blob: 0e6fb8db1cf2738ef0f7063ae4d4cf5e824b32b1 [file] [log] [blame]
#include "config.h"
#include "occ_manager.hpp"
#include "i2c_occ.hpp"
#include "occ_dbus.hpp"
#include "utils.hpp"
#include <phosphor-logging/elog-errors.hpp>
#include <phosphor-logging/log.hpp>
#include <xyz/openbmc_project/Common/error.hpp>
#include <chrono>
#include <cmath>
#include <filesystem>
#include <fstream>
#include <regex>
namespace open_power
{
namespace occ
{
constexpr uint32_t fruTypeNotAvailable = 0xFF;
constexpr auto fruTypeSuffix = "fru_type";
constexpr auto faultSuffix = "fault";
constexpr auto inputSuffix = "input";
constexpr auto maxSuffix = "max";
const auto HOST_ON_FILE = "/run/openbmc/host@0-on";
using namespace phosphor::logging;
using namespace std::literals::chrono_literals;
template <typename T>
T readFile(const std::string& path)
{
std::ifstream ifs;
ifs.exceptions(std::ifstream::failbit | std::ifstream::badbit |
std::ifstream::eofbit);
T data;
try
{
ifs.open(path);
ifs >> data;
ifs.close();
}
catch (const std::exception& e)
{
auto err = errno;
throw std::system_error(err, std::generic_category());
}
return data;
}
void Manager::findAndCreateObjects()
{
#ifndef POWER10
for (auto id = 0; id < MAX_CPUS; ++id)
{
// Create one occ per cpu
auto occ = std::string(OCC_NAME) + std::to_string(id);
createObjects(occ);
}
#else
if (!pmode)
{
// Create the power mode object
pmode = std::make_unique<powermode::PowerMode>(
*this, powermode::PMODE_PATH, powermode::PIPS_PATH, event);
}
if (!fs::exists(HOST_ON_FILE))
{
static bool statusObjCreated = false;
if (!statusObjCreated)
{
// Create the OCCs based on on the /dev/occX devices
auto occs = findOCCsInDev();
if (occs.empty() || (prevOCCSearch.size() != occs.size()))
{
// Something changed or no OCCs yet, try again in 10s.
// Note on the first pass prevOCCSearch will be empty,
// so there will be at least one delay to give things
// a chance to settle.
prevOCCSearch = occs;
log<level::INFO>(
fmt::format(
"Manager::findAndCreateObjects(): Waiting for OCCs (currently {})",
occs.size())
.c_str());
discoverTimer->restartOnce(10s);
}
else
{
// All OCCs appear to be available, create status objects
// createObjects requires OCC0 first.
std::sort(occs.begin(), occs.end());
log<level::INFO>(
fmt::format(
"Manager::findAndCreateObjects(): Creating {} OCC Status Objects",
occs.size())
.c_str());
for (auto id : occs)
{
createObjects(std::string(OCC_NAME) + std::to_string(id));
}
statusObjCreated = true;
waitingForAllOccActiveSensors = true;
}
}
if (statusObjCreated && waitingForAllOccActiveSensors)
{
static bool tracedHostWait = false;
if (utils::isHostRunning())
{
if (tracedHostWait)
{
log<level::INFO>(
"Manager::findAndCreateObjects(): Host is running");
tracedHostWait = false;
}
checkAllActiveSensors();
}
else
{
if (!tracedHostWait)
{
log<level::INFO>(
"Manager::findAndCreateObjects(): Waiting for host to start");
tracedHostWait = true;
}
discoverTimer->restartOnce(30s);
}
}
}
else
{
log<level::INFO>(
fmt::format(
"Manager::findAndCreateObjects(): Waiting for {} to complete...",
HOST_ON_FILE)
.c_str());
discoverTimer->restartOnce(10s);
}
#endif
}
#ifdef POWER10
// Check if all occActive sensors are available
void Manager::checkAllActiveSensors()
{
static bool allActiveSensorAvailable = false;
static bool tracedSensorWait = false;
// Start with the assumption that all are available
allActiveSensorAvailable = true;
for (auto& obj : statusObjects)
{
// If active sensor is already true, then no need to query sensor
if (!obj->occActive())
{
auto instance = obj->getOccInstanceID();
// Check if sensor was queued while waiting for discovery
auto match = queuedActiveState.find(instance);
if (match != queuedActiveState.end())
{
log<level::INFO>(
fmt::format(
"checkAllActiveSensors(): OCC{} is ACTIVE (queued)",
instance)
.c_str());
obj->occActive(true);
}
else
{
allActiveSensorAvailable = false;
if (!tracedSensorWait)
{
log<level::INFO>(
