blob: c43a660095d24f7dd44229d3a234c709611e421e [file] [log] [blame]
#include "config.h"
#include "selutility.hpp"
#include <ipmid/api.hpp>
#include <ipmid/types.hpp>
#include <ipmid/utils.hpp>
#include <phosphor-logging/elog-errors.hpp>
#include <xyz/openbmc_project/Common/error.hpp>
#include <charconv>
#include <chrono>
#include <filesystem>
#include <vector>
extern const ipmi::sensor::InvObjectIDMap invSensors;
using namespace phosphor::logging;
using InternalFailure =
sdbusplus::error::xyz::openbmc_project::common::InternalFailure;
namespace
{
constexpr auto systemEventRecord = 0x02;
constexpr auto generatorID = 0x2000;
constexpr auto eventMsgRevision = 0x04;
constexpr auto assertEvent = 0x00;
constexpr auto deassertEvent = 0x80;
constexpr auto selDataSize = 3;
constexpr auto oemCDDataSize = 9;
constexpr auto oemEFDataSize = 13;
constexpr auto propAdditionalData = "AdditionalData";
constexpr auto propResolved = "Resolved";
constexpr auto strEventDir = "EVENT_DIR";
constexpr auto strGenerateId = "GENERATOR_ID";
constexpr auto strRecordType = "RECORD_TYPE";
constexpr auto strSensorData = "SENSOR_DATA";
constexpr auto strSensorPath = "SENSOR_PATH";
} // namespace
namespace ipmi
{
namespace sel
{
namespace internal
{
inline bool isRecordOEM(uint8_t recordType)
{
return recordType != systemEventRecord;
}
using additionalDataMap = std::map<std::string, std::string>;
using entryDataMap = std::map<PropertyName, PropertyType>;
/** Parse the entry with format like key=val */
std::pair<std::string, std::string> parseEntry(const std::string& entry)
{
constexpr auto equalSign = "=";
auto pos = entry.find(equalSign);
assert(pos != std::string::npos);
auto key = entry.substr(0, pos);
auto val = entry.substr(pos + 1);
return {key, val};
}
additionalDataMap parseAdditionalData(const AdditionalData& data)
{
std::map<std::string, std::string> ret;
for (const auto& d : data)
{
ret.insert(parseEntry(d));
}
return ret;
}
int convert(const std::string_view& str, int base = 10)
{
int ret = 0;
std::from_chars(str.data(), str.data() + str.size(), ret, base);
return ret;
}
// Convert the string to a vector of uint8_t, where the str is formatted as hex
std::vector<uint8_t> convertVec(const std::string_view& str)
{
std::vector<uint8_t> ret;
auto len = str.size() / 2;
ret.reserve(len);
for (size_t i = 0; i < len; ++i)
{
ret.emplace_back(
static_cast<uint8_t>(convert(str.substr(i * 2, 2), 16)));
}
return ret;
}
/** Construct OEM SEL record according to IPMI spec 32.2, 32.3. */
void constructOEMSEL(uint8_t recordType, std::chrono::milliseconds timestamp,
const additionalDataMap& m, GetSELEntryResponse& record)
{
auto dataIter = m.find(strSensorData);
assert(dataIter != m.end());
auto sensorData = convertVec(dataIter->second);
if (recordType >= 0xC0 && recordType < 0xE0)
{
record.event.oemCD.timeStamp = static_cast<uint32_t>(
std::chrono::duration_cast<std::chrono::seconds>(timestamp)
.count());
record.event.oemCD.recordType = recordType;
// The ManufactureID and OEM Defined are packed in the sensor data
// Fill the 9 bytes of Manufacture ID and oemDefined
memcpy(&record.event.oemCD.manufacturerID, sensorData.data(),
std::min(sensorData.size(), static_cast<size_t>(oemCDDataSize)));
}
else if (recordType >= 0xE0)
{
record.event.oemEF.recordType = recordType;
// The remaining 13 bytes are the OEM Defined data
memcpy(&record.event.oemEF.oemDefined, sensorData.data(),
std::min(sensorData.size(), static_cast<size_t>(oemEFDataSize)));
}
}
void constructSEL(uint8_t recordType, std::chrono::milliseconds timestamp,
const additionalDataMap& m, const entryDataMap&,
GetSELEntryResponse& record)
{
if (recordType != systemEventRecord)
{
log<level::ERR>("Invalid recordType");
elog<InternalFailure>();
}
// Default values when there is no matched sensor
record.event.eventRecord.sensorType = 0;
record.event.eventRecord.sensorNum = 0xFF;
record.event.eventRecord.eventType = 0;
auto iter = m.find(strSensorPath);
assert(iter != m.end());
const auto& sensorPath = iter->second;
auto sensorIter = invSensors.find(sensorPath);
