eive-obsw/mission/devices/SolarArrayDeploymentHandler.cpp

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#include "SolarArrayDeploymentHandler.h"
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#include <filesystem>
#include <fstream>
#include <iostream>
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#include "devices/gpioIds.h"
#include "fsfw/ipc/QueueFactory.h"
#include "fsfw/objectmanager/ObjectManager.h"
#include "fsfw_hal/common/gpio/GpioCookie.h"
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static constexpr bool DEBUG_MODE = true;
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SolarArrayDeploymentHandler::SolarArrayDeploymentHandler(object_id_t setObjectId_,
GpioIF& gpioInterface,
PowerSwitchIF& mainLineSwitcher_,
pcdu::Switches mainLineSwitch_,
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gpioId_t deplSA1, gpioId_t deplSA2,
SdCardMountedIF& sdcMountedIF)
: SystemObject(setObjectId_),
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gpioInterface(gpioInterface),
deplSA1(deplSA1),
deplSA2(deplSA2),
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mainLineSwitcher(mainLineSwitcher_),
mainLineSwitch(mainLineSwitch_),
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sdcMan(sdcMountedIF),
actionHelper(this, nullptr) {
auto mqArgs = MqArgs(setObjectId_, static_cast<void*>(this));
commandQueue = QueueFactory::instance()->createMessageQueue(
cmdQueueSize, MessageQueueMessage::MAX_MESSAGE_SIZE, &mqArgs);
}
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SolarArrayDeploymentHandler::~SolarArrayDeploymentHandler() = default;
ReturnValue_t SolarArrayDeploymentHandler::performOperation(uint8_t operationCode) {
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using namespace std::filesystem;
auto activeSdc = sdcMan.getActiveSdCard();
if (activeSdc and activeSdc.value() == sd::SdCard::SLOT_0 and
sdcMan.isSdCardUsable(activeSdc.value())) {
if (exists(SD_0_DEPL_FILE)) {
// perform autonomous deployment handling
performAutonomousDepl(sd::SdCard::SLOT_0, dryRunStringInFile(SD_0_DEPL_FILE));
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}
} else if (activeSdc and activeSdc.value() == sd::SdCard::SLOT_1 and
sdcMan.isSdCardUsable(activeSdc.value())) {
if (exists(SD_1_DEPL_FILE)) {
// perform autonomous deployment handling
performAutonomousDepl(sd::SdCard::SLOT_1, dryRunStringInFile(SD_1_DEPL_FILE));
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}
}
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readCommandQueue();
handleStateMachine();
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return returnvalue::OK;
}
ReturnValue_t SolarArrayDeploymentHandler::performAutonomousDepl(sd::SdCard sdCard, bool dryRun) {
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using namespace std::filesystem;
using namespace std;
auto initFile = [](const char* filename) {
ofstream of(filename);
of << "phase: init\n";
of << "secs_since_start: 0\n";
};
if (sdCard == sd::SdCard::SLOT_0) {
if (not exists(SD_0_DEPLY_INFO)) {
initFile(SD_0_DEPLY_INFO);
}
if (not autonomousDeplForFile(SD_0_DEPLY_INFO, dryRun)) {
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initFile(SD_0_DEPLY_INFO);
}
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} else if (sdCard == sd::SdCard::SLOT_1) {
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if (not exists(SD_1_DEPLY_INFO)) {
initFile(SD_1_DEPLY_INFO);
}
if (not autonomousDeplForFile(SD_1_DEPLY_INFO, dryRun)) {
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initFile(SD_1_DEPLY_INFO);
}
}
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return returnvalue::OK;
}
bool SolarArrayDeploymentHandler::autonomousDeplForFile(const char* filename, bool dryRun) {
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using namespace std;
ifstream file(filename);
string line;
string word;
unsigned int lineNum = 0;
AutonomousDeplState deplState;
bool stateSwitch = false;
uint32_t secsSinceBoot = 0;
while (std::getline(file, line)) {
if (lineNum == 0) {
std::istringstream iss(line);
if (lineNum == 0) {
iss >> word;
if (word.find("phase:") == string::npos) {
return false;
}
iss >> word;
if (word.find(PHASE_INIT_STR) != string::npos) {
deplState = AutonomousDeplState::INIT;
} else if (word.find(PHASE_FIRST_BURN_STR) != string::npos) {
deplState = AutonomousDeplState::FIRST_BURN;
} else if (word.find(PHASE_WAIT_STR) != string::npos) {
deplState = AutonomousDeplState::WAIT;
} else if (word.find(PHASE_SECOND_BURN_STR) != string::npos) {
deplState = AutonomousDeplState::SECOND_BURN;
} else if (word.find(PHASE_DONE) != string::npos) {
deplState = AutonomousDeplState::DONE;
} else {
return false;
}
} else if (lineNum == 1) {
