power-sequencer/ucd90160.cpp - openbmc/phosphor-power - Gitiles

 /**
  * Copyright © 2017 IBM 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 "ucd90160.hpp"

 #include "names_values.hpp"
 #include "utility.hpp"

 #include <elog-errors.hpp>
 #include <org/open_power/Witherspoon/Fault/error.hpp>
 #include <phosphor-logging/elog.hpp>
 #include <phosphor-logging/log.hpp>
 #include <xyz/openbmc_project/Common/Device/error.hpp>

 #include <map>
 #include <memory>

 namespace phosphor
 {
 namespace power
 {

 using namespace std::string_literals;

 const auto MFR_STATUS = "mfr_status"s;

 const auto DEVICE_NAME = "UCD90160"s;
 const auto DRIVER_NAME = "ucd9000"s;
 constexpr auto NUM_PAGES = 16;

 constexpr auto INVENTORY_OBJ_PATH = "/xyz/openbmc_project/inventory";

 namespace fs = std::filesystem;
 using namespace gpio;
 using namespace pmbus;
 using namespace phosphor::logging;

 namespace device_error = sdbusplus::xyz::openbmc_project::Common::Device::Error;
 namespace power_error = sdbusplus::org::open_power::Witherspoon::Fault::Error;

 UCD90160::UCD90160(size_t instance, sdbusplus::bus::bus& bus) :
     Device(DEVICE_NAME, instance),
     interface(std::get<ucd90160::pathField>(deviceMap.find(instance)->second),
               DRIVER_NAME, instance),
     gpioDevice(findGPIODevice(interface.path())), bus(bus)
 {
 }

 void UCD90160::onFailure()
 {
     try
     {
         auto voutError = checkVOUTFaults();

         auto pgoodError = checkPGOODFaults(false);

         // Not a voltage or PGOOD fault, but we know something
         // failed so still create an error log.
         if (!voutError && !pgoodError)
         {
             createPowerFaultLog();
         }
     }
     catch (device_error::ReadFailure& e)
     {
         if (!accessError)
         {
             commit<device_error::ReadFailure>();
             accessError = true;
         }
     }
 }

 void UCD90160::analyze()
 {
     try
     {
         // Note: Voltage faults are always fatal, so they just
         // need to be analyzed in onFailure().

         checkPGOODFaults(true);
     }
     catch (device_error::ReadFailure& e)
     {
         if (!accessError)
         {
             commit<device_error::ReadFailure>();
             accessError = true;
         }
     }
 }

 uint16_t UCD90160::readStatusWord()
 {
     return interface.read(STATUS_WORD, Type::Debug);
 }

 uint32_t UCD90160::readMFRStatus()
 {
     return interface.read(MFR_STATUS, Type::HwmonDeviceDebug);
 }

 bool UCD90160::checkVOUTFaults()
 {
     bool errorCreated = false;
     auto statusWord = readStatusWord();

     // The status_word register has a summary bit to tell us
     // if each page even needs to be checked
     if (!(statusWord & status_word::VOUT_FAULT))
     {
         return errorCreated;
     }

     for (size_t page = 0; page < NUM_PAGES; page++)
     {
         if (isVoutFaultLogged(page))
         {
             continue;
         }

         auto statusVout = interface.insertPageNum(STATUS_VOUT, page);
         uint8_t vout = interface.read(statusVout, Type::Debug);

         // If any bits are on log them, though some are just
         // warnings so they won't cause errors
         if (vout)
         {
             log<level::INFO>("A voltage rail has bits on in STATUS_VOUT",
                              entry("STATUS_VOUT=0x%X", vout),
                              entry("PAGE=%d", page));
         }

