blob: fac2731c7a4cd4a99cc3c928cde7062b2a1cdc05 [file] [log] [blame]
/*
// Copyright (c) 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 <boost/algorithm/string/join.hpp>
#include <me_to_redfish_hooks.hpp>
#include <phosphor-logging/log.hpp>
#include <string_view>
namespace intel_oem::ipmi::sel::redfish_hooks::me
{
namespace health_event
{
namespace smbus_failure
{
static bool messageHook(const SELData& selData, std::string& eventId,
std::vector<std::string>& args)
{
static const boost::container::flat_map<uint8_t, std::string> smlink = {
{0x01, "SmLink0/0B"},
{0x02, "SmLink1"},
{0x03, "SmLink2"},
{0x04, "SmLink3"},
{0x05, "SmLink4"}};
const auto errorDetails = selData.eventData3;
const auto faultySmlink = smlink.find(selData.eventData2);
if (faultySmlink == smlink.end())
{
return false;
}
eventId = "MeSmbusLinkFailure";
args.push_back(faultySmlink->second);
args.push_back(utils::toHex(errorDetails));
return true;
}
} // namespace smbus_failure
namespace fw_status
{
static const boost::container::flat_map<uint8_t, std::string>
manufacturingError = {
{0x00, "Generic error"},
{0x01, "Wrong or missing VSCC table"},
{0x02, "Wrong sensor scanning period in PIA"},
{0x03, "Wrong device definition in PIA"},
{0x04, "Reserved (Wrong SMART/CLST configuration)"},
{0x05, "Intel ME FW configuration is inconsistent or out of range"},
{0x06, "Reserved"},
{0x07, "Intel ME FW configuration is corrupted"},
{0x08, "SMLink0/0B misconfiguration"}};
static const boost::container::flat_map<uint8_t, std::string> peciOverDmiError =
{{0x01, "DRAM Init Done HECI message not received by Intel ME before EOP"},
{0x02, "System PCIe bus configuration not known or not valid on DID HECI "
"message arrival to Intel ME"},
{0x03, "PECI over DMI run-time failure"}};
static const boost::container::flat_map<uint8_t, std::string>
mctpInterfaceError = {
{0x01, "No DID HECI message received before EOP"},
{0x02, "No MCTP_SET_BUS_OWNER HECI message received by Intel ME on EOP "
"arrival "
"to ME while MCTP stack is configured in Bus Owner Proxy mode"}};
static const boost::container::flat_map<uint8_t, std::string>
unsupportedFeature = {{0x00, "Other Segment Defined Feature"},
{0x01, "Fast NM limiting"},
{0x02, "Volumetric Airflow and Outlet Temperature"},
{0x03, "CUPS"},
{0x04, "Thermal policies and Inlet Temperature"},
{0x05, "Platform limiting with MICs"},
{0x07, "Shared power supplies"},
{0x08, "MIC Proxy"},
{0x09, "Reset warning"},
{0x0A, "PMBus Proxy"},
{0x0B, "Always on"},
{0x0C, "IPMI Intel ME FW update"},
{0x0D, "MCTP bus owner"},
{0x0E, "MCTP bus owner proxy"},
{0x0F, "Dual BIOS"},
{0x10, "Battery less"}};
static const boost::container::flat_map<uint8_t, std::string> umaError = {
{0x00, "UMA Read integrity error. Checksum of data read from UMA differs "
"from expected one."},
{0x01, "UMA Read/Write timeout. Timeout occurred during copying data "
"from/to UMA."},
{0x02,
"UMA not granted. BIOS did not grant any UMA or DRAM INIT done message "
"was not received from BIOS before EOP. Intel ME FW goes to recovery."},
{0x03, "UMA size granted by BIOS differs from requested. ME FW goes to "
"recovery."}};
static const boost::container::flat_map<uint8_t, std::string> pttHealthEvent = {
{0x00, "Intel PTT disabled (PTT region is not present)."},
{0x01, "Intel PTT downgrade (PTT data should be not available)."},
{0x02, "Intel PTT disabled (battery less configuration)."}};
static const boost::container::flat_map<uint8_t, std::string>
bootGuardHealthEvent = {
