fsfw/devicehandlers/DeviceHandlerBase.cpp

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#include <framework/datapool/DataSet.h>
#include <framework/datapool/PoolVariable.h>
#include <framework/datapool/PoolVector.h>
#include <framework/devicehandlers/AcceptsDeviceResponsesIF.h>
#include <framework/devicehandlers/DeviceHandlerBase.h>
#include <framework/devicehandlers/DeviceTmReportingWrapper.h>
#include <framework/globalfunctions/CRC.h>
#include <framework/objectmanager/ObjectManager.h>
#include <framework/storagemanager/StorageManagerIF.h>
#include <framework/subsystem/SubsystemBase.h>
#include <framework/thermal/ThermalComponentIF.h>
#include <framework/ipc/QueueFactory.h>
#include <framework/serviceinterface/ServiceInterfaceStream.h>
object_id_t DeviceHandlerBase::powerSwitcherId = 0;
object_id_t DeviceHandlerBase::rawDataReceiverId = 0;
object_id_t DeviceHandlerBase::defaultFDIRParentId = 0;
DeviceHandlerBase::DeviceHandlerBase(uint32_t ioBoardAddress,
object_id_t setObjectId, uint32_t maxDeviceReplyLen,
uint8_t setDeviceSwitch, object_id_t deviceCommunication,
uint32_t thermalStatePoolId, uint32_t thermalRequestPoolId,
FailureIsolationBase* fdirInstance, uint32_t cmdQueueSize) :
SystemObject(setObjectId), rawPacket(0), rawPacketLen(0), mode(
MODE_OFF), submode(SUBMODE_NONE), pstStep(0), maxDeviceReplyLen(
maxDeviceReplyLen), wiretappingMode(OFF), defaultRawReceiver(0), storedRawData(
StorageManagerIF::INVALID_ADDRESS), requestedRawTraffic(0), powerSwitcher(
NULL), IPCStore(NULL), deviceCommunicationId(deviceCommunication), communicationInterface(
NULL), cookie(
NULL), commandQueue(NULL), deviceThermalStatePoolId(thermalStatePoolId), deviceThermalRequestPoolId(
thermalRequestPoolId), healthHelper(this, setObjectId), modeHelper(
this), parameterHelper(this), childTransitionFailure(RETURN_OK), ignoreMissedRepliesCount(
0), fdirInstance(fdirInstance), hkSwitcher(this), defaultFDIRUsed(
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fdirInstance == NULL), switchOffWasReported(false),executingTask(NULL), actionHelper(this, NULL), cookieInfo(), ioBoardAddress(
ioBoardAddress), timeoutStart(0), childTransitionDelay(5000), transitionSourceMode(
_MODE_POWER_DOWN), transitionSourceSubMode(SUBMODE_NONE), deviceSwitch(
setDeviceSwitch) {
commandQueue = QueueFactory::instance()->createMessageQueue(cmdQueueSize,
CommandMessage::MAX_MESSAGE_SIZE);
cookieInfo.state = COOKIE_UNUSED;
insertInCommandMap(RAW_COMMAND_ID);
if (this->fdirInstance == NULL) {
this->fdirInstance = new DeviceHandlerFailureIsolation(setObjectId,
defaultFDIRParentId);
}
}
DeviceHandlerBase::~DeviceHandlerBase() {
communicationInterface->close(cookie);
if (defaultFDIRUsed) {
delete fdirInstance;
}
QueueFactory::instance()->deleteMessageQueue(commandQueue);
}
ReturnValue_t DeviceHandlerBase::performOperation(uint8_t counter) {
this->pstStep = counter;
if (counter == 0) {
cookieInfo.state = COOKIE_UNUSED;
readCommandQueue();
doStateMachine();
checkSwitchState();
decrementDeviceReplyMap();
fdirInstance->checkForFailures();
hkSwitcher.performOperation();
}
if (mode == MODE_OFF) {
return RETURN_OK;
}
switch (getRmapAction()) {
case SEND_WRITE:
if ((cookieInfo.state == COOKIE_UNUSED)) {
buildInternalCommand();
}
doSendWrite();
break;
case GET_WRITE:
doGetWrite();
break;
case SEND_READ:
doSendRead();
break;
case GET_READ:
doGetRead();
cookieInfo.state = COOKIE_UNUSED;
break;
default:
break;
}
return RETURN_OK;
}
void DeviceHandlerBase::decrementDeviceReplyMap() {
for (std::map<DeviceCommandId_t, DeviceReplyInfo>::iterator iter =
deviceReplyMap.begin(); iter != deviceReplyMap.end(); iter++) {
if (iter->second.delayCycles != 0) {
iter->second.delayCycles--;
if (iter->second.delayCycles == 0) {
if (iter->second.periodic != 0) {
iter->second.delayCycles = iter->second.maxDelayCycles;
}
replyToReply(iter, TIMEOUT);
missedReply(iter->first);
}
}
}
}
void DeviceHandlerBase::readCommandQueue() {
if (dontCheckQueue()) {
return;
}
CommandMessage message;
ReturnValue_t result = commandQueue->receiveMessage(&message);
if (result != RETURN_OK) {
return;
}
result = healthHelper.handleHealthCommand(&message);
if (result == RETURN_OK) {
return;
}
result = modeHelper.handleModeCommand(&message);
if (result == RETURN_OK) {
return;
}
result = actionHelper.handleActionMessage(&message);
if (result == RETURN_OK) {
return;
}
result = parameterHelper.handleParameterMessage(&message);
if (result == RETURN_OK) {
return;
}