         // Log errors if any non-warning bits on
         if (vout & ~status_vout::WARNING_MASK)
         {
             auto& railNames = std::get<ucd90160::railNamesField>(
                 deviceMap.find(getInstance())->second);
             auto railName = railNames.at(page);

             util::NamesValues nv;
             try
             {
                 nv.add("STATUS_WORD", statusWord);
                 nv.add("STATUS_VOUT", vout);
                 nv.add("MFR_STATUS", readMFRStatus());
             }
             catch (device_error::ReadFailure& e)
             {
                 log<level::ERR>("ReadFailure when collecting metadata");
                 commit<device_error::ReadFailure>();
             }

             using metadata =
                 org::open_power::Witherspoon::Fault::PowerSequencerVoltageFault;

             report<power_error::PowerSequencerVoltageFault>(
                 metadata::RAIL(page), metadata::RAIL_NAME(railName.c_str()),
                 metadata::RAW_STATUS(nv.get().c_str()));

             setVoutFaultLogged(page);
             errorCreated = true;
         }
     }

     return errorCreated;
 }

 bool UCD90160::checkPGOODFaults(bool polling)
 {
     bool errorCreated = false;

     // While PGOOD faults could show up in MFR_STATUS (and we could then
     // check the summary bit in STATUS_WORD first), they are edge triggered,
     // and as the device driver sends a clear faults command every time we
     // do a read, we will never see them.  So, we'll have to just read the
     // real time GPI status GPIO.

     // Check only the GPIs configured on this system.
     auto& gpiConfigs = std::get<ucd90160::gpiConfigField>(
         deviceMap.find(getInstance())->second);

     for (const auto& gpiConfig : gpiConfigs)
     {
         auto gpiNum = std::get<ucd90160::gpiNumField>(gpiConfig);
         auto doPoll = std::get<ucd90160::pollField>(gpiConfig);

         // Can skip this one if there is already an error on this input,
         // or we are polling and these inputs don't need to be polled
         //(because errors on them are fatal).
         if (isPGOODFaultLogged(gpiNum) || (polling && !doPoll))
         {
             continue;
         }

         // The real time status is read via the pin ID
         auto pinID = std::get<ucd90160::pinIDField>(gpiConfig);
         auto gpio = gpios.find(pinID);
         Value gpiStatus;

         try
         {
             // The first time through, create the GPIO objects
             if (gpio == gpios.end())
             {
                 gpios.emplace(pinID, std::make_unique<GPIO>(gpioDevice, pinID,
                                                             Direction::input));
                 gpio = gpios.find(pinID);
             }

             gpiStatus = gpio->second->read();
         }
         catch (std::exception& e)
         {
             if (!accessError)
             {
                 log<level::ERR>(e.what());
                 accessError = true;
             }
             continue;
         }

         if (gpiStatus == Value::low)
         {
             // There may be some extra analysis we can do to narrow the
             // error down further.  Note that finding an error here won't
             // prevent us from checking this GPI again.
             errorCreated = doExtraAnalysis(gpiConfig);

             if (errorCreated)
             {
                 continue;
             }

             auto& gpiName = std::get<ucd90160::gpiNameField>(gpiConfig);
             auto status = (gpiStatus == Value::low) ? 0 : 1;

             util::NamesValues nv;

             try
             {
                 nv.add("STATUS_WORD", readStatusWord());
                 nv.add("MFR_STATUS", readMFRStatus());
                 nv.add("INPUT_STATUS", status);
             }
             catch (device_error::ReadFailure& e)
             {
                 log<level::ERR>("ReadFailure when collecting metadata");
                 commit<device_error::ReadFailure>();
             }

             using metadata =
                 org::open_power::Witherspoon::Fault::PowerSequencerPGOODFault;

             report<power_error::PowerSequencerPGOODFault>(
                 metadata::INPUT_NUM(gpiNum),
                 metadata::INPUT_NAME(gpiName.c_str()),
                 metadata::RAW_STATUS(nv.get().c_str()));

             setPGOODFaultLogged(gpiNum);
             errorCreated = true;
         }
     }

     return errorCreated;
 }

 void UCD90160::createPowerFaultLog()
 {
     util::NamesValues nv;

     try
     {
         nv.add("STATUS_WORD", readStatusWord());
         nv.add("MFR_STATUS", readMFRStatus());
     }
     catch (device_error::ReadFailure& e)
     {
         log<level::ERR>("ReadFailure when collecting metadata");
         commit<device_error::ReadFailure>();
     }

     using metadata = org::open_power::Witherspoon::Fault::PowerSequencerFault;

     report<power_error::PowerSequencerFault>(
         metadata::RAW_STATUS(nv.get().c_str()));
 }

 fs::path UCD90160::findGPIODevice(const fs::path& path)
 {
     fs::path gpioDevicePath;

