#include #include #include #include "OBSWConfig.h" SyrlinksHkHandler::SyrlinksHkHandler(object_id_t objectId, object_id_t comIF, CookieIF* comCookie, power::Switch_t powerSwitch) : DeviceHandlerBase(objectId, comIF, comCookie), rxDataset(this), txDataset(this), temperatureSet(this), powerSwitch(powerSwitch) { if (comCookie == NULL) { sif::warning << "SyrlinksHkHandler: Invalid com cookie" << std::endl; } } SyrlinksHkHandler::~SyrlinksHkHandler() {} void SyrlinksHkHandler::doStartUp() { switch (startupState) { case StartupState::OFF: { startupState = StartupState::ENABLE_TEMPERATURE_PROTECTION; break; } case StartupState::DONE: { setMode(_MODE_TO_ON); break; } default: break; } } void SyrlinksHkHandler::doShutDown() { setMode(_MODE_POWER_DOWN); } ReturnValue_t SyrlinksHkHandler::buildNormalDeviceCommand(DeviceCommandId_t* id) { switch (nextCommand) { case (syrlinks::READ_RX_STATUS_REGISTERS): *id = syrlinks::READ_RX_STATUS_REGISTERS; nextCommand = syrlinks::READ_TX_STATUS; break; case (syrlinks::READ_TX_STATUS): *id = syrlinks::READ_TX_STATUS; nextCommand = syrlinks::READ_TX_WAVEFORM; break; case (syrlinks::READ_TX_WAVEFORM): *id = syrlinks::READ_TX_WAVEFORM; nextCommand = syrlinks::READ_TX_AGC_VALUE_HIGH_BYTE; break; case (syrlinks::READ_TX_AGC_VALUE_HIGH_BYTE): *id = syrlinks::READ_TX_AGC_VALUE_HIGH_BYTE; nextCommand = syrlinks::READ_TX_AGC_VALUE_LOW_BYTE; break; case (syrlinks::READ_TX_AGC_VALUE_LOW_BYTE): *id = syrlinks::READ_TX_AGC_VALUE_LOW_BYTE; nextCommand = syrlinks::TEMP_POWER_AMPLIFIER_HIGH_BYTE; break; case (syrlinks::TEMP_POWER_AMPLIFIER_HIGH_BYTE): *id = syrlinks::TEMP_POWER_AMPLIFIER_HIGH_BYTE; nextCommand = syrlinks::TEMP_POWER_AMPLIFIER_LOW_BYTE; break; case (syrlinks::TEMP_POWER_AMPLIFIER_LOW_BYTE): *id = syrlinks::TEMP_POWER_AMPLIFIER_LOW_BYTE; nextCommand = syrlinks::TEMP_BASEBAND_BOARD_HIGH_BYTE; break; case (syrlinks::TEMP_BASEBAND_BOARD_HIGH_BYTE): *id = syrlinks::TEMP_BASEBAND_BOARD_HIGH_BYTE; nextCommand = syrlinks::TEMP_BASEBAND_BOARD_LOW_BYTE; break; case (syrlinks::TEMP_BASEBAND_BOARD_LOW_BYTE): *id = syrlinks::TEMP_BASEBAND_BOARD_LOW_BYTE; nextCommand = syrlinks::READ_RX_STATUS_REGISTERS; break; default: sif::debug << "SyrlinksHkHandler::buildNormalDeviceCommand: rememberCommandId has invalid" << "command id" << std::endl; break; } return buildCommandFromCommand(*id, NULL, 0); } ReturnValue_t SyrlinksHkHandler::buildTransitionDeviceCommand(DeviceCommandId_t* id) { switch (startupState) { case StartupState::ENABLE_TEMPERATURE_PROTECTION: { *id = syrlinks::WRITE_LCL_CONFIG; return HasReturnvaluesIF::RETURN_OK; } default: break; } return NOTHING_TO_SEND; } ReturnValue_t SyrlinksHkHandler::buildCommandFromCommand(DeviceCommandId_t deviceCommand, const uint8_t* commandData, size_t commandDataLen) { switch (deviceCommand) { case (syrlinks::RESET_UNIT): { prepareCommand(resetCommand, deviceCommand); return RETURN_OK; } case (syrlinks::SET_TX_MODE_STANDBY): { prepareCommand(setTxModeStandby, deviceCommand); return RETURN_OK; } case (syrlinks::SET_TX_MODE_MODULATION): { prepareCommand(setTxModeModulation, deviceCommand); return RETURN_OK; } case (syrlinks::SET_TX_MODE_CW): { prepareCommand(setTxModeCw, deviceCommand); return RETURN_OK; } case (syrlinks::WRITE_LCL_CONFIG): { prepareCommand(writeLclConfig, deviceCommand); return RETURN_OK; } case (syrlinks::READ_RX_STATUS_REGISTERS): { prepareCommand(readRxStatusRegCommand, deviceCommand); return RETURN_OK; } case (syrlinks::READ_LCL_CONFIG): { prepareCommand(readLclConfig, deviceCommand); return RETURN_OK; } case (syrlinks::READ_TX_STATUS): { prepareCommand(readTxStatus, deviceCommand); return RETURN_OK; } case (syrlinks::READ_TX_WAVEFORM): { prepareCommand(readTxWaveform, deviceCommand); return RETURN_OK; } case (syrlinks::READ_TX_AGC_VALUE_HIGH_BYTE): { prepareCommand(readTxAgcValueHighByte, deviceCommand); return RETURN_OK; } case (syrlinks::READ_TX_AGC_VALUE_LOW_BYTE): { prepareCommand(readTxAgcValueLowByte, deviceCommand); return RETURN_OK; } case (syrlinks::TEMP_POWER_AMPLIFIER_HIGH_BYTE): { prepareCommand(tempPowerAmpBoardHighByte, deviceCommand); return RETURN_OK; } case (syrlinks::TEMP_POWER_AMPLIFIER_LOW_BYTE): { prepareCommand(tempPowerAmpBoardLowByte, deviceCommand); return RETURN_OK; } case (syrlinks::TEMP_BASEBAND_BOARD_HIGH_BYTE): { prepareCommand(tempBasebandBoardHighByte, deviceCommand); return RETURN_OK; } case (syrlinks::TEMP_BASEBAND_BOARD_LOW_BYTE): { prepareCommand(tempBasebandBoardLowByte, deviceCommand); return RETURN_OK; } case (syrlinks::CONFIG_BPSK): { prepareCommand(configBPSK, deviceCommand); return RETURN_OK; } case (syrlinks::CONFIG_OQPSK): { prepareCommand(configOQPSK, deviceCommand); return RETURN_OK; } case (syrlinks::ENABLE_DEBUG): { debug = true; return RETURN_OK; } case (syrlinks::DISABLE_DEBUG): { debug = false; return RETURN_OK; } default: return DeviceHandlerIF::COMMAND_NOT_IMPLEMENTED; } return HasReturnvaluesIF::RETURN_FAILED; } void SyrlinksHkHandler::fillCommandAndReplyMap() { this->insertInCommandAndReplyMap(syrlinks::RESET_UNIT, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandAndReplyMap(syrlinks::SET_TX_MODE_STANDBY, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandAndReplyMap(syrlinks::SET_TX_MODE_MODULATION, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandAndReplyMap(syrlinks::SET_TX_MODE_CW, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandAndReplyMap(syrlinks::WRITE_LCL_CONFIG, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandAndReplyMap(syrlinks::CONFIG_BPSK, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandAndReplyMap(syrlinks::CONFIG_OQPSK, 1, nullptr, syrlinks::ACK_SIZE, false, true, syrlinks::ACK_REPLY); this->insertInCommandMap(syrlinks::ENABLE_DEBUG); this->insertInCommandMap(syrlinks::DISABLE_DEBUG); this->insertInCommandAndReplyMap(syrlinks::READ_LCL_CONFIG, 1, nullptr, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::READ_TX_STATUS, 1, &txDataset, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::READ_TX_WAVEFORM, 1, &txDataset, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::READ_TX_AGC_VALUE_HIGH_BYTE, 1, &txDataset, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::READ_TX_AGC_VALUE_LOW_BYTE, 1, &txDataset, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::TEMP_POWER_AMPLIFIER_HIGH_BYTE, 1, nullptr, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::TEMP_POWER_AMPLIFIER_LOW_BYTE, 1, nullptr, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::TEMP_BASEBAND_BOARD_HIGH_BYTE, 1, nullptr, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::TEMP_BASEBAND_BOARD_LOW_BYTE, 1, nullptr, syrlinks::READ_ONE_REGISTER_REPLY_SIE); this->insertInCommandAndReplyMap(syrlinks::READ_RX_STATUS_REGISTERS, 1, &rxDataset, syrlinks::RX_STATUS_REGISTERS_REPLY_SIZE); } ReturnValue_t SyrlinksHkHandler::scanForReply(const uint8_t* start, size_t remainingSize, DeviceCommandId_t* foundId, size_t* foundLen) { ReturnValue_t