control/zone.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 "config.h"

 #include "zone.hpp"

 #include "sdbusplus.hpp"
 #include "utility.hpp"

 #include <cereal/archives/json.hpp>
 #include <cereal/cereal.hpp>
 #include <phosphor-logging/elog-errors.hpp>
 #include <phosphor-logging/elog.hpp>
 #include <phosphor-logging/log.hpp>
 #include <xyz/openbmc_project/Common/error.hpp>

 #include <chrono>
 #include <filesystem>
 #include <fstream>
 #include <functional>
 #include <stdexcept>

 namespace phosphor
 {
 namespace fan
 {
 namespace control
 {

 using namespace std::chrono;
 using namespace phosphor::fan;
 using namespace phosphor::logging;
 namespace fs = std::filesystem;
 using InternalFailure =
     sdbusplus::xyz::openbmc_project::Common::Error::InternalFailure;

 Zone::Zone(Mode mode, sdbusplus::bus_t& bus, const std::string& path,
            const sdeventplus::Event& event, const ZoneDefinition& def) :
     ThermalObject(bus, path.c_str(), ThermalObject::action::defer_emit),
     _bus(bus), _path(path),
     _ifaces({"xyz.openbmc_project.Control.ThermalMode"}),
     _fullSpeed(std::get<fullSpeedPos>(def)),
     _zoneNum(std::get<zoneNumPos>(def)),
     _defFloorSpeed(std::get<floorSpeedPos>(def)),
     _defCeilingSpeed(std::get<fullSpeedPos>(def)),
     _incDelay(std::get<incDelayPos>(def)),
     _decInterval(std::get<decIntervalPos>(def)),
     _incTimer(event, std::bind(&Zone::incTimerExpired, this)),
     _decTimer(event, std::bind(&Zone::decTimerExpired, this)), _eventLoop(event)
 {
     auto& fanDefs = std::get<fanListPos>(def);

     for (auto& fanDef : fanDefs)
     {
         _fans.emplace_back(std::make_unique<Fan>(bus, fanDef));
     }

     // Do not enable set speed events when in init mode
     if (mode == Mode::control)
     {
         // Process any zone handlers defined
         for (auto& hand : std::get<handlerPos>(def))
         {
             hand(*this);
         }

         // Restore thermal control current mode state
         restoreCurrentMode();

         // Emit objects added in control mode only
         this->emit_object_added();

         // Update target speed to current zone target speed
         if (!_fans.empty())
         {
             _targetSpeed = _fans.front()->getTargetSpeed();
         }
         // Setup signal trigger for set speed events
         for (auto& ssEvent : std::get<setSpeedEventsPos>(def))
         {
             initEvent(ssEvent);
         }
         // Start timer for fan speed decreases
         _decTimer.restart(_decInterval);
     }
 }

 void Zone::setSpeed(uint64_t speed)
 {
     if (_isActive)
     {
         _targetSpeed = speed;
         for (auto& fan : _fans)
         {
             fan->setSpeed(_targetSpeed);
         }
     }
 }

 void Zone::setFullSpeed()
 {
     if (_fullSpeed != 0)
     {
         _targetSpeed = _fullSpeed;
         for (auto& fan : _fans)
         {
             fan->setSpeed(_targetSpeed);
         }
     }
 }

 void Zone::setActiveAllow(const Group* group, bool isActiveAllow)
 {
     _active[*(group)] = isActiveAllow;
     if (!isActiveAllow)
     {
         _isActive = false;
     }
     else
     {
         // Check all entries are set to allow control active
         auto actPred = [](const auto& entry) { return entry.second; };
         _isActive = std::all_of(_active.begin(), _active.end(), actPred);
     }
 }

 void Zone::removeService(const Group* group, const std::string& name)
 {
     try
     {
         auto& sNames = _services.at(*group);
         auto it = std::find_if(sNames.begin(), sNames.end(),
                                [&name](const auto& entry) {
                                    return name == std::get<namePos>(entry);
                                });
         if (it != std::end(sNames))
         {
             // Remove service name from group
             sNames.erase(it);
         }
     }
     catch (const std::out_of_range& oore)
     {
         // No services for group found
     }
 }