fmt::format(
"checkAllActiveSensors(): Waiting on OCC{} Active sensor",
instance)
.c_str());
tracedSensorWait = true;
}
pldmHandle->checkActiveSensor(obj->getOccInstanceID());
break;
}
}
}
if (allActiveSensorAvailable)
{
// All sensors were found, disable the discovery timer
discoverTimer.reset();
waitingForAllOccActiveSensors = false;
queuedActiveState.clear();
log<level::INFO>(
"checkAllActiveSensors(): OCC Active sensors are available");
tracedSensorWait = false;
}
else
{
// Not all sensors were available, so keep waiting
if (!tracedSensorWait)
{
log<level::INFO>(
"checkAllActiveSensors(): Waiting for OCC Active sensors to become available");
tracedSensorWait = true;
}
discoverTimer->restartOnce(10s);
}
}
#endif
std::vector<int> Manager::findOCCsInDev()
{
std::vector<int> occs;
std::regex expr{R"(occ(\d+)$)"};
for (auto& file : fs::directory_iterator("/dev"))
{
std::smatch match;
std::string path{file.path().string()};
if (std::regex_search(path, match, expr))
{
auto num = std::stoi(match[1].str());
// /dev numbering starts at 1, ours starts at 0.
occs.push_back(num - 1);
}
}
return occs;
}
int Manager::cpuCreated(sdbusplus::message::message& msg)
{
namespace fs = std::filesystem;
sdbusplus::message::object_path o;
msg.read(o);
fs::path cpuPath(std::string(std::move(o)));
auto name = cpuPath.filename().string();
auto index = name.find(CPU_NAME);
name.replace(index, std::strlen(CPU_NAME), OCC_NAME);
createObjects(name);
return 0;
}
void Manager::createObjects(const std::string& occ)
{
auto path = fs::path(OCC_CONTROL_ROOT) / occ;
statusObjects.emplace_back(std::make_unique<Status>(
event, path.c_str(), *this,
#ifdef POWER10
pmode,
#endif
std::bind(std::mem_fn(&Manager::statusCallBack), this,
std::placeholders::_1, std::placeholders::_2)
#ifdef PLDM
,
std::bind(std::mem_fn(&pldm::Interface::resetOCC), pldmHandle.get(),
std::placeholders::_1)
#endif
));
// Create the power cap monitor object
if (!pcap)
{
pcap = std::make_unique<open_power::occ::powercap::PowerCap>(
*statusObjects.back());
}
if (statusObjects.back()->isMasterOcc())
{
log<level::INFO>(
fmt::format("Manager::createObjects(): OCC{} is the master",
statusObjects.back()->getOccInstanceID())
.c_str());
_pollTimer->setEnabled(false);
#ifdef POWER10
// Set the master OCC on the PowerMode object
pmode->setMasterOcc(path);
#endif
}
passThroughObjects.emplace_back(std::make_unique<PassThrough>(path.c_str()
#ifdef POWER10
,
pmode
#endif
));
}
void Manager::statusCallBack(instanceID instance, bool status)
{
using InternalFailure =
sdbusplus::xyz::openbmc_project::Common::Error::InternalFailure;
// At this time, it won't happen but keeping it
// here just in case something changes in the future
if ((activeCount == 0) && (!status))
{
log<level::ERR>(
fmt::format("Invalid update on OCCActive with OCC{}", instance)
.c_str());
elog<InternalFailure>();
}
if (status == true)
{
// OCC went active
++activeCount;
#ifdef POWER10
if (activeCount == 1)
{
// First OCC went active (allow some time for all OCCs to go active)
waitForAllOccsTimer->restartOnce(60s);
}
#endif
if (activeCount == statusObjects.size())
{
#ifdef POWER10
// All OCCs are now running
if (waitForAllOccsTimer->isEnabled())
{
// stop occ wait timer
waitForAllOccsTimer->setEnabled(false);
}
#endif
// Verify master OCC and start presence monitor
validateOccMaster();
}
// Start poll timer if not already started
if (!_pollTimer->isEnabled())
{
log<level::INFO>(
fmt::format("Manager: OCCs will be polled every {} seconds",
pollInterval)
.c_str());
// Send poll and start OCC poll timer
pollerTimerExpired();
}
}
else
{
// OCC went away
--activeCount;
if (activeCount == 0)
{
// No OCCs are running
// Stop OCC poll timer
if (_pollTimer->isEnabled())
{
log<level::INFO>(
"Manager::statusCallBack(): OCCs are not running, stopping poll timer");
_pollTimer->setEnabled(false);
}
#ifdef POWER10
// stop wait timer
if (waitForAllOccsTimer->isEnabled())