iss >> word;
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if (word.find("secs_since_start:") == string::npos) {
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return false;
}
iss >> secsSinceBoot;
if (not initUptime) {
initUptime = secsSinceBoot;
}
if (iss.bad()) {
return false;
}
auto switchCheck = [&](AutonomousDeplState expected) {
if (deplState != expected) {
deplState = expected;
stateSwitch = true;
}
};
if ((secsSinceBoot > FIRST_BURN_START_TIME) and (secsSinceBoot < FIRST_BURN_END_TIME)) {
switchCheck(AutonomousDeplState::FIRST_BURN);
} else if ((secsSinceBoot > WAIT_START_TIME) and (secsSinceBoot < WAIT_END_TIME)) {
switchCheck(AutonomousDeplState::WAIT);
} else if ((secsSinceBoot > SECOND_BURN_START_TIME) and
(secsSinceBoot < SECOND_BURN_END_TIME)) {
switchCheck(AutonomousDeplState::SECOND_BURN);
} else if (secsSinceBoot > SECOND_BURN_END_TIME) {
switchCheck(AutonomousDeplState::DONE);
}
}
}
lineNum++;
}
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bool updateUptime = false;
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if (opDivider.checkAndIncrement()) {
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if (initUptime) {
secsSinceBoot = initUptime.value();
}
// Uptime has increased by X seconds so we need to update the uptime count inside the file
secsSinceBoot += Clock::getUptime().tv_sec;
updateUptime = true;
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}
if (stateSwitch) {
if (deplState == AutonomousDeplState::FIRST_BURN or
deplState == AutonomousDeplState::SECOND_BURN) {
startFsmOn(config::SA_DEPL_BURN_TIME_SECS, dryRun);
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} else if (deplState == AutonomousDeplState::WAIT or deplState == AutonomousDeplState::DONE) {
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startFsmOff();
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}
}
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if (stateSwitch or updateUptime) {
std::ofstream of(filename);
of << "phase: ";
if (deplState == AutonomousDeplState::INIT) {
of << PHASE_INIT_STR << "\n";
} else if (deplState == AutonomousDeplState::FIRST_BURN) {
of << PHASE_FIRST_BURN_STR << "\n";
} else if (deplState == AutonomousDeplState::WAIT) {
of << PHASE_WAIT_STR << "\n";
} else if (deplState == AutonomousDeplState::SECOND_BURN) {
of << PHASE_SECOND_BURN_STR << "\n";
} else if (deplState == AutonomousDeplState::DONE) {
of << PHASE_DONE << "\n";
}
of << "secs_since_start: " << std::to_string(secsSinceBoot) << "\n";
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}
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return true;
}
void SolarArrayDeploymentHandler::handleStateMachine() {
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if (stateMachine == MAIN_POWER_ON) {
mainLineSwitcher.sendSwitchCommand(mainLineSwitch, PowerSwitchIF::SWITCH_ON);
mainSwitchCountdown.setTimeout(mainLineSwitcher.getSwitchDelayMs());
stateMachine = WAIT_MAIN_POWER_ON;
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if (DEBUG_MODE) {
sif::debug << "SA DEPL FSM: MAIN_POWER_ON done -> WAIT_MAIN_POWER_ON" << std::endl;
}
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}
if (stateMachine == MAIN_POWER_OFF) {
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// These should never fail
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allOff();
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stateMachine = WAIT_MAIN_POWER_OFF;
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if (DEBUG_MODE) {
sif::debug << "SA DEPL FSM: MAIN_POWER_OFF done -> WAIT_MAIN_POWER_OFF" << std::endl;
}
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}
if (stateMachine == WAIT_MAIN_POWER_ON) {
if (checkMainPowerOn()) {
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if (DEBUG_MODE) {
sif::debug << "SA DEPL FSM: WAIT_MAIN_POWER_ON done -> SWITCH_DEPL_GPIOS" << std::endl;
}
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stateMachine = SWITCH_DEPL_GPIOS;
}
}
if (stateMachine == WAIT_MAIN_POWER_OFF) {
if (checkMainPowerOff()) {
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if (DEBUG_MODE) {
sif::debug << "SA DEPL FSM: WAIT_MAIN_POWER_OFF done -> FSM DONE" << std::endl;
}
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finishFsm(returnvalue::OK);
}
}
if (stateMachine == SWITCH_DEPL_GPIOS) {
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burnCountdown.setTimeout(fsmInfo.burnCountdownMs);
// This should never fail
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channelAlternationCd.resetTimer();
if (not fsmInfo.dryRun) {
sa2Off();
sa1On();
fsmInfo.alternationDummy = true;
}
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if (DEBUG_MODE) {
