/** * SDRangel * This is the web REST/JSON API of SDRangel SDR software. SDRangel is an Open Source Qt5/OpenGL 3.0+ (4.3+ in Windows) GUI and server Software Defined Radio and signal analyzer in software. It supports Airspy, BladeRF, HackRF, LimeSDR, PlutoSDR, RTL-SDR, SDRplay RSP1 and FunCube --- Limitations and specifcities: * In SDRangel GUI the first Rx device set cannot be deleted. Conversely the server starts with no device sets and its number of device sets can be reduced to zero by as many calls as necessary to /sdrangel/deviceset with DELETE method. * Preset import and export from/to file is a server only feature. * Device set focus is a GUI only feature. * The following channels are not implemented (status 501 is returned): ATV and DATV demodulators, Channel Analyzer NG, LoRa demodulator * The device settings and report structures contains only the sub-structure corresponding to the device type. The DeviceSettings and DeviceReport structures documented here shows all of them but only one will be or should be present at a time * The channel settings and report structures contains only the sub-structure corresponding to the channel type. The ChannelSettings and ChannelReport structures documented here shows all of them but only one will be or should be present at a time --- * * OpenAPI spec version: 7.0.0 * Contact: f4exb06@gmail.com * * NOTE: This class is auto generated by the swagger code generator program. * https://github.com/swagger-api/swagger-codegen.git * Do not edit the class manually. */ #include "SWGLimeSdrInputSettings.h" #include "SWGHelpers.h" #include #include #include #include namespace SWGSDRangel { SWGLimeSdrInputSettings::SWGLimeSdrInputSettings(QString* json) { init(); this->fromJson(*json); } SWGLimeSdrInputSettings::SWGLimeSdrInputSettings() { center_frequency = 0L; m_center_frequency_isSet = false; dev_sample_rate = 0; m_dev_sample_rate_isSet = false; log2_hard_decim = 0; m_log2_hard_decim_isSet = false; dc_block = 0; m_dc_block_isSet = false; iq_correction = 0; m_iq_correction_isSet = false; log2_soft_decim = 0; m_log2_soft_decim_isSet = false; lpf_bw = 0; m_lpf_bw_isSet = false; lpf_fir_enable = 0; m_lpf_fir_enable_isSet = false; lpf_firbw = 0; m_lpf_firbw_isSet = false; gain = 0; m_gain_isSet = false; nco_enable = 0; m_nco_enable_isSet = false; nco_frequency = 0; m_nco_frequency_isSet = false; antenna_path = 0; m_antenna_path_isSet = false; gain_mode = 0; m_gain_mode_isSet = false; lna_gain = 0; m_lna_gain_isSet = false; tia_gain = 0; m_tia_gain_isSet = false; pga_gain = 0; m_pga_gain_isSet = false; ext_clock = 0; m_ext_clock_isSet = false; ext_clock_freq = 0; m_ext_clock_freq_isSet = false; transverter_mode = 0; m_transverter_mode_isSet = false; transverter_delta_frequency = 0L; m_transverter_delta_frequency_isSet = false; iq_order = 0; m_iq_order_isSet = false; gpio_dir = 0; m_gpio_dir_isSet = false; gpio_pins = 0; m_gpio_pins_isSet = false; use_reverse_api = 0; m_use_reverse_api_isSet = false; reverse_api_address = nullptr; m_reverse_api_address_isSet = false; reverse_api_port = 0; m_reverse_api_port_isSet = false; reverse_api_device_index = 0; m_reverse_api_device_index_isSet = false; } SWGLimeSdrInputSettings::~SWGLimeSdrInputSettings() { this->cleanup(); } void SWGLimeSdrInputSettings::init() { center_frequency = 0L; m_center_frequency_isSet = false; dev_sample_rate = 0; m_dev_sample_rate_isSet = false; log2_hard_decim = 0; m_log2_hard_decim_isSet = false; dc_block = 0; m_dc_block_isSet = false; iq_correction = 0; m_iq_correction_isSet = false; log2_soft_decim = 0; m_log2_soft_decim_isSet = false; lpf_bw = 0; m_lpf_bw_isSet = false; lpf_fir_enable = 0; m_lpf_fir_enable_isSet = false; lpf_firbw = 0; m_lpf_firbw_isSet = false; gain = 0; m_gain_isSet = false; nco_enable = 0; m_nco_enable_isSet = false; nco_frequency = 0; m_nco_frequency_isSet = false; antenna_path = 0; m_antenna_path_isSet = false; gain_mode = 0; m_gain_mode_isSet = false; lna_gain = 0; m_lna_gain_isSet = false; tia_gain = 0; m_tia_gain_isSet = false; pga_gain = 0; m_pga_gain_isSet = false; ext_clock = 0; m_ext_clock_isSet = false; ext_clock_freq = 0; m_ext_clock_freq_isSet = false; transverter_mode = 0; m_transverter_mode_isSet = false; transverter_delta_frequency = 0L; m_transverter_delta_frequency_isSet = false; iq_order = 0; m_iq_order_isSet = false; gpio_dir = 0; m_gpio_dir_isSet = false; gpio_pins = 0; m_gpio_pins_isSet = false; use_reverse_api = 0; m_use_reverse_api_isSet = false; reverse_api_address = new QString(""); m_reverse_api_address_isSet = false; reverse_api_port = 0; m_reverse_api_port_isSet = false; reverse_api_device_index = 0; m_reverse_api_device_index_isSet = false; } void SWGLimeSdrInputSettings::cleanup() { if(reverse_api_address != nullptr) { delete reverse_api_address; } } SWGLimeSdrInputSettings* SWGLimeSdrInputSettings::fromJson(QString &json) { QByteArray array (json.toStdString().c_str()); QJsonDocument doc = QJsonDocument::fromJson(array); QJsonObject jsonObject = doc.object(); this->fromJsonObject(jsonObject); return this; } void SWGLimeSdrInputSettings::fromJsonObject(QJsonObject &pJson) { ::SWGSDRangel::setValue(¢er_frequency, pJson["centerFrequency"], "qint64", ""); ::SWGSDRangel::setValue(&dev_sample_rate, pJson["devSampleRate"], "qint32", ""); ::SWGSDRangel::setValue(&log2_hard_decim, pJson["log2HardDecim"], "qint32", ""); ::SWGSDRangel::setValue(&dc_block, pJson["dcBlock"], "qint32", ""); ::SWGSDRangel::setValue(&iq_correction, pJson["iqCorrection"], "qint32", ""); ::SWGSDRangel::setValue(&log2_soft_decim, pJson["log2SoftDecim"], "qint32", ""); ::SWGSDRangel::setValue(&lpf_bw, pJson["lpfBW"], "qint32", ""); ::SWGSDRangel::setValue(&lpf_fir_enable, pJson["lpfFIREnable"], "qint32", ""); ::SWGSDRangel::setValue(&lpf_firbw, pJson["lpfFIRBW"], "qint32", ""); ::SWGSDRangel::setValue(&gain, pJson["gain"], "qint32", ""); ::SWGSDRangel::setValue(&nco_enable, pJson["ncoEnable"], "qint32", ""); ::SWGSDRangel::setValue(&nco_frequency, pJson["ncoFrequency"], "qint32", ""); ::SWGSDRangel::setValue(&antenna_path, pJson["antennaPath"], "qint32", ""); ::SWGSDRangel::setValue(&gain_mode, pJson["gainMode"], "qint32", ""); ::SWGSDRangel::setValue(&lna_gain, pJson["lnaGain"], "qint32", ""); ::SWGSDRangel::setValue(&tia_gain, pJson["tiaGain"], "qint32", ""); ::SWGSDRangel::setValue(&pga_gain, pJson["pgaGain"], "qint32", ""); ::SWGSDRangel::setValue(&ext_clock, pJson["extClock"], "qint32", ""); ::SWGSDRangel::setValue(&ext_clock_freq, pJson["extClockFreq"], "qint32", ""); ::SWGSDRangel::setValue(&transverter_mode, pJson["transverterMode"], "qint32", ""); ::SWGSDRangel::setValue(&transverter_delta_frequency, pJson["transverterDeltaFrequency"], "qint64", ""); ::SWGSDRangel::setValue(&iq_order, pJson["iqOrder"], "qint32", ""); ::SWGSDRangel::setValue(&gpio_dir, pJson["gpioDir"], "qint32", ""); ::SWGSDRangel::setValue(&gpio_pins, pJson["gpioPins"], "qint32", ""); ::SWGSDRangel::setValue(&use_reverse_api, pJson["useReverseAPI"], "qint32", ""); ::SWGSDRangel::setValue(&reverse_api_address, pJson["reverseAPIAddress"], "QString", "QString"); ::SWGSDRangel::setValue(&reverse_api_port, pJson["reverseAPIPort"], "qint32", ""); ::SWGSDRangel::setValue(&reverse_api_device_index, pJson["reverseAPIDeviceIndex"], "qint32", ""); } QString