/* // Copyright (c) 2017-2019 Intel Corporation // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. */ #include "dbus-sdr/storagecommands.hpp" #include "dbus-sdr/sdrutils.hpp" #include "selutility.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static constexpr bool DEBUG = false; namespace dynamic_sensors::ipmi::sel { static const std::filesystem::path selLogDir = "/var/log"; static const std::string selLogFilename = "ipmi_sel"; static int getFileTimestamp(const std::filesystem::path& file) { struct stat st; if (stat(file.c_str(), &st) >= 0) { return st.st_mtime; } return ::ipmi::sel::invalidTimeStamp; } namespace erase_time { static constexpr const char* selEraseTimestamp = "/var/lib/ipmi/sel_erase_time"; int get() { return getFileTimestamp(selEraseTimestamp); } } // namespace erase_time } // namespace dynamic_sensors::ipmi::sel namespace ipmi { namespace storage { constexpr static const size_t maxMessageSize = 64; constexpr static const size_t maxFruSdrNameSize = 16; using ObjectType = boost::container::flat_map>; using ManagedObjectType = boost::container::flat_map; using ManagedEntry = std::pair; constexpr static const char* selLoggerServiceName = "xyz.openbmc_project.Logging.IPMI"; constexpr static const char* fruDeviceServiceName = "xyz.openbmc_project.FruDevice"; constexpr static const char* entityManagerServiceName = "xyz.openbmc_project.EntityManager"; constexpr static const size_t writeTimeoutSeconds = 10; constexpr static const char* chassisTypeRackMount = "23"; constexpr static const char* chassisTypeMainServer = "17"; // event direction is bit[7] of eventType where 1b = Deassertion event constexpr static const uint8_t deassertionEvent = 0x80; static std::vector fruCache; static constexpr uint16_t invalidBus = 0xFFFF; static constexpr uint8_t invalidAddr = 0xFF; static uint16_t cacheBus = invalidBus; static uint8_t cacheAddr = invalidAddr; static uint8_t lastDevId = 0xFF; static uint16_t writeBus = invalidBus; static uint8_t writeAddr = invalidAddr; std::unique_ptr writeTimer = nullptr; static std::vector fruMatches; ManagedObjectType frus; // we unfortunately have to build a map of hashes in case there is a // collision to verify our dev-id boost::container::flat_map> deviceHashes; void registerStorageFunctions() __attribute__((constructor)); bool writeFru(const std::vector& fru) { if (writeBus == invalidBus && writeAddr == invalidAddr) { return true; } lastDevId = 0xFF; std::shared_ptr dbus = getSdBus(); sdbusplus::message_t writeFru = dbus->new_method_call( fruDeviceServiceName, "/xyz/openbmc_project/FruDevice", "xyz.openbmc_project.FruDeviceManager", "WriteFru"); writeFru.append(writeBus, writeAddr, fru); try { sdbusplus::message_t writeFruResp = dbus->call(writeFru); } catch (const sdbusplus::exception_t&) { // todo: log sel? phosphor::logging::log( "error writing fru"); return false; } writeBus = invalidBus; writeAddr = invalidAddr; return true; } void writeFruCache() { writeFru(fruCache); } void createTimers() { writeTimer = std::make_unique(writeFruCache); } void recalculateHashes() { deviceHashes.clear(); // hash the object paths to create unique device id's. increment on // collision std::hash hasher; for (const auto& fru : frus) { auto fruIface = fru.second.find("xyz.openbmc_project.FruDevice"); if (fruIface == fru.second.end()) { continue; } auto busFind = fruIface->second.find("BUS"); auto addrFind = fruIface->second.find("ADDRESS"); if (busFind == fruIface->second.end() || addrFind == fruIface->second.end()) { phosphor::logging::log( "fru device missing Bus or Address", phosphor::logging::entry("FRU=%s", fru.first.str.c_str())); continue; } uint16_t fruBus = std::get(busFind->second); uint8_t fruAddr = std::get(addrFind->second); auto