#include #include #include #include #include #include #include "devices/powerSwitcherList.h" #include "fsfw/subsystem/helper.h" HeaterHandler::HeaterHandler(object_id_t setObjectId_, GpioIF* gpioInterface_, HeaterHelper helper, PowerSwitchIF* mainLineSwitcher_, power::Switch_t mainLineSwitch_) : SystemObject(setObjectId_), helper(helper), modeHelper(this), gpioInterface(gpioInterface_), mainLineSwitcher(mainLineSwitcher_), mainLineSwitch(mainLineSwitch_), actionHelper(this, nullptr) { for (const auto& heater : helper.heaters) { if (heater.first == nullptr) { throw std::invalid_argument("HeaterHandler::HeaterHandler: Invalid Heater Object"); } } if (gpioInterface_ == nullptr) { throw std::invalid_argument("HeaterHandler::HeaterHandler: Invalid Gpio IF"); } if (mainLineSwitcher == nullptr) { throw std::invalid_argument("HeaterHandler::HeaterHandler: Invalid PowerSwitchIF"); } handlerLock = MutexFactory::instance()->createMutex(); if (handlerLock == nullptr) { throw std::runtime_error("HeaterHandler::HeaterHandler: Creating Mutex failed"); } auto mqArgs = MqArgs(setObjectId_, static_cast(this)); commandQueue = QueueFactory::instance()->createMessageQueue( cmdQueueSize, MessageQueueMessage::MAX_MESSAGE_SIZE, &mqArgs); } HeaterHandler::~HeaterHandler() = default; ReturnValue_t HeaterHandler::performOperation(uint8_t operationCode) { try { readCommandQueue(); for (const auto& heater : helper.heaters) { heater.first->performOperation(0); } handleSwitchHandling(); if (waitForSwitchOff) { if (mainLineSwitcher->getSwitchState(mainLineSwitch) == SWITCH_OFF) { waitForSwitchOff = false; mode = MODE_OFF; modeHelper.modeChanged(mode, submode); } } } catch (const std::out_of_range& e) { sif::warning << "HeaterHandler::performOperation: " "Out of range error | " << e.what() << std::endl; } return returnvalue::OK; } ReturnValue_t HeaterHandler::initialize() { ReturnValue_t result = SystemObject::initialize(); if (result != returnvalue::OK) { return ObjectManagerIF::CHILD_INIT_FAILED; } result = initializeHeaterMap(); if (result != returnvalue::OK) { return ObjectManagerIF::CHILD_INIT_FAILED; } ipcStore = ObjectManager::instance()->get(objects::IPC_STORE); if (ipcStore == nullptr) { sif::error << "HeaterHandler::initialize: IPC store not set up in factory." << std::endl; return ObjectManagerIF::CHILD_INIT_FAILED; } result = actionHelper.initialize(commandQueue); if (result != returnvalue::OK) { return ObjectManagerIF::CHILD_INIT_FAILED; } result = modeHelper.initialize(); if (result != returnvalue::OK) { return ObjectManagerIF::CHILD_INIT_FAILED; } return returnvalue::OK; } ReturnValue_t HeaterHandler::initializeHeaterMap() { for (power::Switch_t switchNr = 0; switchNr < heater::NUMBER_OF_SWITCHES; switchNr++) { heaterVec.push_back(HeaterWrapper(helper.heaters[switchNr], SwitchState::OFF)); } return returnvalue::OK; } void HeaterHandler::readCommandQueue() { ReturnValue_t result = returnvalue::OK; CommandMessage command; do { result = commandQueue->receiveMessage(&command); if (result == MessageQueueIF::EMPTY) { break; } else if (result != returnvalue::OK) { sif::warning << "HeaterHandler::readCommandQueue: Message reception error" << std::endl; break; } result = actionHelper.handleActionMessage(&command); if (result == returnvalue::OK) { continue; } result = modeHelper.handleModeCommand(&command); if (result == returnvalue::OK) { continue; } } while (result == returnvalue::OK); } ReturnValue_t HeaterHandler::executeAction(ActionId_t actionId, MessageQueueId_t