SWGLimeSdrInputSettings::asJson () { QJsonObject* obj = this->asJsonObject(); QJsonDocument doc(*obj); QByteArray bytes = doc.toJson(); delete obj; return QString(bytes); } QJsonObject* SWGLimeSdrInputSettings::asJsonObject() { QJsonObject* obj = new QJsonObject(); if(m_center_frequency_isSet){ obj->insert("centerFrequency", QJsonValue(center_frequency)); } if(m_dev_sample_rate_isSet){ obj->insert("devSampleRate", QJsonValue(dev_sample_rate)); } if(m_log2_hard_decim_isSet){ obj->insert("log2HardDecim", QJsonValue(log2_hard_decim)); } if(m_dc_block_isSet){ obj->insert("dcBlock", QJsonValue(dc_block)); } if(m_iq_correction_isSet){ obj->insert("iqCorrection", QJsonValue(iq_correction)); } if(m_log2_soft_decim_isSet){ obj->insert("log2SoftDecim", QJsonValue(log2_soft_decim)); } if(m_lpf_bw_isSet){ obj->insert("lpfBW", QJsonValue(lpf_bw)); } if(m_lpf_fir_enable_isSet){ obj->insert("lpfFIREnable", QJsonValue(lpf_fir_enable)); } if(m_lpf_firbw_isSet){ obj->insert("lpfFIRBW", QJsonValue(lpf_firbw)); } if(m_gain_isSet){ obj->insert("gain", QJsonValue(gain)); } if(m_nco_enable_isSet){ obj->insert("ncoEnable", QJsonValue(nco_enable)); } if(m_nco_frequency_isSet){ obj->insert("ncoFrequency", QJsonValue(nco_frequency)); } if(m_antenna_path_isSet){ obj->insert("antennaPath", QJsonValue(antenna_path)); } if(m_gain_mode_isSet){ obj->insert("gainMode", QJsonValue(gain_mode)); } if(m_lna_gain_isSet){ obj->insert("lnaGain", QJsonValue(lna_gain)); } if(m_tia_gain_isSet){ obj->insert("tiaGain", QJsonValue(tia_gain)); } if(m_pga_gain_isSet){ obj->insert("pgaGain", QJsonValue(pga_gain)); } if(m_ext_clock_isSet){ obj->insert("extClock", QJsonValue(ext_clock)); } if(m_ext_clock_freq_isSet){ obj->insert("extClockFreq", QJsonValue(ext_clock_freq)); } if(m_transverter_mode_isSet){ obj->insert("transverterMode", QJsonValue(transverter_mode)); } if(m_transverter_delta_frequency_isSet){ obj->insert("transverterDeltaFrequency", QJsonValue(transverter_delta_frequency)); } if(m_iq_order_isSet){ obj->insert("iqOrder", QJsonValue(iq_order)); } if(m_gpio_dir_isSet){ obj->insert("gpioDir", QJsonValue(gpio_dir)); } if(m_gpio_pins_isSet){ obj->insert("gpioPins", QJsonValue(gpio_pins)); } if(m_use_reverse_api_isSet){ obj->insert("useReverseAPI", QJsonValue(use_reverse_api)); } if(reverse_api_address != nullptr && *reverse_api_address != QString("")){ toJsonValue(QString("reverseAPIAddress"), reverse_api_address, obj, QString("QString")); } if(m_reverse_api_port_isSet){ obj->insert("reverseAPIPort", QJsonValue(reverse_api_port)); } if(m_reverse_api_device_index_isSet){ obj->insert("reverseAPIDeviceIndex", QJsonValue(reverse_api_device_index)); } return obj; } qint64 SWGLimeSdrInputSettings::getCenterFrequency() { return center_frequency; } void SWGLimeSdrInputSettings::setCenterFrequency(qint64 center_frequency) { this->center_frequency = center_frequency; this->m_center_frequency_isSet = true; } qint32 SWGLimeSdrInputSettings::getDevSampleRate() { return dev_sample_rate; } void SWGLimeSdrInputSettings::setDevSampleRate(qint32 dev_sample_rate) { this->dev_sample_rate = dev_sample_rate; this->m_dev_sample_rate_isSet = true; } qint32 SWGLimeSdrInputSettings::getLog2HardDecim() { return log2_hard_decim; } void SWGLimeSdrInputSettings::setLog2HardDecim(qint32 log2_hard_decim) { this->log2_hard_decim = log2_hard_decim; this->m_log2_hard_decim_isSet = true; } qint32 SWGLimeSdrInputSettings::getDcBlock() { return