#include "AcsBoardPolling.h" #include #include #include #include #include #include #include #include #include #include #include #include #include "devices/gpioIds.h" using namespace returnvalue; AcsBoardPolling::AcsBoardPolling(object_id_t objectId, SpiComIF& lowLevelComIF, GpioIF& gpioIF) : SystemObject(objectId), spiComIF(lowLevelComIF), gpioIF(gpioIF) { semaphore = SemaphoreFactory::instance()->createBinarySemaphore(); semaphore->acquire(); ipcLock = MutexFactory::instance()->createMutex(); } ReturnValue_t AcsBoardPolling::performOperation(uint8_t operationCode) { while (true) { ipcLock->lockMutex(LOCK_TYPE, LOCK_TIMEOUT); state = InternalState::IDLE; ipcLock->unlockMutex(); semaphore->acquire(); // Give all tasks or the PST some time to submit all consecutive requests. TaskFactory::delayTask(2); { // Measured to take 0-1 ms in debug build. // Stopwatch watch; gyroAdisHandler(gyro0Adis); gyroAdisHandler(gyro2Adis); gyroL3gHandler(gyro1L3g); gyroL3gHandler(gyro3L3g); mgmRm3100Handler(mgm1Rm3100); mgmRm3100Handler(mgm3Rm3100); mgmLis3Handler(mgm0Lis3); mgmLis3Handler(mgm2Lis3); } // To prevent task being not reactivated by tardy tasks TaskFactory::delayTask(20); } return returnvalue::OK; } ReturnValue_t AcsBoardPolling::initialize() { return returnvalue::OK; } ReturnValue_t AcsBoardPolling::initializeInterface(CookieIF* cookie) { SpiCookie* spiCookie = dynamic_cast(cookie); if (spiCookie == nullptr) { return returnvalue::FAILED; } switch (spiCookie->getChipSelectPin()) { case (gpioIds::MGM_0_LIS3_CS): { mgm0Lis3.cookie = spiCookie; break; } case (gpioIds::MGM_1_RM3100_CS): { mgm1Rm3100.cookie = spiCookie; break; } case (gpioIds::MGM_2_LIS3_CS): { mgm2Lis3.cookie = spiCookie; break; } case (gpioIds::MGM_3_RM3100_CS): { mgm3Rm3100.cookie = spiCookie; break; } case (gpioIds::GYRO_0_ADIS_CS): { gyro0Adis.cookie = spiCookie; break; } case (gpioIds::GYRO_1_L3G_CS): { gyro1L3g.cookie = spiCookie; break; } case (gpioIds::GYRO_2_ADIS_CS): { gyro2Adis.cookie = spiCookie; break; } case (gpioIds::GYRO_3_L3G_CS): { gyro3L3g.cookie = spiCookie; break; } default: { sif::error << "AcsBoardPollingTask: invalid spi cookie" << std::endl; } } return spiComIF.initializeInterface(cookie); } ReturnValue_t AcsBoardPolling::sendMessage(CookieIF* cookie, const uint8_t* sendData, size_t sendLen) { SpiCookie* spiCookie = dynamic_cast(cookie); if (spiCookie == nullptr) { return returnvalue::FAILED; } auto handleAdisRequest = [&](GyroAdis& adis) { if (sendLen != sizeof(acs::Adis1650XRequest)) { sif::error << "AcsBoardPolling: invalid adis request send length"; adis.replyResult = returnvalue::FAILED; return returnvalue::FAILED; } auto* req = reinterpret_cast(sendData); if (req->mode != adis.mode) { if (req->mode == acs::SimpleSensorMode::NORMAL) { adis.type = req->type; // The initial countdown is handled by the device handler now. // adis.countdown.setTimeout(adis1650x::START_UP_TIME); if (adis.type == adis1650x::Type::ADIS16507) { adis.ownReply.data.accelScaling = adis1650x::ACCELEROMETER_RANGE_16507; } else if (adis.type == adis1650x::Type::ADIS16505) { adis.ownReply.data.accelScaling = adis1650x::ACCELEROMETER_RANGE_16505; } else { sif::warning << "AcsBoardPolling: Unknown ADIS type" << std::endl; } adis.performStartup = true; } else if (req->mode == acs::SimpleSensorMode::OFF) { adis.performStartup = false; adis.ownReply.cfgWasSet = false; adis.ownReply.dataWasSet = false; } adis.replyResult = returnvalue::FAILED; adis.mode = req->mode; } return returnvalue::OK; }; auto handleL3gRequest = [&](GyroL3g& gyro) { if (sendLen != sizeof(acs::GyroL3gRequest)) { sif::error << "AcsBoardPolling: invalid l3g request send length"; gyro.replyResult = returnvalue::FAILED; return returnvalue::FAILED; } auto* req = reinterpret_cast(sendData); if (req->mode != gyro.mode) { if (req->mode == acs::SimpleSensorMode::NORMAL) { std::memcpy(gyro.sensorCfg, req->ctrlRegs, 5); gyro.performStartup = true; } else { gyro.ownReply.cfgWasSet = false; } gyro.replyResult = returnvalue::FAILED; gyro.mode = req->mode; } return returnvalue::OK; }; auto handleLis3Request = [&](MgmLis3& mgm) { if (sendLen != sizeof(acs::MgmLis3Request)) { sif::error << "AcsBoardPolling: invalid lis3 request send length"; mgm.replyResult = returnvalue::FAILED; return returnvalue::FAILED; } auto* req = reinterpret_cast(sendData); if (req->mode != mgm.mode) { if (req->mode == acs::SimpleSensorMode::NORMAL) { mgm.performStartup = true; } else { mgm.ownReply.dataWasSet = false; mgm.ownReply.temperatureWasSet = false; } mgm.replyResult = returnvalue::FAILED; mgm.mode = req->mode; } return returnvalue::OK; }; auto handleRm3100Request = [&](MgmRm3100& mgm) { if (sendLen != sizeof(acs::MgmRm3100Request)) { sif::error << "AcsBoardPolling: invalid rm3100 request send length"; mgm.replyResult = returnvalue::FAILED; return returnvalue::FAILED; } auto* req = reinterpret_cast(sendData); if (req->mode != mgm.mode) { if (req->mode == acs::SimpleSensorMode::NORMAL) { mgm.performStartup = true; } else { mgm.ownReply.dataWasRead = false; } mgm.replyResult = returnvalue::FAILED; mgm.mode = req->mode; } return returnvalue::OK; }; { MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); switch (spiCookie->getChipSelectPin()) { case (gpioIds::MGM_0_LIS3_CS): { handleLis3Request(mgm0Lis3); break; } case (gpioIds::MGM_1_RM3100_CS): { handleRm3100Request(mgm1Rm3100); break; } case (gpioIds::MGM_2_LIS3_CS): { handleLis3Request(mgm2Lis3); break; } case (gpioIds::MGM_3_RM3100_CS): { handleRm3100Request(mgm3Rm3100); break; } case (gpioIds::GYRO_0_ADIS_CS): { handleAdisRequest(gyro0Adis); break; } case (gpioIds::GYRO_2_ADIS_CS): { handleAdisRequest(gyro2Adis); break; } case (gpioIds::GYRO_1_L3G_CS): { handleL3gRequest(gyro1L3g); break; } case (gpioIds::GYRO_3_L3G_CS): { handleL3gRequest(gyro3L3g); break; } } if (state == InternalState::IDLE) { state = InternalState::IS_BUSY; } } semaphore->release(); return returnvalue::OK; } ReturnValue_t AcsBoardPolling::getSendSuccess(CookieIF* cookie) { return returnvalue::OK; } ReturnValue_t AcsBoardPolling::requestReceiveMessage(CookieIF* cookie, size_t requestLen) { return returnvalue::OK; } ReturnValue_t AcsBoardPolling::readReceivedMessage(CookieIF* cookie, uint8_t** buffer, size_t* size) { SpiCookie* spiCookie = dynamic_cast(cookie); if (spiCookie == nullptr) { return returnvalue::FAILED; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); auto handleAdisReply = [&](GyroAdis& gyro) { std::memcpy(&gyro.readerReply, &gyro.ownReply, sizeof(acs::Adis1650XReply)); *buffer = reinterpret_cast(&gyro.readerReply); *size = sizeof(acs::Adis1650XReply); return gyro.replyResult; }; auto