{
waitForAllOccsTimer->setEnabled(false);
}
#endif
}
#ifdef READ_OCC_SENSORS
// Clear OCC sensors
setSensorValueToNonFunctional(instance);
#endif
}
#ifdef POWER10
if (waitingForAllOccActiveSensors)
{
if (utils::isHostRunning())
{
checkAllActiveSensors();
}
}
#endif
}
#ifdef I2C_OCC
void Manager::initStatusObjects()
{
// Make sure we have a valid path string
static_assert(sizeof(DEV_PATH) != 0);
auto deviceNames = i2c_occ::getOccHwmonDevices(DEV_PATH);
for (auto& name : deviceNames)
{
i2c_occ::i2cToDbus(name);
name = std::string(OCC_NAME) + '_' + name;
auto path = fs::path(OCC_CONTROL_ROOT) / name;
statusObjects.emplace_back(
std::make_unique<Status>(event, path.c_str(), *this));
}
// The first device is master occ
pcap = std::make_unique<open_power::occ::powercap::PowerCap>(
*statusObjects.front());
#ifdef POWER10
pmode = std::make_unique<powermode::PowerMode>(*this, powermode::PMODE_PATH,
powermode::PIPS_PATH);
// Set the master OCC on the PowerMode object
pmode->setMasterOcc(path);
#endif
}
#endif
#ifdef PLDM
void Manager::sbeTimeout(unsigned int instance)
{
auto obj = std::find_if(statusObjects.begin(), statusObjects.end(),
[instance](const auto& obj) {
return instance == obj->getOccInstanceID();
});
if (obj != statusObjects.end() && (*obj)->occActive())
{
log<level::INFO>(
fmt::format("SBE timeout, requesting HRESET (OCC{})", instance)
.c_str());
setSBEState(instance, SBE_STATE_NOT_USABLE);
pldmHandle->sendHRESET(instance);
}
}
bool Manager::updateOCCActive(instanceID instance, bool status)
{
auto obj = std::find_if(statusObjects.begin(), statusObjects.end(),
[instance](const auto& obj) {
return instance == obj->getOccInstanceID();
});
if (obj != statusObjects.end())
{
return (*obj)->occActive(status);
}
else
{
log<level::WARNING>(
fmt::format(
"Manager::updateOCCActive: No status object to update for OCC{} (active={})",
instance, status)
.c_str());
if (status == true)
{
// OCC went active
queuedActiveState.insert(instance);
}
else
{
auto match = queuedActiveState.find(instance);
if (match != queuedActiveState.end())
{
// OCC was disabled
queuedActiveState.erase(match);
}
}
return false;
}
}
void Manager::sbeHRESETResult(instanceID instance, bool success)
{
if (success)
{
log<level::INFO>(
fmt::format("HRESET succeeded (OCC{})", instance).c_str());
setSBEState(instance, SBE_STATE_BOOTED);
return;
}
setSBEState(instance, SBE_STATE_FAILED);
if (sbeCanDump(instance))
{
log<level::INFO>(
fmt::format("HRESET failed (OCC{}), triggering SBE dump", instance)
.c_str());
auto& bus = utils::getBus();
uint32_t src6 = instance << 16;
uint32_t logId =
FFDC::createPEL("org.open_power.Processor.Error.SbeChipOpTimeout",
src6, "SBE command timeout");
try
{
constexpr auto path = "/org/openpower/dump";
constexpr auto interface = "xyz.openbmc_project.Dump.Create";
constexpr auto function = "CreateDump";
std::string service = utils::getService(path, interface);
auto method =
bus.new_method_call(service.c_str(), path, interface, function);
std::map<std::string, std::variant<std::string, uint64_t>>
createParams{
{"com.ibm.Dump.Create.CreateParameters.ErrorLogId",
uint64_t(logId)},
{"com.ibm.Dump.Create.CreateParameters.DumpType",
"com.ibm.Dump.Create.DumpType.SBE"},
{"com.ibm.Dump.Create.CreateParameters.FailingUnitId",
uint64_t(instance)},
};
method.append(createParams);
auto response = bus.call(method);
}
catch (const sdbusplus::exception::exception& e)
{
constexpr auto ERROR_DUMP_DISABLED =
"xyz.openbmc_project.Dump.Create.Error.Disabled";
if (e.name() == ERROR_DUMP_DISABLED)
{
log<level::INFO>("Dump is disabled, skipping");
}
else
{
log<level::ERR>("Dump failed");
}
}
}
}
bool Manager::sbeCanDump(unsigned int instance)
{
struct pdbg_target* proc = getPdbgTarget(instance);
if (!proc)
{
// allow the dump in the error case
return true;
}
try
{
if (!openpower::phal::sbe::isDumpAllowed(proc))
{
return false;
}
if (openpower::phal::pdbg::isSbeVitalAttnActive(proc))