     // In the driver directory, look for a subdirectory
     // named gpiochipX, where X is some number.  Then
     // we'll access the GPIO at /dev/gpiochipX.
     if (fs::is_directory(path))
     {
         for (auto& f : fs::directory_iterator(path))
         {
             if (f.path().filename().string().find("gpiochip") !=
                 std::string::npos)
             {
                 gpioDevicePath = "/dev" / f.path().filename();
                 break;
             }
         }
     }

     if (gpioDevicePath.empty())
     {
         log<level::ERR>("Could not find GPIO device path",
                         entry("BASE_PATH=%s", path.c_str()));
     }

     return gpioDevicePath;
 }

 bool UCD90160::doExtraAnalysis(const ucd90160::GPIConfig& config)
 {

     auto type = std::get<ucd90160::extraAnalysisField>(config);
     if (type == ucd90160::extraAnalysisType::none)
     {
         return false;
     }

     // Currently the only extra analysis to do is to check other GPIOs.
     return doGPIOAnalysis(type);
 }

 bool UCD90160::doGPIOAnalysis(ucd90160::extraAnalysisType type)
 {
     bool errorFound = false;
     bool shutdown = false;

     const auto& analysisConfig = std::get<ucd90160::gpioAnalysisField>(
         deviceMap.find(getInstance())->second);

     auto gpioConfig = analysisConfig.find(type);
     if (gpioConfig == analysisConfig.end())
     {
         return errorFound;
     }

     auto path = std::get<ucd90160::gpioDevicePathField>(gpioConfig->second);

     // The /dev/gpiochipX device
     auto device = findGPIODevice(path);

     if (device.empty())
     {
         log<level::ERR>(
             "Missing GPIO device - cannot do GPIO analysis of fault",
             entry("ANALYSIS_TYPE=%d\n", type));
         return errorFound;
     }

     // The GPIO value of the fault condition
     auto polarity = std::get<ucd90160::gpioPolarityField>(gpioConfig->second);

     // The GPIOs to check
     auto& gpios = std::get<ucd90160::gpioDefinitionField>(gpioConfig->second);

     for (const auto& gpio : gpios)
     {
         gpio::Value value;

         try
         {
             GPIO g{device, std::get<ucd90160::gpioNumField>(gpio),
                    Direction::input};

             value = g.read();
         }
         catch (std::exception& e)
         {
             if (!gpioAccessError)
             {
                 // GPIO only throws InternalErrors - not worth committing.
                 log<level::ERR>(
                     "GPIO read failed while analyzing a power fault",
                     entry("CHIP_PATH=%s", path.c_str()));

                 gpioAccessError = true;
             }
             continue;
         }

         if (value == polarity)
         {
             errorFound = true;

             std::string part{INVENTORY_OBJ_PATH};
             part = part + std::get<ucd90160::gpioCalloutField>(gpio);
             PartCallout callout{type, part};

             if (isPartCalledOut(callout))
             {
                 continue;
             }

             // Look up and call the error creation function
             auto logError =
                 std::get<ucd90160::errorFunctionField>(gpioConfig->second);

             logError(*this, part);

             // Save the part callout so we don't call it out again
             setPartCallout(callout);