handleL3gReply = [&](GyroL3g& gyro) { std::memcpy(&gyro.readerReply, &gyro.ownReply, sizeof(acs::GyroL3gReply)); *buffer = reinterpret_cast(&gyro.readerReply); *size = sizeof(acs::GyroL3gReply); return gyro.replyResult; }; auto handleRm3100Reply = [&](MgmRm3100& mgm) { std::memcpy(&mgm.readerReply, &mgm.ownReply, sizeof(acs::MgmRm3100Reply)); *buffer = reinterpret_cast(&mgm.readerReply); *size = sizeof(acs::MgmRm3100Reply); return mgm.replyResult; }; auto handleLis3Reply = [&](MgmLis3& mgm) { std::memcpy(&mgm.readerReply, &mgm.ownReply, sizeof(acs::MgmLis3Reply)); *buffer = reinterpret_cast(&mgm.readerReply); *size = sizeof(acs::MgmLis3Reply); return mgm.replyResult; }; switch (spiCookie->getChipSelectPin()) { case (gpioIds::MGM_0_LIS3_CS): { return handleLis3Reply(mgm0Lis3); } case (gpioIds::MGM_1_RM3100_CS): { return handleRm3100Reply(mgm1Rm3100); } case (gpioIds::MGM_2_LIS3_CS): { return handleLis3Reply(mgm2Lis3); } case (gpioIds::MGM_3_RM3100_CS): { return handleRm3100Reply(mgm3Rm3100); } case (gpioIds::GYRO_0_ADIS_CS): { return handleAdisReply(gyro0Adis); } case (gpioIds::GYRO_2_ADIS_CS): { return handleAdisReply(gyro2Adis); } case (gpioIds::GYRO_1_L3G_CS): { return handleL3gReply(gyro1L3g); } case (gpioIds::GYRO_3_L3G_CS): { return handleL3gReply(gyro3L3g); } } return returnvalue::OK; } void AcsBoardPolling::gyroL3gHandler(GyroL3g& l3g) { ReturnValue_t result; acs::SimpleSensorMode mode = acs::SimpleSensorMode::OFF; bool gyroPerformStartup = false; { MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); mode = l3g.mode; gyroPerformStartup = l3g.performStartup; } if (mode == acs::SimpleSensorMode::NORMAL) { if (gyroPerformStartup) { cmdBuf[0] = l3gd20h::CTRL_REG_1 | l3gd20h::AUTO_INCREMENT_MASK; std::memcpy(cmdBuf.data() + 1, l3g.sensorCfg, 5); result = spiComIF.sendMessage(l3g.cookie, cmdBuf.data(), 6); if (result != returnvalue::OK) { l3g.replyResult = result; } // Ignore useless reply and red config cmdBuf[0] = l3gd20h::CTRL_REG_1 | l3gd20h::AUTO_INCREMENT_MASK | l3gd20h::READ_MASK; std::memset(cmdBuf.data() + 1, 0, 5); result = spiComIF.sendMessage(l3g.cookie, cmdBuf.data(), 6); if (result != returnvalue::OK) { l3g.replyResult = result; } result = spiComIF.readReceivedMessage(l3g.cookie, &rawReply, &dummy); if (result != returnvalue::OK) { l3g.replyResult = result; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); // Cross check configuration as verification that communication is working for (uint8_t idx = 0; idx < 5; idx++) { if (rawReply[idx + 1] != l3g.sensorCfg[idx]) { sif::warning << "AcsBoardPolling: l3g config check missmatch" << std::endl; l3g.replyResult = returnvalue::FAILED; return; } } l3g.replyResult = returnvalue::OK; l3g.performStartup = false; l3g.ownReply.cfgWasSet = true; l3g.ownReply.sensitivity = l3gd20h::ctrlReg4ToSensitivity(l3g.sensorCfg[3]); } cmdBuf[0] = l3gd20h::READ_START | l3gd20h::AUTO_INCREMENT_MASK | l3gd20h::READ_MASK; std::memset(cmdBuf.data() + 1, 0, l3gd20h::READ_LEN); result = spiComIF.sendMessage(l3g.cookie, cmdBuf.data(), l3gd20h::READ_LEN + 1); if (result != returnvalue::OK) { l3g.replyResult = returnvalue::FAILED; return; } result = spiComIF.readReceivedMessage(l3g.cookie, &rawReply, &dummy); if (result != returnvalue::OK) { l3g.replyResult = returnvalue::FAILED; return; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); // The