eive-obsw/mission/cfdp/CfdpHandler.cpp

#include "CfdpHandler.h"

#include <fsfw/cfdp/CfdpMessage.h>
#include <fsfw/ipc/CommandMessage.h>

#include "fsfw/cfdp/pdu/AckPduReader.h"
#include "fsfw/cfdp/pdu/PduHeaderReader.h"
#include "fsfw/globalfunctions/arrayprinter.h"
#include "fsfw/ipc/QueueFactory.h"
#include "fsfw/tmtcservices/TmTcMessage.h"

using namespace returnvalue;
using namespace cfdp;

CfdpHandler::CfdpHandler(const FsfwHandlerParams& fsfwHandlerParams, const CfdpHandlerCfg& cfdpCfg)
    : SystemObject(fsfwHandlerParams.objectId),
      pduQueue(fsfwHandlerParams.tmtcQueue),
      cfdpRequestQueue(fsfwHandlerParams.cfdpQueue),
      localCfg(cfdpCfg.id, cfdpCfg.indicCfg, cfdpCfg.faultHandler),
      remoteCfgProvider(cfdpCfg.remoteCfgProvider),
      fsfwParams(fsfwHandlerParams.packetDest, &fsfwHandlerParams.tmtcQueue, this,
                 fsfwHandlerParams.tcStore, fsfwHandlerParams.tmStore),
      destHandler(DestHandlerParams(localCfg, cfdpCfg.userHandler, cfdpCfg.remoteCfgProvider,
                                    cfdpCfg.packetInfoList, cfdpCfg.lostSegmentsList),
                  this->fsfwParams),
      srcHandler(SourceHandlerParams(localCfg, cfdpCfg.userHandler, seqCntProvider),
                 this->fsfwParams),
      ipcStore(fsfwHandlerParams.ipcStore) {}

[[nodiscard]] const char* CfdpHandler::getName() const { return "CFDP Handler"; }

[[nodiscard]] uint32_t CfdpHandler::getIdentifier() const {
  return destHandler.getDestHandlerParams().cfg.localId.getValue();
}

[[nodiscard]] MessageQueueId_t CfdpHandler::getRequestQueue() const { return pduQueue.getId(); }

ReturnValue_t CfdpHandler::initialize() {
  ReturnValue_t result = destHandler.initialize();
  if (result != OK) {
    return result;
  }
  tcStore = destHandler.getTcStore();
  tmStore = destHandler.getTmStore();

  return SystemObject::initialize();
}

ReturnValue_t CfdpHandler::performOperation(uint8_t operationCode) {
  ReturnValue_t status = OK;
  ReturnValue_t result = handlePduPacketMessages();
  if (result != OK) {
    status = result;
  }
  result = handleCfdpMessages();
  if (result != OK) {
    status = result;
  }
  const DestHandler::FsmResult& destResult = destHandler.stateMachine();
  // TODO: Error handling?
  while (destResult.callStatus == CallStatus::CALL_AGAIN) {
    destHandler.stateMachine();
    // TODO: Error handling?
  }
  const SourceHandler::FsmResult& srcResult = srcHandler.stateMachine();
  while (srcResult.callStatus == CallStatus::CALL_AGAIN) {
    srcHandler.stateMachine();
  }
  return status;
}

ReturnValue_t CfdpHandler::handlePduPacket(TmTcMessage& msg) {
  auto accessorPair = tcStore->getData(msg.getStorageId());
  if (accessorPair.first != OK) {
    return accessorPair.first;
  }
  PduHeaderReader reader(accessorPair.second.data(), accessorPair.second.size());
  ReturnValue_t result = reader.parseData();
  if (result != returnvalue::OK) {
    return INVALID_PDU_FORMAT;
  }
  // The CFDP distributor should have taken care of ensuring the destination ID is correct
  PduType type = reader.getPduType();
  // Only the destination handler can process these PDUs
  if (type == PduType::FILE_DATA) {
    // Disable auto-deletion of packet
    accessorPair.second.release();
    PacketInfo info(type, msg.getStorageId());
    result = destHandler.passPacket(info);
  } else {
    // Route depending on PDU type and directive type if applicable. It retrieves directive type
    // from the raw stream for better performance (with sanity and directive code check).
    // The routing is based on section 4.5 of the CFDP standard which specifies the PDU forwarding
    // procedure.