if (sensorIter != invSensors.end())
{
// There is a matched sensor
record.event.eventRecord.sensorType = sensorIter->second.sensorType;
record.event.eventRecord.sensorNum = sensorIter->second.sensorID;
iter = m.find(strEventDir);
assert(iter != m.end());
auto eventDir = static_cast<uint8_t>(convert(iter->second));
uint8_t assert = eventDir ? assertEvent : deassertEvent;
record.event.eventRecord.eventType =
assert | sensorIter->second.eventReadingType;
}
record.event.eventRecord.recordType = recordType;
record.event.eventRecord.timeStamp = static_cast<uint32_t>(
std::chrono::duration_cast<std::chrono::seconds>(timestamp).count());
iter = m.find(strGenerateId);
assert(iter != m.end());
record.event.eventRecord.generatorID =
static_cast<uint16_t>(convert(iter->second));
record.event.eventRecord.eventMsgRevision = eventMsgRevision;
iter = m.find(strSensorData);
assert(iter != m.end());
auto sensorData = convertVec(iter->second);
// The remaining 3 bytes are the sensor data
memcpy(&record.event.eventRecord.eventData1, sensorData.data(),
std::min(sensorData.size(), static_cast<size_t>(selDataSize)));
}
GetSELEntryResponse
prepareSELEntry(const std::string& objPath,
ipmi::sensor::InvObjectIDMap::const_iterator iter)
{
GetSELEntryResponse record{};
sdbusplus::bus_t bus{ipmid_get_sd_bus_connection()};
auto service = ipmi::getService(bus, logEntryIntf, objPath);
// Read all the log entry properties.
auto methodCall = bus.new_method_call(service.c_str(), objPath.c_str(),
propIntf, "GetAll");
methodCall.append(logEntryIntf);
entryDataMap entryData;
try
{
auto reply = bus.call(methodCall);
reply.read(entryData);
}
catch (const std::exception& e)
{
log<level::ERR>("Error in reading logging property entries",
entry("ERROR=%s", e.what()));
elog<InternalFailure>();
}
// Read Id from the log entry.
static constexpr auto propId = "Id";
auto iterId = entryData.find(propId);
if (iterId == entryData.end())
{
log<level::ERR>("Error in reading Id of logging entry");
elog<InternalFailure>();
}
// Read Timestamp from the log entry.
static constexpr auto propTimeStamp = "Timestamp";
auto iterTimeStamp = entryData.find(propTimeStamp);
if (iterTimeStamp == entryData.end())
{
log<level::ERR>("Error in reading Timestamp of logging entry");
elog<InternalFailure>();
}
std::chrono::milliseconds chronoTimeStamp(
std::get<uint64_t>(iterTimeStamp->second));
bool isFromSELLogger = false;
additionalDataMap m;
// The recordID are with the same offset between different types,
// so we are safe to set the recordID here
record.event.eventRecord.recordID =
static_cast<uint16_t>(std::get<uint32_t>(iterId->second));
iterId = entryData.find(propAdditionalData);
if (iterId != entryData.end())
{
// Check if it's a SEL from phosphor-sel-logger which shall contain
// the record ID, etc
const auto& addData = std::get<AdditionalData>(iterId->second);
m = parseAdditionalData(addData);
auto recordTypeIter = m.find(strRecordType);
if (recordTypeIter != m.end())
{
// It is a SEL from phosphor-sel-logger
isFromSELLogger = true;
}
else
{
// Not a SEL from phosphor-sel-logger, it shall have a valid
// invSensor
if (iter == invSensors.end())
{
log<level::ERR>("System event sensor not found");
elog<InternalFailure>();
}
}
}
if (isFromSELLogger)
{
// It is expected to be a custom SEL entry
auto recordType = static_cast<uint8_t>(convert(m[strRecordType]));
auto isOEM = isRecordOEM(recordType);
if (isOEM)
{
constructOEMSEL(recordType, chronoTimeStamp, m, record);
}
else
{
constructSEL(recordType, chronoTimeStamp, m, entryData, record);
}
}
else
{
record.event.eventRecord.timeStamp = static_cast<uint32_t>(
std::chrono::duration_cast<std::chrono::seconds>(chronoTimeStamp)
.count());
record.event.eventRecord.recordType = systemEventRecord;
record.event.eventRecord.generatorID = generatorID;
record.event.eventRecord.eventMsgRevision = eventMsgRevision;
record.event.eventRecord.sensorType = iter->second.sensorType;
record.event.eventRecord.sensorNum = iter->second.sensorID;
record.event.eventRecord.eventData1 = iter->second.eventOffset;
// Read Resolved from the log entry.