sif::debug << "SA DEPL FSM: SWITCH_DEPL_GPIOS done -> BURNING" << std::endl;
}
stateMachine = BURNING;
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}
if (stateMachine == BURNING) {
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saGpioAlternation();
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if (burnCountdown.hasTimedOut()) {
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if (DEBUG_MODE) {
sif::debug << "SA DEPL FSM: BURNING done -> WAIT_MAIN_POWER_OFF" << std::endl;
}
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allOff();
stateMachine = WAIT_MAIN_POWER_OFF;
}
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}
}
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bool SolarArrayDeploymentHandler::checkMainPowerOn() { return checkMainPower(true); }
bool SolarArrayDeploymentHandler::checkMainPowerOff() { return checkMainPower(false); }
bool SolarArrayDeploymentHandler::checkMainPower(bool onOff) {
if ((onOff and mainLineSwitcher.getSwitchState(mainLineSwitch) == PowerSwitchIF::SWITCH_ON) or
(not onOff and
mainLineSwitcher.getSwitchState(mainLineSwitch) == PowerSwitchIF::SWITCH_OFF)) {
return true;
}
if (mainSwitchCountdown.hasTimedOut()) {
if (onOff) {
triggerEvent(MAIN_SWITCH_ON_TIMEOUT);
} else {
triggerEvent(MAIN_SWITCH_OFF_TIMEOUT);
}
if (retryCounter < 3) {
if (onOff) {
stateMachine = MAIN_POWER_ON;
} else {
stateMachine = MAIN_POWER_OFF;
}
retryCounter++;
} else {
finishFsm(MAIN_SWITCH_TIMEOUT_FAILURE);
}
}
return false;
}
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bool SolarArrayDeploymentHandler::startFsmOn(uint32_t burnCountdownSecs, bool dryRun) {
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if (stateMachine != StateMachine::IDLE) {
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return false;
}
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if (burnCountdownSecs > config::SA_DEPL_MAX_BURN_TIME) {
burnCountdownSecs = config::SA_DEPL_MAX_BURN_TIME;
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}
fsmInfo.onOff = true;
fsmInfo.dryRun = dryRun;
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fsmInfo.burnCountdownMs = burnCountdownSecs * 1000;
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stateMachine = StateMachine::MAIN_POWER_ON;
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retryCounter = 0;
return true;
}
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void SolarArrayDeploymentHandler::startFsmOff() {
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if (stateMachine != StateMachine::IDLE) {
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// off commands override the state machine. Cancel any active action commands.
finishFsm(returnvalue::FAILED);
}
fsmInfo.onOff = false;
retryCounter = 0;
stateMachine = StateMachine::MAIN_POWER_ON;
}
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void SolarArrayDeploymentHandler::finishFsm(ReturnValue_t resultForActionHelper) {
retryCounter = 0;
stateMachine = StateMachine::IDLE;
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fsmInfo.dryRun = false;
fsmInfo.onOff = false;
fsmInfo.alternationDummy = false;
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if (actionActive) {
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bool success = false;
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if (resultForActionHelper == returnvalue::OK or
resultForActionHelper == HasActionsIF::EXECUTION_FINISHED) {
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success = true;
}
actionHelper.finish(success, rememberCommanderId, activeCmd, resultForActionHelper);
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}
}
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void SolarArrayDeploymentHandler::allOff() {
deploymentTransistorsOff();
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mainLineSwitcher.sendSwitchCommand(mainLineSwitch, PowerSwitchIF::SWITCH_OFF);
mainSwitchCountdown.setTimeout(mainLineSwitcher.getSwitchDelayMs());
}
bool SolarArrayDeploymentHandler::dryRunStringInFile(const char* filename) {
std::ifstream ifile(filename);
if (ifile.bad()) {
return false;
}
std::string line;
while (getline(ifile, line)) {
if (line.find("dryrun") != std::string::npos) {
return true;
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}
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}
return false;
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}
ReturnValue_t SolarArrayDeploymentHandler::executeAction(ActionId_t actionId,
MessageQueueId_t commandedBy,
const uint8_t* data, size_t size) {
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ReturnValue_t result = returnvalue::OK;