    // PDU header only. Invalid supplied data. A directive packet should have a valid data field
    // with at least one byte being the directive code
    const uint8_t* pduDataField = reader.getPduDataField();
    if (pduDataField == nullptr) {
      return INVALID_PDU_FORMAT;
    }
    if (not FileDirectiveReader::checkFileDirective(pduDataField[0])) {
      sif::error << "CfdpHandler: Invalid PDU directive field " << static_cast<int>(pduDataField[0])
                 << std::endl;
      return INVALID_DIRECTIVE_FIELD;
    }
    auto directive = static_cast<FileDirective>(pduDataField[0]);

    auto passToDestHandler = [&]() {
      accessorPair.second.release();
      PacketInfo info(type, msg.getStorageId(), directive);
      result = destHandler.passPacket(info);
    };
    auto passToSourceHandler = [&]() {

    };
    if (directive == FileDirective::METADATA or directive == FileDirective::EOF_DIRECTIVE or
        directive == FileDirective::PROMPT) {
      // Section b) of 4.5.3: These PDUs should always be targeted towards the file receiver a.k.a.
      // the destination handler
      passToDestHandler();
    } else if (directive == FileDirective::FINISH or directive == FileDirective::NAK or
               directive == FileDirective::KEEP_ALIVE) {
      // Section c) of 4.5.3: These PDUs should always be targeted towards the file sender a.k.a.
      // the source handler
      passToSourceHandler();
    } else if (directive == FileDirective::ACK) {
      // Section a): Recipient depends of the type of PDU that is being acknowledged. We can simply
      // extract the PDU type from the raw stream. If it is an EOF PDU, this packet is passed to
      // the source handler, for a Finished PDU, it is passed to the destination handler.
      FileDirective ackedDirective;
      if (not AckPduReader::checkAckedDirectiveField(pduDataField[1], ackedDirective)) {
        return INVALID_ACK_DIRECTIVE_FIELDS;
      }
      if (ackedDirective == FileDirective::EOF_DIRECTIVE) {
        passToSourceHandler();
      } else if (ackedDirective == FileDirective::FINISH) {
        passToDestHandler();
      }
    }
  }
  return result;
}

ReturnValue_t CfdpHandler::handleCfdpRequest(CommandMessage& msg) {
  // TODO: Handle CFDP requests here, most importantly put requests. If a put request is received,
  //       check whether one is pending. If none are, start a transaction with the put request,
  //       otherwise store for put request inside a FIFO for later processing.
  if (msg.getCommand() == CfdpMessage::PUT_REQUEST) {
    sif::info << "Received CFDP put request" << std::endl;
    if (srcHandler.getState() != CfdpState::IDLE) {
      if (putRequestQueue.full()) {
        // TODO: Trigger event and discard request. Queue is full, too many requests.
        return FAILED;
      }
      putRequestQueue.push(CfdpMessage::getStoreId(&msg));
    } else {
      // TODO: Retrieve put request and remote configuration.
      PutRequest putRequest;
      auto accessorPair = ipcStore.getData(CfdpMessage::getStoreId(&msg));
      const uint8_t* dataPtr = accessorPair.second.data();
      size_t dataSize = accessorPair.second.size();
      ReturnValue_t result =
          putRequest.deSerialize(&dataPtr, &dataSize, SerializeIF::Endianness::MACHINE);
      if (result != OK) {
        return result;
      }
      RemoteEntityCfg* remoteCfg;
      remoteCfgProvider.getRemoteCfg(putRequest.getDestId(), &remoteCfg);
      if (remoteCfg == nullptr) {
        sif::error << "CfdpHandler: No remote configuration found for destination ID "
                   << putRequest.getDestId() << std::endl;
        // TODO: Trigger event
        return FAILED;
      }
      sif::info << "Starting file copy operation for source file "
                << putRequest.getSourceName().getString() << " and dest file "
                << putRequest.getDestName().getString() << std::endl;
      return srcHandler.transactionStart(putRequest, *remoteCfg);
    }
  }
  return OK;
}

ReturnValue_t CfdpHandler::handlePduPacketMessages() {
  ReturnValue_t status;
  ReturnValue_t result = OK;
  TmTcMessage pduMsg;
  for (status = pduQueue.receiveMessage(&pduMsg); status == returnvalue::OK;
       status = pduQueue.receiveMessage(&pduMsg)) {
    result = handlePduPacket(pduMsg);
    if (result != OK) {
      // TODO: Maybe add printout with context specific information?
      status = result;
    }
  }
  return status;
}

