/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2015 Edouard Griffiths, F4EXB. // // Copyright (C) 2021 Jon Beniston, M7RCE // // // // This program is free software; you can redistribute it and/or modify // // it under the terms of the GNU General Public License as published by // // the Free Software Foundation as version 3 of the License, or // // (at your option) any later version. // // // // This program is distributed in the hope that it will be useful, // // but WITHOUT ANY WARRANTY; without even the implied warranty of // // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // // GNU General Public License V3 for more details. // // // // You should have received a copy of the GNU General Public License // // along with this program. If not, see . // /////////////////////////////////////////////////////////////////////////////////// #include #include "util/simpleserializer.h" #include "settings/serializable.h" #include "radioastronomysettings.h" RadioAstronomySettings::RadioAstronomySettings() : m_channelMarker(nullptr), m_rollupState(nullptr) { resetToDefaults(); } void RadioAstronomySettings::resetToDefaults() { m_inputFrequencyOffset = 0; m_sampleRate = 1000000; m_rfBandwidth = 1000000; m_integration = 4000; m_fftSize = 256; m_fftWindow = HAN; m_filterFreqs = ""; m_starTracker = ""; m_rotator = "None"; m_tempRX = 75.0f; m_tempCMB = 2.73; m_tempGal = 2.0; m_tempSP = 85.0; m_tempAtm = 2.0; m_tempAir = 15.0; m_zenithOpacity = 0.0055; m_elevation = 90.0; m_tempGalLink = true; m_tempAtmLink = true; m_tempAirLink = true; m_elevationLink = true; m_gainVariation = 0.0011f; m_sourceType = UNKNOWN; m_omegaS = 0.0; m_omegaSUnits = DEGREES; m_omegaAUnits = DEGREES; m_spectrumPeaks = false; m_spectrumMarkers = false; m_spectrumTemp = false; m_spectrumReverseXAxis = false; m_spectrumRefLine = false; m_spectrumLAB = false; m_spectrumDistance = false; m_spectrumLegend = false; m_spectrumReference = 0.0f; m_spectrumRange = 120.0f; m_spectrumCenterFreqOffset = 0.0f; m_spectrumAutoscale = true; m_spectrumSpan = 1.0f; m_spectrumYScale = SY_DBFS; m_spectrumBaseline = SBL_TSYS0; m_recalibrate = false; m_tCalHot = 300.0f; m_tCalCold = 10.0f; m_line = HI; m_lineCustomFrequency = 0.0f; m_refFrame = LSR; m_powerAutoscale = true; m_powerReference = 0.0f; m_powerRange = 100.0f; m_powerPeaks = false; m_powerMarkers = false; m_powerAvg = false; m_powerLegend = false; m_powerYData = PY_POWER; m_powerYUnits = PY_DBFS; m_powerShowTsys0 = false; m_powerShowAirTemp = false; m_powerShowGaussian = false; m_powerShowFiltered = false; m_powerFilter = FILT_MEDIAN; m_powerFilterN = 10; m_powerShowMeasurement = true; m_power2DLinkSweep = true; m_power2DSweepType = SWP_OFFSET; m_power2DHeight = 3; m_power2DWidth = 3; m_power2DXMin = 0; m_power2DXMax = 10; m_power2DYMin = 0; m_power2DYMax = 10; m_powerColourAutoscale = true; m_powerColourScaleMin = 0.0f; m_powerColourScaleMax = 0.0f; m_powerColourPalette = "Colour"; m_sensorName[0] = "Temperature"; m_sensorDevice[0] = ""; m_sensorInit[0] = "UNIT:TEMP C"; m_sensorMeasure[0] = "MEAS:TEMP?"; m_sensorEnabled[0] = false; m_sensorVisible[0] = false; m_sensorName[1] = "Voltage"; m_sensorDevice[1] = ""; m_sensorInit[1] = ""; m_sensorMeasure[1] = "MEAS:VOLT:DC?"; m_sensorEnabled[1] = false; m_sensorVisible[1] = false; m_sensorMeasurePeriod = 1.0f; m_sunDistanceToGC = 8.1f; m_sunOrbitalVelocity = 248.0f; m_runMode = CONTINUOUS; m_sweepStartAtTime = false; m_sweepStartDateTime = QDateTime::currentDateTime(); m_sweepType = SWP_OFFSET; m_sweep1Start = -5.0; m_sweep1Stop = 5.0; m_sweep1Step = 5.0; m_sweep1Delay = 0.0; m_sweep2Start = -5.0; m_sweep2Stop = 5.0; m_sweep2Step = 5.0; m_sweep2Delay = 0.0; m_gpioEnabled = false; m_gpioPin = 0; m_gpioSense = 1; m_startCalCommand = ""; m_stopCalCommand = ""; m_calCommandDelay = 1.0f; m_rgbColor = QColor(102, 0, 0).rgb(); m_title = "Radio Astronomy"; m_streamIndex = 0; m_useReverseAPI = false; m_reverseAPIAddress = "127.0.0.1"; m_reverseAPIPort = 8888; m_reverseAPIDeviceIndex = 0; m_reverseAPIChannelIndex = 0; m_workspaceIndex = 0; m_hidden = false; for (int i = 0; i < RADIOASTRONOMY_POWERTABLE_COLUMNS; i++) { m_powerTableColumnIndexes[i] = i; m_powerTableColumnSizes[i] = -1; // Autosize } } QByteArray RadioAstronomySettings::serialize() const { SimpleSerializer s(1); s.writeS32(1, m_inputFrequencyOffset); s.writeS32(2, m_sampleRate); s.writeS32(3, m_rfBandwidth); s.writeS32(4, m_integration); s.writeS32(5, m_fftSize); s.writeS32(6, (int)m_fftWindow); s.writeString(7, m_filterFreqs); s.writeString(10, m_starTracker); s.writeString(11, m_rotator); s.writeFloat(20, m_tempRX); s.writeFloat(21, m_tempCMB); s.writeFloat(22, m_tempGal); s.writeFloat(23, m_tempSP); s.writeFloat(24, m_tempAtm); s.writeFloat(25, m_tempAir); s.writeFloat(26, m_zenithOpacity); s.writeFloat(27, m_elevation); s.writeBool(28, m_tempGalLink); s.writeBool(29, m_tempAtmLink); s.writeBool(30, m_tempAirLink); s.writeBool(31, m_elevationLink); s.writeFloat(40, m_gainVariation); s.writeS32(41, (int)m_sourceType); s.writeFloat(42, m_omegaS); s.writeS32(43, (int)m_omegaSUnits); s.writeS32(44, (int)m_omegaAUnits); s.writeBool(50, m_spectrumPeaks); s.writeBool(51, m_spectrumMarkers); s.writeBool(52, m_spectrumTemp); s.writeBool(53, m_spectrumReverseXAxis); s.writeBool(54, m_spectrumRefLine); s.writeBool(55, m_spectrumLegend); s.writeBool(56, m_spectrumDistance); s.writeBool(57, m_spectrumLAB); s.writeFloat(60, m_spectrumReference); s.writeFloat(61, m_spectrumRange); s.writeFloat(62, m_spectrumSpan); s.writeFloat(63, m_spectrumCenterFreqOffset); s.writeBool(64, m_spectrumAutoscale); s.writeS32(65, (int)m_spectrumYScale); s.writeS32(66, (int)m_spectrumBaseline); s.writeBool(70, m_recalibrate); s.writeFloat(71, m_tCalHot); s.writeFloat(72, m_tCalCold); s.writeS32(73, (int)m_line); s.writeFloat(74, m_lineCustomFrequency); s.writeS32(