 void Zone::setServiceOwner(const Group* group, const std::string& name,
                            const bool hasOwner)
 {
     try
     {
         auto& sNames = _services.at(*group);
         auto it = std::find_if(sNames.begin(), sNames.end(),
                                [&name](const auto& entry) {
                                    return name == std::get<namePos>(entry);
                                });
         if (it != std::end(sNames))
         {
             std::get<hasOwnerPos>(*it) = hasOwner;
         }
         else
         {
             _services[*group].emplace_back(name, hasOwner);
         }
     }
     catch (const std::out_of_range& oore)
     {
         _services[*group].emplace_back(name, hasOwner);
     }
 }

 void Zone::setServices(const Group* group)
 {
     // Remove the empty service name if exists
     removeService(group, "");
     for (auto it = group->begin(); it != group->end(); ++it)
     {
         std::string name;
         bool hasOwner = false;
         try
         {
             name = getService(std::get<pathPos>(*it), std::get<intfPos>(*it));
             hasOwner = util::SDBusPlus::callMethodAndRead<bool>(
                 _bus, "org.freedesktop.DBus", "/org/freedesktop/DBus",
                 "org.freedesktop.DBus", "NameHasOwner", name);
         }
         catch (const util::DBusMethodError& e)
         {
             // Failed to get service name owner state
             hasOwner = false;
         }
         setServiceOwner(group, name, hasOwner);
     }
 }

 void Zone::setFloor(uint64_t speed)
 {
     // Check all entries are set to allow floor to be set
     auto pred = [](const auto& entry) { return entry.second; };
     auto setFloor = std::all_of(_floorChange.begin(), _floorChange.end(), pred);
     if (setFloor)
     {
         _floorSpeed = speed;
         // Floor speed above target, update target to floor speed
         if (_targetSpeed < _floorSpeed)
         {
             requestSpeedIncrease(_floorSpeed - _targetSpeed);
         }
     }
 }

 void Zone::requestSpeedIncrease(uint64_t targetDelta)
 {
     // Only increase speed when delta is higher than
     // the current increase delta for the zone and currently under ceiling
     if (targetDelta > _incSpeedDelta && _targetSpeed < _ceilingSpeed)
     {
         auto requestTarget = getRequestSpeedBase();
         requestTarget = (targetDelta - _incSpeedDelta) + requestTarget;
         _incSpeedDelta = targetDelta;
         // Target speed can not go above a defined ceiling speed
         if (requestTarget > _ceilingSpeed)
         {
             requestTarget = _ceilingSpeed;
         }
         setSpeed(requestTarget);
         // Retart timer countdown for fan speed increase
         _incTimer.restartOnce(_incDelay);
     }
 }

 void Zone::incTimerExpired()
 {
     // Clear increase delta when timer expires allowing additional speed
     // increase requests or speed decreases to occur
     _incSpeedDelta = 0;
 }

 void Zone::requestSpeedDecrease(uint64_t targetDelta)
 {
     // Only decrease the lowest target delta requested
     if (_decSpeedDelta == 0 || targetDelta < _decSpeedDelta)
     {
         _decSpeedDelta = targetDelta;
     }
 }

 void Zone::decTimerExpired()
 {
     // Check all entries are set to allow a decrease
     auto pred = [](const auto& entry) { return entry.second; };
     auto decAllowed = std::all_of(_decAllowed.begin(), _decAllowed.end(), pred);