chassisFind = fruIface->second.find("CHASSIS_TYPE"); std::string chassisType; if (chassisFind != fruIface->second.end()) { chassisType = std::get(chassisFind->second); } uint8_t fruHash = 0; if (chassisType.compare(chassisTypeRackMount) != 0 && chassisType.compare(chassisTypeMainServer) != 0) { fruHash = hasher(fru.first.str); // can't be 0xFF based on spec, and 0 is reserved for baseboard if (fruHash == 0 || fruHash == 0xFF) { fruHash = 1; } } std::pair newDev(fruBus, fruAddr); bool emplacePassed = false; while (!emplacePassed) { auto resp = deviceHashes.emplace(fruHash, newDev); emplacePassed = resp.second; if (!emplacePassed) { fruHash++; // can't be 0xFF based on spec, and 0 is reserved for // baseboard if (fruHash == 0XFF) { fruHash = 0x1; } } } } } void replaceCacheFru( const std::shared_ptr& bus, boost::asio::yield_context& yield, [[maybe_unused]] const std::optional& path = std::nullopt) { boost::system::error_code ec; frus = bus->yield_method_call( yield, ec, fruDeviceServiceName, "/", "org.freedesktop.DBus.ObjectManager", "GetManagedObjects"); if (ec) { phosphor::logging::log( "GetMangagedObjects for replaceCacheFru failed", phosphor::logging::entry("ERROR=%s", ec.message().c_str())); return; } recalculateHashes(); } std::pair> getFru(ipmi::Context::ptr ctx, uint8_t devId) { if (lastDevId == devId && devId != 0xFF) { return {ipmi::ccSuccess, fruCache}; } auto deviceFind = deviceHashes.find(devId); if (deviceFind == deviceHashes.end()) { return {IPMI_CC_SENSOR_INVALID, {}}; } cacheBus = deviceFind->second.first; cacheAddr = deviceFind->second.second; boost::system::error_code ec; std::vector fru = ctx->bus->yield_method_call>( ctx->yield, ec, fruDeviceServiceName, "/xyz/openbmc_project/FruDevice", "xyz.openbmc_project.FruDeviceManager", "GetRawFru", cacheBus, cacheAddr); if (ec) { phosphor::logging::log( "Couldn't get raw fru", phosphor::logging::entry("ERROR=%s", ec.message().c_str())); cacheBus = invalidBus; cacheAddr = invalidAddr; return {ipmi::ccResponseError, {}}; } fruCache.clear(); lastDevId = devId; fruCache = fru; return {ipmi::ccSuccess, fru}; } void writeFruIfRunning() { if (!writeTimer->isRunning()) { return; } writeTimer->stop(); writeFruCache(); } void startMatch(void) { if (fruMatches.size()) { return; } fruMatches.reserve(2); auto bus = getSdBus(); fruMatches.emplace_back(*bus, "type='signal',arg0path='/xyz/openbmc_project/" "FruDevice/',member='InterfacesAdded'", [](sdbusplus::message_t& message) { sdbusplus::message::object_path path; ObjectType object; try { message.read(path, object); } catch (const sdbusplus::exception_t&) { return; } auto findType = object.find("xyz.openbmc_project.FruDevice"); if (findType == object.end()) { return; } writeFruIfRunning(); frus[path] = object; recalculateHashes(); lastDevId = 0xFF; }); fruMatches.emplace_back(*bus, "type='signal',arg0path='/xyz/openbmc_project/" "FruDevice/',member='InterfacesRemoved'", [](sdbusplus::message_t& message) { sdbusplus::message::object_path path; std::set interfaces; try { message.read(path, interfaces); } catch (const sdbusplus::exception_t&) { return; } auto findType = interfaces.find("xyz.openbmc_project.FruDevice"); if (findType == interfaces.end()) { return; } writeFruIfRunning(); frus.erase(path); recalculateHashes(); lastDevId = 0xFF; }); // call once to populate boost::asio::spawn(*getIoContext(), [](boost::asio::yield_context yield) { replaceCacheFru(getSdBus(), yield); }); } /** @brief implements the read FRU data command * @param fruDeviceId - FRU Device ID * @param fruInventoryOffset - FRU Inventory Offset to write * @param countToRead - Count to read * * @returns ipmi completion code plus response data * - countWritten - Count written */ ipmi::RspType // Requested