{0x00, "Boot Guard flow error (possible reasons: verification timeout; "
"verification error; BIOS Protection error)."}};
static const boost::container::flat_map<uint8_t, std::string> restrictedMode = {
{0x01, "Firmware entered restricted mode – UMA is not available. "
"Restricted features set."},
{0x02, "Firmware exited restricted mode."}};
static const boost::container::flat_map<uint8_t, std::string>
multiPchModeMisconfig = {
{0x01, "BIOS did not set reset synchronization in multiPCH mode"},
{0x02,
"PMC indicates different non/legacy mode for the PCH than BMC set "
"on the GPIO"},
{0x03,
"Misconfiguration MPCH support enabled due to BTG support enabled"}};
static const boost::container::flat_map<uint8_t, std::string>
flashVerificationError = {
{0x00, "OEM Public Key verification error"},
{0x01, "Flash Descriptor Region Manifest verification error"},
{0x02, "Soft Straps verification error"}};
namespace autoconfiguration
{
bool messageHook(const SELData& selData, std::string& eventId,
std::vector<std::string>& args)
{
static const boost::container::flat_map<uint8_t, std::string> dcSource = {
{0b00, "BMC"}, {0b01, "PSU"}, {0b10, "On-board power sensor"}};
static const boost::container::flat_map<uint8_t, std::string>
chassisSource = {{0b00, "BMC"},
{0b01, "PSU"},
{0b10, "On-board power sensor"},
{0b11, "Not supported"}};
static const boost::container::flat_map<uint8_t, std::string>
efficiencySource = {
{0b00, "BMC"}, {0b01, "PSU"}, {0b11, "Not supported"}};
static const boost::container::flat_map<uint8_t, std::string>
unmanagedSource = {{0b00, "BMC"}, {0b01, "Estimated"}};
static const boost::container::flat_map<uint8_t, std::string>
failureReason = {{0b00, "BMC discovery failure"},
{0b01, "Insufficient factory configuration"},
{0b10, "Unknown sensor type"},
{0b11, "Other error encountered"}};
auto succeeded = selData.eventData3 >> 7 & 0b1;
if (succeeded)
{
eventId = "MeAutoConfigSuccess";
auto dc = dcSource.find(selData.eventData3 >> 5 & 0b11);
auto chassis = chassisSource.find(selData.eventData3 >> 3 & 0b11);
auto efficiency = efficiencySource.find(selData.eventData3 >> 1 & 0b11);
auto unmanaged = unmanagedSource.find(selData.eventData3 & 0b1);
if (dc == dcSource.end() || chassis == chassisSource.end() ||
efficiency == efficiencySource.end() ||
unmanaged == unmanagedSource.end())
{
return false;
}
args.push_back(dc->second);
args.push_back(chassis->second);
args.push_back(efficiency->second);
args.push_back(unmanaged->second);
}
else
{
eventId = "MeAutoConfigFailed";
const auto it = failureReason.find(selData.eventData3 >> 5 & 0b11);
if (it == failureReason.end())
{
return false;
}
args.push_back(it->second);
}
return true;
}
} // namespace autoconfiguration
namespace factory_reset
{
bool messageHook(const SELData& selData, std::string& eventId,
std::vector<std::string>& args)
{
static const boost::container::flat_map<uint8_t, std::string>
restoreToFactoryPreset = {
{0x00,
"Flash file system error detected. Automatic restore to factory "
"presets has been triggered."},
{0x01, "Automatic restore to factory presets has been completed."},
{0x02,
"Restore to factory presets triggered by “Force ME Recovery” "
"IPMI command has been completed."},
{0x03,
"Restore to factory presets triggered by AC power cycle with "
"Recovery jumper asserted has been completed."}};
auto param = restoreToFactoryPreset.find(selData.eventData3);
if (param == restoreToFactoryPreset.end())
{
return false;
}
if (selData.eventData3 == 0x00)
{
eventId = "MeFactoryResetError";