     // Only decrease speeds when allowed,
     // a requested decrease speed delta exists,
     // where no requested increases exist and
     // the increase timer is not running
     // (i.e. not in the middle of increasing)
     if (decAllowed && _decSpeedDelta != 0 && _incSpeedDelta == 0 &&
         !_incTimer.isEnabled())
     {
         auto requestTarget = getRequestSpeedBase();
         // Request target speed should not start above ceiling
         if (requestTarget > _ceilingSpeed)
         {
             requestTarget = _ceilingSpeed;
         }
         // Target speed can not go below the defined floor speed
         if ((requestTarget < _decSpeedDelta) ||
             (requestTarget - _decSpeedDelta < _floorSpeed))
         {
             requestTarget = _floorSpeed;
         }
         else
         {
             requestTarget = requestTarget - _decSpeedDelta;
         }
         setSpeed(requestTarget);
     }
     // Clear decrease delta when timer expires
     _decSpeedDelta = 0;
     // Decrease timer is restarted since its repeating
 }

 void Zone::initEvent(const SetSpeedEvent& event)
 {
     // Enable event triggers
     std::for_each(
         std::get<triggerPos>(event).begin(), std::get<triggerPos>(event).end(),
         [this, &event](const auto& trigger) {
             if (!std::get<actionsPos>(event).empty())
             {
                 std::for_each(
                     std::get<actionsPos>(event).begin(),
                     std::get<actionsPos>(event).end(),
                     [this, &trigger, &event](const auto& action) {
                         // Default to use group defined with action if exists
                         if (!std::get<adGroupPos>(action).empty())
                         {
                             trigger(*this, std::get<sseNamePos>(event),
                                     std::get<adGroupPos>(action),
                                     std::get<adActionsPos>(action));
                         }
                         else
                         {
                             trigger(*this, std::get<sseNamePos>(event),
                                     std::get<groupPos>(event),
                                     std::get<adActionsPos>(action));
                         }
                     });
             }
             else
             {
                 trigger(*this, std::get<sseNamePos>(event),
                         std::get<groupPos>(event), {});
             }
         });
 }

 void Zone::removeEvent(const SetSpeedEvent& event)
 {
     // Remove event signals
     auto sigIter = _signalEvents.find(std::get<sseNamePos>(event));
     if (sigIter != _signalEvents.end())
     {
         auto& signals = sigIter->second;
         for (auto it = signals.begin(); it != signals.end(); ++it)
         {
             removeSignal(it);
         }
         _signalEvents.erase(sigIter);
     }

     // Remove event timers
     auto timIter = _timerEvents.find(std::get<sseNamePos>(event));
     if (timIter != _timerEvents.end())
     {
         _timerEvents.erase(timIter);
     }
 }

 std::vector<TimerEvent>::iterator Zone::findTimer(
     const Group& eventGroup, const std::vector<Action>& eventActions,
     std::vector<TimerEvent>& eventTimers)
 {
     for (auto it = eventTimers.begin(); it != eventTimers.end(); ++it)
     {
         const auto& teEventData = *std::get<timerEventDataPos>(*it);
         if (std::get<eventGroupPos>(teEventData) == eventGroup &&
             std::get<eventActionsPos>(teEventData).size() ==
                 eventActions.size())
         {
             // TODO openbmc/openbmc#2328 - Use the action function target
             // for comparison
             auto actsEqual = [](const auto& a1, const auto& a2) {
                 return a1.target_type().name() == a2.target_type().name();
             };
             if (std::equal(eventActions.begin(), eventActions.end(),
                            std::get<eventActionsPos>(teEventData).begin(),
                            actsEqual))
             {
                 return it;
             }
         }
     }

     return eventTimers.end();
 }

 void Zone::addTimer(const std::string& name, const Group& group,
                     const std::vector<Action>& actions, const TimerConf& tConf)
 {
     auto eventData = std::make_unique<EventData>(group, "", nullptr, actions);
     Timer timer(
         _eventLoop,
         std::bind(&Zone::timerExpired, this,
                   std::cref(std::get<Group>(*eventData)),
                   std::cref(std::get<std::vector<Action>>(*eventData))));
     if (std::get<TimerType>(tConf) == TimerType::repeating)
     {
         timer.restart(std::get<intervalPos>(tConf));
     }
     else if (std::get<TimerType>(tConf) == TimerType::oneshot)
     {
         timer.restartOnce(std::get<intervalPos>(tConf));
     }
     else
     {
         throw std::invalid_argument("Invalid Timer Type");
     }
     _timerEvents[name].emplace_back(std::move(eventData), std::move(timer));
 }