result = RETURN_OK; if (*start != '<') { sif::warning << "SyrlinksHkHandler::scanForReply: Missing start frame character" << std::endl; return MISSING_START_FRAME_CHARACTER; } switch (*(start + 1)) { case ('A'): *foundLen = syrlinks::ACK_SIZE; *foundId = syrlinks::ACK_REPLY; break; case ('E'): *foundLen = syrlinks::RX_STATUS_REGISTERS_REPLY_SIZE; *foundId = syrlinks::READ_RX_STATUS_REGISTERS; break; case ('R'): *foundId = rememberCommandId; *foundLen = syrlinks::READ_ONE_REGISTER_REPLY_SIE; break; default: sif::warning << "SyrlinksHkHandler::scanForReply: Unknown reply identifier" << std::endl; result = IGNORE_REPLY_DATA; break; } return result; } ReturnValue_t SyrlinksHkHandler::getSwitches(const uint8_t** switches, uint8_t* numberOfSwitches) { if (powerSwitch == power::NO_SWITCH) { return DeviceHandlerBase::NO_SWITCH; } *numberOfSwitches = 1; *switches = &powerSwitch; return RETURN_OK; } ReturnValue_t SyrlinksHkHandler::interpretDeviceReply(DeviceCommandId_t id, const uint8_t* packet) { ReturnValue_t result; switch (id) { case (syrlinks::ACK_REPLY): { result = verifyReply(packet, syrlinks::ACK_SIZE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Acknowledgment reply has " "invalid crc" << std::endl; return CRC_FAILURE; } result = handleAckReply(packet); if (result != RETURN_OK) { return result; } break; } case (syrlinks::READ_RX_STATUS_REGISTERS): { result = verifyReply(packet, syrlinks::RX_STATUS_REGISTERS_REPLY_SIZE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read rx status registers reply " << "has invalid crc" << std::endl; return CRC_FAILURE; } parseRxStatusRegistersReply(packet); break; } case (syrlinks::READ_LCL_CONFIG): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read config lcl reply " << "has invalid crc" << std::endl; return CRC_FAILURE; } parseLclConfigReply(packet); break; } case (syrlinks::READ_TX_STATUS): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read tx status reply " << "has invalid crc" << std::endl; return CRC_FAILURE; } parseTxStatusReply(packet); break; } case (syrlinks::READ_TX_WAVEFORM): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read tx waveform reply " << "has invalid crc" << std::endl; return CRC_FAILURE; } parseTxWaveformReply(packet); break; } case (syrlinks::READ_TX_AGC_VALUE_HIGH_BYTE): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read tx AGC high byte reply " << "has invalid crc" << std::endl; return CRC_FAILURE; } parseAgcHighByte(packet); break; } case (syrlinks::READ_TX_AGC_VALUE_LOW_BYTE): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read tx AGC low byte reply " << "has invalid crc" << std::endl; return CRC_FAILURE; } parseAgcLowByte(packet); break; } case (syrlinks::TEMP_BASEBAND_BOARD_HIGH_BYTE): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read temperature baseband board " << "high byte reply has invalid crc" << std::endl; return CRC_FAILURE; } rawTempBasebandBoard = convertHexStringToUint8(reinterpret_cast( packet + syrlinks::MESSAGE_HEADER_SIZE)) << 8; break; } case (syrlinks::TEMP_BASEBAND_BOARD_LOW_BYTE): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read temperature baseband board" " low byte reply has invalid crc" << std::endl; return CRC_FAILURE; } rawTempBasebandBoard |= convertHexStringToUint8( reinterpret_cast(packet + syrlinks::MESSAGE_HEADER_SIZE)); tempBasebandBoard = calcTempVal(rawTempBasebandBoard); temperatureSet.temperatureBasebandBoard = tempBasebandBoard; PoolReadGuard rg(&temperatureSet); if (debug) { sif::info << "Syrlinks temperature baseband board: " << tempBasebandBoard << " °C" << std::endl; } break; } case (syrlinks::TEMP_POWER_AMPLIFIER_HIGH_BYTE): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read temperature power amplifier " << "board high byte reply has invalid crc" << std::endl; return CRC_FAILURE; } rawTempPowerAmplifier = 0; rawTempPowerAmplifier = convertHexStringToUint8(reinterpret_cast( packet + syrlinks::MESSAGE_HEADER_SIZE)) << 8; break; } case (syrlinks::TEMP_POWER_AMPLIFIER_LOW_BYTE): { result = verifyReply(packet, syrlinks::READ_ONE_REGISTER_REPLY_SIE); if (result != RETURN_OK) { sif::warning << "SyrlinksHkHandler::interpretDeviceReply: Read temperature power amplifier" << " board low byte reply has invalid crc" << std::endl; return CRC_FAILURE; } rawTempPowerAmplifier |= convertHexStringToUint8( reinterpret_cast(packet + syrlinks::MESSAGE_HEADER_SIZE)); tempPowerAmplifier = calcTempVal(rawTempPowerAmplifier); PoolReadGuard rg(&temperatureSet); temperatureSet.temperaturePowerAmplifier = tempPowerAmplifier; if (debug) { sif::info << "Syrlinks temperature power amplifier board: " << tempPowerAmplifier << " °C" << std::endl; } break; } default: { sif::debug << "SyrlinksHkHandler::interpretDeviceReply: Unknown device reply id" << std::endl; return DeviceHandlerIF::UNKNOWN_DEVICE_REPLY; } } return RETURN_OK; } LocalPoolDataSetBase* SyrlinksHkHandler::getDataSetHandle(sid_t sid) { if (sid == rxDataset.getSid()) { return &rxDataset; } else if (sid == txDataset.getSid()) { return &txDataset; } else if (sid == temperatureSet.getSid()) { return &temperatureSet; } else { sif::warning << "SyrlinksHkHandler::getDataSetHandle: Invalid sid" << std::endl; return nullptr; } } std::string SyrlinksHkHandler::convertUint16ToHexString(uint16_t intValue) { std::stringstream stream; stream << std::setfill('0') << std::setw(4) << std::hex << std::uppercase << intValue; return stream.str(); } uint8_t SyrlinksHkHandler::convertHexStringToUint8(const char* twoChars) { uint32_t value; std::string hexString(twoChars, 2); std::stringstream stream; stream << std::hex << hexString; stream >> value; return static_cast(value); } uint16_t SyrlinksHkHandler::convertHexStringToUint16(const char* fourChars) { uint16_t value = 0; value = convertHexStringToUint8(fourChars) << 8 | convertHexStringToUint8(fourChars + 2); return value; } uint32_t SyrlinksHkHandler::convertHexStringToUint32(const char* characters, uint8_t numberOfChars) { uint32_t value = 0; switch (numberOfChars) { case 6: value = convertHexStringToUint8(characters) << 16 | convertHexStringToUint8(characters + 2) << 8 | convertHexStringToUint8(characters + 4); return value; case 8: value = convertHexStringToUint8(characters) << 24 | convertHexStringToUint8(characters + 2) << 16 | convertHexStringToUint8(characters + 4) << 8 | convertHexStringToUint8(characters + 4); return value; default: sif::debug << "SyrlinksHkHandler::convertHexStringToUint32: Invalid number of characters. " << "Must be either 6 or 8" << std::endl; return 0; } } ReturnValue_t SyrlinksHkHandler::parseReplyStatus(const char* status) { switch (*status) { case '0': return RETURN_OK; case '1': sif::debug << "SyrlinksHkHandler::parseReplyStatus: Uart faming or parity error" << std::endl; return UART_FRAMIN_OR_PARITY_ERROR_ACK; case '2': sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad