monitor/fan.cpp - openbmc/phosphor-fan-presence - 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 <algorithm>
 #include <phosphor-logging/log.hpp>
 #include "fan.hpp"
 #include "types.hpp"
 #include "utility.hpp"
 #include "sdbusplus.hpp"

 namespace phosphor
 {
 namespace fan
 {
 namespace monitor
 {

 using namespace phosphor::logging;

 Fan::Fan(Mode mode,
          sdbusplus::bus::bus& bus,
          phosphor::fan::event::EventPtr&  events,
          std::unique_ptr<trust::Manager>& trust,
          const FanDefinition& def) :
     _bus(bus),
     _name(std::get<fanNameField>(def)),
     _deviation(std::get<fanDeviationField>(def)),
     _numSensorFailsForNonFunc(std::get<numSensorFailsForNonfuncField>(def)),
     _trustManager(trust)
 {
     // Setup tach sensors for monitoring
     auto& sensors = std::get<sensorListField>(def);
     for (auto& s : sensors)
     {
         try
         {
             _sensors.emplace_back(
                     std::make_unique<TachSensor>(
                             mode,
                             bus,
                             *this,
                             std::get<sensorNameField>(s),
                             std::get<hasTargetField>(s),
                             std::get<factorField>(s),
                             std::get<offsetField>(s),
                             std::get<timeoutField>(def),
                             events));

             _trustManager->registerSensor(_sensors.back());
         }
         catch (InvalidSensorError& e)
         {

         }
     }

     //Start from a known state of functional
     updateInventory(true);

     // Check current tach state when entering monitor mode
     if (mode != Mode::init)
     {
         //The TachSensors will now have already read the input
         //and target values, so check them.
         tachChanged();
     }
 }


 void Fan::tachChanged()
 {
     for (auto& s : _sensors)
     {
         tachChanged(*s);
     }
 }


 void Fan::tachChanged(TachSensor& sensor)
 {
     if (_trustManager->active())
     {
         if (!_trustManager->checkTrust(sensor))
         {
             return;
         }
     }

     auto running = sensor.timerRunning();

     //If this sensor is out of range at this moment, start
     //its timer, at the end of which the inventory
     //for the fan may get updated to not functional.

     //If this sensor is OK, put everything back into a good state.

     if (outOfRange(sensor))
     {
         if (sensor.functional() && !running)
         {
             sensor.startTimer();
         }
     }
     else
     {
         if (!sensor.functional())
         {
             sensor.setFunctional(true);
         }

         if (running)
         {
             sensor.stopTimer();
         }

         //If the fan was nonfunctional and enough sensors are now OK,
         //the fan can go back to functional
         if (!_functional && !tooManySensorsNonfunctional())
         {
             log<level::INFO>("Setting a fan back to functional",
                              entry("FAN=%s", _name.c_str()));

             updateInventory(true);
         }
     }
 }


 uint64_t Fan::findTargetSpeed()
 {
     uint64_t target = 0;
     //The sensor doesn't support a target,
     //so get it from another sensor.
     auto s = std::find_if(_sensors.begin(), _sensors.end(),
                           [](const auto& s)
                           {
                               return s->hasTarget();
                           });

     if (s != _sensors.end())
     {
         target = (*s)->getTarget();
     }

     return target;
 }


 bool Fan::tooManySensorsNonfunctional()
 {
     size_t numFailed =  std::count_if(_sensors.begin(), _sensors.end(),
                                       [](const auto& s)
                                       {
                                           return !s->functional();
                                       });

     return (numFailed >= _numSensorFailsForNonFunc);
 }


 bool Fan::outOfRange(const TachSensor& sensor)
 {
     auto actual = static_cast<uint64_t>(sensor.getInput());
     auto target = sensor.getTarget();
     auto factor = sensor.getFactor();
     auto offset = sensor.getOffset();

     uint64_t min = target * (100 - _deviation) / 100;
     uint64_t max = target * (100 + _deviation) / 100;

     // TODO: openbmc/openbmc#2937 enhance this function
     // either by making it virtual, or by predefining different
     // outOfRange ops and selecting by yaml config
     min = min * factor + offset;
     max = max * factor + offset;
     if ((actual < min) || (actual > max))
     {
         return true;
     }

     return false;
 }


 void Fan::timerExpired(TachSensor& sensor)
 {
     sensor.setFunctional(false);

     //If the fan is currently functional, but too many
     //contained sensors are now nonfunctional, update
     //the whole fan nonfunctional.

     if (_functional && tooManySensorsNonfunctional())
     {
         log<level::ERR>("Setting a fan to nonfunctional",
                 entry("FAN=%s", _name.c_str()),
                 entry("TACH_SENSOR=%s", sensor.name().c_str()),
                 entry("ACTUAL_SPEED=%lld", sensor.getInput()),
                 entry("TARGET_SPEED=%lld", sensor.getTarget()));

         updateInventory(false);
     }
 }


 void Fan::updateInventory(bool functional)
 {
     auto objectMap = util::getObjMap<bool>(
             _name,
             util::OPERATIONAL_STATUS_INTF,
             util::FUNCTIONAL_PROPERTY,
             functional);
     auto response = util::SDBusPlus::lookupAndCallMethod(
             _bus,
             util::INVENTORY_PATH,
             util::INVENTORY_INTF,
             "Notify",
             objectMap);
     if (response.is_method_error())
     {
         log<level::ERR>("Error in Notify call to update inventory");
         return;
     }