 void Zone::timerExpired(const Group& eventGroup,
                         const std::vector<Action>& eventActions)
 {
     // Perform the actions
     std::for_each(eventActions.begin(), eventActions.end(),
                   [this, &eventGroup](const auto& action) {
                       action(*this, eventGroup);
                   });
 }

 void Zone::handleEvent(sdbusplus::message_t& msg, const EventData* eventData)
 {
     // Handle the callback
     std::get<eventHandlerPos> (*eventData)(_bus, msg, *this);
     // Perform the actions
     std::for_each(std::get<eventActionsPos>(*eventData).begin(),
                   std::get<eventActionsPos>(*eventData).end(),
                   [this, &eventData](const auto& action) {
                       action(*this, std::get<eventGroupPos>(*eventData));
                   });
 }

 const std::string& Zone::getService(const std::string& path,
                                     const std::string& intf)
 {
     // Retrieve service from cache
     auto srvIter = _servTree.find(path);
     if (srvIter != _servTree.end())
     {
         for (auto& serv : srvIter->second)
         {
             auto it = std::find_if(
                 serv.second.begin(), serv.second.end(),
                 [&intf](const auto& interface) { return intf == interface; });
             if (it != std::end(serv.second))
             {
                 // Service found
                 return serv.first;
             }
         }
         // Interface not found in cache, add and return
         return addServices(path, intf, 0);
     }
     else
     {
         // Path not found in cache, add and return
         return addServices(path, intf, 0);
     }
 }

 const std::string& Zone::addServices(const std::string& path,
                                      const std::string& intf, int32_t depth)
 {
     static const std::string empty = "";
     auto it = _servTree.end();

     // Get all subtree objects for the given interface
     auto objects = util::SDBusPlus::getSubTree(_bus, "/", intf, depth);
     // Add what's returned to the cache of path->services
     for (auto& pIter : objects)
     {
         auto pathIter = _servTree.find(pIter.first);
         if (pathIter != _servTree.end())
         {
             // Path found in cache
             for (auto& sIter : pIter.second)
             {
                 auto servIter = pathIter->second.find(sIter.first);
                 if (servIter != pathIter->second.end())
                 {
                     // Service found in cache
                     for (auto& iIter : sIter.second)
                     {
                         if (std::find(servIter->second.begin(),
                                       servIter->second.end(), iIter) ==
                             servIter->second.end())
                         {
                             // Add interface to cache
                             servIter->second.emplace_back(iIter);
                         }
                     }
                 }
                 else
                 {
                     // Service not found in cache
                     pathIter->second.insert(sIter);
                 }
             }
         }
         else
         {
             _servTree.insert(pIter);
         }
         // When the paths match, since a single interface constraint is given,
         // that is the service to return
         if (path == pIter.first)
         {
             it = _servTree.find(pIter.first);
         }
     }

     if (it != _servTree.end())
     {
         return it->second.begin()->first;
     }

     return empty;
 }

 auto Zone::getPersisted(const std::string& intf, const std::string& prop)
 {
     auto persisted = false;

     auto it = _persisted.find(intf);
     if (it != _persisted.end())
     {
         return std::any_of(it->second.begin(), it->second.end(),
                            [&prop](const auto& p) { return prop == p; });
     }

     return persisted;
 }

 std::string Zone::current(std::string value)
 {
     auto current = ThermalObject::current();
     std::transform(value.begin(), value.end(), value.begin(), toupper);

     auto supported = ThermalObject::supported();
     auto isSupported =
         std::any_of(supported.begin(), supported.end(), [&value](auto& s) {
             std::transform(s.begin(), s.end(), s.begin(), toupper);
             return value == s;
         });