data > ipmiStorageReadFruData(ipmi::Context::ptr ctx, uint8_t fruDeviceId, uint16_t fruInventoryOffset, uint8_t countToRead) { if (fruDeviceId == 0xFF) { return ipmi::responseInvalidFieldRequest(); } auto [status, fru] = getFru(ctx, fruDeviceId); if (status != ipmi::ccSuccess) { return ipmi::response(status); } size_t fromFruByteLen = 0; if (countToRead + fruInventoryOffset < fru.size()) { fromFruByteLen = countToRead; } else if (fru.size() > fruInventoryOffset) { fromFruByteLen = fru.size() - fruInventoryOffset; } else { return ipmi::responseReqDataLenExceeded(); } std::vector requestedData; requestedData.insert(requestedData.begin(), fru.begin() + fruInventoryOffset, fru.begin() + fruInventoryOffset + fromFruByteLen); return ipmi::responseSuccess(static_cast(requestedData.size()), requestedData); } /** @brief implements the write FRU data command * @param fruDeviceId - FRU Device ID * @param fruInventoryOffset - FRU Inventory Offset to write * @param dataToWrite - Data to write * * @returns ipmi completion code plus response data * - countWritten - Count written */ ipmi::RspType ipmiStorageWriteFruData(ipmi::Context::ptr ctx, uint8_t fruDeviceId, uint16_t fruInventoryOffset, std::vector& dataToWrite) { if (fruDeviceId == 0xFF) { return ipmi::responseInvalidFieldRequest(); } size_t writeLen = dataToWrite.size(); auto [status, fru] = getFru(ctx, fruDeviceId); if (status != ipmi::ccSuccess) { return ipmi::response(status); } size_t lastWriteAddr = fruInventoryOffset + writeLen; if (fru.size() < lastWriteAddr) { fru.resize(fruInventoryOffset + writeLen); } std::copy(dataToWrite.begin(), dataToWrite.begin() + writeLen, fru.begin() + fruInventoryOffset); bool atEnd = false; if (fru.size() >= sizeof(FRUHeader)) { FRUHeader* header = reinterpret_cast(fru.data()); size_t areaLength = 0; size_t lastRecordStart = std::max( {header->internalOffset, header->chassisOffset, header->boardOffset, header->productOffset, header->multiRecordOffset}); lastRecordStart *= 8; // header starts in are multiples of 8 bytes if (header->multiRecordOffset) { // This FRU has a MultiRecord Area uint8_t endOfList = 0; // Walk the MultiRecord headers until the last record while (!endOfList) { // The MSB in the second byte of the MultiRecord header signals // "End of list" endOfList = fru[lastRecordStart + 1] & 0x80; // Third byte in the MultiRecord header is the length areaLength = fru[lastRecordStart + 2]; // This length is in bytes (not 8 bytes like other headers) areaLength += 5; // The length omits the 5 byte header if (!endOfList) { // Next MultiRecord header lastRecordStart += areaLength; } } } else { // This FRU does not have a MultiRecord Area // Get the length of the area in multiples of 8 bytes if (lastWriteAddr > (lastRecordStart + 1)) { // second byte in record area is the length areaLength = fru[lastRecordStart + 1]; areaLength *= 8; // it is in multiples of 8 bytes } } if (lastWriteAddr >= (areaLength + lastRecordStart)) { atEnd = true; } } uint8_t countWritten = 0; writeBus = cacheBus; writeAddr = cacheAddr; if (atEnd) { // cancel timer, we're at the end so might as well send it writeTimer->stop(); if (!writeFru(fru)) { return ipmi::responseInvalidFieldRequest(); } countWritten = std::min(fru.size(), static_cast(0xFF)); } else { fruCache = fru; // Write-back // start a timer, if no further data is sent to check to see if it is // valid writeTimer->start(std::chrono::duration_cast( std::chrono::seconds(writeTimeoutSeconds))); countWritten = 0; } return ipmi::responseSuccess(countWritten); } /** @brief implements the get FRU inventory area info command * @param fruDeviceId - FRU Device ID * * @returns IPMI completion code plus response data * - inventorySize - Number of possible