result = handleDeviceHandlerMessage(&message);
if (result == RETURN_OK) {
return;
}
result = letChildHandleMessage(&message);
if (result == RETURN_OK) {
return;
}
replyReturnvalueToCommand(CommandMessage::UNKNOW_COMMAND);
}
void DeviceHandlerBase::doStateMachine() {
switch (mode) {
case _MODE_START_UP:
case _MODE_SHUT_DOWN:
case _MODE_TO_NORMAL:
case _MODE_TO_ON:
case _MODE_TO_RAW: {
Mode_t currentMode = mode;
callChildStatemachine();
//Only do timeout if child did not change anything
if (mode != currentMode) {
break;
}
uint32_t currentUptime;
Clock::getUptime(&currentUptime);
if (currentUptime - timeoutStart >= childTransitionDelay) {
triggerEvent(MODE_TRANSITION_FAILED, childTransitionFailure, 0);
setMode(transitionSourceMode, transitionSourceSubMode);
break;
}
}
break;
case _MODE_POWER_DOWN:
commandSwitch(PowerSwitchIF::SWITCH_OFF);
setMode(_MODE_WAIT_OFF);
break;
case _MODE_POWER_ON:
commandSwitch(PowerSwitchIF::SWITCH_ON);
setMode(_MODE_WAIT_ON);
break;
case _MODE_WAIT_ON: {
uint32_t currentUptime;
Clock::getUptime(&currentUptime);
if (currentUptime - timeoutStart >= powerSwitcher->getSwitchDelayMs()) {
triggerEvent(MODE_TRANSITION_FAILED, PowerSwitchIF::SWITCH_TIMEOUT,
0);
setMode(_MODE_POWER_DOWN);
callChildStatemachine();
break;
}
ReturnValue_t switchState = getStateOfSwitches();
if ((switchState == PowerSwitchIF::SWITCH_ON)
|| (switchState == NO_SWITCH)) {
//NOTE: TransitionSourceMode and -SubMode are set by handleCommandedModeTransition
childTransitionFailure = CHILD_TIMEOUT;
setMode(_MODE_START_UP);
callChildStatemachine();
}
}
break;
case _MODE_WAIT_OFF: {
uint32_t currentUptime;
Clock::getUptime(&currentUptime);
if (currentUptime - timeoutStart >= powerSwitcher->getSwitchDelayMs()) {
triggerEvent(MODE_TRANSITION_FAILED, PowerSwitchIF::SWITCH_TIMEOUT,
0);
setMode(MODE_ERROR_ON);
break;
}
ReturnValue_t switchState = getStateOfSwitches();
if ((switchState == PowerSwitchIF::SWITCH_OFF)
|| (switchState == NO_SWITCH)) {
setMode(_MODE_SWITCH_IS_OFF);
}
}
break;
case MODE_OFF:
doOffActivity();
break;
case MODE_ON:
doOnActivity();
break;
case MODE_RAW:
case MODE_NORMAL:
case MODE_ERROR_ON:
break;
case _MODE_SWITCH_IS_OFF:
setMode(MODE_OFF, SUBMODE_NONE);
break;
default:
triggerEvent(OBJECT_IN_INVALID_MODE, mode, submode);
setMode(_MODE_POWER_DOWN, 0);
break;
}
}
ReturnValue_t DeviceHandlerBase::isModeCombinationValid(Mode_t mode,
Submode_t submode) {
switch (mode) {
case MODE_OFF:
case MODE_ON:
case MODE_NORMAL:
case MODE_RAW:
if (submode == SUBMODE_NONE) {
return RETURN_OK;
} else {
return INVALID_SUBMODE;
}
default:
return HasModesIF::INVALID_MODE;
}
}
ReturnValue_t DeviceHandlerBase::insertInCommandAndReplyMap(
DeviceCommandId_t deviceCommand, uint16_t maxDelayCycles,
uint8_t periodic, bool hasDifferentReplyId, DeviceCommandId_t replyId) {
//No need to check, as we may try to insert multiple times.
insertInCommandMap(deviceCommand);
if (hasDifferentReplyId) {
return insertInReplyMap(replyId, maxDelayCycles, periodic);
} else {
return insertInReplyMap(deviceCommand, maxDelayCycles, periodic);
}
}
ReturnValue_t DeviceHandlerBase::insertInReplyMap(DeviceCommandId_t replyId,
uint16_t maxDelayCycles, uint8_t periodic) {
DeviceReplyInfo info;
info.maxDelayCycles = maxDelayCycles;
info.periodic = periodic;
info.delayCycles = 0;
info.command = deviceCommandMap.end();
std::pair<std::map<DeviceCommandId_t, DeviceReplyInfo>::iterator, bool> returnValue;
returnValue = deviceReplyMap.insert(
std::pair<DeviceCommandId_t, DeviceReplyInfo>(replyId, info));
if (returnValue.second) {
return RETURN_OK;
} else {
return RETURN_FAILED;
}
}
ReturnValue_t DeviceHandlerBase::insertInCommandMap(
DeviceCommandId_t deviceCommand) {
DeviceCommandInfo info;
info.expectedReplies = 0;
info.isExecuting = false;
info.sendReplyTo = NO_COMMANDER;
std::pair<std::map<DeviceCommandId_t, DeviceCommandInfo>::iterator, bool> returnValue;
returnValue = deviceCommandMap.insert(
std::pair<DeviceCommandId_t, DeviceCommandInfo>(deviceCommand,
info));
if (returnValue.second) {
return RETURN_OK;
} else {
return RETURN_FAILED;
}
}
ReturnValue_t DeviceHandlerBase::updateReplyMapEntry(
DeviceCommandId_t deviceReply, uint16_t delayCycles,
uint16_t maxDelayCycles, uint8_t periodic) {
std::map<DeviceCommandId_t, DeviceReplyInfo>::iterator iter =
deviceReplyMap.find(deviceReply);
if (iter == deviceReplyMap.end()) {
triggerEvent(INVALID_DEVICE_COMMAND, deviceReply);
return RETURN_FAILED;
} else {