     if (value != current && isSupported)
     {
         current = ThermalObject::current(value);
         if (getPersisted("xyz.openbmc_project.Control.ThermalMode", "Current"))
         {
             saveCurrentMode();
         }
         // Trigger event(s) for current mode property change
         auto eData = _objects[_path]["xyz.openbmc_project.Control.ThermalMode"]
                              ["Current"];
         if (eData != nullptr)
         {
             sdbusplus::message_t nullMsg{nullptr};
             handleEvent(nullMsg, eData);
         }
     }

     return current;
 }

 void Zone::saveCurrentMode()
 {
     fs::path path{CONTROL_PERSIST_ROOT_PATH};
     // Append zone and property description
     path /= std::to_string(_zoneNum);
     path /= "CurrentMode";
     std::ofstream ofs(path.c_str(), std::ios::binary);
     cereal::JSONOutputArchive oArch(ofs);
     oArch(ThermalObject::current());
 }

 void Zone::restoreCurrentMode()
 {
     auto current = ThermalObject::current();
     fs::path path{CONTROL_PERSIST_ROOT_PATH};
     path /= std::to_string(_zoneNum);
     path /= "CurrentMode";
     fs::create_directories(path.parent_path());

     try
     {
         if (fs::exists(path))
         {
             std::ifstream ifs(path.c_str(), std::ios::in | std::ios::binary);
             cereal::JSONInputArchive iArch(ifs);
             iArch(current);
         }
     }
     catch (const std::exception& e)
     {
         log<level::ERR>(e.what());
         fs::remove(path);
         current = ThermalObject::current();
     }

     this->current(current);
 }

 } // namespace control
 } // namespace fan
 } // 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 "config.h"

	#include "zone.hpp"

	#include "sdbusplus.hpp"
	#include "utility.hpp"

	#include <cereal/archives/json.hpp>
	#include <cereal/cereal.hpp>
	#include <phosphor-logging/elog-errors.hpp>
	#include <phosphor-logging/elog.hpp>
	#include <phosphor-logging/log.hpp>
	#include <xyz/openbmc_project/Common/error.hpp>

	#include <chrono>
	#include <filesystem>
	#include <fstream>
	#include <functional>
	#include <stdexcept>

	namespace phosphor
	{
	namespace fan
	{
	namespace control
	{

	using namespace std::chrono;
	using namespace phosphor::fan;
	using namespace phosphor::logging;
	namespace fs = std::filesystem;
	using InternalFailure =
	sdbusplus::xyz::openbmc_project::Common::Error::InternalFailure;

	Zone::Zone(Mode mode, sdbusplus::bus_t& bus, const std::string& path,
	const sdeventplus::Event& event, const ZoneDefinition& def) :
	ThermalObject(bus, path.c_str(), ThermalObject::action::defer_emit),
	_bus(bus), _path(path),
	_ifaces({"xyz.openbmc_project.Control.ThermalMode"}),
	_fullSpeed(std::get<fullSpeedPos>(def)),
	_zoneNum(std::get<zoneNumPos>(def)),
	_defFloorSpeed(std::get<floorSpeedPos>(def)),
	_defCeilingSpeed(std::get<fullSpeedPos>(def)),
	_incDelay(std::get<incDelayPos>(def)),
	_decInterval(std::get<decIntervalPos>(def)),
	_incTimer(event, std::bind(&Zone::incTimerExpired, this)),
	_decTimer(event, std::bind(&Zone::decTimerExpired, this)), _eventLoop(event)
	{
	auto& fanDefs = std::get<fanListPos>(def);

	for (auto& fanDef : fanDefs)
	{
	_fans.emplace_back(std::make_unique<Fan>(bus, fanDef));
	}

	// Do not enable set speed events when in init mode
	if (mode == Mode::control)
	{
	// Process any zone handlers defined
	for (auto& hand : std::get<handlerPos>(def))
	{
	hand(*this);
	}

	// Restore thermal control current mode state
	restoreCurrentMode();