allocation units * - accessType - Allocation unit size in bytes. */ ipmi::RspType // accessType ipmiStorageGetFruInvAreaInfo(ipmi::Context::ptr ctx, uint8_t fruDeviceId) { if (fruDeviceId == 0xFF) { return ipmi::responseInvalidFieldRequest(); } auto [ret, fru] = getFru(ctx, fruDeviceId); if (ret != ipmi::ccSuccess) { return ipmi::response(ret); } constexpr uint8_t accessType = static_cast(GetFRUAreaAccessType::byte); return ipmi::responseSuccess(fru.size(), accessType); } ipmi_ret_t getFruSdrCount(ipmi::Context::ptr, size_t& count) { count = deviceHashes.size(); return IPMI_CC_OK; } ipmi_ret_t getFruSdrs([[maybe_unused]] ipmi::Context::ptr ctx, size_t index, get_sdr::SensorDataFruRecord& resp) { if (deviceHashes.size() < index) { return IPMI_CC_INVALID_FIELD_REQUEST; } auto device = deviceHashes.begin() + index; uint16_t& bus = device->second.first; uint8_t& address = device->second.second; boost::container::flat_map* fruData = nullptr; auto fru = std::find_if(frus.begin(), frus.end(), [bus, address, &fruData](ManagedEntry& entry) { auto findFruDevice = entry.second.find("xyz.openbmc_project.FruDevice"); if (findFruDevice == entry.second.end()) { return false; } fruData = &(findFruDevice->second); auto findBus = findFruDevice->second.find("BUS"); auto findAddress = findFruDevice->second.find("ADDRESS"); if (findBus == findFruDevice->second.end() || findAddress == findFruDevice->second.end()) { return false; } if (std::get(findBus->second) != bus) { return false; } if (std::get(findAddress->second) != address) { return false; } return true; }); if (fru == frus.end()) { return IPMI_CC_RESPONSE_ERROR; } std::string name; #ifdef USING_ENTITY_MANAGER_DECORATORS boost::container::flat_map* entityData = nullptr; // todo: this should really use caching, this is a very inefficient lookup boost::system::error_code ec; ManagedObjectType entities = ctx->bus->yield_method_call( ctx->yield, ec, entityManagerServiceName, "/xyz/openbmc_project/inventory", "org.freedesktop.DBus.ObjectManager", "GetManagedObjects"); if (ec) { phosphor::logging::log( "GetMangagedObjects for ipmiStorageGetFruInvAreaInfo failed", phosphor::logging::entry("ERROR=%s", ec.message().c_str())); return ipmi::ccResponseError; } auto entity = std::find_if(entities.begin(), entities.end(), [bus, address, &entityData, &name](ManagedEntry& entry) { auto findFruDevice = entry.second.find( "xyz.openbmc_project.Inventory.Decorator.I2CDevice"); if (findFruDevice == entry.second.end()) { return false; } // Integer fields added via Entity-Manager json are uint64_ts by // default. auto findBus = findFruDevice->second.find("Bus"); auto findAddress = findFruDevice->second.find("Address"); if (findBus == findFruDevice->second.end() || findAddress == findFruDevice->second.end()) { return false; } if ((std::get(findBus->second) != bus) || (std::get(findAddress->second) != address)) { return false; } auto fruName = findFruDevice->second.find("Name"); if (fruName != findFruDevice->second.end()) { name = std::get(fruName->second); } // At this point we found the device entry and should return // true. auto findIpmiDevice = entry.second.find("xyz.openbmc_project.Inventory.Decorator.Ipmi"); if (findIpmiDevice != entry.second.end()) { entityData = &(findIpmiDevice->second); } return true; }); if (entity == entities.end()) { if constexpr (DEBUG) { std::fprintf(stderr, "Ipmi or FruDevice Decorator interface " "not found for Fru\n"); } } #endif if (name.empty()) { name = "UNKNOWN"; } if (name.size() > maxFruSdrNameSize) { name = name.substr(0, maxFruSdrNameSize); } size_t sizeDiff = maxFruSdrNameSize - name.size(); resp.header.record_id_lsb = 0x0; // calling code is to implement these resp.header.record_id_msb = 0x0; resp.header.sdr_version = ipmiSdrVersion; resp.header.record_type = get_sdr::SENSOR_DATA_FRU_RECORD; resp.header.record_length = sizeof(resp.body) + sizeof(resp.key) - sizeDiff; resp.key.deviceAddress = 0x20; resp.key.fruID = device->first; resp.key.accessLun = 0x80; // logical / physical fru device resp.key.channelNumber = 0x0; resp.body.reserved = 0x0; resp.body.deviceType = 0x10; resp.body.deviceTypeModifier = 0x0; uint8_t entityID = 0; uint8_t entityInstance = 0x1; #ifdef USING_ENTITY_MANAGER_DECORATORS if (entityData) { auto entityIdProperty = entityData->find("EntityId"); auto entityInstanceProperty = entityData->find("EntityInstance"); if (entityIdProperty != entityData->end()) { entityID = static_cast( std::get(entityIdProperty->second)); } if (entityInstanceProperty != entityData->end()) { entityInstance = static_cast( std::get(entityInstanceProperty->second)); } } #endif resp.body.entityID = entityID; resp.body.entityInstance = entityInstance; resp.body.oem = 0x0; resp.body.deviceIDLen = name.size(); name.copy(resp.body.deviceID, name.size()); return IPMI_CC_OK; } static bool getSELLogFiles(std::vector& selLogFiles) { // Loop through the directory looking for ipmi_sel log files for (const std::filesystem::directory_entry& dirEnt : std::filesystem::directory_iterator( dynamic_sensors::ipmi::sel::selLogDir)) { std::string filename = dirEnt.path().filename(); if (boost::starts_with(filename, dynamic_sensors::ipmi::sel::selLogFilename)) { // If we find an ipmi_sel log file, save the path selLogFiles.emplace_back(dynamic_sensors::ipmi::sel::selLogDir / filename); } } // As the log files rotate, they are appended with a ".#" that is higher for // the older logs. Since we don't expect more than 10 log files, we // can just sort the list to get them in order from newest to oldest std::sort(selLogFiles.begin(), selLogFiles.end()); return !selLogFiles.empty(); } static int countSELEntries() { // Get the list of ipmi_sel log files std::vector selLogFiles; if (!getSELLogFiles(selLogFiles)) { return 0; } int numSELEntries = 0; // Loop through each log file and count the number of logs for (const std::filesystem::path& file : selLogFiles) { std::ifstream logStream(file); if (!logStream.is_open()) { continue; } std::string line; while (std::getline(logStream, line)) { numSELEntries++; } } return numSELEntries; } static bool findSELEntry(const int recordID, const std::vector& selLogFiles, std::string& entry) { // Record ID is the first entry field following the timestamp. It is // preceded by a space and followed by a comma std::string search = " " + std::to_string(recordID) + ","; // Loop through the ipmi_sel log entries for (const std::filesystem::path& file : selLogFiles) { std::ifstream logStream(file); if (!logStream.is_open()) { continue; } while (std::getline(logStream, entry)) { // Check if the record ID matches if (entry.find(search) != std::string::npos) { return true; } } } return false; } static uint16_t getNextRecordID(const uint16_t recordID, const std::vector& selLogFiles) { uint16_t nextRecordID = recordID + 1; std::string entry; if (findSELEntry(nextRecordID, selLogFiles, entry)) { return nextRecordID; } else { return ipmi::sel::lastEntry; } } static int fromHexStr(const std::string& hexStr, std::vector& data) { for (unsigned int i = 0; i < hexStr.size(); i += 2) { try { data.push_back(static_cast( std::stoul(hexStr.substr(i, 2), nullptr, 16))); } catch (const std::invalid_argument& e) { phosphor::logging::log(e.what()); return -1; } catch (const std::out_of_range& e) { phosphor::logging::log(e.what()); return -1; } } return 0; } ipmi::RspType // operation support ipmiStorageGetSELInfo() { constexpr uint8_t selVersion = ipmi::sel::selVersion; uint16_t entries = countSELEntries(); uint32_t