regular read function always returns the full sensor config as well. Use that // to verify communications. for (uint8_t idx = 0; idx < 5; idx++) { if (rawReply[idx + 1] != l3g.sensorCfg[idx]) { sif::warning << "AcsBoardPolling: l3g config check missmatch" << std::endl; l3g.replyResult = returnvalue::FAILED; return; } } l3g.replyResult = returnvalue::OK; l3g.ownReply.statusReg = rawReply[l3gd20h::STATUS_IDX]; l3g.ownReply.angVelocities[0] = (rawReply[l3gd20h::OUT_X_H] << 8) | rawReply[l3gd20h::OUT_X_L]; l3g.ownReply.angVelocities[1] = (rawReply[l3gd20h::OUT_Y_H] << 8) | rawReply[l3gd20h::OUT_Y_L]; l3g.ownReply.angVelocities[2] = (rawReply[l3gd20h::OUT_Z_H] << 8) | rawReply[l3gd20h::OUT_Z_L]; l3g.ownReply.tempOffsetRaw = rawReply[l3gd20h::TEMPERATURE_IDX]; } } ReturnValue_t AcsBoardPolling::readAdisCfg(SpiCookie& cookie, size_t transferLen) { ReturnValue_t result = returnvalue::OK; int retval = 0; // Prepare transfer int fileDescriptor = 0; std::string device = spiComIF.getSpiDev(); UnixFileGuard fileHelper(device, fileDescriptor, O_RDWR, "SpiComIF::sendMessage"); if (fileHelper.getOpenResult() != returnvalue::OK) { return spi::OPENING_FILE_FAILED; } spi::SpiModes spiMode = spi::SpiModes::MODE_0; uint32_t spiSpeed = 0; cookie.getSpiParameters(spiMode, spiSpeed, nullptr); spiComIF.setSpiSpeedAndMode(fileDescriptor, spiMode, spiSpeed); cookie.assignWriteBuffer(cmdBuf.data()); cookie.setTransferSize(2); gpioId_t gpioId = cookie.getChipSelectPin(); MutexIF::TimeoutType timeoutType = MutexIF::TimeoutType::WAITING; uint32_t timeoutMs = 0; MutexIF* mutex = spiComIF.getCsMutex(); cookie.getMutexParams(timeoutType, timeoutMs); if (mutex == nullptr) { sif::warning << "GyroADIS16507Handler::spiSendCallback: " "Mutex or GPIO interface invalid" << std::endl; return returnvalue::FAILED; } size_t idx = 0; spi_ioc_transfer* transferStruct = cookie.getTransferStructHandle(); uint64_t origTx = transferStruct->tx_buf; uint64_t origRx = transferStruct->rx_buf; while (idx < transferLen) { result = mutex->lockMutex(timeoutType, timeoutMs); if (result != returnvalue::OK) { #if FSFW_CPP_OSTREAM_ENABLED == 1 sif::error << "AcsBoardPolling: Failed to lock mutex" << std::endl; #endif return result; } // Pull SPI CS low. For now, no support for active high given if (gpioId != gpio::NO_GPIO) { gpioIF.pullLow(gpioId); } // Execute transfer // Initiate a full duplex SPI transfer. retval = ioctl(fileDescriptor, SPI_IOC_MESSAGE(1), cookie.getTransferStructHandle()); if (retval < 0) { utility::handleIoctlError("SpiComIF::sendMessage: ioctl error."); result = spi::FULL_DUPLEX_TRANSFER_FAILED; } #if FSFW_HAL_SPI_WIRETAPPING == 1 comIf->performSpiWiretapping(cookie); #endif /* FSFW_LINUX_SPI_WIRETAPPING == 1 */ if (gpioId != gpio::NO_GPIO) { gpioIF.pullHigh(gpioId); } mutex->unlockMutex(); idx += 2; transferStruct->tx_buf += 2; transferStruct->rx_buf += 2; if (idx < transferLen) { usleep(adis1650x::STALL_TIME_MICROSECONDS); } } transferStruct->tx_buf = origTx; transferStruct->rx_buf = origRx; cookie.setTransferSize(transferLen); return returnvalue::OK; } void AcsBoardPolling::gyroAdisHandler(GyroAdis& gyro) { ReturnValue_t result; acs::SimpleSensorMode mode = acs::SimpleSensorMode::OFF; bool mustPerformStartup = false; { MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); mode = gyro.mode; mustPerformStartup = gyro.performStartup; } if (mode == acs::SimpleSensorMode::OFF) { return; } if (mustPerformStartup) { uint8_t regList[6]; // Read configuration regList[0] = adis1650x::DIAG_STAT_REG; regList[1] = adis1650x::FILTER_CTRL_REG; regList[2] = adis1650x::RANG_MDL_REG; regList[3] = adis1650x::MSC_CTRL_REG; regList[4] = adis1650x::DEC_RATE_REG; regList[5] = adis1650x::PROD_ID_REG; size_t transferLen = adis1650x::prepareReadCommand(regList, sizeof(regList), cmdBuf.data(), cmdBuf.size()); result = readAdisCfg(*gyro.cookie, transferLen); if (result != returnvalue::OK) { gyro.replyResult = result; return; } result = spiComIF.readReceivedMessage(gyro.cookie, &rawReply, &dummy); if (result != returnvalue::OK or rawReply == nullptr) { gyro.replyResult = result; return; } uint16_t prodId = (rawReply[12] << 8) | rawReply[13]; if (((gyro.type == adis1650x::Type::ADIS16505) and (prodId != adis1650x::PROD_ID_16505)) or ((gyro.type == adis1650x::Type::ADIS16507) and (prodId != adis1650x::PROD_ID_16507))) { sif::warning << "AcsPollingTask: Invalid ADIS product ID " << prodId << std::endl; gyro.replyResult = returnvalue::FAILED; return; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); gyro.ownReply.cfgWasSet = true; gyro.ownReply.cfg.diagStat = (rawReply[2] << 8) | rawReply[3]; gyro.ownReply.cfg.filterSetting = (rawReply[4] << 8) | rawReply[5]; gyro.ownReply.cfg.rangMdl = (rawReply[6] << 8) | rawReply[7]; gyro.ownReply.cfg.mscCtrlReg = (rawReply[8] << 8) | rawReply[9]; gyro.ownReply.cfg.decRateReg = (rawReply[10] << 8) | rawReply[11]; gyro.ownReply.cfg.prodId = prodId; gyro.ownReply.data.sensitivity = adis1650x::rangMdlToSensitivity(gyro.ownReply.cfg.rangMdl); gyro.performStartup = false; gyro.replyResult = returnvalue::OK; } // Read regular registers std::memcpy(cmdBuf.data(), adis1650x::BURST_READ_ENABLE.data(), adis1650x::BURST_READ_ENABLE.size()); std::memset(cmdBuf.data() + 2, 0, 10 * 2); result = spiComIF.sendMessage(gyro.cookie, cmdBuf.data(), adis1650x::SENSOR_READOUT_SIZE); if (result != returnvalue::OK) { gyro.replyResult = returnvalue::FAILED; return; } result = spiComIF.readReceivedMessage(gyro.cookie, &rawReply, &dummy); if (result != returnvalue::OK or rawReply == nullptr) { gyro.replyResult = returnvalue::FAILED; return; } uint16_t checksum = (rawReply[20] << 8) | rawReply[21]; // Now verify the read checksum with the expected checksum according to datasheet p. 20 uint16_t calcChecksum = 0; for (size_t idx = 2; idx < 20; idx++) { calcChecksum += rawReply[idx]; } if (checksum != calcChecksum) { sif::warning << "AcsPollingTask: Invalid ADIS reply checksum" << std::endl; gyro.replyResult = returnvalue::FAILED; return; } auto burstMode = adis1650x::burstModeFromMscCtrl(gyro.ownReply.cfg.mscCtrlReg); if (burstMode != adis1650x::BurstModes::BURST_16_BURST_SEL_0) { sif::error << "GyroADIS1650XHandler::interpretDeviceReply: Analysis for select burst mode" " not implemented!" << std::endl; gyro.replyResult = returnvalue::FAILED; return; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); gyro.replyResult = returnvalue::OK; gyro.ownReply.dataWasSet = true; gyro.ownReply.cfg.diagStat = rawReply[2] << 8 | rawReply[3]; gyro.ownReply.data.angVelocities[0] = (rawReply[4] << 8) | rawReply[5]; gyro.ownReply.data.angVelocities[1] = (rawReply[6] << 