commandedBy, const uint8_t* data, size_t size) { if (data == nullptr or size < 3) { return HasActionsIF::INVALID_PARAMETERS; } if (actionId != SWITCH_HEATER) { return COMMAND_NOT_SUPPORTED; } auto switchNr = data[0]; if (switchNr > 7) { return HasActionsIF::INVALID_PARAMETERS; } auto& heater = heaterVec.at(switchNr); auto actionRaw = data[1]; if (actionRaw != 0 and actionRaw != 1) { return HasActionsIF::INVALID_PARAMETERS; } auto action = static_cast(data[1]); // Always accepts OFF commands if (action == SwitchAction::SET_SWITCH_ON) { HasHealthIF::HealthState health; { MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); health = heater.healthDevice->getHealth(); } if (health == HasHealthIF::FAULTY or health == HasHealthIF::PERMANENT_FAULTY or health == HasHealthIF::NEEDS_RECOVERY) { return HasHealthIF::OBJECT_NOT_HEALTHY; } CmdSourceParam cmdSource = CmdSourceParam::EXTERNAL; uint8_t cmdSourceRaw = data[2]; if (cmdSourceRaw > 1) { return HasActionsIF::INVALID_PARAMETERS; } cmdSource = static_cast(data[2]); if (health == HasHealthIF::EXTERNAL_CONTROL and cmdSource == CmdSourceParam::INTERNAL) { return HasHealthIF::IS_EXTERNALLY_CONTROLLED; } } if (heater.cmdActive) { return COMMAND_ALREADY_WAITING; } heater.action = action; heater.cmdActive = true; heater.replyQueue = commandedBy; return returnvalue::OK; } ReturnValue_t HeaterHandler::sendSwitchCommand(uint8_t switchNr, ReturnValue_t onOff) { ReturnValue_t result; store_address_t storeAddress; uint8_t commandData[3] = {}; switch (onOff) { case PowerSwitchIF::SWITCH_ON: commandData[0] = switchNr; commandData[1] = SET_SWITCH_ON; commandData[2] = CmdSourceParam::INTERNAL; break; case PowerSwitchIF::SWITCH_OFF: commandData[0] = switchNr; commandData[1] = SET_SWITCH_OFF; commandData[2] = CmdSourceParam::INTERNAL; break; default: sif::error << "HeaterHandler::sendSwitchCommand: Invalid switch request" << std::endl; break; } result = ipcStore->addData(&storeAddress, commandData, sizeof(commandData)); if (result == returnvalue::OK) { CommandMessage message; ActionMessage::setCommand(&message, SWITCH_HEATER, storeAddress); /* Send heater command to own command queue */ result = commandQueue->sendMessage(commandQueue->getId(), &message, 0); if (result != returnvalue::OK) { sif::debug << "HeaterHandler::sendSwitchCommand: Failed to send switch" << "message" << std::endl; } } return result; } void HeaterHandler::handleSwitchHandling() { for (uint8_t idx = 0; idx < heater::NUMBER_OF_SWITCHES; idx++) { auto health = heaterVec[idx].healthDevice->getHealth(); if (heaterVec[idx].switchState == SwitchState::ON) { // If a heater is still on but the device was marked faulty by the operator, the SW // will shut down the heater if (health == HasHealthIF::FAULTY or health == HasHealthIF::PERMANENT_FAULTY) { heaterVec[idx].cmdActive = true; heaterVec[idx].action = SET_SWITCH_OFF; triggerEvent(FAULTY_HEATER_WAS_ON, idx, 0); handleSwitchOffCommand(static_cast(idx)); continue; } } if (heaterVec[idx].cmdActive) { switch (heaterVec[idx].action) { case SET_SWITCH_ON: handleSwitchOnCommand(static_cast(idx)); break; case SET_SWITCH_OFF: handleSwitchOffCommand(static_cast(idx)); break; default: sif::error << "HeaterHandler::handleActiveCommands: Invalid action commanded" << std::endl; break; } } } } void HeaterHandler::handleSwitchOnCommand(heater::Switch heaterIdx) { ReturnValue_t result = returnvalue::OK; auto& heater = heaterVec.at(heaterIdx); if (waitForSwitchOff) { waitForSwitchOff = false; } /* Check if command waits for main switch