addTimeStamp = dynamic_sensors::ipmi::sel::getFileTimestamp( dynamic_sensors::ipmi::sel::selLogDir / dynamic_sensors::ipmi::sel::selLogFilename); uint32_t eraseTimeStamp = dynamic_sensors::ipmi::sel::erase_time::get(); constexpr uint8_t operationSupport = dynamic_sensors::ipmi::sel::selOperationSupport; constexpr uint16_t freeSpace = 0xffff; // Spec indicates that more than 64kB is free return ipmi::responseSuccess(selVersion, entries, freeSpace, addTimeStamp, eraseTimeStamp, operationSupport); } using systemEventType = std::tuple< uint32_t, // Timestamp uint16_t, // Generator ID uint8_t, // EvM Rev uint8_t, // Sensor Type uint8_t, // Sensor Number uint7_t, // Event Type bool, // Event Direction std::array>; // Event // Data using oemTsEventType = std::tuple< uint32_t, // Timestamp std::array>; // Event // Data using oemEventType = std::array; // Event Data ipmi::RspType> // Record Content ipmiStorageGetSELEntry(uint16_t reservationID, uint16_t targetID, uint8_t offset, uint8_t size) { // Only support getting the entire SEL record. If a partial size or non-zero // offset is requested, return an error if (offset != 0 || size != ipmi::sel::entireRecord) { return ipmi::responseRetBytesUnavailable(); } // Check the reservation ID if one is provided or required (only if the // offset is non-zero) if (reservationID != 0 || offset != 0) { if (!checkSELReservation(reservationID)) { return ipmi::responseInvalidReservationId(); } } // Get the ipmi_sel log files std::vector selLogFiles; if (!getSELLogFiles(selLogFiles)) { return ipmi::responseSensorInvalid(); } std::string targetEntry; if (targetID == ipmi::sel::firstEntry) { // The first entry will be at the top of the oldest log file std::ifstream logStream(selLogFiles.back()); if (!logStream.is_open()) { return ipmi::responseUnspecifiedError(); } if (!std::getline(logStream, targetEntry)) { return ipmi::responseUnspecifiedError(); } } else if (targetID == ipmi::sel::lastEntry) { // The last entry will be at the bottom of the newest log file std::ifstream logStream(selLogFiles.front()); if (!logStream.is_open()) { return ipmi::responseUnspecifiedError(); } std::string line; while (std::getline(logStream, line)) { targetEntry = line; } } else { if (!findSELEntry(targetID, selLogFiles, targetEntry)) { return ipmi::responseSensorInvalid(); } } // The format of the ipmi_sel message is " // ,,,[,,]". // First get the Timestamp size_t space = targetEntry.find_first_of(" "); if (space == std::string::npos) { return ipmi::responseUnspecifiedError(); } std::string entryTimestamp = targetEntry.substr(0, space); // Then get the log contents size_t entryStart = targetEntry.find_first_not_of(" ", space); if (entryStart == std::string::npos) { return ipmi::responseUnspecifiedError(); } std::string_view entry(targetEntry); entry.remove_prefix(entryStart); // Use split to separate the entry into its fields std::vector targetEntryFields; boost::split(targetEntryFields, entry, boost::is_any_of(","), boost::token_compress_on); if (targetEntryFields.size() < 3) { return ipmi::responseUnspecifiedError(); } std::string& recordIDStr = targetEntryFields[0]; std::string& recordTypeStr = targetEntryFields[1]; std::string& eventDataStr = targetEntryFields[2]; uint16_t recordID; uint8_t recordType; try { recordID = std::stoul(recordIDStr); recordType = std::stoul(recordTypeStr, nullptr, 16); } catch (const std::invalid_argument&) { return ipmi::responseUnspecifiedError(); } uint16_t nextRecordID = getNextRecordID(recordID, selLogFiles); std::vector eventDataBytes; if (fromHexStr(eventDataStr, eventDataBytes) < 0) { return ipmi::responseUnspecifiedError(); } if (recordType == dynamic_sensors::ipmi::sel::systemEvent) { // Get the timestamp std::tm