gem5/ext/dsent/model/optical/ThrottledLaserSource.cc

#include "model/optical/ThrottledLaserSource.h"

#include "model/PortInfo.h"
#include "model/TransitionInfo.h"
#include "model/EventInfo.h"
#include "model/optical_graph/OpticalWaveguide.h"
#include "model/optical_graph/OpticalWavelength.h"
#include "model/optical_graph/OpticalLaser.h"
#include "model/optical_graph/OpticalGraph.h"

namespace DSENT
{
    ThrottledLaserSource::ThrottledLaserSource(const String& instance_name_, const TechModel* tech_model_)
        : OpticalModel(instance_name_, tech_model_), m_wavelength_(NULL)
    {
        initParameters();
        initProperties();
    }

    ThrottledLaserSource::~ThrottledLaserSource()
    {
        if (m_wavelength_ != NULL) delete m_wavelength_;
    }

    void ThrottledLaserSource::initParameters()
    {
        addParameterName("OutStart");
        addParameterName("OutEnd");
        addParameterName("MaxDetectors");
        addParameterName("MinDetectors");
        return;
    }

    void ThrottledLaserSource::initProperties()
    {
		addPropertyName("OptUtil", 1.0);
        addPropertyName("LaserEventTime");
        return;
    }

    void ThrottledLaserSource::constructModel()
    {
        // Get parameters
        WavelengthGroup laser_wavelengths = makeWavelengthGroup(getParameter("OutStart"), getParameter("OutEnd"));
        unsigned int max_detectors = getParameter("MaxDetectors").toUInt();
        unsigned int min_detectors = getParameter("MinDetectors").toUInt();
        
        // Create electrical input port for laser control
        createInputPort(    "LaserEnable");
            
        // Create Area result
        addAreaResult(new AtomicResult("Photonic"));
        // Create event result for each detector number possibility
        for (unsigned int i = min_detectors; i <= max_detectors; ++i)
        {
            createElectricalEventAtomicResult("Laser" + (String) i);
            getEventInfo("Laser" + (String) i)->setTransitionInfo("LaserEnable", TransitionInfo(0.0, 1.0, 0.0));
        }

        // Create optical ports
        createOpticalOutputPort(    "Out",      laser_wavelengths);
        // Create the filter
        createLaser(                "Laser",    laser_wavelengths);
        OpticalLaser* laser = getLaser("Laser");
        // Connect the laser to the output
        laser->addDownstreamNode(getWaveguide("Out"));
    }
    
    void ThrottledLaserSource::updateModel()
    {
        // Get properties
        double laser_efficiency = getTechModel()->get("Laser->CW->Efficiency").toDouble();
        double laser_area = getTechModel()->get("Laser->CW->Area").toDouble();
        double laser_diode_loss = getTechModel()->get("Laser->CW->LaserDiodeLoss");

        // Get parameters
        WavelengthGroup laser_wavelengths = makeWavelengthGroup(getParameter("OutStart"), getParameter("OutEnd"));
        unsigned int number_wavelengths = laser_wavelengths.second - laser_wavelengths.first + 1;
        // Update losses
        OpticalLaser* laser = getLaser("Laser");
        laser->setLoss(laser_diode_loss);
        laser->setEfficiency(laser_efficiency);
        // Update area
        getAreaResult("Photonic")->setValue(laser_area * number_wavelengths);
    }
    
    void ThrottledLaserSource::evaluateModel()
    {    
        // Get parameters
        unsigned int max_detectors = getParameter("MaxDetectors");
        WavelengthGroup laser_wavelengths = makeWavelengthGroup(getParameter("OutStart"), getParameter("OutEnd"));
		
		// Get properties
		double opt_util = getProperty("OptUtil");
		
        // Create optical graph object
        OpticalGraph* optical_graph = new OpticalGraph("LaserTrace", this);        
        // Ask optical graph object to perform power optimization
        bool success = optical_graph->performPowerOpt(getLaser("Laser"), laser_wavelengths, max_detectors, opt_util);
        if (!success)
        {
            Log::printLine(std::cerr, "[Warning] " + getInstanceName() +
                " -> Wavelengths contains data paths with no possible modulator configurations!");
        }
        
        // Trace the wavelengths the laser is outputting to find the output
        // power needed by the laser        
        if (m_wavelength_ != NULL) delete m_wavelength_;
        m_wavelength_ = optical_graph->traceWavelength(laser_wavelengths, getLaser("Laser"));        

        delete optical_graph;
    }
    
    void ThrottledLaserSource::useModel()
    {
        // Get parameters
        unsigned int max_detectors = getParameter("MaxDetectors");
        unsigned int min_detectors = getParameter("MinDetectors");

        // Get properties
        double laser_event_time = getProperty("LaserEventTime");
        // Get laser enable information
        const TransitionInfo& enable_info = getInputPort("LaserEnable")->getTransitionInfo();
        
        for (unsigned int i = min_detectors; i <= max_detectors; ++i)
        {
            // Calculate the power needed by the wavelength
            double laser_power = m_wavelength_->getLaserPower(i);
            // Calculate the laser event power by calculating the amount
            // of time the laser is on
            getEventResult("Laser" + (String) i)->setValue(laser_power * laser_event_time *
                enable_info.getFrequencyMultiplier() * enable_info.getProbability1());
        }
    }
    
} // namespace DSENT