auto iterResolved = entryData.find(propResolved);
if (iterResolved == entryData.end())
{
log<level::ERR>("Error in reading Resolved field of logging entry");
elog<InternalFailure>();
}
// Evaluate if the event is assertion or deassertion event
if (std::get<bool>(iterResolved->second))
{
record.event.eventRecord.eventType = deassertEvent |
iter->second.eventReadingType;
}
else
{
record.event.eventRecord.eventType = iter->second.eventReadingType;
}
}
return record;
}
} // namespace internal
GetSELEntryResponse convertLogEntrytoSEL(const std::string& objPath)
{
sdbusplus::bus_t bus{ipmid_get_sd_bus_connection()};
static constexpr auto assocIntf =
"xyz.openbmc_project.Association.Definitions";
static constexpr auto assocProp = "Associations";
std::vector<ipmi::Association> assocs;
try
{
auto service = ipmi::getService(bus, assocIntf, objPath);
auto propValue = ipmi::getDbusProperty(bus, service, objPath, assocIntf,
assocProp);
assocs = std::get<std::vector<ipmi::Association>>(propValue);
}
catch (const std::exception& e)
{
log<level::ERR>("Error in reading Associations interface",
entry("ERROR=%s", e.what()));
elog<InternalFailure>();
}
/*
* Check if the log entry has any callout associations, if there is a
* callout association try to match the inventory path to the corresponding
* IPMI sensor.
*/
for (const auto& item : assocs)
{
if (std::get<0>(item).compare(CALLOUT_FWD_ASSOCIATION) == 0)
{
auto iter = invSensors.find(std::get<2>(item));
if (iter == invSensors.end())
{
iter = invSensors.find(BOARD_SENSOR);
if (iter == invSensors.end())
{
log<level::ERR>("Motherboard sensor not found");
elog<InternalFailure>();
}
}
return internal::prepareSELEntry(objPath, iter);
}
}
// If there are no callout associations link the log entry to system event
// sensor
auto iter = invSensors.find(SYSTEM_SENSOR);
return internal::prepareSELEntry(objPath, iter);
}
std::chrono::seconds getEntryTimeStamp(const std::string& objPath)
{
sdbusplus::bus_t bus{ipmid_get_sd_bus_connection()};
static constexpr auto propTimeStamp = "Timestamp";
uint64_t timeStamp;
try
{
auto service = ipmi::getService(bus, logEntryIntf, objPath);
auto propValue = ipmi::getDbusProperty(bus, service, objPath,
logEntryIntf, propTimeStamp);
timeStamp = std::get<uint64_t>(propValue);
}
catch (const std::exception& e)
{
log<level::ERR>("Error in reading Timestamp from Entry interface",
entry("ERROR=%s", e.what()));
elog<InternalFailure>();
}
std::chrono::milliseconds chronoTimeStamp(timeStamp);
return std::chrono::duration_cast<std::chrono::seconds>(chronoTimeStamp);
}
void readLoggingObjectPaths(ObjectPaths& paths)
{
sdbusplus::bus_t bus{ipmid_get_sd_bus_connection()};
auto depth = 0;
paths.clear();
auto mapperCall = bus.new_method_call(mapperBusName, mapperObjPath,
mapperIntf, "GetSubTreePaths");
mapperCall.append(logBasePath);
mapperCall.append(depth);
mapperCall.append(ObjectPaths({logEntryIntf}));
try
{
auto reply = bus.call(mapperCall);
reply.read(paths);
}
catch (const sdbusplus::exception_t& e)
{
if (strcmp(e.name(),
"xyz.openbmc_project.Common.Error.ResourceNotFound"))
{
throw;
}
}
std::sort(paths.begin(), paths.end(),
[](const std::string& a, const std::string& b) {
namespace fs = std::filesystem;
fs::path pathA(a);
fs::path pathB(b);
auto idA = std::stoul(pathA.filename().string());
auto idB = std::stoul(pathB.filename().string());
return idA < idB;
});
}
} // namespace sel
} // namespace ipmi