);
	}

	void Statistics::calculateMinMax(const DataFrame& dataFrame, DataFrame& min, DataFrame& max)
	{
	if(dataFrame.getTotalDataIn() < min.getTotalDataIn())
	min.setTotalDataIn(dataFrame.getTotalDataIn());
	if(dataFrame.getTotalDataIn() > max.getTotalDataIn())
	max.setTotalDataIn(dataFrame.getTotalDataIn());
	if(dataFrame.getTotalDataOut() < min.getTotalDataOut())
	min.setTotalDataOut(dataFrame.getTotalDataOut());
	if(dataFrame.getTotalDataOut() > max.getTotalDataOut())
	max.setTotalDataOut(dataFrame.getTotalDataOut());

	if(dataFrame.getTotalPacketsIn() < min.getTotalPacketsIn())
	min.setTotalPacketsIn(dataFrame.getTotalPacketsIn());
	if(dataFrame.getTotalPacketsIn() > max.getTotalPacketsIn())
	max.setTotalPacketsIn(dataFrame.getTotalPacketsIn());
	if(dataFrame.getTotalPacketsOut() < min.getTotalPacketsOut())
	min.setTotalPacketsOut(dataFrame.getTotalPacketsOut());
	if(dataFrame.getTotalPacketsOut() > max.getTotalPacketsOut())
	max.setTotalPacketsOut(dataFrame.getTotalPacketsOut());

	if(dataFrame.getTotalErrorsIn() < min.getTotalErrorsIn())
	min.setTotalErrorsIn(dataFrame.getTotalErrorsIn());
	if(dataFrame.getTotalErrorsIn() > max.getTotalErrorsIn())
	max.setTotalErrorsIn(dataFrame.getTotalErrorsIn());
	if(dataFrame.getTotalErrorsOut() < min.getTotalErrorsOut())
	min.setTotalErrorsOut(dataFrame.getTotalErrorsOut());
	if(dataFrame.getTotalErrorsOut() > max.getTotalErrorsOut())
	max.setTotalErrorsOut(dataFrame.getTotalErrorsOut());

	if(dataFrame.getTotalDropsIn() < min.getTotalDropsIn())
	min.setTotalDropsIn(dataFrame.getTotalDropsIn());
	if(dataFrame.getTotalDropsIn() > max.getTotalDropsIn())
	max.setTotalDropsIn(dataFrame.getTotalDropsIn());
	if(dataFrame.getTotalDropsOut() < min.getTotalDropsOut())
	min.setTotalDropsOut(dataFrame.getTotalDropsOut());
	if(dataFrame.getTotalDropsOut() > max.getTotalDropsOut())
	max.setTotalDropsOut(dataFrame.getTotalDropsOut());
	}

	unsigned int Statistics::getAverageWindow()
	{
	unsigned int sleepInterval = SettingStore::get("sleep_interval");
	unsigned int averageWindow = SettingStore::get("average_window");

	return 1000.0 / sleepInterval * averageWindow;
	}

	unsigned int Statistics::getSecondWindow()
	{
	unsigned int sleepInterval = SettingStore::get("sleep_interval");
	unsigned int secondWindow = 1000.0 / sleepInterval;

	return secondWindow > 0 ? secondWindow : 1;
	}