character detected" << std::endl; return BAD_CHARACTER_ACK; case '3': sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad parameter value (unexpected value " << "detected" << std::endl; return BAD_PARAMETER_VALUE_ACK; case '4': sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad end of frame" << std::endl; return BAD_END_OF_FRAME_ACK; case '5': sif::debug << "SyrlinksHkHandler::parseReplyStatus: Unknown command id or attempt to access" << " a protected register" << std::endl; return UNKNOWN_COMMAND_ID_ACK; case '6': sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad CRC" << std::endl; return BAD_CRC_ACK; default: sif::debug << "SyrlinksHkHandler::parseReplyStatus: Status reply contains an invalid " << "status id" << std::endl; return RETURN_FAILED; } } ReturnValue_t SyrlinksHkHandler::verifyReply(const uint8_t* packet, uint8_t size) { int result = 0; /* Calculate crc from received packet */ uint16_t crc = CRC::crc16ccitt(packet, size - syrlinks::SIZE_CRC_AND_TERMINATION, CRC_INITIAL_VALUE); std::string recalculatedCrc = convertUint16ToHexString(crc); const char* startOfCrc = reinterpret_cast(packet + size - syrlinks::SIZE_CRC_AND_TERMINATION); const char* endOfCrc = reinterpret_cast(packet + size - 1); std::string replyCrc(startOfCrc, endOfCrc); result = recalculatedCrc.compare(replyCrc); if (result != 0) { return RETURN_FAILED; } return RETURN_OK; } void SyrlinksHkHandler::parseRxStatusRegistersReply(const uint8_t* packet) { PoolReadGuard readHelper(&rxDataset); uint16_t offset = syrlinks::MESSAGE_HEADER_SIZE; rxDataset.rxStatus = convertHexStringToUint8(reinterpret_cast(packet + offset)); offset += 2; rxDataset.rxSensitivity = convertHexStringToUint32(reinterpret_cast(packet + offset), 6); offset += 6; rxDataset.rxFrequencyShift = convertHexStringToUint32(reinterpret_cast(packet + offset), 6); offset += 6; rxDataset.rxIqPower = convertHexStringToUint16(reinterpret_cast(packet + offset)); offset += 4; rxDataset.rxAgcValue = convertHexStringToUint16(reinterpret_cast(packet + offset)); offset += 4; offset += 2; // reserved register rxDataset.rxDemodEb = convertHexStringToUint32(reinterpret_cast(packet + offset), 6); offset += 6; rxDataset.rxDemodN0 = convertHexStringToUint32(reinterpret_cast(packet + offset), 6); offset += 6; rxDataset.rxDataRate = convertHexStringToUint8(reinterpret_cast(packet + offset)); #if OBSW_VERBOSE_LEVEL >= 1 && OBSW_DEBUG_SYRLINKS == 1 if (debug) { sif::info << "Syrlinks RX Status: 0x" << std::hex << (unsigned int)rxDataset.rxStatus.value << std::endl; sif::info << "Syrlinks RX Sensitivity: " << std::dec << rxDataset.rxSensitivity << std::endl; sif::info << "Syrlinks RX Frequency Shift: " << rxDataset.rxFrequencyShift << std::endl; sif::info << "Syrlinks RX IQ Power: " << rxDataset.rxIqPower << std::endl; sif::info << "Syrlinks RX AGC Value: " << rxDataset.rxAgcValue << std::endl; sif::info << "Syrlinks RX Demod Eb: " << rxDataset.rxDemodEb << std::endl; sif::info << "Syrlinks RX Demod N0: " << rxDataset.rxDemodN0 << std::endl; sif::info << "Syrlinks RX Datarate: " << (unsigned int)rxDataset.rxDataRate.value << std::endl; } #endif } void SyrlinksHkHandler::parseLclConfigReply(const uint8_t* packet) { uint16_t offset = syrlinks::MESSAGE_HEADER_SIZE; uint8_t lclConfig = convertHexStringToUint8(reinterpret_cast(packet + offset)); sif::info << "SyrlinksHkHandler::parseRxStatusRegistersReply: Lcl config: " << static_cast(lclConfig) << std::endl; } void SyrlinksHkHandler::parseTxStatusReply(const uint8_t* packet) { PoolReadGuard readHelper(&txDataset); uint16_t offset = syrlinks::MESSAGE_HEADER_SIZE; txDataset.txStatus = convertHexStringToUint8(reinterpret_cast(packet + offset)); #if OBSW_DEBUG_SYRLINKS == 1 sif::info << "Syrlinks TX Status: 0x" << std::hex << (unsigned int)txDataset.txStatus.value << std::endl; #endif } void SyrlinksHkHandler::parseTxWaveformReply(const uint8_t* packet) { PoolReadGuard readHelper(&txDataset); uint16_t offset = syrlinks::MESSAGE_HEADER_SIZE; txDataset.txWaveform = convertHexStringToUint8(reinterpret_cast(packet + offset)); #if OBSW_DEBUG_SYRLINKS == 1 sif::info << "Syrlinks TX Waveform: 0x" << std::hex << (unsigned int)txDataset.txWaveform.value << std::endl; #endif } void SyrlinksHkHandler::parseAgcLowByte(const uint8_t* packet) { PoolReadGuard readHelper(&txDataset); uint16_t offset = syrlinks::MESSAGE_HEADER_SIZE; txDataset.txAgcValue = agcValueHighByte << 8 | convertHexStringToUint8(reinterpret_cast(packet + offset)); #if OBSW_DEBUG_SYRLINKS == 1 sif::info << "Syrlinks TX AGC Value: " << txDataset.txAgcValue << std::endl; #endif } void SyrlinksHkHandler::parseAgcHighByte(const uint8_t* packet) { PoolReadGuard readHelper(&txDataset); uint16_t offset = syrlinks::MESSAGE_HEADER_SIZE; agcValueHighByte = convertHexStringToUint8(reinterpret_cast(packet + offset)); } void SyrlinksHkHandler::setNormalDatapoolEntriesInvalid() {} uint32_t SyrlinksHkHandler::getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo) { return 5000; } ReturnValue_t SyrlinksHkHandler::initializeLocalDataPool(localpool::DataPool& localDataPoolMap, LocalDataPoolManager& poolManager) { localDataPoolMap.emplace(syrlinks::RX_STATUS, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_SENSITIVITY, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_FREQUENCY_SHIFT, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_IQ_POWER, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_AGC_VALUE, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_DEMOD_EB, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_DEMOD_N0, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::RX_DATA_RATE, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::TX_STATUS, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::TX_WAVEFORM, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::TX_AGC_VALUE, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::TEMP_BASEBAND_BOARD, new PoolEntry({0})); localDataPoolMap.emplace(syrlinks::TEMP_POWER_AMPLIFIER, new PoolEntry({0})); return HasReturnvaluesIF::RETURN_OK; } void SyrlinksHkHandler::setModeNormal() { mode = MODE_NORMAL; } float SyrlinksHkHandler::calcTempVal(uint16_t raw) { return 0.126984 * raw - 67.87; } ReturnValue_t SyrlinksHkHandler::handleAckReply(const uint8_t* packet) { ReturnValue_t result = parseReplyStatus(reinterpret_cast(packet + syrlinks::MESSAGE_HEADER_SIZE)); if (rememberCommandId == syrlinks::WRITE_LCL_CONFIG and result != RETURN_OK) { startupState = StartupState::OFF; } else if (rememberCommandId == syrlinks::WRITE_LCL_CONFIG and result == RETURN_OK) { startupState = StartupState::DONE; } return result; } void SyrlinksHkHandler::prepareCommand(std::string command, DeviceCommandId_t commandId) { command.copy(reinterpret_cast(commandBuffer), readTxWaveform.size(), 0); rawPacketLen = command.size(); rememberCommandId = commandId; rawPacket = commandBuffer; }