{
return false;
}
}
catch (openpower::phal::exception::SbeError& e)
{
log<level::INFO>("Failed to query SBE state");
}
// allow the dump in the error case
return true;
}
void Manager::setSBEState(unsigned int instance, enum sbe_state state)
{
struct pdbg_target* proc = getPdbgTarget(instance);
if (!proc)
{
return;
}
try
{
openpower::phal::sbe::setState(proc, state);
}
catch (const openpower::phal::exception::SbeError& e)
{
log<level::ERR>("Failed to set SBE state");
}
}
struct pdbg_target* Manager::getPdbgTarget(unsigned int instance)
{
if (!pdbgInitialized)
{
try
{
openpower::phal::pdbg::init();
pdbgInitialized = true;
}
catch (const openpower::phal::exception::PdbgError& e)
{
log<level::ERR>("pdbg initialization failed");
return nullptr;
}
}
struct pdbg_target* proc = nullptr;
pdbg_for_each_class_target("proc", proc)
{
if (pdbg_target_index(proc) == instance)
{
return proc;
}
}
log<level::ERR>("Failed to get pdbg target");
return nullptr;
}
#endif
void Manager::pollerTimerExpired()
{
if (!_pollTimer)
{
log<level::ERR>(
"Manager::pollerTimerExpired() ERROR: Timer not defined");
return;
}
for (auto& obj : statusObjects)
{
if (!obj->occActive())
{
// OCC is not running yet
#ifdef READ_OCC_SENSORS
auto id = obj->getOccInstanceID();
setSensorValueToNonFunctional(id);
#endif
continue;
}
// Read sysfs to force kernel to poll OCC
obj->readOccState();
#ifdef READ_OCC_SENSORS
// Read occ sensor values
getSensorValues(obj);
#endif
}
if (activeCount > 0)
{
// Restart OCC poll timer
_pollTimer->restartOnce(std::chrono::seconds(pollInterval));
}
else
{
// No OCCs running, so poll timer will not be restarted
log<level::INFO>(
fmt::format(
"Manager::pollerTimerExpired: poll timer will not be restarted")
.c_str());
}
}
#ifdef READ_OCC_SENSORS
void Manager::readTempSensors(const fs::path& path, uint32_t id)
{
std::regex expr{"temp\\d+_label$"}; // Example: temp5_label
for (auto& file : fs::directory_iterator(path))
{
if (!std::regex_search(file.path().string(), expr))
{
continue;
}
uint32_t labelValue{0};
try
{
labelValue = readFile<uint32_t>(file.path());
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format("readTempSensors: Failed reading {}, errno = {}",
file.path().string(), e.code().value())
.c_str());
continue;
}
const std::string& tempLabel = "label";
const std::string filePathString = file.path().string().substr(
0, file.path().string().length() - tempLabel.length());
uint32_t fruTypeValue{0};
try
{
fruTypeValue = readFile<uint32_t>(filePathString + fruTypeSuffix);
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format("readTempSensors: Failed reading {}, errno = {}",
filePathString + fruTypeSuffix, e.code().value())
.c_str());
continue;
}
std::string sensorPath =
OCC_SENSORS_ROOT + std::string("/temperature/");
std::string dvfsTempPath;
if (fruTypeValue == VRMVdd)
{
sensorPath.append("vrm_vdd" + std::to_string(id) + "_temp");
}
else if (fruTypeValue == processorIoRing)
{
sensorPath.append("proc" + std::to_string(id) + "_ioring_temp");
dvfsTempPath = std::string{OCC_SENSORS_ROOT} + "/temperature/proc" +
std::to_string(id) + "_ioring_dvfs_temp";
}
else
{
uint16_t type = (labelValue & 0xFF000000) >> 24;
uint16_t instanceID = labelValue & 0x0000FFFF;
if (type == OCC_DIMM_TEMP_SENSOR_TYPE)
{
if (fruTypeValue == fruTypeNotAvailable)
{
// Not all DIMM related temps are available to read
// (no _input file in this case)
continue;
}
auto iter = dimmTempSensorName.find(fruTypeValue);
if (iter == dimmTempSensorName.end())
{
log<level::ERR>(
fmt::format(
"readTempSensors: Fru type error! fruTypeValue = {}) ",
fruTypeValue)
.c_str());
continue;
}
sensorPath.append("dimm" + std::to_string(instanceID) +
iter->second);
}
else if (type == OCC_CPU_TEMP_SENSOR_TYPE)
{
if (fruTypeValue == processorCore)
{
// The OCC reports small core temps, of which there are
// two per big core. All current P10 systems are in big
// core mode, so use a big core name.