             // Some errors (like overtemps) require a shutdown
             auto actions = static_cast<uint32_t>(
                 std::get<ucd90160::optionFlagsField>(gpioConfig->second));

             if (actions & static_cast<decltype(actions)>(
                               ucd90160::optionFlags::shutdownOnFault))
             {
                 shutdown = true;
             }
         }
     }

     if (shutdown)
     {
         // Will be replaced with a GPU specific error in a future commit
         util::powerOff<power_error::Shutdown>(bus);
     }

     return errorFound;
 }

 void UCD90160::gpuPGOODError(const std::string& callout)
 {
     util::NamesValues nv;

     try
     {
         nv.add("STATUS_WORD", readStatusWord());
         nv.add("MFR_STATUS", readMFRStatus());
     }
     catch (device_error::ReadFailure& e)
     {
         log<level::ERR>("ReadFailure when collecting metadata");
         commit<device_error::ReadFailure>();
     }

     using metadata = org::open_power::Witherspoon::Fault::GPUPowerFault;

     report<power_error::GPUPowerFault>(
         metadata::RAW_STATUS(nv.get().c_str()),
         metadata::CALLOUT_INVENTORY_PATH(callout.c_str()));
 }

 void UCD90160::gpuOverTempError(const std::string& callout)
 {
     util::NamesValues nv;

     try
     {
         nv.add("STATUS_WORD", readStatusWord());
         nv.add("MFR_STATUS", readMFRStatus());
     }
     catch (device_error::ReadFailure& e)
     {
         log<level::ERR>("ReadFailure when collecting metadata");
         commit<device_error::ReadFailure>();
     }

     using metadata = org::open_power::Witherspoon::Fault::GPUOverTemp;

     report<power_error::GPUOverTemp>(
         metadata::RAW_STATUS(nv.get().c_str()),
         metadata::CALLOUT_INVENTORY_PATH(callout.c_str()));
 }

 void UCD90160::memGoodError(const std::string& callout)
 {
     util::NamesValues nv;

     try
     {
         nv.add("STATUS_WORD", readStatusWord());
         nv.add("MFR_STATUS", readMFRStatus());
     }
     catch (device_error::ReadFailure& e)
     {
         log<level::ERR>("ReadFailure when collecting metadata");
         commit<device_error::ReadFailure>();
     }

     using metadata = org::open_power::Witherspoon::Fault::MemoryPowerFault;

     report<power_error::MemoryPowerFault>(
         metadata::RAW_STATUS(nv.get().c_str()),
         metadata::CALLOUT_INVENTORY_PATH(callout.c_str()));
 }

 } // namespace power
 } // namespace phosphor
	/**
	* Copyright © 2017 IBM 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 "ucd90160.hpp"

	#include "names_values.hpp"
	#include "utility.hpp"

	#include <elog-errors.hpp>
	#include <org/open_power/Witherspoon/Fault/error.hpp>
	#include <phosphor-logging/elog.hpp>
	#include <phosphor-logging/log.hpp>
	#include <xyz/openbmc_project/Common/Device/error.hpp>

	#include <map>
	#include <memory>

	namespace phosphor
	{
	namespace power
	{

	using namespace std::string_literals;

	const auto MFR_STATUS = "mfr_status"s;

	const auto DEVICE_NAME = "UCD90160"s;
	const auto DRIVER_NAME = "ucd9000"s;
	constexpr auto NUM_PAGES = 16;

	constexpr auto INVENTORY_OBJ_PATH = "/xyz/openbmc_project/inventory";

	namespace fs = std::filesystem;
	using namespace gpio;
	using namespace pmbus;
	using namespace phosphor::logging;

	namespace device_error = sdbusplus::xyz::openbmc_project::Common::Device::Error;
	namespace power_error = sdbusplus::org::open_power::Witherspoon::Fault::Error;

	UCD90160::UCD90160(size_t instance, sdbusplus::bus::bus& bus) :
	Device(DEVICE_NAME, instance),
	interface(std::get<ucd90160::pathField>(deviceMap.find(instance)->second),
	DRIVER_NAME, instance),
	gpioDevice(findGPIODevice(interface.path())), bus(bus)
	{
	}

	void UCD90160::onFailure()
	{
	try
	{
	auto voutError = checkVOUTFaults();

	auto pgoodError = checkPGOODFaults(false);