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if (actionId == DEPLOY_SOLAR_ARRAYS_MANUALLY) {
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ManualDeploymentCommand cmd;
if (size < cmd.getSerializedSize()) {
return HasActionsIF::INVALID_PARAMETERS;
}
result = cmd.deSerialize(&data, &size, SerializeIF::Endianness::NETWORK);
if (result != returnvalue::OK) {
return result;
}
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uint32_t burnCountdown = cmd.getBurnTime();
if (not startFsmOn(burnCountdown, cmd.isDryRun())) {
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return HasActionsIF::IS_BUSY;
}
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actionActive = true;
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return result;
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} else if (actionId == SWITCH_OFF_DEPLOYMENT) {
startFsmOff();
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actionActive = true;
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return result;
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} else {
return HasActionsIF::INVALID_ACTION_ID;
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}
return result;
}
ReturnValue_t SolarArrayDeploymentHandler::saGpioAlternation() {
ReturnValue_t status = returnvalue::OK;
ReturnValue_t result;
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if (channelAlternationCd.hasTimedOut() and not fsmInfo.dryRun) {
if (fsmInfo.alternationDummy) {
result = sa1Off();
if (result != returnvalue::OK) {
status = result;
}
result = sa2On();
if (result != returnvalue::OK) {
status = result;
}
} else {
result = sa1On();
if (result != returnvalue::OK) {
status = result;
}
result = sa2Off();
if (result != returnvalue::OK) {
status = result;
}
}
fsmInfo.alternationDummy = not fsmInfo.alternationDummy;
channelAlternationCd.resetTimer();
}
return status;
}
ReturnValue_t SolarArrayDeploymentHandler::deploymentTransistorsOff() {
ReturnValue_t status = returnvalue::OK;
ReturnValue_t result = sa1Off();
if (result != returnvalue::OK) {
status = result;
}
result = sa2Off();
if (result != returnvalue::OK) {
status = result;
}
return status;
}
ReturnValue_t SolarArrayDeploymentHandler::sa1On() {
ReturnValue_t result = gpioInterface.pullHigh(deplSA1);
if (result != returnvalue::OK) {
sif::warning << "SolarArrayDeploymentHandler::handleStateMachine: Failed to pull solar"
" array deployment switch 1 high"
<< std::endl;
// If gpio switch high failed, state machine is reset to wait for a command re-initiating
// the deployment sequence.
triggerEvent(DEPL_SA1_GPIO_SWTICH_ON_FAILED);
}
return result;
}
ReturnValue_t SolarArrayDeploymentHandler::sa1Off() {
ReturnValue_t result = gpioInterface.pullLow(deplSA1);
if (result != returnvalue::OK) {
sif::warning << "SolarArrayDeploymentHandler::handleStateMachine: Failed to pull solar"
" array deployment switch 1 low"
<< std::endl;
// If gpio switch high failed, state machine is reset to wait for a command re-initiating
// the deployment sequence.
triggerEvent(DEPL_SA1_GPIO_SWTICH_OFF_FAILED);
}
return result;
}
ReturnValue_t SolarArrayDeploymentHandler::sa2On() {
ReturnValue_t result = gpioInterface.pullHigh(deplSA2);
if (result != returnvalue::OK) {
sif::warning << "SolarArrayDeploymentHandler::handleStateMachine: Failed to pull solar"
" array deployment switch 2 high"
<< std::endl;
// If gpio switch high failed, state machine is reset to wait for a command re-initiating
// the deployment sequence.
triggerEvent(DEPL_SA2_GPIO_SWTICH_ON_FAILED);
}
return result;
}
ReturnValue_t SolarArrayDeploymentHandler::sa2Off() {
ReturnValue_t result = gpioInterface.pullLow(deplSA2);
if (result != returnvalue::OK) {
sif::warning << "SolarArrayDeploymentHandler::handleStateMachine: Failed to pull solar"
" array deployment switch 2 low"
<< std::endl;
// If gpio switch high failed, state machine is reset to wait for a command re-initiating
// the deployment sequence.
triggerEvent(DEPL_SA2_GPIO_SWTICH_OFF_FAILED);
}
return result;
}
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void SolarArrayDeploymentHandler::readCommandQueue() {
CommandMessage command;
ReturnValue_t result = commandQueue->receiveMessage(&command);
if (result != returnvalue::OK) {
return;
}
result = actionHelper.handleActionMessage(&command);
if (result == returnvalue::OK) {
return;
}
}
MessageQueueId_t SolarArrayDeploymentHandler::getCommandQueue() const {
return commandQueue->getId();
}
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ReturnValue_t SolarArrayDeploymentHandler::initialize() {
ReturnValue_t result = actionHelper.initialize(commandQueue);
if (result != returnvalue::OK) {
return ObjectManagerIF::CHILD_INIT_FAILED;
}
return SystemObject::initialize();
}