Jungfraujoch/broker/gen/model/Spot_finding_settings.cpp

/**
* Jungfraujoch
* API to control Jungfraujoch developed by the Paul Scherrer Institute (Switzerland). Jungfraujoch is a data acquisition and analysis system for pixel array detectors, primarly PSI JUNGFRAU. Jungfraujoch uses FPGA boards to acquire data at high data rates.  # License Clarification  While this API definition is licensed under GPL-3.0, **the GPL copyleft provisions do not apply** when this file is used solely to generate OpenAPI clients or when implementing applications that interact with the API. Generated client code and applications using this API definition are not subject to the GPL license requirements and may be distributed under terms of your choosing.  This exception is similar in spirit to the Linux Kernel's approach to userspace API headers and the GCC Runtime Library Exception. The Linux Kernel developers have explicitly stated that user programs that merely use the kernel interfaces (syscalls, ioctl definitions, etc.) are not derivative works of the kernel and are not subject to the terms of the GPL.  This exception is intended to allow wider use of this API specification without imposing GPL requirements on applications that merely interact with the API, regardless of whether they communicate through network calls or other mechanisms. 
*
* The version of the OpenAPI document: 1.0.0-rc.65
* Contact: filip.leonarski@psi.ch
*
* NOTE: This class is auto generated by OpenAPI Generator (https://openapi-generator.tech).
* https://openapi-generator.tech
* Do not edit the class manually.
*/


#include "Spot_finding_settings.h"
#include "Helpers.h"

#include <sstream>

namespace org::openapitools::server::model
{

Spot_finding_settings::Spot_finding_settings()
{
    m_Enable = true;
    m_Indexing = true;
    m_Signal_to_noise_threshold = 0.0f;
    m_Photon_count_threshold = 0L;
    m_Min_pix_per_spot = 0L;
    m_Max_pix_per_spot = 0L;
    m_High_resolution_limit = 0.0f;
    m_Low_resolution_limit = 0.0f;
    m_High_resolution_limit_for_spot_count_low_res = 0.0f;
    m_Resolution_estimate = true;
    m_Resolution_estimateIsSet = false;
    m_Quick_integration = false;
    
}

void Spot_finding_settings::validate() const
{
    std::stringstream msg;
    if (!validate(msg))
    {
        throw org::openapitools::server::helpers::ValidationException(msg.str());
    }
}

bool Spot_finding_settings::validate(std::stringstream& msg) const
{
    return validate(msg, "");
}

bool Spot_finding_settings::validate(std::stringstream& msg, const std::string& pathPrefix) const
{
    bool success = true;
    const std::string _pathPrefix = pathPrefix.empty() ? "Spot_finding_settings" : pathPrefix;

                 
    
    /* Signal_to_noise_threshold */ {
        const float& value = m_Signal_to_noise_threshold;
        const std::string currentValuePath = _pathPrefix + ".signalToNoiseThreshold";
                
        
        if (value < static_cast<float>(0))
        {
            success = false;
            msg << currentValuePath << ": must be greater than or equal to 0;";
        }

    }
         
    
    /* Photon_count_threshold */ {
        const int64_t& value = m_Photon_count_threshold;
        const std::string currentValuePath = _pathPrefix + ".photonCountThreshold";
                
        
        if (value < 0ll)
        {
            success = false;
            msg << currentValuePath << ": must be greater than or equal to 0;";
        }

    }
         
    
    /* Min_pix_per_spot */ {
        const int64_t& value = m_Min_pix_per_spot;
        const std::string currentValuePath = _pathPrefix + ".minPixPerSpot";
                
        
        if (value < 1ll)
        {
            success = false;
            msg << currentValuePath << ": must be greater than or equal to 1;";
        }

    }
         
    
    /* Max_pix_per_spot */ {
        const int64_t& value = m_Max_pix_per_spot;
        const std::string currentValuePath = _pathPrefix + ".maxPixPerSpot";
                
        
        if (value < 1ll)
        {
            success = false;
            msg << currentValuePath << ": must be greater than or equal to 1;";
        }

    }
                 
    
    /* High_resolution_limit_for_spot_count_low_res */ {
        const float& value = m_High_resolution_limit_for_spot_count_low_res;
        const std::string currentValuePath = _pathPrefix + ".highResolutionLimitForSpotCountLowRes";
                
        
        if (value < static_cast<float>(2.0))
        {
            success = false;
            msg << currentValuePath << ": must be greater than or equal to 2.0;";
        }
        if (value > static_cast<float>(8.0))
        {
            success = false;
            msg << currentValuePath << ": must be less than or equal to 8.0;";
        }

    }
            
    return success;
}

bool Spot_finding_settings::operator==(const Spot_finding_settings& rhs) const
{
    return
    
    
    (isEnable() == rhs.isEnable())
     &&
    
    (isIndexing() == rhs.isIndexing())
     &&
    
    (getSignalToNoiseThreshold() == rhs.getSignalToNoiseThreshold())
     &&
    
    (getPhotonCountThreshold() == rhs.getPhotonCountThreshold())
     &&
    
    (getMinPixPerSpot() == rhs.getMinPixPerSpot())
     &&
    
    (getMaxPixPerSpot() == rhs.getMaxPixPerSpot())
     &&
    
    (getHighResolutionLimit() == rhs.getHighResolutionLimit())
     &&
    
    (getLowResolutionLimit() == rhs.getLowResolutionLimit())
     &&
    
    (getHighResolutionLimitForSpotCountLowRes() == rhs.getHighResolutionLimitForSpotCountLowRes())
     &&
    