being set on and whether the timeout has expired */ if (heater.waitMainSwitchOn && heater.mainSwitchCountdown.hasTimedOut()) { // TODO - This requires the initiation of an FDIR procedure triggerEvent(MAIN_SWITCH_TIMEOUT); sif::error << "HeaterHandler::handleSwitchOnCommand: Main switch setting on timeout" << std::endl; heater.cmdActive = false; heater.waitMainSwitchOn = false; if (heater.replyQueue != commandQueue->getId()) { actionHelper.finish(false, heater.replyQueue, heater.action, MAIN_SWITCH_SET_TIMEOUT); } return; } // Check state of main line switch ReturnValue_t mainSwitchState = mainLineSwitcher->getSwitchState(mainLineSwitch); if (mainSwitchState == PowerSwitchIF::SWITCH_ON) { if (getSwitchState(heaterIdx) == SwitchState::OFF) { gpioId_t gpioId = heater.gpioId; result = gpioInterface->pullHigh(gpioId); if (result != returnvalue::OK) { sif::error << "HeaterHandler::handleSwitchOnCommand: Failed to pull gpio with id " << gpioId << " high" << std::endl; triggerEvent(GPIO_PULL_HIGH_FAILED, result); } else { triggerEvent(HEATER_WENT_ON, heaterIdx, 0); { MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); heater.switchState = ON; } } } else { triggerEvent(SWITCH_ALREADY_ON, heaterIdx); } mode = HasModesIF::MODE_ON; modeHelper.modeChanged(mode, submode); // There is no need to send action finish replies if the sender was the // HeaterHandler itself if (heater.replyQueue != commandQueue->getId()) { if (result == returnvalue::OK) { actionHelper.finish(true, heater.replyQueue, heater.action, result); } else { actionHelper.finish(false, heater.replyQueue, heater.action, result); } } heater.cmdActive = false; heater.waitMainSwitchOn = false; } else if (mainSwitchState == PowerSwitchIF::SWITCH_OFF && heater.waitMainSwitchOn) { // Just waiting for the main switch being set on return; } else if (mainSwitchState == PowerSwitchIF::SWITCH_OFF or mainSwitchState == PowerSwitchIF::SWITCH_UNKNOWN) { mainLineSwitcher->sendSwitchCommand(mainLineSwitch, PowerSwitchIF::SWITCH_ON); heater.mainSwitchCountdown.setTimeout(mainLineSwitcher->getSwitchDelayMs()); heater.waitMainSwitchOn = true; } else { sif::debug << "HeaterHandler::handleSwitchOnCommand: Failed to get state of" << " main line switch" << std::endl; if (heater.replyQueue != commandQueue->getId()) { actionHelper.finish(false, heater.replyQueue, heater.action, mainSwitchState); } heater.cmdActive = false; } } void HeaterHandler::handleSwitchOffCommand(heater::Switch heaterIdx) { ReturnValue_t result = returnvalue::OK; auto& heater = heaterVec.at(heaterIdx); // Check whether switch is already off if (getSwitchState(heaterIdx)) { gpioId_t gpioId = heater.gpioId; result = gpioInterface->pullLow(gpioId); if (result != returnvalue::OK) { sif::error << "HeaterHandler::handleSwitchOffCommand: Failed to pull gpio with id" << gpioId << " low" << std::endl; triggerEvent(GPIO_PULL_LOW_FAILED, result); } else { { MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); heater.switchState = OFF; } triggerEvent(HEATER_WENT_OFF, heaterIdx, 0); // When all switches are off, also main line switch will be turned off if (allSwitchesOff()) { mainLineSwitcher->sendSwitchCommand(mainLineSwitch, PowerSwitchIF::SWITCH_OFF); waitForSwitchOff = true; } } } else { sif::info << "HeaterHandler::handleSwitchOffCommand: Switch already off" << std::endl; triggerEvent(SWITCH_ALREADY_OFF, heaterIdx); } if (heater.replyQueue != NO_COMMANDER) { // Report back switch command reply if necessary if (result == returnvalue::OK) { actionHelper.finish(true, heater.replyQueue, heater.action, result); } else { actionHelper.finish(false, heater.replyQueue, heater.action, result); } } heater.cmdActive = false; } HeaterHandler::SwitchState HeaterHandler::getSwitchState(heater::Switch switchNr) const { MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); return heaterVec.at(switchNr).switchState; } ReturnValue_t HeaterHandler::switchHeater(heater::Switch heater, SwitchState switchState) { if (switchState == SwitchState::ON) { return sendSwitchCommand(heater, PowerSwitchIF::SWITCH_ON); } else if (switchState == SwitchState::OFF) { return sendSwitchCommand(heater, PowerSwitchIF::SWITCH_OFF); } return returnvalue::FAILED; } void HeaterHandler::announceMode(bool recursive) { triggerEvent(MODE_INFO, mode, submode); std::array states; getAllSwitchStates(states); for (unsigned idx = 0; idx < helper.heaters.size(); idx++) { if (states[idx] == ON) { EventManagerIF::triggerEvent(helper.heaters[idx].first->getObjectId(), MODE_INFO, MODE_ON, 0); } else { EventManagerIF::triggerEvent(helper.heaters[idx].first->getObjectId(), MODE_INFO, MODE_OFF, 0); } } } void HeaterHandler::getMode(Mode_t* mode, Submode_t* submode) { if (!mode || !submode) { return; } *mode = this->mode; *submode = this->submode; } const HasHealthIF* HeaterHandler::getOptHealthIF() const { return nullptr; } const HasModesIF& HeaterHandler::getModeIF() const { return *this; } ReturnValue_t HeaterHandler::connectModeTreeParent(HasModeTreeChildrenIF& parent) { return modetree::connectModeTreeParent(parent, *this, nullptr, modeHelper); } ModeTreeChildIF& HeaterHandler::getModeTreeChildIF() { return *this; } object_id_t HeaterHandler::getObjectId() const { return SystemObject::getObjectId(); } ReturnValue_t HeaterHandler::getAllSwitchStates(std::array& statesBuf) { { MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); if (mg.getLockResult() != returnvalue::OK) { return returnvalue::FAILED; } for (unsigned idx = 0; idx < helper.heaters.size(); idx++) { statesBuf[idx] = heaterVec[idx].switchState; } } return returnvalue::OK; } bool HeaterHandler::allSwitchesOff() { bool allSwitchesOrd = false; MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); /* Or all switches. As soon one switch is on, allSwitchesOrd will be true */ for (power::Switch_t switchNr = 0; switchNr < heater::NUMBER_OF_SWITCHES; switchNr++) { allSwitchesOrd = allSwitchesOrd || heaterVec.at(switchNr).switchState; } return !allSwitchesOrd; } MessageQueueId_t HeaterHandler::getCommandQueue() const { return commandQueue->getId(); } ReturnValue_t HeaterHandler::sendFuseOnCommand(uint8_t fuseNr) { return returnvalue::OK; } ReturnValue_t HeaterHandler::getSwitchState(uint8_t switchNr) const { ReturnValue_t mainSwitchState = mainLineSwitcher->getSwitchState(mainLineSwitch); if (mainSwitchState == PowerSwitchIF::SWITCH_OFF) { return PowerSwitchIF::SWITCH_OFF; } if (switchNr > 7) { return returnvalue::FAILED; } if (getSwitchState(static_cast(switchNr)) == SwitchState::ON) { return PowerSwitchIF::SWITCH_ON; } return PowerSwitchIF::SWITCH_OFF; } ReturnValue_t HeaterHandler::getFuseState(uint8_t fuseNr) const { return 0; } uint32_t HeaterHandler::getSwitchDelayMs(void) const { return 2000; } HasHealthIF::HealthState HeaterHandler::getHealth(heater::Switch heater) { auto* healthDev = heaterVec.at(heater).healthDevice; if (healthDev != nullptr) { MutexGuard mg(handlerLock, LOCK_TYPE, LOCK_TIMEOUT, LOCK_CTX); return healthDev->getHealth(); } return HasHealthIF::HealthState::FAULTY; }