ReturnValue_t CfdpHandler::handleCfdpMessages() {
  ReturnValue_t status;
  ReturnValue_t result;
  CommandMessage cfdpMsg;
  for (status = cfdpRequestQueue.receiveMessage(&cfdpMsg); status == returnvalue::OK;
       status = cfdpRequestQueue.receiveMessage(&cfdpMsg)) {
    result = handleCfdpRequest(cfdpMsg);
    if (result != OK) {
      sif::warning << "Handling CFDP request failed with code 0x" << std::setw(4) << std::hex
                   << result << std::dec << std::endl;
      triggerEvent(cfdp::events::HANDLING_CFDP_REQUEST_FAILED, 0, result);
      // TODO: Maybe add printout with context specific information?
      status = result;
    }
  }
  return status;
}
move cfdp handler 2023-04-11 16:51:49 +02:00			`#include "CfdpHandler.h"`

proxy request should now arrive at the handler 2023-08-16 13:22:05 +02:00			`#include <fsfw/cfdp/CfdpMessage.h>`
clean up handler a bit 2023-08-14 21:22:01 +02:00			`#include <fsfw/ipc/CommandMessage.h>`

move cfdp handler 2023-04-11 16:51:49 +02:00			`#include "fsfw/cfdp/pdu/AckPduReader.h"`
			`#include "fsfw/cfdp/pdu/PduHeaderReader.h"`
			`#include "fsfw/globalfunctions/arrayprinter.h"`
			`#include "fsfw/ipc/QueueFactory.h"`
			`#include "fsfw/tmtcservices/TmTcMessage.h"`

			`using namespace returnvalue;`
			`using namespace cfdp;`

instantiated source handler 2023-08-14 16:29:51 +02:00			`CfdpHandler::CfdpHandler(const FsfwHandlerParams& fsfwHandlerParams, const CfdpHandlerCfg& cfdpCfg)`
			`: SystemObject(fsfwHandlerParams.objectId),`
better naming 2023-08-14 21:06:49 +02:00			`pduQueue(fsfwHandlerParams.tmtcQueue),`
continue source handler integration 2023-08-14 20:48:37 +02:00			`cfdpRequestQueue(fsfwHandlerParams.cfdpQueue),`
instantiated source handler 2023-08-14 16:29:51 +02:00			`localCfg(cfdpCfg.id, cfdpCfg.indicCfg, cfdpCfg.faultHandler),`
that should cause a transaction start 2023-08-30 11:58:21 +02:00			`remoteCfgProvider(cfdpCfg.remoteCfgProvider),`
continue source handler integration 2023-08-14 20:48:37 +02:00			`fsfwParams(fsfwHandlerParams.packetDest, &fsfwHandlerParams.tmtcQueue, this,`
instantiated source handler 2023-08-14 16:29:51 +02:00			`fsfwHandlerParams.tcStore, fsfwHandlerParams.tmStore),`
			`destHandler(DestHandlerParams(localCfg, cfdpCfg.userHandler, cfdpCfg.remoteCfgProvider,`
			`cfdpCfg.packetInfoList, cfdpCfg.lostSegmentsList),`
			`this->fsfwParams),`
			`srcHandler(SourceHandlerParams(localCfg, cfdpCfg.userHandler, seqCntProvider),`
proxy request should now arrive at the handler 2023-08-16 13:22:05 +02:00			`this->fsfwParams),`
			`ipcStore(fsfwHandlerParams.ipcStore) {}`
move cfdp handler 2023-04-11 16:51:49 +02:00
			`[[nodiscard]] const char* CfdpHandler::getName() const { return "CFDP Handler"; }`

			`[[nodiscard]] uint32_t CfdpHandler::getIdentifier() const {`
			`return destHandler.getDestHandlerParams().cfg.localId.getValue();`
			`}`

better naming 2023-08-14 21:06:49 +02:00			`[[nodiscard]] MessageQueueId_t CfdpHandler::getRequestQueue() const { return pduQueue.getId(); }`
move cfdp handler 2023-04-11 16:51:49 +02:00
			`ReturnValue_t CfdpHandler::initialize() {`
			`ReturnValue_t result = destHandler.initialize();`
			`if (result != OK) {`
			`return result;`
			`}`
			`tcStore = destHandler.getTcStore();`
			`tmStore = destHandler.getTmStore();`