uint16_t coreNum = instanceID / 2;
uint16_t tempNum = instanceID % 2;
sensorPath.append("proc" + std::to_string(id) + "_core" +
std::to_string(coreNum) + "_" +
std::to_string(tempNum) + "_temp");
dvfsTempPath = std::string{OCC_SENSORS_ROOT} +
"/temperature/proc" + std::to_string(id) +
"_core_dvfs_temp";
}
else
{
continue;
}
}
else
{
continue;
}
}
// The dvfs temp file only needs to be read once per chip per type.
if (!dvfsTempPath.empty() &&
!dbus::OccDBusSensors::getOccDBus().hasDvfsTemp(dvfsTempPath))
{
try
{
auto dvfsValue = readFile<double>(filePathString + maxSuffix);
dbus::OccDBusSensors::getOccDBus().setDvfsTemp(
dvfsTempPath, dvfsValue * std::pow(10, -3));
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format(
"readTempSensors: Failed reading {}, errno = {}",
filePathString + maxSuffix, e.code().value())
.c_str());
}
}
uint32_t faultValue{0};
try
{
faultValue = readFile<uint32_t>(filePathString + faultSuffix);
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format("readTempSensors: Failed reading {}, errno = {}",
filePathString + faultSuffix, e.code().value())
.c_str());
continue;
}
if (faultValue != 0)
{
dbus::OccDBusSensors::getOccDBus().setValue(
sensorPath, std::numeric_limits<double>::quiet_NaN());
dbus::OccDBusSensors::getOccDBus().setOperationalStatus(sensorPath,
false);
continue;
}
double tempValue{0};
try
{
tempValue = readFile<double>(filePathString + inputSuffix);
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format("readTempSensors: Failed reading {}, errno = {}",
filePathString + inputSuffix, e.code().value())
.c_str());
continue;
}
dbus::OccDBusSensors::getOccDBus().setValue(
sensorPath, tempValue * std::pow(10, -3));
dbus::OccDBusSensors::getOccDBus().setOperationalStatus(sensorPath,
true);
// At this point, the sensor will be created for sure.
if (existingSensors.find(sensorPath) == existingSensors.end())
{
dbus::OccDBusSensors::getOccDBus().setChassisAssociation(
sensorPath);
}
existingSensors[sensorPath] = id;
}
return;
}
std::optional<std::string>
Manager::getPowerLabelFunctionID(const std::string& value)
{
// If the value is "system", then the FunctionID is "system".
if (value == "system")
{
return value;
}
// If the value is not "system", then the label value have 3 numbers, of
// which we only care about the middle one:
// <sensor id>_<function id>_<apss channel>
// eg: The value is "0_10_5" , then the FunctionID is "10".