	// Not a voltage or PGOOD fault, but we know something
	// failed so still create an error log.
	if (!voutError && !pgoodError)
	{
	createPowerFaultLog();
	}
	}
	catch (device_error::ReadFailure& e)
	{
	if (!accessError)
	{
	commit<device_error::ReadFailure>();
	accessError = true;
	}
	}
	}

	void UCD90160::analyze()
	{
	try
	{
	// Note: Voltage faults are always fatal, so they just
	// need to be analyzed in onFailure().

	checkPGOODFaults(true);
	}
	catch (device_error::ReadFailure& e)
	{
	if (!accessError)
	{
	commit<device_error::ReadFailure>();
	accessError = true;
	}
	}
	}

	uint16_t UCD90160::readStatusWord()
	{
	return interface.read(STATUS_WORD, Type::Debug);
	}

	uint32_t UCD90160::readMFRStatus()
	{
	return interface.read(MFR_STATUS, Type::HwmonDeviceDebug);
	}

	bool UCD90160::checkVOUTFaults()
	{
	bool errorCreated = false;
	auto statusWord = readStatusWord();

	// The status_word register has a summary bit to tell us
	// if each page even needs to be checked
	if (!(statusWord & status_word::VOUT_FAULT))
	{
	return errorCreated;
	}

	for (size_t page = 0; page < NUM_PAGES; page++)
	{
	if (isVoutFaultLogged(page))
	{
	continue;
	}

	auto statusVout = interface.insertPageNum(STATUS_VOUT, page);
	uint8_t vout = interface.read(statusVout, Type::Debug);

	// If any bits are on log them, though some are just
	// warnings so they won't cause errors
	if (vout)
	{
	log<level::INFO>("A voltage rail has bits on in STATUS_VOUT",
	entry("STATUS_VOUT=0x%X", vout),
	entry("PAGE=%d", page));
	}

	// Log errors if any non-warning bits on
	if (vout & ~status_vout::WARNING_MASK)
	{
	auto& railNames = std::get<ucd90160::railNamesField>(
	deviceMap.find(getInstance())->second);
	auto railName = railNames.at(page);

	util::NamesValues nv;
	try
	{
	nv.add("STATUS_WORD", statusWord);
	nv.add("STATUS_VOUT", vout);
	nv.add("MFR_STATUS", readMFRStatus());
	}
	catch (device_error::ReadFailure& e)
	{
	log<level::ERR>("ReadFailure when collecting metadata");
	commit<device_error::ReadFailure>();
	}

	using metadata =
	org::open_power::Witherspoon::Fault::PowerSequencerVoltageFault;

	report<power_error::PowerSequencerVoltageFault>(
	metadata::RAIL(page), metadata::RAIL_NAME(railName.c_str()),
	metadata::RAW_STATUS(nv.get().c_str()));

	setVoutFaultLogged(page);
	errorCreated = true;
	}
	}

	return errorCreated;
	}

	bool UCD90160::checkPGOODFaults(bool polling)
	{
	bool errorCreated = false;

	// While PGOOD faults could show up in MFR_STATUS (and we could then
	// check the summary bit in STATUS_WORD first), they are edge triggered,
	// and as the device driver sends a clear faults command every time we
	// do a read, we will never see them. So, we'll have to just read the
	// real time GPI status GPIO.

	// Check only the GPIs configured on this system.
	auto& gpiConfigs = std::get<ucd90160::gpiConfigField>(
	deviceMap.find(getInstance())->second);

	for (const auto& gpiConfig : gpiConfigs)
	{
	auto gpiNum = std::get<ucd90160::gpiNumField>(gpiConfig);
	auto doPoll = std::get<ucd90160::pollField>(gpiConfig);

	// Can skip this one if there is already an error on this input,
	// or we are polling and these inputs don't need to be polled
	//(because errors on them are fatal).
	if (isPGOODFaultLogged(gpiNum) \|\| (polling && !doPoll))
	{
	continue;
	}