DeviceReplyInfo *info = &(iter->second);
if (maxDelayCycles != 0) {
info->maxDelayCycles = maxDelayCycles;
}
info->delayCycles = delayCycles;
info->periodic = periodic;
return RETURN_OK;
}
}
void DeviceHandlerBase::callChildStatemachine() {
if (mode == _MODE_START_UP) {
doStartUp();
} else if (mode == _MODE_SHUT_DOWN) {
doShutDown();
} else if (mode & TRANSITION_MODE_CHILD_ACTION_MASK) {
doTransition(transitionSourceMode, transitionSourceSubMode);
}
}
void DeviceHandlerBase::setTransition(Mode_t modeTo, Submode_t submodeTo) {
triggerEvent(CHANGING_MODE, modeTo, submodeTo);
childTransitionDelay = getTransitionDelayMs(mode, modeTo);
transitionSourceMode = mode;
transitionSourceSubMode = submode;
childTransitionFailure = CHILD_TIMEOUT;
//transitionTargetMode is set by setMode
setMode((modeTo | TRANSITION_MODE_CHILD_ACTION_MASK), submodeTo);
}
void DeviceHandlerBase::setMode(Mode_t newMode, uint8_t newSubmode) {
changeHK(mode, submode, false);
submode = newSubmode;
mode = newMode;
modeChanged();
setNormalDatapoolEntriesInvalid();
if (!isTransitionalMode()) {
modeHelper.modeChanged(newMode, newSubmode);
announceMode(false);
}
Clock::getUptime(&timeoutStart);
if (mode == MODE_OFF) {
DataSet mySet;
PoolVariable<int8_t> thermalRequest(deviceThermalRequestPoolId, &mySet,
PoolVariableIF::VAR_READ_WRITE);
mySet.read();
if (thermalRequest != ThermalComponentIF::STATE_REQUEST_IGNORE) {
thermalRequest = ThermalComponentIF::STATE_REQUEST_NON_OPERATIONAL;
}
mySet.commit(PoolVariableIF::VALID);
}
changeHK(mode, submode, true);
}
void DeviceHandlerBase::setMode(Mode_t newMode) {
setMode(newMode, submode);
}
void DeviceHandlerBase::replyReturnvalueToCommand(ReturnValue_t status,
uint32_t parameter) {
//This is actually the reply protocol for raw and misc DH commands.
if (status == RETURN_OK) {
CommandMessage reply(CommandMessage::REPLY_COMMAND_OK, 0, parameter);
commandQueue->reply(&reply);
} else {
CommandMessage reply(CommandMessage::REPLY_REJECTED, status, parameter);
commandQueue->reply(&reply);
}
}
void DeviceHandlerBase::replyToCommand(ReturnValue_t status,
uint32_t parameter) {
//Check if we reply to a raw command.
if (cookieInfo.pendingCommand->first == RAW_COMMAND_ID) {
if (status == NO_REPLY_EXPECTED) {
status = RETURN_OK;
}
replyReturnvalueToCommand(status, parameter);
//Always delete data from a raw command.
IPCStore->deleteData(storedRawData);
return;
}
//Check if we were externally commanded.
if (cookieInfo.pendingCommand->second.sendReplyTo != NO_COMMANDER) {
MessageQueueId_t queueId = cookieInfo.pendingCommand->second.sendReplyTo;
if (status == NO_REPLY_EXPECTED) {
actionHelper.finish(queueId, cookieInfo.pendingCommand->first,
RETURN_OK);
} else {
actionHelper.step(1, queueId, cookieInfo.pendingCommand->first,
status);
}
}
}
void DeviceHandlerBase::replyToReply(DeviceReplyMap::iterator iter,
ReturnValue_t status) {
//No need to check if iter exists, as this is checked by callers. If someone else uses the method, add check.
if (iter->second.command == deviceCommandMap.end()) {
//Is most likely periodic reply. Silent return.
return;
}
//Check if more replies are expected. If so, do nothing.
DeviceCommandInfo* info = &(iter->second.command->second);
if (--info->expectedReplies == 0) {
//Check if it was transition or internal command. Don't send any replies in that case.
if (info->sendReplyTo != NO_COMMANDER) {
actionHelper.finish(info->sendReplyTo, iter->first, status);
}
info->isExecuting = false;
}
}
void DeviceHandlerBase::doSendWrite() {
if (cookieInfo.state == COOKIE_WRITE_READY) {
ReturnValue_t result = communicationInterface->sendMessage(cookie,
rawPacket, rawPacketLen);
if (result == RETURN_OK) {
cookieInfo.state = COOKIE_WRITE_SENT;
} else {
//always generate a failure event, so that FDIR knows what's up
triggerEvent(DEVICE_SENDING_COMMAND_FAILED, result,
cookieInfo.pendingCommand->first);
replyToCommand(result);
cookieInfo.state = COOKIE_UNUSED;
cookieInfo.pendingCommand->second.isExecuting = false;
}
}
}
void DeviceHandlerBase::doGetWrite() {
if (cookieInfo.state != COOKIE_WRITE_SENT) {
return;
}
cookieInfo.state = COOKIE_UNUSED;
ReturnValue_t result = communicationInterface->getSendSuccess(cookie);
if (result == RETURN_OK) {
if (wiretappingMode == RAW) {
replyRawData(rawPacket, rawPacketLen, requestedRawTraffic, true);
}
//We need to distinguish here, because a raw command never expects a reply. (Could be done in eRIRM, but then child implementations need to be careful.