			`return SystemObject::initialize();`
			`}`

			`ReturnValue_t CfdpHandler::performOperation(uint8_t operationCode) {`
clean up handler a bit 2023-08-14 21:22:01 +02:00			`ReturnValue_t status = OK;`
			`ReturnValue_t result = handlePduPacketMessages();`
			`if (result != OK) {`
			`status = result;`
			`}`
			`result = handleCfdpMessages();`
			`if (result != OK) {`
			`status = result;`
move cfdp handler 2023-04-11 16:51:49 +02:00			`}`
continue source handler integration 2023-08-14 20:48:37 +02:00			`const DestHandler::FsmResult& destResult = destHandler.stateMachine();`
move cfdp handler 2023-04-11 16:51:49 +02:00			`// TODO: Error handling?`
continue source handler integration 2023-08-14 20:48:37 +02:00			`while (destResult.callStatus == CallStatus::CALL_AGAIN) {`
			`destHandler.stateMachine();`
move cfdp handler 2023-04-11 16:51:49 +02:00			`// TODO: Error handling?`
			`}`
continue source handler integration 2023-08-14 20:48:37 +02:00			`const SourceHandler::FsmResult& srcResult = srcHandler.stateMachine();`
			`while (srcResult.callStatus == CallStatus::CALL_AGAIN) {`
			`srcHandler.stateMachine();`
			`}`
move cfdp handler 2023-04-11 16:51:49 +02:00			`return status;`
			`}`

better naming 2023-08-14 21:06:49 +02:00			`ReturnValue_t CfdpHandler::handlePduPacket(TmTcMessage& msg) {`
move cfdp handler 2023-04-11 16:51:49 +02:00			`auto accessorPair = tcStore->getData(msg.getStorageId());`
			`if (accessorPair.first != OK) {`
			`return accessorPair.first;`
			`}`
			`PduHeaderReader reader(accessorPair.second.data(), accessorPair.second.size());`
			`ReturnValue_t result = reader.parseData();`
			`if (result != returnvalue::OK) {`
			`return INVALID_PDU_FORMAT;`
			`}`
			`// The CFDP distributor should have taken care of ensuring the destination ID is correct`
			`PduType type = reader.getPduType();`
			`// Only the destination handler can process these PDUs`
			`if (type == PduType::FILE_DATA) {`
			`// Disable auto-deletion of packet`
			`accessorPair.second.release();`
			`PacketInfo info(type, msg.getStorageId());`
			`result = destHandler.passPacket(info);`
			`} else {`
			`// Route depending on PDU type and directive type if applicable. It retrieves directive type`
			`// from the raw stream for better performance (with sanity and directive code check).`
			`// The routing is based on section 4.5 of the CFDP standard which specifies the PDU forwarding`
			`// procedure.`

			`// PDU header only. Invalid supplied data. A directive packet should have a valid data field`
			`// with at least one byte being the directive code`
			`const uint8_t* pduDataField = reader.getPduDataField();`
			`if (pduDataField == nullptr) {`
			`return INVALID_PDU_FORMAT;`
			`}`
			`if (not FileDirectiveReader::checkFileDirective(pduDataField[0])) {`
minor improvements 2023-06-17 12:24:54 +02:00			`sif::error << "CfdpHandler: Invalid PDU directive field " << static_cast<int>(pduDataField[0])`
			`<< std::endl;`
move cfdp handler 2023-04-11 16:51:49 +02:00			`return INVALID_DIRECTIVE_FIELD;`
			`}`
			`auto directive = static_cast<FileDirective>(pduDataField[0]);`

			`auto passToDestHandler = [&]() {`
			`accessorPair.second.release();`
			`PacketInfo info(type, msg.getStorageId(), directive);`
			`result = destHandler.passPacket(info);`
			`};`
			`auto passToSourceHandler = [&]() {`