timeStruct = {}; std::istringstream entryStream(entryTimestamp); uint32_t timestamp = ipmi::sel::invalidTimeStamp; if (entryStream >> std::get_time(&timeStruct, "%Y-%m-%dT%H:%M:%S")) { timeStruct.tm_isdst = -1; timestamp = std::mktime(&timeStruct); } // Set the event message revision uint8_t evmRev = dynamic_sensors::ipmi::sel::eventMsgRev; uint16_t generatorID = 0; uint8_t sensorType = 0; uint16_t sensorAndLun = 0; uint8_t sensorNum = 0xFF; uint7_t eventType = 0; bool eventDir = 0; // System type events should have six fields if (targetEntryFields.size() >= 6) { std::string& generatorIDStr = targetEntryFields[3]; std::string& sensorPath = targetEntryFields[4]; std::string& eventDirStr = targetEntryFields[5]; // Get the generator ID try { generatorID = std::stoul(generatorIDStr, nullptr, 16); } catch (const std::invalid_argument&) { std::cerr << "Invalid Generator ID\n"; } // Get the sensor type, sensor number, and event type for the sensor sensorType = getSensorTypeFromPath(sensorPath); sensorAndLun = getSensorNumberFromPath(sensorPath); sensorNum = static_cast(sensorAndLun); if ((generatorID & 0x0001) == 0) { // IPMB Address generatorID |= sensorAndLun & 0x0300; } else { // system software generatorID |= sensorAndLun >> 8; } eventType = getSensorEventTypeFromPath(sensorPath); // Get the event direction try { eventDir = std::stoul(eventDirStr) ? 0 : 1; } catch (const std::invalid_argument&) { std::cerr << "Invalid Event Direction\n"; } } // Only keep the eventData bytes that fit in the record std::array eventData{}; std::copy_n(eventDataBytes.begin(), std::min(eventDataBytes.size(), eventData.size()), eventData.begin()); return ipmi::responseSuccess( nextRecordID, recordID, recordType, systemEventType{timestamp, generatorID, evmRev, sensorType, sensorNum, eventType, eventDir, eventData}); } if (recordType >= dynamic_sensors::ipmi::sel::oemTsEventFirst && recordType <= dynamic_sensors::ipmi::sel::oemTsEventLast) { // Get the timestamp std::tm timeStruct = {}; std::istringstream entryStream(entryTimestamp); uint32_t timestamp = ipmi::sel::invalidTimeStamp; if (entryStream >> std::get_time(&timeStruct, "%Y-%m-%dT%H:%M:%S")) { timeStruct.tm_isdst = -1; timestamp = std::mktime(&timeStruct); } // Only keep the bytes that fit in the record std::array eventData{}; std::copy_n(eventDataBytes.begin(), std::min(eventDataBytes.size(), eventData.size()), eventData.begin()); return ipmi::responseSuccess(nextRecordID, recordID, recordType, oemTsEventType{timestamp, eventData}); } if (recordType >= dynamic_sensors::ipmi::sel::oemEventFirst) { // Only keep the bytes that fit in the record std::array eventData{}; std::copy_n(eventDataBytes.begin(), std::min(eventDataBytes.size(), eventData.size()), eventData.begin()); return ipmi::responseSuccess(nextRecordID, recordID, recordType, eventData); } return ipmi::responseUnspecifiedError(); } /* Unused arguments uint16_t recordID, uint8_t recordType, uint32_t timestamp, uint16_t generatorID, uint8_t evmRev, uint8_t sensorType, uint8_t sensorNum, uint8_t eventType, uint8_t eventData1, uint8_t eventData2, uint8_t eventData3 */ ipmi::RspType ipmiStorageAddSELEntry(uint16_t, uint8_t, uint32_t, uint16_t, uint8_t, uint8_t, uint8_t, uint8_t, uint8_t, uint8_t, uint8_t) { // Per the IPMI spec, need to cancel any reservation when a SEL entry is // added cancelSELReservation(); uint16_t responseID = 0xFFFF; return ipmi::responseSuccess(responseID); } ipmi::RspType ipmiStorageClearSEL(ipmi::Context::ptr ctx, uint16_t reservationID, const std::array& clr, uint8_t eraseOperation) { if (!checkSELReservation(reservationID)) { return ipmi::responseInvalidReservationId(); } static constexpr std::array clrExpected = {'C', 'L', 'R'}; if (clr != clrExpected) { return