result = enableReplyInReplyMap(cookieInfo.pendingCommand);
} else {
//always generate a failure event, so that FDIR knows what's up
triggerEvent(DEVICE_SENDING_COMMAND_FAILED, result,
cookieInfo.pendingCommand->first);
}
if (result != RETURN_OK) {
cookieInfo.pendingCommand->second.isExecuting = false;
}
replyToCommand(result);
}
void DeviceHandlerBase::doSendRead() {
ReturnValue_t result;
result = communicationInterface->requestReceiveMessage(cookie);
if (result == RETURN_OK) {
cookieInfo.state = COOKIE_READ_SENT;
} else {
triggerEvent(DEVICE_REQUESTING_REPLY_FAILED, result);
//We can't inform anyone, because we don't know which command was sent last.
//So, we need to wait for a timeout.
//but I think we can allow to ignore one missedReply.
ignoreMissedRepliesCount++;
cookieInfo.state = COOKIE_UNUSED;
}
}
void DeviceHandlerBase::doGetRead() {
uint32_t receivedDataLen;
uint8_t *receivedData;
DeviceCommandId_t foundId = 0xFFFFFFFF;
uint32_t foundLen = 0;
ReturnValue_t result;
if (cookieInfo.state != COOKIE_READ_SENT) {
cookieInfo.state = COOKIE_UNUSED;
return;
}
cookieInfo.state = COOKIE_UNUSED;
result = communicationInterface->readReceivedMessage(cookie, &receivedData,
&receivedDataLen);
if (result != RETURN_OK) {
triggerEvent(DEVICE_REQUESTING_REPLY_FAILED, result);
//I think we can allow to ignore one missedReply.
ignoreMissedRepliesCount++;
return;
}
if (receivedDataLen == 0)
return;
if (wiretappingMode == RAW) {
replyRawData(receivedData, receivedDataLen, requestedRawTraffic);
}
if (mode == MODE_RAW) {
replyRawReplyIfnotWiretapped(receivedData, receivedDataLen);
} else {
//The loop may not execute more often than the number of received bytes (worst case).
//This approach avoids infinite loops due to buggy scanForReply routines (seen in bug 1077).
uint32_t remainingLength = receivedDataLen;
for (uint32_t count = 0; count < receivedDataLen; count++) {
result = scanForReply(receivedData, remainingLength, &foundId,
&foundLen);
switch (result) {
case RETURN_OK:
handleReply(receivedData, foundId, foundLen);
break;
case APERIODIC_REPLY: {
result = interpretDeviceReply(foundId, receivedData);
if (result != RETURN_OK) {
replyRawReplyIfnotWiretapped(receivedData, foundLen);
triggerEvent(DEVICE_INTERPRETING_REPLY_FAILED, result,
foundId);
}
}
break;
case IGNORE_REPLY_DATA:
break;
default:
//We need to wait for timeout.. don't know what command failed and who sent it.
replyRawReplyIfnotWiretapped(receivedData, foundLen);
triggerEvent(DEVICE_READING_REPLY_FAILED, result, foundLen);
break;
}
receivedData += foundLen;
if (remainingLength > foundLen) {
remainingLength -= foundLen;
} else {
return;
}
}
}
}
ReturnValue_t DeviceHandlerBase::getStorageData(store_address_t storageAddress,
uint8_t * *data, uint32_t * len) {
uint32_t lenTmp;
if (IPCStore == NULL) {
*data = NULL;
*len = 0;
return RETURN_FAILED;
}
ReturnValue_t result = IPCStore->modifyData(storageAddress, data, &lenTmp);
if (result == RETURN_OK) {
*len = lenTmp;
return RETURN_OK;
} else {
triggerEvent(StorageManagerIF::GET_DATA_FAILED, result,
storageAddress.raw);
*data = NULL;
*len = 0;
return result;
}
}
ReturnValue_t DeviceHandlerBase::initialize() {
ReturnValue_t result = SystemObject::initialize();
if (result != RETURN_OK) {
return result;
}
communicationInterface = objectManager->get<DeviceCommunicationIF>(
deviceCommunicationId);
if (communicationInterface == NULL) {
return RETURN_FAILED;
}
result = communicationInterface->open(&cookie, ioBoardAddress,
maxDeviceReplyLen);
if (result != RETURN_OK) {
return result;
}
IPCStore = objectManager->get<StorageManagerIF>(objects::IPC_STORE);
if (IPCStore == NULL) {
return RETURN_FAILED;
}
AcceptsDeviceResponsesIF *rawReceiver = objectManager->get<
AcceptsDeviceResponsesIF>(rawDataReceiverId);
if (rawReceiver == NULL) {
return RETURN_FAILED;
}
defaultRawReceiver = rawReceiver->getDeviceQueue();
powerSwitcher = objectManager->get<PowerSwitchIF>(powerSwitcherId);
if (powerSwitcher == NULL) {
return RETURN_FAILED;
}
result = healthHelper.initialize();
if (result != RETURN_OK) {
return result;
}
result = modeHelper.initialize();
if (result != RETURN_OK) {
return result;
}
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result = actionHelper.initialize(commandQueue);
if (result != RETURN_OK) {
return result;
}
result = fdirInstance->initialize();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
result = parameterHelper.initialize();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
result = hkSwitcher.initialize();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
fillCommandAndReplyMap();
//Set temperature target state to NON_OP.
