#include "utils.hpp" #include "libpldm/pdr.h" #include "libpldm/pldm_types.h" #include #include #include #include #include #include #include #include #include namespace pldm { namespace utils { constexpr auto mapperBusName = "xyz.openbmc_project.ObjectMapper"; constexpr auto mapperPath = "/xyz/openbmc_project/object_mapper"; constexpr auto mapperInterface = "xyz.openbmc_project.ObjectMapper"; constexpr auto eidPath = "/usr/share/pldm/host_eid"; std::vector> findStateEffecterPDR(uint8_t /*tid*/, uint16_t entityID, uint16_t stateSetId, const pldm_pdr* repo) { uint8_t* outData = nullptr; uint32_t size{}; const pldm_pdr_record* record{}; std::vector> pdrs; try { do { record = pldm_pdr_find_record_by_type(repo, PLDM_STATE_EFFECTER_PDR, record, &outData, &size); if (record) { auto pdr = reinterpret_cast(outData); auto compositeEffecterCount = pdr->composite_effecter_count; auto possible_states_start = pdr->possible_states; for (auto effecters = 0x00; effecters < compositeEffecterCount; effecters++) { auto possibleStates = reinterpret_cast( possible_states_start); auto setId = possibleStates->state_set_id; auto possibleStateSize = possibleStates->possible_states_size; if (pdr->entity_type == entityID && setId == stateSetId) { std::vector effecter_pdr(&outData[0], &outData[size]); pdrs.emplace_back(std::move(effecter_pdr)); break; } possible_states_start += possibleStateSize + sizeof(setId) + sizeof(possibleStateSize); } } } while (record); } catch (const std::exception& e) { std::cerr << " Failed to obtain a record. ERROR =" << e.what() << std::endl; } return pdrs; } std::vector> findStateSensorPDR(uint8_t /*tid*/, uint16_t entityID, uint16_t stateSetId, const pldm_pdr* repo) { uint8_t* outData = nullptr; uint32_t size{}; const pldm_pdr_record* record{}; std::vector> pdrs; try { do { record = pldm_pdr_find_record_by_type(repo, PLDM_STATE_SENSOR_PDR, record, &outData, &size); if (record) { auto pdr = reinterpret_cast(outData); auto compositeSensorCount = pdr->composite_sensor_count; auto possible_states_start = pdr->possible_states; for (auto sensors = 0x00; sensors < compositeSensorCount; sensors++) { auto possibleStates = reinterpret_cast( possible_states_start); auto setId = possibleStates->state_set_id; auto possibleStateSize = possibleStates->possible_states_size; if (pdr->entity_type == entityID && setId == stateSetId) { std::vector sensor_pdr(&outData[0], &outData[size]); pdrs.emplace_back(std::move(sensor_pdr)); break; } possible_states_start += possibleStateSize + sizeof(setId) + sizeof(possibleStateSize); } } } while (record); } catch (const std::exception& e) { std::cerr << " Failed to obtain a record. ERROR =" << e.what() << std::endl; } return pdrs; } uint8_t readHostEID() { uint8_t eid{}; std::ifstream eidFile{eidPath}; if (!eidFile.good()) { std::cerr << "Could not open host EID file" << "\n"; } else { std::string eidStr; eidFile >> eidStr; if (!eidStr.empty()) { eid = atoi(eidStr.c_str()); } else { std::cerr << "Host EID file was empty" << "\n"; } } return eid; } uint8_t getNumPadBytes(uint32_t data) { uint8_t pad; pad = ((data % 4) ? (4 - data % 4) : 0); return pad; } // end getNumPadBytes bool uintToDate(uint64_t data, uint16_t* year, uint8_t* month, uint8_t* day, uint8_t* hour, uint8_t* min, uint8_t* sec) { constexpr uint64_t max_data = 29991231115959; constexpr uint64_t min_data = 19700101000000; if (data < min_data || data > max_data) { return false; } *year = data / 10000000000; data = data % 10000000000; *month = data / 100000000; data = data % 100000000; *day = data / 1000000; data = data % 1000000; *hour = data / 10000; data = data % 10000; *min = data / 