	// The real time status is read via the pin ID
	auto pinID = std::get<ucd90160::pinIDField>(gpiConfig);
	auto gpio = gpios.find(pinID);
	Value gpiStatus;

	try
	{
	// The first time through, create the GPIO objects
	if (gpio == gpios.end())
	{
	gpios.emplace(pinID, std::make_unique<GPIO>(gpioDevice, pinID,
	Direction::input));
	gpio = gpios.find(pinID);
	}

	gpiStatus = gpio->second->read();
	}
	catch (std::exception& e)
	{
	if (!accessError)
	{
	log<level::ERR>(e.what());
	accessError = true;
	}
	continue;
	}

	if (gpiStatus == Value::low)
	{
	// There may be some extra analysis we can do to narrow the
	// error down further. Note that finding an error here won't
	// prevent us from checking this GPI again.
	errorCreated = doExtraAnalysis(gpiConfig);

	if (errorCreated)
	{
	continue;
	}

	auto& gpiName = std::get<ucd90160::gpiNameField>(gpiConfig);
	auto status = (gpiStatus == Value::low) ? 0 : 1;

	util::NamesValues nv;

	try
	{
	nv.add("STATUS_WORD", readStatusWord());
	nv.add("MFR_STATUS", readMFRStatus());
	nv.add("INPUT_STATUS", status);
	}
	catch (device_error::ReadFailure& e)
	{
	log<level::ERR>("ReadFailure when collecting metadata");
	commit<device_error::ReadFailure>();
	}

	using metadata =
	org::open_power::Witherspoon::Fault::PowerSequencerPGOODFault;

	report<power_error::PowerSequencerPGOODFault>(
	metadata::INPUT_NUM(gpiNum),
	metadata::INPUT_NAME(gpiName.c_str()),
	metadata::RAW_STATUS(nv.get().c_str()));

	setPGOODFaultLogged(gpiNum);
	errorCreated = true;
	}
	}

	return errorCreated;
	}

	void UCD90160::createPowerFaultLog()
	{
	util::NamesValues nv;

	try
	{
	nv.add("STATUS_WORD", readStatusWord());
	nv.add("MFR_STATUS", readMFRStatus());
	}
	catch (device_error::ReadFailure& e)
	{
	log<level::ERR>("ReadFailure when collecting metadata");
	commit<device_error::ReadFailure>();
	}

	using metadata = org::open_power::Witherspoon::Fault::PowerSequencerFault;

	report<power_error::PowerSequencerFault>(
	metadata::RAW_STATUS(nv.get().c_str()));
	}

	fs::path UCD90160::findGPIODevice(const fs::path& path)
	{
	fs::path gpioDevicePath;

	// In the driver directory, look for a subdirectory
	// named gpiochipX, where X is some number. Then
	// we'll access the GPIO at /dev/gpiochipX.
	if (fs::is_directory(path))
	{
	for (auto& f : fs::directory_iterator(path))
	{
	if (f.path().filename().string().find("gpiochip") !=
	std::string::npos)
	{
	gpioDevicePath = "/dev" / f.path().filename();
	break;
	}
	}
	}

	if (gpioDevicePath.empty())
	{
	log<level::ERR>("Could not find GPIO device path",
	entry("BASE_PATH=%s", path.c_str()));
	}

	return gpioDevicePath;
	}

	bool UCD90160::doExtraAnalysis(const ucd90160::GPIConfig& config)
	{

	auto type = std::get<ucd90160::extraAnalysisField>(config);
	if (type == ucd90160::extraAnalysisType::none)
	{
	return false;
	}

	// Currently the only extra analysis to do is to check other GPIOs.
	return doGPIOAnalysis(type);
	}

	bool UCD90160::doGPIOAnalysis(ucd90160::extraAnalysisType type)
	{
	bool errorFound = false;
	bool shutdown = false;

	const auto& analysisConfig = std::get<ucd90160::gpioAnalysisField>(
	deviceMap.find(getInstance())->second);

	auto gpioConfig = analysisConfig.find(type);
	if (gpioConfig == analysisConfig.end())
	{
	return errorFound;
	}

	auto path = std::get<ucd90160::gpioDevicePathField>(gpioConfig->second);

	// The /dev/gpiochipX device
	auto device = findGPIODevice(path);

	if (device.empty())
	{
	log<level::ERR>(
	"Missing GPIO device - cannot do GPIO analysis of fault",
	entry("ANALYSIS_TYPE=%d\n", type));
	return errorFound;
	}