75, (int)m_refFrame); s.writeFloat(76, m_sunDistanceToGC); s.writeFloat(77, m_sunOrbitalVelocity); s.writeBool(80, m_powerPeaks); s.writeBool(81, m_powerMarkers); s.writeBool(82, m_powerAvg); s.writeBool(83, m_powerLegend); s.writeBool(84, m_powerShowTsys0); s.writeBool(85, m_powerShowAirTemp); s.writeBool(86, m_powerShowGaussian); s.writeFloat(87, m_powerReference); s.writeFloat(88, m_powerRange); s.writeBool(89, m_powerAutoscale); s.writeS32(90, (int)m_powerYData); s.writeS32(91, (int)m_powerYUnits); s.writeBool(92, m_powerShowFiltered); s.writeS32(93, (int)m_powerFilter); s.writeS32(94, m_powerFilterN); s.writeBool(95, m_powerShowMeasurement); s.writeBool(100, m_power2DLinkSweep); s.writeS32(102, (int)m_power2DSweepType); s.writeS32(103, m_power2DWidth); s.writeS32(104, m_power2DHeight); s.writeFloat(105, m_power2DXMin); s.writeFloat(106, m_power2DXMax); s.writeFloat(107, m_power2DYMin); s.writeFloat(108, m_power2DYMax); s.writeBool(109, m_powerColourAutoscale); s.writeFloat(110, m_powerColourScaleMin); s.writeFloat(111, m_powerColourScaleMax); s.writeString(112, m_powerColourPalette); s.writeS32(120, m_runMode); s.writeBool(121, m_sweepStartAtTime); s.writeS64(122, m_sweepStartDateTime.toMSecsSinceEpoch()); s.writeS32(123, (int)m_sweepType); s.writeFloat(124, m_sweep1Start); s.writeFloat(125, m_sweep1Stop); s.writeFloat(126, m_sweep1Step); s.writeFloat(127, m_sweep1Delay); s.writeFloat(128, m_sweep2Start); s.writeFloat(129, m_sweep2Stop); s.writeFloat(130, m_sweep2Step); s.writeFloat(131, m_sweep2Delay); s.writeString(140, m_sensorName[0]); s.writeString(141, m_sensorDevice[0]); s.writeString(142, m_sensorInit[0]); s.writeString(143, m_sensorMeasure[0]); s.writeBool(144, m_sensorEnabled[0]); s.writeBool(145, m_sensorVisible[0]); s.writeString(146, m_sensorName[1]); s.writeString(147, m_sensorDevice[1]); s.writeString(148, m_sensorInit[1]); s.writeString(149, m_sensorMeasure[1]); s.writeBool(150, m_sensorEnabled[1]); s.writeBool(151, m_sensorVisible[1]); s.writeFloat(152, m_sensorMeasurePeriod); s.writeBool(160, m_gpioEnabled); s.writeS32(161, m_gpioPin); s.writeS32(162, m_gpioSense); s.writeString(167, m_startCalCommand); s.writeString(168, m_stopCalCommand); s.writeFloat(169, m_calCommandDelay); s.writeU32(180, m_rgbColor); s.writeString(181, m_title); if (m_channelMarker) { s.writeBlob(182, m_channelMarker->serialize()); } s.writeS32(183, m_streamIndex); s.writeBool(184, m_useReverseAPI); s.writeString(185, m_reverseAPIAddress); s.writeU32(186, m_reverseAPIPort); s.writeU32(187, m_reverseAPIDeviceIndex); s.writeU32(188, m_reverseAPIChannelIndex); s.writeS32(189, m_workspaceIndex); s.writeBlob(190, m_geometryBytes); s.writeBool(191, m_hidden); for (int i = 0; i < RADIOASTRONOMY_POWERTABLE_COLUMNS; i++) { s.writeS32(400 + i, m_powerTableColumnIndexes[i]); } for (int i = 0; i < RADIOASTRONOMY_POWERTABLE_COLUMNS; i++) { s.writeS32(500 + i, m_powerTableColumnSizes[i]); } return