DataSet mySet;
PoolVariable<int8_t> thermalRequest(deviceThermalRequestPoolId, &mySet,
PoolVariableIF::VAR_WRITE);
mySet.read();
thermalRequest = ThermalComponentIF::STATE_REQUEST_NON_OPERATIONAL;
mySet.commit(PoolVariableIF::VALID);
return RETURN_OK;
}
void DeviceHandlerBase::replyRawData(const uint8_t *data, size_t len,
MessageQueueId_t sendTo, bool isCommand) {
if (IPCStore == NULL || len == 0) {
return;
}
store_address_t address;
ReturnValue_t result = IPCStore->addData(&address, data, len);
if (result != RETURN_OK) {
triggerEvent(StorageManagerIF::STORE_DATA_FAILED, result);
return;
}
CommandMessage message;
DeviceHandlerMessage::setDeviceHandlerRawReplyMessage(&message,
getObjectId(), address, isCommand);
// this->DeviceHandlerCommand = CommandMessage::CMD_NONE;
result = commandQueue->sendMessage(sendTo, &message);
if (result != RETURN_OK) {
IPCStore->deleteData(address);
//Silently discard data, this indicates heavy TM traffic which should not be increased by additional events.
}
}
//Default child implementations
DeviceHandlerBase::RmapAction_t DeviceHandlerBase::getRmapAction() {
switch (pstStep) {
case 0:
return SEND_WRITE;
break;
case 1:
return GET_WRITE;
break;
case 2:
return SEND_READ;
break;
case 3:
return GET_READ;
break;
default:
break;
}
return NOTHING;
}
MessageQueueId_t DeviceHandlerBase::getCommandQueue() const {
return commandQueue->getId();
}
void DeviceHandlerBase::handleReply(const uint8_t* receivedData,
DeviceCommandId_t foundId, uint32_t foundLen) {
ReturnValue_t result;
DeviceReplyMap::iterator iter = deviceReplyMap.find(foundId);
if (iter == deviceReplyMap.end()) {
replyRawReplyIfnotWiretapped(receivedData, foundLen);
triggerEvent(DEVICE_UNKNOWN_REPLY, foundId);
return;
}
DeviceReplyInfo *info = &(iter->second);
if (info->delayCycles != 0) {
if (info->periodic != 0) {
info->delayCycles = info->maxDelayCycles;
} else {
info->delayCycles = 0;
}
result = interpretDeviceReply(foundId, receivedData);
if (result != RETURN_OK) {
//Report failed interpretation to FDIR.
replyRawReplyIfnotWiretapped(receivedData, foundLen);
triggerEvent(DEVICE_INTERPRETING_REPLY_FAILED, result, foundId);
}
replyToReply(iter, result);
} else {
//Other completion failure messages are created by timeout.
//Powering down the device might take some time during which periodic replies may still come in.
if (mode != _MODE_WAIT_OFF) {
triggerEvent(DEVICE_UNREQUESTED_REPLY, foundId);
}
}
}
ReturnValue_t DeviceHandlerBase::switchCookieChannel(object_id_t newChannelId) {
DeviceCommunicationIF *newCommunication = objectManager->get<
DeviceCommunicationIF>(newChannelId);
if (newCommunication != NULL) {
ReturnValue_t result = newCommunication->reOpen(cookie, ioBoardAddress,
maxDeviceReplyLen);
if (result != RETURN_OK) {
return result;
}
return RETURN_OK;
}
return RETURN_FAILED;
}
void DeviceHandlerBase::buildRawDeviceCommand(CommandMessage* commandMessage) {
storedRawData = DeviceHandlerMessage::getStoreAddress(commandMessage);
ReturnValue_t result = getStorageData(storedRawData, &rawPacket,
&rawPacketLen);
if (result != RETURN_OK) {
replyReturnvalueToCommand(result, RAW_COMMAND_ID);
storedRawData.raw = StorageManagerIF::INVALID_ADDRESS;
} else {
cookieInfo.pendingCommand = deviceCommandMap.find(
(DeviceCommandId_t) RAW_COMMAND_ID);
cookieInfo.pendingCommand->second.isExecuting = true;
cookieInfo.state = COOKIE_WRITE_READY;
}
}
void DeviceHandlerBase::commandSwitch(ReturnValue_t onOff) {
const uint8_t *switches;
uint8_t numberOfSwitches = 0;
ReturnValue_t result = getSwitches(&switches, &numberOfSwitches);
if (result == RETURN_OK) {
while (numberOfSwitches > 0) {
powerSwitcher->sendSwitchCommand(switches[numberOfSwitches - 1],
onOff);
numberOfSwitches--;
}
}
}
ReturnValue_t DeviceHandlerBase::getSwitches(const uint8_t **switches,
uint8_t *numberOfSwitches) {
*switches = &deviceSwitch;
*numberOfSwitches = 1;
return RETURN_OK;
}
void DeviceHandlerBase::modeChanged(void) {
}
ReturnValue_t DeviceHandlerBase::enableReplyInReplyMap(
DeviceCommandMap::iterator command, uint8_t expectedReplies,
bool useAlternativeId, DeviceCommandId_t alternativeReply) {
DeviceReplyMap::iterator iter;
if (useAlternativeId) {
iter = deviceReplyMap.find(alternativeReply);
} else {
iter = deviceReplyMap.find(command->first);
}
if (iter != deviceReplyMap.end()) {
DeviceReplyInfo *info = &(iter->second);
info->delayCycles = info->maxDelayCycles;
info->command = command;
command->second.expectedReplies = expectedReplies;
return RETURN_OK;
} else {
return NO_REPLY_EXPECTED;
}
}
void DeviceHandlerBase::doTransition(Mode_t modeFrom, Submode_t subModeFrom) {
setMode(getBaseMode(mode));
}
uint32_t DeviceHandlerBase::getTransitionDelayMs(Mode_t modeFrom,
Mode_t modeTo) {
return 0;
}
ReturnValue_t DeviceHandlerBase::getStateOfSwitches(void) {