if (value.find("_") == std::string::npos)
{
return std::nullopt;
}
auto powerLabelValue = value.substr((value.find("_") + 1));
if (powerLabelValue.find("_") == std::string::npos)
{
return std::nullopt;
}
return powerLabelValue.substr(0, powerLabelValue.find("_"));
}
void Manager::readPowerSensors(const fs::path& path, uint32_t id)
{
std::regex expr{"power\\d+_label$"}; // Example: power5_label
for (auto& file : fs::directory_iterator(path))
{
if (!std::regex_search(file.path().string(), expr))
{
continue;
}
std::string labelValue;
try
{
labelValue = readFile<std::string>(file.path());
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format("readPowerSensors: Failed reading {}, errno = {}",
file.path().string(), e.code().value())
.c_str());
continue;
}
auto functionID = getPowerLabelFunctionID(labelValue);
if (functionID == std::nullopt)
{
continue;
}
const std::string& tempLabel = "label";
const std::string filePathString = file.path().string().substr(
0, file.path().string().length() - tempLabel.length());
std::string sensorPath = OCC_SENSORS_ROOT + std::string("/power/");
auto iter = powerSensorName.find(*functionID);
if (iter == powerSensorName.end())
{
continue;
}
sensorPath.append(iter->second);
double tempValue{0};
try
{
tempValue = readFile<double>(filePathString + inputSuffix);
}
catch (const std::system_error& e)
{
log<level::DEBUG>(
fmt::format("readPowerSensors: Failed reading {}, errno = {}",
filePathString + inputSuffix, e.code().value())
.c_str());
continue;
}
dbus::OccDBusSensors::getOccDBus().setUnit(
sensorPath, "xyz.openbmc_project.Sensor.Value.Unit.Watts");
dbus::OccDBusSensors::getOccDBus().setValue(
sensorPath, tempValue * std::pow(10, -3) * std::pow(10, -3));
dbus::OccDBusSensors::getOccDBus().setOperationalStatus(sensorPath,
true);
if (existingSensors.find(sensorPath) == existingSensors.end())
{
dbus::OccDBusSensors::getOccDBus().setChassisAssociation(
sensorPath);
}
existingSensors[sensorPath] = id;
}
return;
}
void Manager::setSensorValueToNaN(uint32_t id)
{
for (const auto& [sensorPath, occId] : existingSensors)
{
if (occId == id)
{
dbus::OccDBusSensors::getOccDBus().setValue(
sensorPath, std::numeric_limits<double>::quiet_NaN());
}
}
return;
}
void Manager::setSensorValueToNonFunctional(uint32_t id) const
{
for (const auto& [sensorPath, occId] : existingSensors)
{
if (occId == id)
{
dbus::OccDBusSensors::getOccDBus().setValue(
sensorPath, std::numeric_limits<double>::quiet_NaN());
dbus::OccDBusSensors::getOccDBus().setOperationalStatus(sensorPath,
false);
}
}
return;
}
void Manager::getSensorValues(std::unique_ptr<Status>& occ)
{
static bool tracedError[8] = {0};
const fs::path sensorPath = occ->getHwmonPath();
const uint32_t id = occ->getOccInstanceID();
if (fs::exists(sensorPath))
{
// Read temperature sensors
readTempSensors(sensorPath, id);
if (occ->isMasterOcc())
{
// Read power sensors
readPowerSensors(sensorPath, id);
}
tracedError[id] = false;
}
else
{
if (!tracedError[id])
{
log<level::ERR>(
fmt::format(
"Manager::getSensorValues: OCC{} sensor path missing: {}",
id, sensorPath.c_str())
.c_str());
tracedError[id] = true;
}
}
return;
}
#endif
// Read the altitude from DBus
void Manager::readAltitude()
{
static bool traceAltitudeErr = true;
utils::PropertyValue altitudeProperty{};
try
{
altitudeProperty = utils::getProperty(ALTITUDE_PATH, ALTITUDE_INTERFACE,
ALTITUDE_PROP);
auto sensorVal = std::get<double>(altitudeProperty);
if (sensorVal < 0xFFFF)
{
if (sensorVal < 0)
{
altitude = 0;
}
else
{
// Round to nearest meter
altitude = uint16_t(sensorVal + 0.5);
}
log<level::DEBUG>(fmt::format("readAltitude: sensor={} ({}m)",
sensorVal, altitude)
.c_str());
traceAltitudeErr = true;
}
else
{
if (traceAltitudeErr)
{
traceAltitudeErr = false;
log<level::DEBUG>(
fmt::format("Invalid altitude value: {}", sensorVal)
.c_str());
}
}
}
catch (const sdbusplus::exception::exception& e)
{
if (traceAltitudeErr)