    
    ((!resolutionEstimateIsSet() && !rhs.resolutionEstimateIsSet()) || (resolutionEstimateIsSet() && rhs.resolutionEstimateIsSet() && isResolutionEstimate() == rhs.isResolutionEstimate())) &&
    
    (isQuickIntegration() == rhs.isQuickIntegration())
    
    
    ;
}

bool Spot_finding_settings::operator!=(const Spot_finding_settings& rhs) const
{
    return !(*this == rhs);
}

void to_json(nlohmann::json& j, const Spot_finding_settings& o)
{
    j = nlohmann::json::object();
    j["enable"] = o.m_Enable;
    j["indexing"] = o.m_Indexing;
    j["signal_to_noise_threshold"] = o.m_Signal_to_noise_threshold;
    j["photon_count_threshold"] = o.m_Photon_count_threshold;
    j["min_pix_per_spot"] = o.m_Min_pix_per_spot;
    j["max_pix_per_spot"] = o.m_Max_pix_per_spot;
    j["high_resolution_limit"] = o.m_High_resolution_limit;
    j["low_resolution_limit"] = o.m_Low_resolution_limit;
    j["high_resolution_limit_for_spot_count_low_res"] = o.m_High_resolution_limit_for_spot_count_low_res;
    if(o.resolutionEstimateIsSet())
        j["resolution_estimate"] = o.m_Resolution_estimate;
    j["quick_integration"] = o.m_Quick_integration;
    
}

void from_json(const nlohmann::json& j, Spot_finding_settings& o)
{
    j.at("enable").get_to(o.m_Enable);
    j.at("indexing").get_to(o.m_Indexing);
    j.at("signal_to_noise_threshold").get_to(o.m_Signal_to_noise_threshold);
    j.at("photon_count_threshold").get_to(o.m_Photon_count_threshold);
    j.at("min_pix_per_spot").get_to(o.m_Min_pix_per_spot);
    j.at("max_pix_per_spot").get_to(o.m_Max_pix_per_spot);
    j.at("high_resolution_limit").get_to(o.m_High_resolution_limit);
    j.at("low_resolution_limit").get_to(o.m_Low_resolution_limit);
    j.at("high_resolution_limit_for_spot_count_low_res").get_to(o.m_High_resolution_limit_for_spot_count_low_res);
    if(j.find("resolution_estimate") != j.end())
    {
        j.at("resolution_estimate").get_to(o.m_Resolution_estimate);
        o.m_Resolution_estimateIsSet = true;
    } 
    j.at("quick_integration").get_to(o.m_Quick_integration);
    
}

bool Spot_finding_settings::isEnable() const
{
    return m_Enable;
}
void Spot_finding_settings::setEnable(bool const value)
{
    m_Enable = value;
}
bool Spot_finding_settings::isIndexing() const
{
    return m_Indexing;
}
void Spot_finding_settings::setIndexing(bool const value)
{
    m_Indexing = value;
}
float Spot_finding_settings::getSignalToNoiseThreshold() const
{
    return m_Signal_to_noise_threshold;
}
void Spot_finding_settings::setSignalToNoiseThreshold(float const value)
{
    m_Signal_to_noise_threshold = value;
}
int64_t Spot_finding_settings::getPhotonCountThreshold() const
{
    return m_Photon_count_threshold;
}
void Spot_finding_settings::setPhotonCountThreshold(int64_t const value)
{
    m_Photon_count_threshold = value;
}
int64_t Spot_finding_settings::getMinPixPerSpot() const
{
    return m_Min_pix_per_spot;
}
void Spot_finding_settings::setMinPixPerSpot(int64_t const value)
{
    m_Min_pix_per_spot = value;
}
int64_t Spot_finding_settings::getMaxPixPerSpot() const
{
    return m_Max_pix_per_spot;
}
void Spot_finding_settings::setMaxPixPerSpot(int64_t const value)
{
    m_Max_pix_per_spot = value;
}
float Spot_finding_settings::getHighResolutionLimit() const
{
    return m_High_resolution_limit;
}
void Spot_finding_settings::setHighResolutionLimit(float const value)
{
    m_High_resolution_limit = value;
}
float Spot_finding_settings::getLowResolutionLimit() const
{
    return m_Low_resolution_limit;
}
void Spot_finding_settings::setLowResolutionLimit(float const value)
{
    m_Low_resolution_limit = value;
}
float Spot_finding_settings::getHighResolutionLimitForSpotCountLowRes() const
{
    return m_High_resolution_limit_for_spot_count_low_res;
}
void Spot_finding_settings::setHighResolutionLimitForSpotCountLowRes(float const value)
{
    m_High_resolution_limit_for_spot_count_low_res = value;
}
bool Spot_finding_settings::isResolutionEstimate() const
{
    return m_Resolution_estimate;
}
void Spot_finding_settings::setResolutionEstimate(bool const value)
{
    m_Resolution_estimate = value;
    m_Resolution_estimateIsSet = true;
}
bool Spot_finding_settings::resolutionEstimateIsSet() const
{
    return m_Resolution_estimateIsSet;
}
void Spot_finding_settings::unsetResolution_estimate()
{
    m_Resolution_estimateIsSet = false;
}
bool Spot_finding_settings::isQuickIntegration() const
{
    return m_Quick_integration;
}
void Spot_finding_settings::setQuickIntegration(bool const value)
{
    m_Quick_integration = value;
}


} // namespace org::openapitools::server::model