     //This will always track the current state of the inventory.
     _functional = functional;
 }

 }
 }
 }
	/**
	* 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 <algorithm>
	#include <phosphor-logging/log.hpp>
	#include "fan.hpp"
	#include "types.hpp"
	#include "utility.hpp"
	#include "sdbusplus.hpp"

	namespace phosphor
	{
	namespace fan
	{
	namespace monitor
	{

	using namespace phosphor::logging;

	Fan::Fan(Mode mode,
	sdbusplus::bus::bus& bus,
	phosphor::fan::event::EventPtr& events,
	std::unique_ptr<trust::Manager>& trust,
	const FanDefinition& def) :
	_bus(bus),
	_name(std::get<fanNameField>(def)),
	_deviation(std::get<fanDeviationField>(def)),
	_numSensorFailsForNonFunc(std::get<numSensorFailsForNonfuncField>(def)),
	_trustManager(trust)
	{
	// Setup tach sensors for monitoring
	auto& sensors = std::get<sensorListField>(def);
	for (auto& s : sensors)
	{
	try
	{
	_sensors.emplace_back(
	std::make_unique<TachSensor>(
	mode,
	bus,
	*this,
	std::get<sensorNameField>(s),
	std::get<hasTargetField>(s),
	std::get<factorField>(s),
	std::get<offsetField>(s),
	std::get<timeoutField>(def),
	events));

	_trustManager->registerSensor(_sensors.back());
	}
	catch (InvalidSensorError& e)
	{

	}
	}

	//Start from a known state of functional
	updateInventory(true);

	// Check current tach state when entering monitor mode
	if (mode != Mode::init)
	{
	//The TachSensors will now have already read the input
	//and target values, so check them.
	tachChanged();
	}
	}


	void Fan::tachChanged()
	{
	for (auto& s : _sensors)
	{
	tachChanged(*s);
	}
	}


	void Fan::tachChanged(TachSensor& sensor)
	{
	if (_trustManager->active())
	{
	if (!_trustManager->checkTrust(sensor))
	{
	return;
	}
	}

	auto running = sensor.timerRunning();

	//If this sensor is out of range at this moment, start
	//its timer, at the end of which the inventory
	//for the fan may get updated to not functional.

	//If this sensor is OK, put everything back into a good state.

	if (outOfRange(sensor))
	{
	if (sensor.functional() && !running)
	{
	sensor.startTimer();
	}
	}
	else
	{
	if (!sensor.functional())
	{
	sensor.setFunctional(true);
	}

	if (running)
	{
	sensor.stopTimer();
	}

	//If the fan was nonfunctional and enough sensors are now OK,
	//the fan can go back to functional
	if (!_functional && !tooManySensorsNonfunctional())
	{
	log<level::INFO>("Setting a fan back to functional",
	entry("FAN=%s", _name.c_str()));

	updateInventory(true);
	}
	}
	}


	uint64_t Fan::findTargetSpeed()
	{
	uint64_t target = 0;
	//The sensor doesn't support a target,
	//so get it from another sensor.
	auto s = std::find_if(_sensors.begin(), _sensors.end(),
	[](const auto& s)
	{
	return s->hasTarget();
	});

	if (s != _sensors.end())
	{
	target = (*s)->getTarget();
	}

	return target;
	}


	bool Fan::tooManySensorsNonfunctional()
	{
	size_t numFailed = std::count_if(_sensors.begin(), _sensors.end(),
	[](const auto& s)
	{
	return !s->functional();
	});

	return (numFailed >= _numSensorFailsForNonFunc);
	}


	bool Fan::outOfRange(const TachSensor& sensor)
	{
	auto actual = static_cast<uint64_t>(sensor.getInput());
	auto target = sensor.getTarget();
	auto factor = sensor.getFactor();
	auto offset = sensor.getOffset();

	uint64_t min = target * (100 - _deviation) / 100;
	uint64_t max = target * (100 + _deviation) / 100;

	// TODO: openbmc/openbmc#2937 enhance this function
	// either by making it virtual, or by predefining different
	// outOfRange ops and selecting by yaml config
	min = min * factor + offset;
	max = max * factor + offset;
	if ((actual < min) \|\| (actual > max))
	{
	return true;
	}

	return false;
	}


	void Fan::timerExpired(TachSensor& sensor)
	{
	sensor.setFunctional(false);

	//If the fan is currently functional, but too many
	//contained sensors are now nonfunctional, update
	//the whole fan nonfunctional.

	if (_functional && tooManySensorsNonfunctional())
	{
	log<level::ERR>("Setting a fan to nonfunctional",
	entry("FAN=%s", _name.c_str()),
	entry("TACH_SENSOR=%s", sensor.name().c_str()),
	entry("ACTUAL_SPEED=%lld", sensor.getInput()),
	entry("TARGET_SPEED=%lld", sensor.getTarget()));

	updateInventory(false);
	}
	}


	void Fan::updateInventory(bool functional)
	{
	auto objectMap = util::getObjMap<bool>(
	_name,
	util::OPERATIONAL_STATUS_INTF,
	util::FUNCTIONAL_PROPERTY,
	functional);
	auto response = util::SDBusPlus::lookupAndCallMethod(
	_bus,
	util::INVENTORY_PATH,
	util::INVENTORY_INTF,
	"Notify",
	objectMap);
	if (response.is_method_error())
	{
	log<level::ERR>("Error in Notify call to update inventory");
	return;
	}

	//This will always track the current state of the inventory.
	_functional = functional;
	}

	}
	}
	}