{
traceAltitudeErr = false;
log<level::INFO>(
fmt::format("Unable to read Altitude: {}", e.what()).c_str());
}
altitude = 0xFFFF; // not available
}
}
// Callback function when ambient temperature changes
void Manager::ambientCallback(sdbusplus::message::message& msg)
{
double currentTemp = 0;
uint8_t truncatedTemp = 0xFF;
std::string msgSensor;
std::map<std::string, std::variant<double>> msgData;
msg.read(msgSensor, msgData);
auto valPropMap = msgData.find(AMBIENT_PROP);
if (valPropMap == msgData.end())
{
log<level::DEBUG>("ambientCallback: Unknown ambient property changed");
return;
}
currentTemp = std::get<double>(valPropMap->second);
if (std::isnan(currentTemp))
{
truncatedTemp = 0xFF;
}
else
{
if (currentTemp < 0)
{
truncatedTemp = 0;
}
else
{
// Round to nearest degree C
truncatedTemp = uint8_t(currentTemp + 0.5);
}
}
// If ambient changes, notify OCCs
if (truncatedTemp != ambient)
{
log<level::DEBUG>(
fmt::format("ambientCallback: Ambient change from {} to {}C",
ambient, currentTemp)
.c_str());
ambient = truncatedTemp;
if (altitude == 0xFFFF)
{
// No altitude yet, try reading again
readAltitude();
}
log<level::DEBUG>(
fmt::format("ambientCallback: Ambient: {}C, altitude: {}m", ambient,
altitude)
.c_str());
#ifdef POWER10
// Send ambient and altitude to all OCCs
for (auto& obj : statusObjects)
{
if (obj->occActive())
{
obj->sendAmbient(ambient, altitude);
}
}
#endif // POWER10
}
}
// return the current ambient and altitude readings
void Manager::getAmbientData(bool& ambientValid, uint8_t& ambientTemp,
uint16_t& altitudeValue) const
{
ambientValid = true;
ambientTemp = ambient;
altitudeValue = altitude;
if (ambient == 0xFF)
{
ambientValid = false;
}
}
#ifdef POWER10
void Manager::occsNotAllRunning()
{
// Function will also gets called when occ-control app gets
// restarted. (occ active sensors do not change, so the Status
// object does not call Manager back for all OCCs)
if (activeCount != statusObjects.size())
{
// Not all OCCs went active
log<level::WARNING>(
fmt::format(
"occsNotAllRunning: Active OCC count ({}) does not match expected count ({})",
activeCount, statusObjects.size())
.c_str());
// Procs may be garded, so may not need reset.
}
validateOccMaster();
}
#endif // POWER10
// Verify single master OCC and start presence monitor
void Manager::validateOccMaster()
{
int masterInstance = -1;
for (auto& obj : statusObjects)
{
auto instance = obj->getOccInstanceID();
#ifdef POWER10
if (!obj->occActive())
{
if (utils::isHostRunning())
{
// Check if sensor was queued while waiting for discovery
auto match = queuedActiveState.find(instance);
if (match != queuedActiveState.end())
{
log<level::INFO>(
fmt::format(
"validateOccMaster: OCC{} is ACTIVE (queued)",
instance)
.c_str());
obj->occActive(true);
}
else
{
// OCC does not appear to be active yet, check active sensor
pldmHandle->checkActiveSensor(instance);
if (obj->occActive())
{
log<level::INFO>(
fmt::format(
"validateOccMaster: OCC{} is ACTIVE after reading sensor",
instance)
.c_str());
}
}
}
else
{
log<level::WARNING>(
fmt::format(
"validateOccMaster: HOST is not running (OCC{})",
instance)
.c_str());
return;
}
}
#endif // POWER10
if (obj->isMasterOcc())
{
obj->addPresenceWatchMaster();
if (masterInstance == -1)
{
masterInstance = instance;
}
else
{
log<level::ERR>(
fmt::format(
"validateOccMaster: Multiple OCC masters! ({} and {})",
masterInstance, instance)
.c_str());
// request reset
obj->deviceError();
}
}
}
if (masterInstance < 0)
{
log<level::ERR>(
fmt::format("validateOccMaster: Master OCC not found! (of {} OCCs)",
statusObjects.size())
.c_str());
// request reset
statusObjects.front()->deviceError();
}
else
{
log<level::INFO>(
fmt::format("validateOccMaster: OCC{} is master of {} OCCs",
masterInstance, activeCount)
.c_str());
}
}
void Manager::updatePcapBounds() const
{
if (pcap)
{
pcap->updatePcapBounds();
}
}
} // namespace occ
} // namespace open_power