uint8_t numberOfSwitches = 0;
const uint8_t *switches;
ReturnValue_t result = getSwitches(&switches, &numberOfSwitches);
if ((result == RETURN_OK) && (numberOfSwitches != 0)) {
while (numberOfSwitches > 0) {
if (powerSwitcher->getSwitchState(switches[numberOfSwitches - 1])
== PowerSwitchIF::SWITCH_OFF) {
return PowerSwitchIF::SWITCH_OFF;
}
numberOfSwitches--;
}
return PowerSwitchIF::SWITCH_ON;
}
return NO_SWITCH;
}
Mode_t DeviceHandlerBase::getBaseMode(Mode_t transitionMode) {
//only child action special modes are handled, as a child should never see any base action modes
if (transitionMode == _MODE_START_UP) {
return _MODE_TO_ON;
}
if (transitionMode == _MODE_SHUT_DOWN) {
return _MODE_POWER_DOWN;
}
return transitionMode
& ~(TRANSITION_MODE_BASE_ACTION_MASK
| TRANSITION_MODE_CHILD_ACTION_MASK);
}
//SHOULDDO: Allow transition from OFF to NORMAL to reduce complexity in assemblies. And, by the way, throw away DHB and write a new one:
// - Include power and thermal completely, but more modular :-)
// - Don't use modes for state transitions, reduce FSM (Finte State Machine) complexity.
// - Modularization?
ReturnValue_t DeviceHandlerBase::checkModeCommand(Mode_t commandedMode,
Submode_t commandedSubmode, uint32_t* msToReachTheMode) {
if (isTransitionalMode()) {
return IN_TRANSITION;
}
if ((mode == MODE_ERROR_ON) && (commandedMode != MODE_OFF)) {
return TRANS_NOT_ALLOWED;
}
if ((commandedMode == MODE_NORMAL) && (mode == MODE_OFF)) {
return TRANS_NOT_ALLOWED;
}
if ((commandedMode == MODE_ON) && (mode == MODE_OFF)
&& (deviceThermalStatePoolId != PoolVariableIF::NO_PARAMETER)) {
DataSet mySet;
PoolVariable<int8_t> thermalState(deviceThermalStatePoolId, &mySet,
PoolVariableIF::VAR_READ);
PoolVariable<int8_t> thermalRequest(deviceThermalRequestPoolId, &mySet,
PoolVariableIF::VAR_READ);
mySet.read();
if (thermalRequest != ThermalComponentIF::STATE_REQUEST_IGNORE) {
if (!ThermalComponentIF::isOperational(thermalState)) {
triggerEvent(ThermalComponentIF::TEMP_NOT_IN_OP_RANGE,
thermalState);
return NON_OP_TEMPERATURE;
}
}
}
return isModeCombinationValid(commandedMode, commandedSubmode);
}
void DeviceHandlerBase::startTransition(Mode_t commandedMode,
Submode_t commandedSubmode) {
switch (commandedMode) {
case MODE_ON:
if (mode == MODE_OFF) {
transitionSourceMode = _MODE_POWER_DOWN;
transitionSourceSubMode = SUBMODE_NONE;
setMode(_MODE_POWER_ON, commandedSubmode);
//already set the delay for the child transition so we don't need to call it twice
childTransitionDelay = getTransitionDelayMs(_MODE_START_UP,
MODE_ON);
triggerEvent(CHANGING_MODE, commandedMode, commandedSubmode);
DataSet mySet;
PoolVariable<int8_t> thermalRequest(deviceThermalRequestPoolId,
&mySet, PoolVariableIF::VAR_READ_WRITE);
mySet.read();
if (thermalRequest != ThermalComponentIF::STATE_REQUEST_IGNORE) {
thermalRequest = ThermalComponentIF::STATE_REQUEST_OPERATIONAL;
mySet.commit(PoolVariableIF::VALID);
}
} else {
setTransition(MODE_ON, commandedSubmode);
}
break;
case MODE_OFF:
if (mode == MODE_OFF) {
triggerEvent(CHANGING_MODE, commandedMode, commandedSubmode);
setMode(_MODE_POWER_DOWN, commandedSubmode);
} else {
//already set the delay for the child transition so we don't need to call it twice
childTransitionDelay = getTransitionDelayMs(mode, _MODE_POWER_DOWN);
transitionSourceMode = _MODE_POWER_DOWN;
transitionSourceSubMode = commandedSubmode;
childTransitionFailure = CHILD_TIMEOUT;
setMode(_MODE_SHUT_DOWN, commandedSubmode);
triggerEvent(CHANGING_MODE, commandedMode, commandedSubmode);
}
break;
case MODE_RAW:
if (mode != MODE_OFF) {
setTransition(MODE_RAW, commandedSubmode);
} else {
setMode(MODE_RAW, commandedSubmode);
}
break;
case MODE_NORMAL:
if (mode != MODE_OFF) {
setTransition(MODE_NORMAL, commandedSubmode);
} else {
replyReturnvalueToCommand(HasModesIF::TRANS_NOT_ALLOWED);
}
break;
}
}
void DeviceHandlerBase::getMode(Mode_t* mode, Submode_t* submode) {
*mode = this->mode;
*submode = this->submode;
}
void DeviceHandlerBase::setToExternalControl() {
healthHelper.setHealth(EXTERNAL_CONTROL);
}
void DeviceHandlerBase::announceMode(bool recursive) {
triggerEvent(MODE_INFO, mode, submode);
}
bool DeviceHandlerBase::dontCheckQueue() {
return false;
}
void DeviceHandlerBase::missedReply(DeviceCommandId_t id) {
if (ignoreMissedRepliesCount > 0) {
ignoreMissedRepliesCount--;
} else {
triggerEvent(DEVICE_MISSED_REPLY, id);
}
}
HasHealthIF::HealthState DeviceHandlerBase::getHealth() {
return healthHelper.getHealth();
}
ReturnValue_t DeviceHandlerBase::setHealth(HealthState health) {
healthHelper.setHealth(health);
return HasReturnvaluesIF::RETURN_OK;
}
void DeviceHandlerBase::checkSwitchState() {
if ((mode == MODE_ON || mode == MODE_NORMAL)) {
//We only check in ON and NORMAL, ignore RAW and ERROR_ON.
