#include "DualLaneAssemblyBase.h" #include #include #include "OBSWConfig.h" DualLaneAssemblyBase::DualLaneAssemblyBase(object_id_t objectId, object_id_t parentId, PowerSwitchIF* pwrSwitcher, pcdu::Switches switch1, pcdu::Switches switch2, Event pwrTimeoutEvent, Event sideSwitchNotAllowedEvent, Event transitionOtherSideFailedEvent) : AssemblyBase(objectId, parentId, 20), pwrStateMachine(switch1, switch2, pwrSwitcher), pwrTimeoutEvent(pwrTimeoutEvent), sideSwitchNotAllowedEvent(sideSwitchNotAllowedEvent), transitionOtherSideFailedEvent(transitionOtherSideFailedEvent) { eventQueue = QueueFactory::instance()->createMessageQueue(10); } void DualLaneAssemblyBase::performChildOperation() { using namespace duallane; if (pwrStateMachine.active()) { pwrStateMachineWrapper(); } // Only perform the regular child operation if the power state machine is not active. // It does not make any sense to command device modes while the power switcher is busy // switching off or on devices. if (not pwrStateMachine.active()) { AssemblyBase::performChildOperation(); // TODO: Handle Event Queue } } void DualLaneAssemblyBase::startTransition(Mode_t mode, Submode_t submode) { // doStartTransition(mode, submode); using namespace duallane; pwrStateMachine.reset(); if (mode != MODE_OFF) { // If anything other than MODE_OFF is commanded, perform power state machine first // Cache the target modes, required by power state machine pwrStateMachine.start(mode, submode); // Cache these for later after the power state machine has finished targetMode = mode; targetSubmode = submode; } else { AssemblyBase::startTransition(mode, submode); } } bool DualLaneAssemblyBase::isUseable(object_id_t object, Mode_t mode) { if (healthHelper.healthTable->isFaulty(object)) { return false; } // Check if device is already in target mode if (childrenMap[object].mode == mode) { return true; } if (healthHelper.healthTable->isCommandable(object)) { return true; } return false; } ReturnValue_t DualLaneAssemblyBase::pwrStateMachineWrapper() { using namespace power; OpCodes opCode = pwrStateMachine.fsm(); if (customRecoveryStates == RecoveryCustomStates::IDLE) { if (opCode == OpCodes::NONE) { return RETURN_OK; } else if (opCode == OpCodes::TO_OFF_DONE) { // Will be called for transitions to MODE_OFF, where everything is done after power switching finishModeOp(); } else if (opCode == OpCodes::TO_NOT_OFF_DONE) { // Will be called for transitions from MODE_OFF to anything else, where the mode still has // to be commanded after power switching AssemblyBase::startTransition(targetMode, targetSubmode); } else if (opCode == OpCodes::TIMEOUT_OCCURED) { if (powerRetryCounter == 0) { powerRetryCounter++; pwrStateMachine.reset(); } else { #if OBSW_VERBOSE_LEVEL >= 1 sif::warning << "Timeout occured in power state machine" << std::endl; #endif triggerEvent(pwrTimeoutEvent, 0, 0); return RETURN_FAILED; } } } return RETURN_OK; } ModeDefinitionHelper DualLaneAssemblyBase::getModeDefinitionHelper() { return ModeDefinitionHelper::create(); } ReturnValue_t DualLaneAssemblyBase::isModeCombinationValid(Mode_t mode, Submode_t submode) { using namespace duallane; if (submode != A_SIDE and submode != B_SIDE and submode != DUAL_MODE) { return HasReturnvaluesIF::RETURN_FAILED; } if (sideSwitchTransition(mode, submode)) { // I could implement this but this would increase the already high complexity. This is not // necessary. The operator should can send a command to switch the assembly off first and // then send a command to turn on the other side, either to ON or to NORMAL triggerEvent(SIDE_SWITCH_TRANSITION_NOT_ALLOWED_ID, 0, 0); return TRANS_NOT_ALLOWED; } return HasReturnvaluesIF::RETURN_OK; } void DualLaneAssemblyBase::handleModeReached() { using namespace duallane; if (targetMode == MODE_OFF) { pwrStateMachine.start(targetMode, targetSubmode); // Now we can switch off the power. After that, the AssemblyBase::handleModeReached function // will be called pwrStateMachineWrapper(); } else { finishModeOp(); } } MessageQueueId_t