	// The GPIO value of the fault condition
	auto polarity = std::get<ucd90160::gpioPolarityField>(gpioConfig->second);

	// The GPIOs to check
	auto& gpios = std::get<ucd90160::gpioDefinitionField>(gpioConfig->second);

	for (const auto& gpio : gpios)
	{
	gpio::Value value;

	try
	{
	GPIO g{device, std::get<ucd90160::gpioNumField>(gpio),
	Direction::input};

	value = g.read();
	}
	catch (std::exception& e)
	{
	if (!gpioAccessError)
	{
	// GPIO only throws InternalErrors - not worth committing.
	log<level::ERR>(
	"GPIO read failed while analyzing a power fault",
	entry("CHIP_PATH=%s", path.c_str()));

	gpioAccessError = true;
	}
	continue;
	}

	if (value == polarity)
	{
	errorFound = true;

	std::string part{INVENTORY_OBJ_PATH};
	part = part + std::get<ucd90160::gpioCalloutField>(gpio);
	PartCallout callout{type, part};

	if (isPartCalledOut(callout))
	{
	continue;
	}

	// Look up and call the error creation function
	auto logError =
	std::get<ucd90160::errorFunctionField>(gpioConfig->second);

	logError(*this, part);

	// Save the part callout so we don't call it out again
	setPartCallout(callout);

	// Some errors (like overtemps) require a shutdown
	auto actions = static_cast<uint32_t>(
	std::get<ucd90160::optionFlagsField>(gpioConfig->second));

	if (actions & static_cast<decltype(actions)>(
	ucd90160::optionFlags::shutdownOnFault))
	{
	shutdown = true;
	}
	}
	}

	if (shutdown)
	{
	// Will be replaced with a GPU specific error in a future commit
	util::powerOff<power_error::Shutdown>(bus);
	}

	return errorFound;
	}

	void UCD90160::gpuPGOODError(const std::string& callout)
	{
	util::NamesValues nv;

	try
	{
	nv.add("STATUS_WORD", readStatusWord());
	nv.add("MFR_STATUS", readMFRStatus());
	}
	catch (device_error::ReadFailure& e)
	{
	log<level::ERR>("ReadFailure when collecting metadata");
	commit<device_error::ReadFailure>();
	}

	using metadata = org::open_power::Witherspoon::Fault::GPUPowerFault;

	report<power_error::GPUPowerFault>(
	metadata::RAW_STATUS(nv.get().c_str()),
	metadata::CALLOUT_INVENTORY_PATH(callout.c_str()));
	}

	void UCD90160::gpuOverTempError(const std::string& callout)
	{
	util::NamesValues nv;

	try
	{
	nv.add("STATUS_WORD", readStatusWord());
	nv.add("MFR_STATUS", readMFRStatus());
	}
	catch (device_error::ReadFailure& e)
	{
	log<level::ERR>("ReadFailure when collecting metadata");
	commit<device_error::ReadFailure>();
	}

	using metadata = org::open_power::Witherspoon::Fault::GPUOverTemp;

	report<power_error::GPUOverTemp>(
	metadata::RAW_STATUS(nv.get().c_str()),
	metadata::CALLOUT_INVENTORY_PATH(callout.c_str()));
	}

	void UCD90160::memGoodError(const std::string& callout)
	{
	util::NamesValues nv;

	try
	{
	nv.add("STATUS_WORD", readStatusWord());
	nv.add("MFR_STATUS", readMFRStatus());
	}
	catch (device_error::ReadFailure& e)
	{
	log<level::ERR>("ReadFailure when collecting metadata");
	commit<device_error::ReadFailure>();
	}

	using metadata = org::open_power::Witherspoon::Fault::MemoryPowerFault;

	report<power_error::MemoryPowerFault>(
	metadata::RAW_STATUS(nv.get().c_str()),
	metadata::CALLOUT_INVENTORY_PATH(callout.c_str()));
	}

	} // namespace power
	} // namespace phosphor