100; *sec = data % 100; return true; } std::optional> parseEffecterData(const std::vector& effecterData, uint8_t effecterCount) { std::vector stateField; if (effecterData.size() != effecterCount * 2) { return std::nullopt; } for (uint8_t i = 0; i < effecterCount; ++i) { uint8_t set_request = effecterData[i * 2] == PLDM_REQUEST_SET ? PLDM_REQUEST_SET : PLDM_NO_CHANGE; set_effecter_state_field filed{set_request, effecterData[i * 2 + 1]}; stateField.emplace_back(std::move(filed)); } return std::make_optional(std::move(stateField)); } std::string DBusHandler::getService(const char* path, const char* interface) const { using DbusInterfaceList = std::vector; std::map> mapperResponse; auto& bus = DBusHandler::getBus(); auto mapper = bus.new_method_call(mapperBusName, mapperPath, mapperInterface, "GetObject"); mapper.append(path, DbusInterfaceList({interface})); auto mapperResponseMsg = bus.call(mapper); mapperResponseMsg.read(mapperResponse); return mapperResponse.begin()->first; } void reportError(const char* errorMsg) { static constexpr auto logObjPath = "/xyz/openbmc_project/logging"; static constexpr auto logInterface = "xyz.openbmc_project.Logging.Create"; auto& bus = pldm::utils::DBusHandler::getBus(); try { auto service = DBusHandler().getService(logObjPath, logInterface); using namespace sdbusplus::xyz::openbmc_project::Logging::server; auto severity = sdbusplus::xyz::openbmc_project::Logging::server::convertForMessage( sdbusplus::xyz::openbmc_project::Logging::server::Entry::Level:: Error); auto method = bus.new_method_call(service.c_str(), logObjPath, logInterface, "Create"); std::map addlData{}; method.append(errorMsg, severity, addlData); bus.call_noreply(method); } catch (const std::exception& e) { std::cerr << "failed to make a d-bus call to create error log, ERROR=" << e.what() << "\n"; } } void DBusHandler::setDbusProperty(const DBusMapping& dBusMap, const PropertyValue& value) const { auto setDbusValue = [&dBusMap, this](const auto& variant) { auto& bus = getBus(); auto service = getService(dBusMap.objectPath.c_str(), dBusMap.interface.c_str()); auto method = bus.new_method_call( service.c_str(), dBusMap.objectPath.c_str(), dbusProperties, "Set"); method.append(dBusMap.interface.c_str(), dBusMap.propertyName.c_str(), variant); bus.call_noreply(method); }; if (dBusMap.propertyType == "uint8_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "bool") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "int16_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "uint16_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "int32_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "uint32_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "int64_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "uint64_t") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "double") { std::variant v = std::get(value); setDbusValue(v); } else if (dBusMap.propertyType == "string") { std::variant v = std::get(value); setDbusValue(v); } else { throw std::invalid_argument("UnSpported Dbus Type"); } } PropertyValue DBusHandler::getDbusPropertyVariant( const char* objPath, const char* dbusProp, const char* dbusInterface) const { auto& bus = DBusHandler::getBus(); auto service = getService(objPath, dbusInterface); auto method = bus.new_method_call(service.c_str(), objPath, dbusProperties, "Get"); method.append(dbusInterface, dbusProp); PropertyValue value{}; auto reply = bus.call(method); reply.read(value); return value; } PropertyValue jsonEntryToDbusVal(std::string_view type, const nlohmann::json& value) { PropertyValue propValue{}; if (type == "uint8_t") { propValue = static_cast(value); } else