			`};`
			`if (directive == FileDirective::METADATA or directive == FileDirective::EOF_DIRECTIVE or`
			`directive == FileDirective::PROMPT) {`
			`// Section b) of 4.5.3: These PDUs should always be targeted towards the file receiver a.k.a.`
			`// the destination handler`
			`passToDestHandler();`
			`} else if (directive == FileDirective::FINISH or directive == FileDirective::NAK or`
			`directive == FileDirective::KEEP_ALIVE) {`
			`// Section c) of 4.5.3: These PDUs should always be targeted towards the file sender a.k.a.`
			`// the source handler`
			`passToSourceHandler();`
			`} else if (directive == FileDirective::ACK) {`
			`// Section a): Recipient depends of the type of PDU that is being acknowledged. We can simply`
			`// extract the PDU type from the raw stream. If it is an EOF PDU, this packet is passed to`
			`// the source handler, for a Finished PDU, it is passed to the destination handler.`
			`FileDirective ackedDirective;`
			`if (not AckPduReader::checkAckedDirectiveField(pduDataField[1], ackedDirective)) {`
			`return INVALID_ACK_DIRECTIVE_FIELDS;`
			`}`
			`if (ackedDirective == FileDirective::EOF_DIRECTIVE) {`
			`passToSourceHandler();`
			`} else if (ackedDirective == FileDirective::FINISH) {`
			`passToDestHandler();`
			`}`
			`}`
			`}`
			`return result;`
			`}`
clean up handler a bit 2023-08-14 21:22:01 +02:00
			`ReturnValue_t CfdpHandler::handleCfdpRequest(CommandMessage& msg) {`
			`// TODO: Handle CFDP requests here, most importantly put requests. If a put request is received,`
introduce queue for put requests 2023-08-30 11:47:39 +02:00			`// check whether one is pending. If none are, start a transaction with the put request,`
			`// otherwise store for put request inside a FIFO for later processing.`
			`if (msg.getCommand() == CfdpMessage::PUT_REQUEST) {`
			`sif::info << "Received CFDP put request" << std::endl;`
			`if (srcHandler.getState() != CfdpState::IDLE) {`
			`if (putRequestQueue.full()) {`
			`// TODO: Trigger event and discard request. Queue is full, too many requests.`
			`return FAILED;`
			`}`
			`putRequestQueue.push(CfdpMessage::getStoreId(&msg));`
			`} else {`
			`// TODO: Retrieve put request and remote configuration.`
that should cause a transaction start 2023-08-30 11:58:21 +02:00			`PutRequest putRequest;`
			`auto accessorPair = ipcStore.getData(CfdpMessage::getStoreId(&msg));`
			`const uint8_t* dataPtr = accessorPair.second.data();`
			`size_t dataSize = accessorPair.second.size();`
			`ReturnValue_t result =`
			`putRequest.deSerialize(&dataPtr, &dataSize, SerializeIF::Endianness::MACHINE);`
			`if (result != OK) {`
			`return result;`
			`}`
			`RemoteEntityCfg* remoteCfg;`
			`remoteCfgProvider.getRemoteCfg(putRequest.getDestId(), &remoteCfg);`
			`if (remoteCfg == nullptr) {`
CFDP handler 2023-08-31 15:20:19 +02:00			`sif::error << "CfdpHandler: No remote configuration found for destination ID "`
			`<< putRequest.getDestId() << std::endl;`
that should cause a transaction start 2023-08-30 11:58:21 +02:00			`// TODO: Trigger event`
			`return FAILED;`
			`}`
CFDP handler 2023-08-31 15:20:19 +02:00			`sif::info << "Starting file copy operation for source file "`
			`<< putRequest.getSourceName().getString() << " and dest file "`
			`<< putRequest.getDestName().getString() << std::endl;`
that should cause a transaction start 2023-08-30 11:58:21 +02:00			`return srcHandler.transactionStart(putRequest, *remoteCfg);`
introduce queue for put requests 2023-08-30 11:47:39 +02:00			`}`
			`}`
clean up handler a bit 2023-08-14 21:22:01 +02:00			`return OK;`
			`}`

			`ReturnValue_t CfdpHandler::handlePduPacketMessages() {`
			`ReturnValue_t status;`
			`ReturnValue_t result = OK;`
			`TmTcMessage pduMsg;`
			`for (status = pduQueue.receiveMessage(&pduMsg); status == returnvalue::OK;`
			`status = pduQueue.receiveMessage(&pduMsg)) {`
			`result = handlePduPacket(pduMsg);`
			`if (result != OK) {`
introduce queue for put requests 2023-08-30 11:47:39 +02:00			`// TODO: Maybe add printout with context specific information?`
clean up handler a bit 2023-08-14 21:22:01 +02:00			`status = result;`
			`}`
			`}`
			`return status;`
			`}`

			`ReturnValue_t CfdpHandler::handleCfdpMessages() {`
			`ReturnValue_t status;`
			`ReturnValue_t result;`
			`CommandMessage cfdpMsg;`
			`for (status = cfdpRequestQueue.receiveMessage(&cfdpMsg); status == returnvalue::OK;`
			`status = cfdpRequestQueue.receiveMessage(&cfdpMsg)) {`
			`result = handleCfdpRequest(cfdpMsg);`
			`if (result != OK) {`
CFDP handler 2023-08-31 15:20:19 +02:00			`sif::warning << "Handling CFDP request failed with code 0x" << std::setw(4) << std::hex`
			`<< result << std::dec << std::endl;`
trigger a useful event 2023-08-31 15:10:43 +02:00			`triggerEvent(cfdp::events::HANDLING_CFDP_REQUEST_FAILED, 0, result);`
introduce queue for put requests 2023-08-30 11:47:39 +02:00			`// TODO: Maybe add printout with context specific information?`
clean up handler a bit 2023-08-14 21:22:01 +02:00			`status = result;`
			`}`
			`}`
			`return status;`
			`}`