8) | rawReply[7]; gyro.ownReply.data.angVelocities[2] = (rawReply[8] << 8) | rawReply[9]; gyro.ownReply.data.accelerations[0] = (rawReply[10] << 8) | rawReply[11]; gyro.ownReply.data.accelerations[1] = (rawReply[12] << 8) | rawReply[13]; gyro.ownReply.data.accelerations[2] = (rawReply[14] << 8) | rawReply[15]; gyro.ownReply.data.temperatureRaw = (rawReply[16] << 8) | rawReply[17]; } void AcsBoardPolling::mgmLis3Handler(MgmLis3& mgm) { ReturnValue_t result; acs::SimpleSensorMode mode = acs::SimpleSensorMode::OFF; bool mustPerformStartup = false; { MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); mode = mgm.mode; mustPerformStartup = mgm.performStartup; } if (mode == acs::SimpleSensorMode::NORMAL) { if (mustPerformStartup) { // To check valid communication, read back identification // register which should always be the same value. cmdBuf[0] = mgmLis3::readCommand(mgmLis3::IDENTIFY_DEVICE_REG_ADDR); cmdBuf[1] = 0x00; result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 2); if (result != OK) { mgm.replyResult = result; return; } result = spiComIF.readReceivedMessage(mgm.cookie, &rawReply, &dummy); if (result != OK) { mgm.replyResult = result; return; } if (rawReply[1] != mgmLis3::DEVICE_ID) { sif::error << "AcsPollingTask: invalid MGM lis3 device ID" << std::endl; mgm.replyResult = result; return; } mgm.cfg[0] = mgmLis3::CTRL_REG1_DEFAULT; mgm.cfg[1] = mgmLis3::CTRL_REG2_DEFAULT; mgm.cfg[2] = mgmLis3::CTRL_REG3_DEFAULT; mgm.cfg[3] = mgmLis3::CTRL_REG4_DEFAULT; mgm.cfg[4] = mgmLis3::CTRL_REG5_DEFAULT; cmdBuf[0] = mgmLis3::writeCommand(mgmLis3::CTRL_REG1, true); std::memcpy(cmdBuf.data() + 1, mgm.cfg, 5); result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 6); if (result != OK) { mgm.replyResult = result; return; } // Done here. We can always read back config and data during periodic handling mgm.performStartup = false; mgm.replyResult = returnvalue::OK; } cmdBuf[0] = mgmLis3::readCommand(mgmLis3::CTRL_REG1, true); std::memset(cmdBuf.data() + 1, 0, mgmLis3::NR_OF_DATA_AND_CFG_REGISTERS); result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), mgmLis3::NR_OF_DATA_AND_CFG_REGISTERS + 1); if (result != returnvalue::OK) { mgm.replyResult = result; return; } result = spiComIF.readReceivedMessage(mgm.cookie, &rawReply, &dummy); if (result != returnvalue::OK) { mgm.replyResult = result; return; } // Verify communication by re-checking config if (rawReply[1] != mgm.cfg[0] or rawReply[2] != mgm.cfg[1] or rawReply[3] != mgm.cfg[2] or rawReply[4] != mgm.cfg[3] or rawReply[5] != mgm.cfg[4]) { mgm.replyResult = returnvalue::FAILED; return; } { MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); mgm.ownReply.dataWasSet = true; mgm.ownReply.sensitivity = mgmLis3::getSensitivityFactor(mgmLis3::getSensitivity(mgm.cfg[1])); mgm.ownReply.mgmValuesRaw[0] = (rawReply[mgmLis3::X_HIGHBYTE_IDX] << 8) | rawReply[mgmLis3::X_LOWBYTE_IDX]; mgm.ownReply.mgmValuesRaw[1] = (rawReply[mgmLis3::Y_HIGHBYTE_IDX] << 8) | rawReply[mgmLis3::Y_LOWBYTE_IDX]; mgm.ownReply.mgmValuesRaw[2] = (rawReply[mgmLis3::Z_HIGHBYTE_IDX] << 8) | rawReply[mgmLis3::Z_LOWBYTE_IDX]; } // Read tempetature cmdBuf[0] = mgmLis3::readCommand(mgmLis3::TEMP_LOWBYTE, true); result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 3); if (result != returnvalue::OK) { mgm.replyResult = result; return; } result = spiComIF.readReceivedMessage(mgm.cookie, &rawReply, &dummy); if (result != returnvalue::OK) { mgm.replyResult = result; return; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); mgm.replyResult = returnvalue::OK; mgm.ownReply.temperatureWasSet = true; mgm.ownReply.temperatureRaw = (rawReply[2] << 8) | rawReply[1]; } } void AcsBoardPolling::mgmRm3100Handler(MgmRm3100& mgm) { ReturnValue_t result; acs::SimpleSensorMode mode = acs::SimpleSensorMode::OFF; bool mustPerformStartup = false; { MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); mode = mgm.mode; mustPerformStartup = mgm.performStartup; } if (mode == acs::SimpleSensorMode::NORMAL) { if (mustPerformStartup) { // Configure CMM first cmdBuf[0] = mgmRm3100::CMM_REGISTER; cmdBuf[1] = mgmRm3100::CMM_VALUE; result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 2); if (result != OK) { mgm.replyResult = result; return; } // Read back register cmdBuf[0] = mgmRm3100::CMM_REGISTER | mgmRm3100::READ_MASK; cmdBuf[1] = 0; result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 2); if (result != OK) { mgm.replyResult = result; return; } result = spiComIF.readReceivedMessage(mgm.cookie, &rawReply, &dummy); if (result != OK) { mgm.replyResult = result; return; } if (rawReply[1] != mgmRm3100::CMM_VALUE) { sif::error << "AcsBoardPolling: MGM RM3100 read back CMM invalid" << std::endl; mgm.replyResult = result; return; } // Configure TMRC register cmdBuf[0] = mgmRm3100::TMRC_REGISTER; // hardcoded for now cmdBuf[1] = mgm.tmrcValue; result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 2); if (result != OK) { mgm.replyResult = result; return; } // Read back and verify value cmdBuf[0] = mgmRm3100::TMRC_REGISTER | mgmRm3100::READ_MASK; cmdBuf[1] = 0; result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 2); if (result != OK) { mgm.replyResult = result; return; } result = spiComIF.readReceivedMessage(mgm.cookie, &rawReply, &dummy); if (result != OK) { mgm.replyResult = result; return; } if (rawReply[1] != mgm.tmrcValue) { sif::error << "AcsBoardPolling: MGM RM3100 read back TMRC invalid" << std::endl; mgm.replyResult = result; return; } mgm.performStartup = false; mgm.replyResult = returnvalue::OK; } // Regular read operation cmdBuf[0] = mgmRm3100::MEASUREMENT_REG_START | mgmRm3100::READ_MASK; std::memset(cmdBuf.data() + 1, 0, 9); result = spiComIF.sendMessage(mgm.cookie, cmdBuf.data(), 10); if (result != OK) { mgm.replyResult = result; return; } result = spiComIF.readReceivedMessage(mgm.cookie, &rawReply, &dummy); if (result != OK) { mgm.replyResult = result; return; } MutexGuard mg(ipcLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); for (uint8_t idx = 0; idx < 3; idx++) { // Hardcoded, but note that the gain depends on the cycle count // value which is configurable! mgm.ownReply.scaleFactors[idx] = 1.0 / mgmRm3100::DEFAULT_GAIN; } mgm.ownReply.dataWasRead = true; mgm.replyResult = returnvalue::OK; // Bitshift trickery to account for 24 bit signed value. mgm.ownReply.mgmValuesRaw[0] = ((rawReply[1] << 24) | (rawReply[2] << 16) | (rawReply[3] << 8)) >> 8; mgm.ownReply.mgmValuesRaw[1] = ((rawReply[4] << 24) | (rawReply[5] << 16) | (rawReply[6] << 8)) >> 8; mgm.ownReply.mgmValuesRaw[2] = ((rawReply[7] << 24) | (rawReply[8] << 16) | (rawReply[9] << 8)) >> 8; } }