s.final(); } bool RadioAstronomySettings::deserialize(const QByteArray& data) { SimpleDeserializer d(data); if(!d.isValid()) { resetToDefaults(); return false; } if(d.getVersion() == 1) { QByteArray bytetmp; uint32_t utmp; QString strtmp; qint64 dttmp; d.readS32(1, &m_inputFrequencyOffset, 0); d.readS32(2, &m_sampleRate, 1000000); d.readS32(3, &m_rfBandwidth, 1000000); d.readS32(4, &m_integration, 4000); d.readS32(5, &m_fftSize, 256); d.readS32(6, (int*)&m_fftWindow, (int)HAN); d.readString(7, &m_filterFreqs, ""); d.readString(10, &m_starTracker, ""); d.readString(11, &m_rotator, "None"); d.readFloat(20, &m_tempRX, 75.0f); d.readFloat(21, &m_tempCMB, 2.73f); d.readFloat(22, &m_tempGal, 2.0f); d.readFloat(23, &m_tempSP, 85.0f); d.readFloat(24, &m_tempAtm, 2.0f); d.readFloat(25, &m_tempAir, 15.0f); d.readFloat(26, &m_zenithOpacity, 0.0055f); d.readFloat(27, &m_elevation, 90.0f); d.readBool(28, &m_tempGalLink, true); d.readBool(29, &m_tempAtmLink, true); d.readBool(30, &m_tempAirLink, true); d.readBool(31, &m_elevationLink, true); d.readFloat(40, &m_gainVariation, 0.0011f); d.readS32(41, (int*)&m_sourceType, UNKNOWN); d.readFloat(42, &m_omegaS, 0.0f); d.readS32(43, (int*)&m_omegaSUnits, DEGREES); d.readS32(44, (int*)&m_omegaAUnits, DEGREES); d.readBool(50, &m_spectrumPeaks, false); d.readBool(51, &m_spectrumMarkers, false); d.readBool(52, &m_spectrumTemp, false); d.readBool(53, &m_spectrumReverseXAxis, false); d.readBool(54, &m_spectrumRefLine, false); d.readBool(55, &m_spectrumLegend, false); d.readBool(56, &m_spectrumDistance, false); d.readBool(57, &m_spectrumLAB, false); d.readFloat(60, &m_spectrumReference, 0.0f); d.readFloat(61, &m_spectrumRange, 120.0f); d.readFloat(62, &m_spectrumSpan, 1.0f); d.readFloat(63, &m_spectrumCenterFreqOffset, 0.0f); d.readBool(64, &m_spectrumAutoscale, false); d.readS32(65, (int*)&m_spectrumYScale, SY_DBFS); d.readS32(66, (int*)&m_spectrumBaseline, SBL_TSYS0); d.readBool(70, &m_recalibrate, false); d.readFloat(71, &m_tCalHot, 300.0f); d.readFloat(72, &m_tCalCold, 10.0f); d.readS32(73, (int*)&m_line, (int)HI); d.readFloat(74, &m_lineCustomFrequency, 0.0f); d.readS32(75, (int*)&m_refFrame, LSR); d.readFloat(76, &m_sunDistanceToGC, 8.1f); d.readFloat(77, &m_sunOrbitalVelocity, 248.0f); d.readBool(80, &m_powerPeaks, false); d.readBool(81, &m_powerMarkers, false); d.readBool(82, &m_powerAvg, false); d.readBool(83, &m_powerLegend, false); d.readBool(84, &m_powerShowTsys0, false); d.readBool(85, &m_powerShowAirTemp, false); d.readBool(86, &m_powerShowGaussian, false); d.readFloat(87, &m_powerReference, 0.0f); d.readFloat(88, &m_powerRange, 100.0f); d.readBool(89, &m_powerAutoscale, true); d.readS32(90, (int*)&m_powerYData, PY_POWER); d.readS32(91, (int*)&m_powerYUnits, PY_DBFS); d.readBool(92, &m_powerShowFiltered, false); d.readS32(93, (int*)&m_powerFilter, FILT_MEDIAN); d.readS32(94, &m_powerFilterN, 