DualLaneAssemblyBase::getEventReceptionQueue() { return eventQueue->getId(); } void DualLaneAssemblyBase::handleChildrenLostMode(ReturnValue_t result) { using namespace duallane; // Some ACS board components are required for Safe-Mode. It would be good if the software // transitions from A side to B side and from B side to dual mode autonomously // to ensure that that enough sensors are available without an operators intervention. // Therefore, the lost mode handler was overwritten to start these transitions Submode_t nextSubmode = Submodes::A_SIDE; if (submode == Submodes::A_SIDE) { nextSubmode = Submodes::B_SIDE; } if (not tryingOtherSide) { triggerEvent(CANT_KEEP_MODE, mode, submode); startTransition(mode, nextSubmode); tryingOtherSide = true; } else { // Not sure when this would happen. This flag is reset if the mode was reached. If it // was not reached, the transition failure handler should be called. sif::error << "DualLaneAssemblyBase::handleChildrenLostMode: Wrong handler called" << std::endl; triggerEvent(transitionOtherSideFailedEvent, mode, targetSubmode); startTransition(mode, Submodes::DUAL_MODE); } } void DualLaneAssemblyBase::handleModeTransitionFailed(ReturnValue_t result) { using namespace duallane; Submode_t nextSubmode = Submodes::A_SIDE; if (submode == Submodes::A_SIDE) { nextSubmode = Submodes::B_SIDE; } // Check whether the transition was started because the mode could not be kept (not commanded). // If this is not the case, start transition to other side. If it is the case, start // transition to dual mode. if (not tryingOtherSide) { triggerEvent(CANT_KEEP_MODE, mode, submode); startTransition(mode, nextSubmode); tryingOtherSide = true; } else { triggerEvent(transitionOtherSideFailedEvent, mode, targetSubmode); startTransition(mode, Submodes::DUAL_MODE); } } bool DualLaneAssemblyBase::checkAndHandleRecovery() { using namespace power; OpCodes opCode = OpCodes::NONE; if (recoveryState == RECOVERY_IDLE) { return AssemblyBase::checkAndHandleRecovery(); } if (customRecoveryStates == IDLE) { pwrStateMachine.start(MODE_OFF, 0); customRecoveryStates = RecoveryCustomStates::POWER_SWITCHING_OFF; } if (customRecoveryStates == POWER_SWITCHING_OFF) { opCode = pwrStateMachine.fsm(); if (opCode == OpCodes::TO_OFF_DONE or opCode == OpCodes::TIMEOUT_OCCURED) { customRecoveryStates = RecoveryCustomStates::POWER_SWITCHING_ON; pwrStateMachine.start(targetMode, targetSubmode); } } if (customRecoveryStates == POWER_SWITCHING_ON) { opCode = pwrStateMachine.fsm(); if (opCode == OpCodes::TO_NOT_OFF_DONE or opCode == OpCodes::TIMEOUT_OCCURED) { customRecoveryStates = RecoveryCustomStates::DONE; } } if (customRecoveryStates == DONE) { bool pendingRecovery = AssemblyBase::checkAndHandleRecovery(); if (not pendingRecovery) { pwrStateMachine.reset(); customRecoveryStates = RecoveryCustomStates::IDLE; } // For a recovery on one side, only do the recovery once for (auto& child : childrenMap) { if (healthHelper.healthTable->getHealth(child.first) == HasHealthIF::NEEDS_RECOVERY) { sendHealthCommand(child.second.commandQueue, HEALTHY); child.second.healthChanged = false; } } return pendingRecovery; } return true; } bool DualLaneAssemblyBase::sideSwitchTransition(Mode_t mode, Submode_t submode) { using namespace duallane; if (this->mode == MODE_OFF) { return false; } if (this->mode == MODE_ON or this->mode == DeviceHandlerIF::MODE_NORMAL) { if (this->submode == Submodes::A_SIDE and submode == Submodes::B_SIDE) { return true; } else if (this->submode == Submodes::B_SIDE and submode == Submodes::A_SIDE) { return true; } return false; } return false; } void DualLaneAssemblyBase::finishModeOp() { using namespace duallane; AssemblyBase::handleModeReached(); pwrStateMachine.reset(); powerRetryCounter = 0; tryingOtherSide = false; dualModeErrorSwitch = true; } void DualLaneAssemblyBase::setPreferredSide(duallane::Submodes submode) { using namespace duallane; if (submode != Submodes::A_SIDE and submode != Submodes::B_SIDE) { return; } this->defaultSubmode = submode; }