ReturnValue_t result = getStateOfSwitches();
if (result == PowerSwitchIF::SWITCH_OFF && !switchOffWasReported) {
triggerEvent(PowerSwitchIF::SWITCH_WENT_OFF);
switchOffWasReported = true;
}
} else {
switchOffWasReported = false;
}
}
void DeviceHandlerBase::doOnActivity() {
}
ReturnValue_t DeviceHandlerBase::acceptExternalDeviceCommands() {
if ((mode != MODE_ON) && (mode != MODE_NORMAL)) {
return WRONG_MODE_FOR_COMMAND;
}
return RETURN_OK;
}
void DeviceHandlerBase::replyRawReplyIfnotWiretapped(const uint8_t* data,
size_t len) {
if ((wiretappingMode == RAW)
&& (defaultRawReceiver == requestedRawTraffic)) {
//The raw packet was already sent by the wiretapping service
} else {
replyRawData(data, len, defaultRawReceiver);
}
}
ReturnValue_t DeviceHandlerBase::handleDeviceHandlerMessage(
CommandMessage * message) {
ReturnValue_t result;
switch (message->getCommand()) {
case DeviceHandlerMessage::CMD_WIRETAPPING:
switch (DeviceHandlerMessage::getWiretappingMode(message)) {
case RAW:
wiretappingMode = RAW;
requestedRawTraffic = commandQueue->getLastPartner();
break;
case TM:
wiretappingMode = TM;
requestedRawTraffic = commandQueue->getLastPartner();
break;
case OFF:
wiretappingMode = OFF;
break;
default:
replyReturnvalueToCommand(INVALID_COMMAND_PARAMETER);
wiretappingMode = OFF;
return RETURN_OK;
}
replyReturnvalueToCommand(RETURN_OK);
return RETURN_OK;
case DeviceHandlerMessage::CMD_SWITCH_IOBOARD:
if (mode != MODE_OFF) {
replyReturnvalueToCommand(WRONG_MODE_FOR_COMMAND);
} else {
result = switchCookieChannel(
DeviceHandlerMessage::getIoBoardObjectId(message));
if (result == RETURN_OK) {
replyReturnvalueToCommand(RETURN_OK);
} else {
replyReturnvalueToCommand(CANT_SWITCH_IOBOARD);
}
}
return RETURN_OK;
case DeviceHandlerMessage::CMD_RAW:
if ((mode != MODE_RAW)) {
DeviceHandlerMessage::clear(message);
replyReturnvalueToCommand(WRONG_MODE_FOR_COMMAND);
} else {
buildRawDeviceCommand(message);
}
return RETURN_OK;
default:
return RETURN_FAILED;
}
}
void DeviceHandlerBase::setParentQueue(MessageQueueId_t parentQueueId) {
modeHelper.setParentQueue(parentQueueId);
healthHelper.setParentQeueue(parentQueueId);
}
bool DeviceHandlerBase::isAwaitingReply() {
std::map<DeviceCommandId_t, DeviceReplyInfo>::iterator iter;
for (iter = deviceReplyMap.begin(); iter != deviceReplyMap.end(); ++iter) {
if (iter->second.delayCycles != 0) {
return true;
}
}
return false;
}
ReturnValue_t DeviceHandlerBase::letChildHandleMessage(
CommandMessage * message) {
return RETURN_FAILED;
}
void DeviceHandlerBase::handleDeviceTM(SerializeIF* data,
DeviceCommandId_t replyId, bool neverInDataPool, bool forceDirectTm) {
DeviceReplyMap::iterator iter = deviceReplyMap.find(replyId);
if (iter == deviceReplyMap.end()) {
triggerEvent(DEVICE_UNKNOWN_REPLY, replyId);
return;
}
DeviceTmReportingWrapper wrapper(getObjectId(), replyId, data);
if (iter->second.command != deviceCommandMap.end()) {//replies to a command
MessageQueueId_t queueId = iter->second.command->second.sendReplyTo;
if (queueId != NO_COMMANDER) {
//This may fail, but we'll ignore the fault.
actionHelper.reportData(queueId, replyId, data);
}
//This check should make sure we get any TM but don't get anything doubled.
if (wiretappingMode == TM && (requestedRawTraffic != queueId)) {
actionHelper.reportData(requestedRawTraffic, replyId, &wrapper);
} else if (forceDirectTm && (defaultRawReceiver != queueId)) {
// hiding of sender needed so the service will handle it as unexpected Data, no matter what state
//(progress or completed) it is in
actionHelper.reportData(defaultRawReceiver, replyId, &wrapper,
true);
}
} else { //unrequested/aperiodic replies
if (wiretappingMode == TM) {
actionHelper.reportData(requestedRawTraffic, replyId, &wrapper);
} else if (forceDirectTm) {
// hiding of sender needed so the service will handle it as unexpected Data, no matter what state
//(progress or completed) it is in
actionHelper.reportData(defaultRawReceiver, replyId, &wrapper,
true);
}
}
//Try to cast to DataSet and commit data.