ipmi::responseInvalidFieldRequest(); } // Erasure status cannot be fetched, so always return erasure status as // `erase completed`. if (eraseOperation == ipmi::sel::getEraseStatus) { return ipmi::responseSuccess(ipmi::sel::eraseComplete); } // Check that initiate erase is correct if (eraseOperation != ipmi::sel::initiateErase) { return ipmi::responseInvalidFieldRequest(); } // Per the IPMI spec, need to cancel any reservation when the SEL is // cleared cancelSELReservation(); boost::system::error_code ec; ctx->bus->yield_method_call<>(ctx->yield, ec, selLoggerServiceName, "/xyz/openbmc_project/Logging/IPMI", "xyz.openbmc_project.Logging.IPMI", "Clear"); if (ec) { std::cerr << "error in clear SEL: " << ec << std::endl; return ipmi::responseUnspecifiedError(); } return ipmi::responseSuccess(ipmi::sel::eraseComplete); } std::vector getType8SDRs(ipmi::sensor::EntityInfoMap::const_iterator& entity, uint16_t recordId) { std::vector resp; get_sdr::SensorDataEntityRecord data{}; /* Header */ get_sdr::header::set_record_id(recordId, &(data.header)); // Based on IPMI Spec v2.0 rev 1.1 data.header.sdr_version = SDR_VERSION; data.header.record_type = 0x08; data.header.record_length = sizeof(data.key) + sizeof(data.body); /* Key */ data.key.containerEntityId = entity->second.containerEntityId; data.key.containerEntityInstance = entity->second.containerEntityInstance; get_sdr::key::set_flags(entity->second.isList, entity->second.isLinked, &(data.key)); data.key.entityId1 = entity->second.containedEntities[0].first; data.key.entityInstance1 = entity->second.containedEntities[0].second; /* Body */ data.body.entityId2 = entity->second.containedEntities[1].first; data.body.entityInstance2 = entity->second.containedEntities[1].second; data.body.entityId3 = entity->second.containedEntities[2].first; data.body.entityInstance3 = entity->second.containedEntities[2].second; data.body.entityId4 = entity->second.containedEntities[3].first; data.body.entityInstance4 = entity->second.containedEntities[3].second; resp.insert(resp.end(), (uint8_t*)&data, ((uint8_t*)&data) + sizeof(data)); return resp; } std::vector getType12SDRs(uint16_t index, uint16_t recordId) { std::vector resp; if (index == 0) { std::string bmcName = "Basbrd Mgmt Ctlr"; Type12Record bmc(recordId, 0x20, 0, 0, 0xbf, 0x2e, 1, 0, bmcName); uint8_t* bmcPtr = reinterpret_cast(&bmc); resp.insert(resp.end(), bmcPtr, bmcPtr + sizeof(Type12Record)); } else if (index == 1) { std::string meName = "Mgmt Engine"; Type12Record me(recordId, 0x2c, 6, 0x24, 0x21, 0x2e, 2, 0, meName); uint8_t* mePtr = reinterpret_cast(&me); resp.insert(resp.end(), mePtr, mePtr + sizeof(Type12Record)); } else { throw std::runtime_error("getType12SDRs:: Illegal index " + std::to_string(index)); } return resp; } void registerStorageFunctions() { createTimers(); startMatch(); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdGetFruInventoryAreaInfo, ipmi::Privilege::User, ipmiStorageGetFruInvAreaInfo); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdReadFruData, ipmi::Privilege::User, ipmiStorageReadFruData); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdWriteFruData, ipmi::Privilege::Operator, ipmiStorageWriteFruData); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdGetSelInfo, ipmi::Privilege::User, ipmiStorageGetSELInfo); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdGetSelEntry, ipmi::Privilege::User, ipmiStorageGetSELEntry); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdAddSelEntry, ipmi::Privilege::Operator, ipmiStorageAddSELEntry); // ipmi::registerHandler(ipmi::prioOpenBmcBase, ipmi::netFnStorage, ipmi::storage::cmdClearSel, ipmi::Privilege::Operator, ipmiStorageClearSEL); } } // namespace storage } // namespace ipmi