}
else
{
eventId = "MeFactoryRestore";
}
args.push_back(param->second);
return true;
}
} // namespace factory_reset
namespace flash_state
{
bool messageHook(const SELData& selData, std::string& eventId,
std::vector<std::string>& args)
{
static const boost::container::flat_map<uint8_t, std::string>
flashStateInformation = {
{0x00,
"Flash partition table, recovery image or factory presets image "
"corrupted"},
{0x01, "Flash erase limit has been reached"},
{0x02,
"Flash write limit has been reached. Writing to flash has been "
"disabled"},
{0x03, "Writing to the flash has been enabled"}};
auto param = flashStateInformation.find(selData.eventData3);
if (param == flashStateInformation.end())
{
return false;
}
if (selData.eventData3 == 0x03)
{
eventId = "MeFlashStateInformationWritingEnabled";
}
else
{
eventId = "MeFlashStateInformation";
}
args.push_back(param->second);
return true;
}
} // namespace flash_state
static bool messageHook(const SELData& selData, std::string& eventId,
std::vector<std::string>& args)
{
static const boost::container::flat_map<
uint8_t,
std::pair<std::string, std::optional<std::variant<utils::ParserFunc,
utils::MessageMap>>>>
eventMap = {
{0x00, {"MeRecoveryGpioForced", {}}},
{0x01, {"MeImageExecutionFailed", {}}},
{0x02, {"MeFlashEraseError", {}}},
{0x03, {{}, flash_state::messageHook}},
{0x04, {"MeInternalError", {}}},
{0x05, {"MeExceptionDuringShutdown", {}}},
{0x06, {"MeDirectFlashUpdateRequested", {}}},
{0x07, {"MeManufacturingError", manufacturingError}},
{0x08, {{}, factory_reset::messageHook}},
{0x09, {"MeFirmwareException", utils::logByteHex<2>}},
{0x0A, {"MeFlashWearOutWarning", utils::logByteDec<2>}},
{0x0D, {"MePeciOverDmiError", peciOverDmiError}},
{0x0E, {"MeMctpInterfaceError", mctpInterfaceError}},
{0x0F, {{}, autoconfiguration::messageHook}},
{0x10, {"MeUnsupportedFeature", unsupportedFeature}},
{0x12, {"MeCpuDebugCapabilityDisabled", {}}},
{0x13, {"MeUmaError", umaError}},
{0x16, {"MePttHealthEvent", pttHealthEvent}},
{0x17, {"MeBootGuardHealthEvent", bootGuardHealthEvent}},
{0x18, {"MeRestrictedMode", restrictedMode}},
{0x19, {"MeMultiPchModeMisconfig", multiPchModeMisconfig}},
{0x1A, {"MeFlashVerificationError", flashVerificationError}}};
return utils::genericMessageHook(eventMap, selData, eventId, args);
}
} // namespace fw_status
static bool messageHook(const SELData& selData, std::string& eventId,
std::vector<std::string>& args)
{
const HealthEventType healthEventType =
static_cast<HealthEventType>(selData.offset);
switch (healthEventType)
{
case HealthEventType::FirmwareStatus:
return fw_status::messageHook(selData, eventId, args);
break;
case HealthEventType::SmbusLinkFailure:
return smbus_failure::messageHook(selData, eventId, args);
break;
}
return false;
}
} // namespace health_event
/**
* @brief Main entry point for parsing ME IPMI Platform Events
*
* @brief selData - IPMI Platform Event structure
* @brief ipmiRaw - the same event in raw binary form
*
* @returns true if event was successfully parsed and consumed
*/
bool messageHook(const SELData& selData, const std::string& ipmiRaw)
{
const EventSensor meSensor = static_cast<EventSensor>(selData.sensorNum);
std::string eventId;
std::vector<std::string> args;
switch (meSensor)
{
case EventSensor::MeFirmwareHealth:
if (health_event::messageHook(selData, eventId, args))
{
utils::storeRedfishEvent(ipmiRaw, eventId, args);
return true;
}
break;
}
return defaultMessageHook(ipmiRaw);
}
} // namespace intel_oem::ipmi::sel::redfish_hooks::me