if (!neverInDataPool) {
DataSet* dataSet = dynamic_cast<DataSet*>(data);
if (dataSet != NULL) {
dataSet->commit(PoolVariableIF::VALID);
}
}
}
ReturnValue_t DeviceHandlerBase::executeAction(ActionId_t actionId,
MessageQueueId_t commandedBy, const uint8_t* data, uint32_t size) {
ReturnValue_t result = acceptExternalDeviceCommands();
if (result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
DeviceCommandMap::iterator iter = deviceCommandMap.find(actionId);
if (iter == deviceCommandMap.end()) {
result = COMMAND_NOT_SUPPORTED;
} else if (iter->second.isExecuting) {
result = COMMAND_ALREADY_SENT;
} else {
result = buildCommandFromCommand(actionId, data, size);
}
if (result == RETURN_OK) {
iter->second.sendReplyTo = commandedBy;
iter->second.isExecuting = true;
cookieInfo.pendingCommand = iter;
cookieInfo.state = COOKIE_WRITE_READY;
}
return result;
}
void DeviceHandlerBase::buildInternalCommand(void) {
//Neither Raw nor Direct could build a command
ReturnValue_t result = NOTHING_TO_SEND;
DeviceCommandId_t deviceCommandId = NO_COMMAND_ID;
if (mode == MODE_NORMAL) {
result = buildNormalDeviceCommand(&deviceCommandId);
if (result == BUSY) {
sif::debug << std::hex << getObjectId()
<< ": DHB::buildInternalCommand busy" << std::endl; //so we can track misconfigurations
result = NOTHING_TO_SEND; //no need to report this
}
} else if (mode == MODE_RAW) {
result = buildChildRawCommand();
deviceCommandId = RAW_COMMAND_ID;
} else if (mode & TRANSITION_MODE_CHILD_ACTION_MASK) {
result = buildTransitionDeviceCommand(&deviceCommandId);
} else {
return;
}
if (result == NOTHING_TO_SEND) {
return;
}
if (result == RETURN_OK) {
DeviceCommandMap::iterator iter = deviceCommandMap.find(
deviceCommandId);
if (iter == deviceCommandMap.end()) {
result = COMMAND_NOT_SUPPORTED;
} else if (iter->second.isExecuting) {
sif::debug << std::hex << getObjectId()
<< ": DHB::buildInternalCommand: Command "
<< deviceCommandId << " isExecuting" << std::endl; //so we can track misconfigurations
return; //this is an internal command, no need to report a failure here, missed reply will track if a reply is too late, otherwise, it's ok
} else {
iter->second.sendReplyTo = NO_COMMANDER;
iter->second.isExecuting = true;
cookieInfo.pendingCommand = iter;
cookieInfo.state = COOKIE_WRITE_READY;
}
}
if (result != RETURN_OK) {
triggerEvent(DEVICE_BUILDING_COMMAND_FAILED, result, deviceCommandId);
}
}
ReturnValue_t DeviceHandlerBase::buildChildRawCommand() {
return NOTHING_TO_SEND;
}
uint8_t DeviceHandlerBase::getReplyDelayCycles(
DeviceCommandId_t deviceCommand) {
DeviceReplyMap::iterator iter = deviceReplyMap.find(deviceCommand);
if (iter == deviceReplyMap.end()) {
return 0;
}
return iter->second.delayCycles;
}
Mode_t DeviceHandlerBase::getTransitionSourceMode() const {
return transitionSourceMode;
}
Submode_t DeviceHandlerBase::getTransitionSourceSubMode() const {
return transitionSourceSubMode;
}
void DeviceHandlerBase::triggerEvent(Event event, uint32_t parameter1,
uint32_t parameter2) {
fdirInstance->triggerEvent(event, parameter1, parameter2);
}
void DeviceHandlerBase::forwardEvent(Event event, uint32_t parameter1,
uint32_t parameter2) const {
fdirInstance->triggerEvent(event, parameter1, parameter2);
}
void DeviceHandlerBase::doOffActivity() {
}
ReturnValue_t DeviceHandlerBase::getParameter(uint8_t domainId,
uint16_t parameterId, ParameterWrapper* parameterWrapper,
const ParameterWrapper* newValues, uint16_t startAtIndex) {
ReturnValue_t result = fdirInstance->getParameter(domainId, parameterId,
parameterWrapper, newValues, startAtIndex);
if (result != INVALID_DOMAIN_ID) {
return result;
}
return INVALID_DOMAIN_ID;
}
bool DeviceHandlerBase::isTransitionalMode() {
return ((mode
& (TRANSITION_MODE_BASE_ACTION_MASK
| TRANSITION_MODE_CHILD_ACTION_MASK)) != 0);
}
bool DeviceHandlerBase::commandIsExecuting(DeviceCommandId_t commandId) {
auto iter = deviceCommandMap.find(commandId);
if (iter != deviceCommandMap.end()) {
return iter->second.isExecuting;
} else {
return false;
}
}
void DeviceHandlerBase::changeHK(Mode_t mode, Submode_t submode, bool enable) {
}
2018-07-13 18:28:26 +02:00
void DeviceHandlerBase::setTaskIF(PeriodicTaskIF* task_){
executingTask = task_;
}