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#include "sunspecinverter.h"
#include "extern-plugininfo.h"

SunSpecInverter::SunSpecInverter(const QHostAddress &hostAddress, uint port, QObject *parent) : SunSpec(hostAddress, port, parent)
{
    connect(m_modbusTcpClient, &QModbusClient::stateChanged, this, [this] (QModbusDevice::State state) {
        if (state == QModbusDevice::ConnectedState) {
            qCDebug(dcSunSpec()) << "Inverter connected successfully";
            QList<BlockId> mapIds;
            mapIds.append(BlockIdInverterSinglePhase);
            mapIds.append(BlockIdInverterSplitPhase);
            mapIds.append(BlockIdInverterThreePhase);
            mapIds.append(BlockIdInverterSinglePhaseFloat);
            mapIds.append(BlockIdInverterSplitPhaseFloat);
            mapIds.append(BlockIdInverterThreePhaseFloat);
            findModbusMap(mapIds);
        }
    });
    connect(this, &SunSpec::foundModbusMap, this, [this] (BlockId mapId, uint modbusRegisterAddress) {
        qCDebug(dcSunSpec()) << "Read map header for mapId" << mapId << "and modbus register" << modbusRegisterAddress;
        readMapHeader(modbusRegisterAddress);
    });

    connect(this, &SunSpec::mapHeaderReceived, this, [this] (uint modbusAddress, BlockId mapId, uint mapLength) {
        m_id = mapId;
        m_mapLength = mapLength;
        m_mapModbusStartRegister = modbusAddress;
        readMap(modbusAddress, mapLength);
    });

    connect(this, &SunSpec::mapReceived, this, &SunSpecInverter::onModbusMapReceived);
}

void SunSpecInverter::getInverterMap()
{
    readMap(m_mapModbusStartRegister, m_mapLength);
}

void SunSpecInverter::readInverterBlockHeader()
{
    readMapHeader(m_mapModbusStartRegister);
}

void SunSpecInverter::onModbusMapReceived(SunSpec::BlockId mapId, uint mapLength, QVector<quint16> data)
{
    Q_UNUSED(mapLength)
    switch (mapId) {
    case BlockIdInverterSinglePhase:
    case BlockIdInverterSplitPhase:
    case BlockIdInverterThreePhase: {
        InverterData inverterData;
        inverterData.acCurrent= convertValueWithSSF(data[Model10X::Model10XAcCurrent], data[Model10X::Model10XAmpereScaleFactor]);
        inverterData.acPower = convertValueWithSSF(data[Model10X::Model10XACPower], data[Model10X::Model10XWattScaleFactor]);
        inverterData.lineFrequency = convertValueWithSSF(data[Model10X::Model10XLineFrequency], data[Model10X::Model10XHerzScaleFactor]);

        inverterData.phaseACurrent = convertValueWithSSF(data[Model10X::Model10XPhaseACurrent], data[Model10X::Model10XAmpereScaleFactor]);
        inverterData.phaseBCurrent = convertValueWithSSF(data[Model10X::Model10XPhaseBCurrent], data[Model10X::Model10XAmpereScaleFactor]);
        inverterData.phaseCCurrent = convertValueWithSSF(data[Model10X::Model10XPhaseCCurrent], data[Model10X::Model10XAmpereScaleFactor]);

        inverterData.phaseVoltageAN = convertValueWithSSF(data[Model10X::Model10XPhaseVoltageAN], data[Model10X::Model10XVoltageScaleFactor]);
        inverterData.phaseVoltageBN = convertValueWithSSF(data[Model10X::Model10XPhaseVoltageBN], data[Model10X::Model10XVoltageScaleFactor]);
        inverterData.phaseVoltageCN = convertValueWithSSF(data[Model10X::Model10XPhaseVoltageCN], data[Model10X::Model10XVoltageScaleFactor]);

        inverterData.acEnergy = convertValueWithSSF(data[Model10X::Model10XAcEnergy], data[Model10X::Model10XWattHoursScaleFactor]);

        inverterData.cabinetTemperature = convertValueWithSSF(data[Model10X::Model10XCabinetTemperature], data[Model10X::Model10XTemperatureScaleFactor]);
        inverterData.event = SunSpecEvent1(data[Model10X::Model10XEvent1]);
        inverterData.operatingState = SunSpecOperatingState(data[Model10X::Model10XOperatingState]);
        emit inverterDataReceived(inverterData);

    } break;
    case BlockIdInverterSinglePhaseFloat:
    case BlockIdInverterSplitPhaseFloat:
    case BlockIdInverterThreePhaseFloat: {
        InverterData inverterData;
        inverterData.acCurrent = convertFloatValues(data[Model11X::Model11XAcCurrent], data[Model11X::Model11XAcCurrent+1]);

        inverterData.phaseACurrent = convertFloatValues(data[Model11X::Model11XPhaseACurrent], data[Model11X::Model11XPhaseACurrent+1]);
        inverterData.phaseBCurrent = convertFloatValues(data[Model11X::Model11XPhaseBCurrent], data[Model11X::Model11XPhaseBCurrent+1]);
        inverterData.phaseCCurrent = convertFloatValues(data[Model11X::Model11XPhaseCCurrent], data[Model11X::Model11XPhaseCCurrent+1]);

        inverterData.phaseVoltageAN = convertFloatValues(data[Model11X::Model11XPhaseVoltageAN], data[Model11X::Model11XPhaseVoltageAN+1]);
        inverterData.phaseVoltageBN = convertFloatValues(data[Model11X::Model11XPhaseVoltageBN], data[Model11X::Model11XPhaseVoltageBN+1]);
        inverterData.phaseVoltageCN = convertFloatValues(data[Model11X::Model11XPhaseVoltageCN], data[Model11X::Model11XPhaseVoltageCN+1]);

        inverterData.acPower = convertFloatValues(data[Model11X::Model11XACPower], data[Model11X::Model11XACPower+1]);
        inverterData.lineFrequency = convertFloatValues(data[Model11X::Model11XLineFrequency], data[Model11X::Model11XLineFrequency+1]);

        inverterData.acEnergy = convertFloatValues(data[Model11X::Model11XAcEnergy], data[Model11X::Model11XAcEnergy+1]);
        inverterData.cabinetTemperature = convertFloatValues(data[Model11X::Model11XCabinetTemperature], data[Model11X::Model11XCabinetTemperature+1]);
        inverterData.event = SunSpecEvent1(data[Model11X::Model11XEvent1]);
        inverterData.operatingState = SunSpecOperatingState(data[Model11X::Model11XOperatingState]);
        emit inverterDataReceived(inverterData);
    } break;
    default:
        //ignore
        break;
    }
}