if (type == "uint16_t") { propValue = static_cast(value); } else if (type == "uint32_t") { propValue = static_cast(value); } else if (type == "uint64_t") { propValue = static_cast(value); } else if (type == "int16_t") { propValue = static_cast(value); } else if (type == "int32_t") { propValue = static_cast(value); } else if (type == "int64_t") { propValue = static_cast(value); } else if (type == "bool") { propValue = static_cast(value); } else if (type == "double") { propValue = static_cast(value); } else if (type == "string") { propValue = static_cast(value); } else { std::cerr << "Unknown D-Bus property type, TYPE=" << type << "\n"; } return propValue; } uint16_t findStateEffecterId(const pldm_pdr* pdrRepo, uint16_t entityType, uint16_t entityInstance, uint16_t containerId, uint16_t stateSetId, bool localOrRemote) { uint8_t* pdrData = nullptr; uint32_t pdrSize{}; const pldm_pdr_record* record{}; do { record = pldm_pdr_find_record_by_type(pdrRepo, PLDM_STATE_EFFECTER_PDR, record, &pdrData, &pdrSize); if (record && (localOrRemote ^ pldm_pdr_record_is_remote(record))) { auto pdr = reinterpret_cast(pdrData); auto compositeEffecterCount = pdr->composite_effecter_count; auto possible_states_start = pdr->possible_states; for (auto effecters = 0x00; effecters < compositeEffecterCount; effecters++) { auto possibleStates = reinterpret_cast( possible_states_start); auto setId = possibleStates->state_set_id; auto possibleStateSize = possibleStates->possible_states_size; if (entityType == pdr->entity_type && entityInstance == pdr->entity_instance && containerId == pdr->container_id && stateSetId == setId) { return pdr->effecter_id; } possible_states_start += possibleStateSize + sizeof(setId) + sizeof(possibleStateSize); } } } while (record); return PLDM_INVALID_EFFECTER_ID; } int emitStateSensorEventSignal(uint8_t tid, uint16_t sensorId, uint8_t sensorOffset, uint8_t eventState, uint8_t previousEventState) { try { auto& bus = DBusHandler::getBus(); auto msg = bus.new_signal("/xyz/openbmc_project/pldm", "xyz.openbmc_project.PLDM.Event", "StateSensorEvent"); msg.append(tid, sensorId, sensorOffset, eventState, previousEventState); msg.signal_send(); } catch (std::exception& e) { std::cerr << "Error emitting pldm event signal:" << "ERROR=" << e.what() << "\n"; return PLDM_ERROR; } return PLDM_SUCCESS; } uint16_t findStateSensorId(const pldm_pdr* pdrRepo, uint8_t tid, uint16_t entityType, uint16_t entityInstance, uint16_t containerId, uint16_t stateSetId) { auto pdrs = findStateSensorPDR(tid, entityType, stateSetId, pdrRepo); for (auto pdr : pdrs) { auto sensorPdr = reinterpret_cast(pdr.data()); auto compositeSensorCount = sensorPdr->composite_sensor_count; auto possible_states_start = sensorPdr->possible_states; for (auto sensors = 0x00; sensors < compositeSensorCount; sensors++) { auto possibleStates = reinterpret_cast( possible_states_start); auto setId = possibleStates->state_set_id; auto possibleStateSize = possibleStates->possible_states_size; if (entityType == sensorPdr->entity_type && entityInstance == sensorPdr->entity_instance && stateSetId == setId && containerId == sensorPdr->container_id) { return sensorPdr->sensor_id; } possible_states_start += possibleStateSize + sizeof(setId) + sizeof(possibleStateSize); } } return PLDM_INVALID_EFFECTER_ID; } void printBuffer(const std::vector& buffer, bool pldmVerbose) { if (pldmVerbose && !buffer.empty()) { std::ostringstream tempStream; for (int byte : buffer) { tempStream << std::setfill('0') << std::setw(2) << std::hex << byte << " "; } std::cout << tempStream.str() << std::endl; } } } // namespace utils } // namespace pldm