dc_block; } void SWGLimeSdrInputSettings::setDcBlock(qint32 dc_block) { this->dc_block = dc_block; this->m_dc_block_isSet = true; } qint32 SWGLimeSdrInputSettings::getIqCorrection() { return iq_correction; } void SWGLimeSdrInputSettings::setIqCorrection(qint32 iq_correction) { this->iq_correction = iq_correction; this->m_iq_correction_isSet = true; } qint32 SWGLimeSdrInputSettings::getLog2SoftDecim() { return log2_soft_decim; } void SWGLimeSdrInputSettings::setLog2SoftDecim(qint32 log2_soft_decim) { this->log2_soft_decim = log2_soft_decim; this->m_log2_soft_decim_isSet = true; } qint32 SWGLimeSdrInputSettings::getLpfBw() { return lpf_bw; } void SWGLimeSdrInputSettings::setLpfBw(qint32 lpf_bw) { this->lpf_bw = lpf_bw; this->m_lpf_bw_isSet = true; } qint32 SWGLimeSdrInputSettings::getLpfFirEnable() { return lpf_fir_enable; } void SWGLimeSdrInputSettings::setLpfFirEnable(qint32 lpf_fir_enable) { this->lpf_fir_enable = lpf_fir_enable; this->m_lpf_fir_enable_isSet = true; } qint32 SWGLimeSdrInputSettings::getLpfFirbw() { return lpf_firbw; } void SWGLimeSdrInputSettings::setLpfFirbw(qint32 lpf_firbw) { this->lpf_firbw = lpf_firbw; this->m_lpf_firbw_isSet = true; } qint32 SWGLimeSdrInputSettings::getGain() { return gain; } void SWGLimeSdrInputSettings::setGain(qint32 gain) { this->gain = gain; this->m_gain_isSet = true; } qint32 SWGLimeSdrInputSettings::getNcoEnable() { return nco_enable; } void SWGLimeSdrInputSettings::setNcoEnable(qint32 nco_enable) { this->nco_enable = nco_enable; this->m_nco_enable_isSet = true; } qint32 SWGLimeSdrInputSettings::getNcoFrequency() { return nco_frequency; } void SWGLimeSdrInputSettings::setNcoFrequency(qint32 nco_frequency) { this->nco_frequency = nco_frequency; this->m_nco_frequency_isSet = true; } qint32 SWGLimeSdrInputSettings::getAntennaPath() { return antenna_path; } void SWGLimeSdrInputSettings::setAntennaPath(qint32 antenna_path) { this->antenna_path = antenna_path; this->m_antenna_path_isSet = true; } qint32 SWGLimeSdrInputSettings::getGainMode() { return gain_mode; } void SWGLimeSdrInputSettings::setGainMode(qint32 gain_mode) { this->gain_mode = gain_mode; this->m_gain_mode_isSet = true; } qint32 SWGLimeSdrInputSettings::getLnaGain() { return lna_gain; } void SWGLimeSdrInputSettings::setLnaGain(qint32 lna_gain) { this->lna_gain = lna_gain; this->m_lna_gain_isSet = true; } qint32 SWGLimeSdrInputSettings::getTiaGain() { return tia_gain; } void SWGLimeSdrInputSettings::setTiaGain(qint32 tia_gain) { this->tia_gain = tia_gain; this->m_tia_gain_isSet = true; } qint32 SWGLimeSdrInputSettings::getPgaGain() { return pga_gain; } void SWGLimeSdrInputSettings::setPgaGain(qint32 pga_gain) { this->pga_gain = pga_gain; this->m_pga_gain_isSet = true; } qint32 SWGLimeSdrInputSettings::getExtClock() { return ext_clock; } void SWGLimeSdrInputSettings::setExtClock(qint32 ext_clock) { this->ext_clock = ext_clock; this->m_ext_clock_isSet = true; } qint32 SWGLimeSdrInputSettings::getExtClockFreq() { return ext_clock_freq; } void SWGLimeSdrInputSettings::setExtClockFreq(qint32 ext_clock_freq) { this->ext_clock_freq = ext_clock_freq; this->m_ext_clock_freq_isSet = true; } qint32 SWGLimeSdrInputSettings::getTransverterMode() { return transverter_mode; } void SWGLimeSdrInputSettings::setTransverterMode(qint32 transverter_mode) { this->transverter_mode = transverter_mode; this->m_transverter_mode_isSet = true; } qint64 SWGLimeSdrInputSettings::getTransverterDeltaFrequency() { return transverter_delta_frequency; } void SWGLimeSdrInputSettings::setTransverterDeltaFrequency(qint64 