10); d.readBool(95, &m_powerShowMeasurement, true); d.readBool(100, &m_power2DLinkSweep, true); d.readS32(102, (int*)&m_power2DSweepType, SWP_OFFSET); d.readS32(103, &m_power2DWidth, 3); d.readS32(104, &m_power2DHeight, 3); d.readFloat(105, &m_power2DXMin, 0); d.readFloat(106, &m_power2DXMax, 10); d.readFloat(107, &m_power2DYMin, 0); d.readFloat(108, &m_power2DYMax, 10); d.readBool(109, &m_powerColourAutoscale, true); d.readFloat(110, &m_powerColourScaleMin, 0.0f); d.readFloat(111, &m_powerColourScaleMax, 0.0f); d.readString(112, &m_powerColourPalette, "Colour"); d.readS32(120, (int *)&m_runMode, CONTINUOUS); d.readBool(121, &m_sweepStartAtTime, false); d.readS64(122, &dttmp, QDateTime::currentDateTime().toMSecsSinceEpoch()); m_sweepStartDateTime = QDateTime::fromMSecsSinceEpoch(dttmp); d.readS32(123, (int*)&m_sweepType, SWP_OFFSET); d.readFloat(124, &m_sweep1Start, -5.0f); d.readFloat(125, &m_sweep1Stop, 5.0f); d.readFloat(126, &m_sweep1Step, 5.0f); d.readFloat(127, &m_sweep1Delay, 0.0f); d.readFloat(128, &m_sweep2Start, -5.0f); d.readFloat(129, &m_sweep2Stop, 5.0); d.readFloat(130, &m_sweep2Step, 5.0f); d.readFloat(131, &m_sweep2Delay, 0.0f); d.readString(140, &m_sensorName[0], ""); d.readString(141, &m_sensorDevice[0], ""); d.readString(142, &m_sensorInit[0], ""); d.readString(143, &m_sensorMeasure[0], ""); d.readBool(144, &m_sensorEnabled[0], false); d.readBool(145, &m_sensorVisible[0], false); d.readString(146, &m_sensorName[1], ""); d.readString(147, &m_sensorDevice[1], ""); d.readString(148, &m_sensorInit[1], ""); d.readString(149, &m_sensorMeasure[1], ""); d.readBool(150, &m_sensorEnabled[1], false); d.readBool(151, &m_sensorVisible[1], false); d.readFloat(152, &m_sensorMeasurePeriod, 1.0f); d.readBool(160, &m_gpioEnabled, false); d.readS32(161, &m_gpioPin, 0); d.readS32(162, &m_gpioSense, 1); d.readString(167, &m_startCalCommand, ""); d.readString(168, &m_stopCalCommand, ""); d.readFloat(169, &m_calCommandDelay, 1.0f); d.readU32(180, &m_rgbColor, QColor(102, 0, 0).rgb()); d.readString(181, &m_title, "Radio Astronomy"); d.readBlob(182, &bytetmp); if (m_channelMarker) { m_channelMarker->deserialize(bytetmp); } d.readS32(183, &m_streamIndex, 0); d.readBool(184, &m_useReverseAPI, false); d.readString(185, &m_reverseAPIAddress, "127.0.0.1"); d.readU32(186, &utmp, 0); if ((utmp > 1023) && (utmp < 65535)) { m_reverseAPIPort = utmp; } else { m_reverseAPIPort = 8888; } d.readU32(187, &utmp, 0); m_reverseAPIDeviceIndex = utmp > 99 ? 99 : utmp; d.readU32(188, &utmp, 0); m_reverseAPIChannelIndex = utmp > 99 ? 99 : utmp; d.readS32(189, &m_workspaceIndex, 0); d.readBlob(190, &m_geometryBytes); d.readBool(191, &m_hidden, false); for (int i = 0; i < RADIOASTRONOMY_POWERTABLE_COLUMNS; i++) { d.readS32(400 + i, &m_powerTableColumnIndexes[i], i); } for (int i = 0; i < RADIOASTRONOMY_POWERTABLE_COLUMNS; i++) { d.readS32(500 + i, &m_powerTableColumnSizes[i], -1); } return true; } else { resetToDefaults(); return false; } }