transverter_delta_frequency) { this->transverter_delta_frequency = transverter_delta_frequency; this->m_transverter_delta_frequency_isSet = true; } qint32 SWGLimeSdrInputSettings::getIqOrder() { return iq_order; } void SWGLimeSdrInputSettings::setIqOrder(qint32 iq_order) { this->iq_order = iq_order; this->m_iq_order_isSet = true; } qint32 SWGLimeSdrInputSettings::getGpioDir() { return gpio_dir; } void SWGLimeSdrInputSettings::setGpioDir(qint32 gpio_dir) { this->gpio_dir = gpio_dir; this->m_gpio_dir_isSet = true; } qint32 SWGLimeSdrInputSettings::getGpioPins() { return gpio_pins; } void SWGLimeSdrInputSettings::setGpioPins(qint32 gpio_pins) { this->gpio_pins = gpio_pins; this->m_gpio_pins_isSet = true; } qint32 SWGLimeSdrInputSettings::getUseReverseApi() { return use_reverse_api; } void SWGLimeSdrInputSettings::setUseReverseApi(qint32 use_reverse_api) { this->use_reverse_api = use_reverse_api; this->m_use_reverse_api_isSet = true; } QString* SWGLimeSdrInputSettings::getReverseApiAddress() { return reverse_api_address; } void SWGLimeSdrInputSettings::setReverseApiAddress(QString* reverse_api_address) { this->reverse_api_address = reverse_api_address; this->m_reverse_api_address_isSet = true; } qint32 SWGLimeSdrInputSettings::getReverseApiPort() { return reverse_api_port; } void SWGLimeSdrInputSettings::setReverseApiPort(qint32 reverse_api_port) { this->reverse_api_port = reverse_api_port; this->m_reverse_api_port_isSet = true; } qint32 SWGLimeSdrInputSettings::getReverseApiDeviceIndex() { return reverse_api_device_index; } void SWGLimeSdrInputSettings::setReverseApiDeviceIndex(qint32 reverse_api_device_index) { this->reverse_api_device_index = reverse_api_device_index; this->m_reverse_api_device_index_isSet = true; } bool SWGLimeSdrInputSettings::isSet(){ bool isObjectUpdated = false; do{ if(m_center_frequency_isSet){ isObjectUpdated = true; break; } if(m_dev_sample_rate_isSet){ isObjectUpdated = true; break; } if(m_log2_hard_decim_isSet){ isObjectUpdated = true; break; } if(m_dc_block_isSet){ isObjectUpdated = true; break; } if(m_iq_correction_isSet){ isObjectUpdated = true; break; } if(m_log2_soft_decim_isSet){ isObjectUpdated = true; break; } if(m_lpf_bw_isSet){ isObjectUpdated = true; break; } if(m_lpf_fir_enable_isSet){ isObjectUpdated = true; break; } if(m_lpf_firbw_isSet){ isObjectUpdated = true; break; } if(m_gain_isSet){ isObjectUpdated = true; break; } if(m_nco_enable_isSet){ isObjectUpdated = true; break; } if(m_nco_frequency_isSet){ isObjectUpdated = true; break; } if(m_antenna_path_isSet){ isObjectUpdated = true; break; } if(m_gain_mode_isSet){ isObjectUpdated = true; break; } if(m_lna_gain_isSet){ isObjectUpdated = true; break; } if(m_tia_gain_isSet){ isObjectUpdated = true; break; } if(m_pga_gain_isSet){ isObjectUpdated = true; break; } if(m_ext_clock_isSet){ isObjectUpdated = true; break; } if(m_ext_clock_freq_isSet){ isObjectUpdated = true; break; } if(m_transverter_mode_isSet){ isObjectUpdated = true; break; } if(m_transverter_delta_frequency_isSet){ isObjectUpdated = true; break; } if(m_iq_order_isSet){ isObjectUpdated = true; break; } if(m_gpio_dir_isSet){ isObjectUpdated = true; break; } if(m_gpio_pins_isSet){ isObjectUpdated = true; break; } if(m_use_reverse_api_isSet){ isObjectUpdated = true; break; } if(reverse_api_address && *reverse_api_address != QString("")){ isObjectUpdated = true; break; } if(m_reverse_api_port_isSet){ isObjectUpdated = true; break; } if(m_reverse_api_device_index_isSet){ isObjectUpdated = true; break; } }while(false); return isObjectUpdated; } }