	// Emit objects added in control mode only
	this->emit_object_added();

	// Update target speed to current zone target speed
	if (!_fans.empty())
	{
	_targetSpeed = _fans.front()->getTargetSpeed();
	}
	// Setup signal trigger for set speed events
	for (auto& ssEvent : std::get<setSpeedEventsPos>(def))
	{
	initEvent(ssEvent);
	}
	// Start timer for fan speed decreases
	_decTimer.restart(_decInterval);
	}
	}

	void Zone::setSpeed(uint64_t speed)
	{
	if (_isActive)
	{
	_targetSpeed = speed;
	for (auto& fan : _fans)
	{
	fan->setSpeed(_targetSpeed);
	}
	}
	}

	void Zone::setFullSpeed()
	{
	if (_fullSpeed != 0)
	{
	_targetSpeed = _fullSpeed;
	for (auto& fan : _fans)
	{
	fan->setSpeed(_targetSpeed);
	}
	}
	}

	void Zone::setActiveAllow(const Group* group, bool isActiveAllow)
	{
	_active[*(group)] = isActiveAllow;
	if (!isActiveAllow)
	{
	_isActive = false;
	}
	else
	{
	// Check all entries are set to allow control active
	auto actPred = [](const auto& entry) { return entry.second; };
	_isActive = std::all_of(_active.begin(), _active.end(), actPred);
	}
	}

	void Zone::removeService(const Group* group, const std::string& name)
	{
	try
	{
	auto& sNames = _services.at(*group);
	auto it = std::find_if(sNames.begin(), sNames.end(),
	[&name](const auto& entry) {
	return name == std::get<namePos>(entry);
	});
	if (it != std::end(sNames))
	{
	// Remove service name from group
	sNames.erase(it);
	}
	}
	catch (const std::out_of_range& oore)
	{
	// No services for group found
	}
	}

	void Zone::setServiceOwner(const Group* group, const std::string& name,
	const bool hasOwner)
	{
	try
	{
	auto& sNames = _services.at(*group);
	auto it = std::find_if(sNames.begin(), sNames.end(),
	[&name](const auto& entry) {
	return name == std::get<namePos>(entry);
	});
	if (it != std::end(sNames))
	{
	std::get<hasOwnerPos>(*it) = hasOwner;
	}
	else
	{
	_services[*group].emplace_back(name, hasOwner);
	}
	}
	catch (const std::out_of_range& oore)
	{
	_services[*group].emplace_back(name, hasOwner);
	}
	}

	void Zone::setServices(const Group* group)
	{
	// Remove the empty service name if exists
	removeService(group, "");
	for (auto it = group->begin(); it != group->end(); ++it)
	{
	std::string name;
	bool hasOwner = false;
	try
	{
	name = getService(std::get<pathPos>(it), std::get<intfPos>(it));
	hasOwner = util::SDBusPlus::callMethodAndRead<bool>(
	_bus, "org.freedesktop.DBus", "/org/freedesktop/DBus",
	"org.freedesktop.DBus", "NameHasOwner", name);
	}
	catch (const util::DBusMethodError& e)
	{
	// Failed to get service name owner state
	hasOwner = false;
	}
	setServiceOwner(group, name, hasOwner);
	}
	}

	void Zone::setFloor(uint64_t speed)
	{
	// Check all entries are set to allow floor to be set
	auto pred = [](const auto& entry) { return entry.second; };
	auto setFloor = std::all_of(_floorChange.begin(), _floorChange.end(), pred);
	if (setFloor)
	{
	_floorSpeed = speed;
	// Floor speed above target, update target to floor speed
	if (_targetSpeed < _floorSpeed)
	{
	requestSpeedIncrease(_floorSpeed - _targetSpeed);
	}
	}
	}

	void Zone::requestSpeedIncrease(uint64_t targetDelta)
	{
	// Only increase speed when delta is higher than
	// the current increase delta for the zone and currently under ceiling
	if (targetDelta > _incSpeedDelta && _targetSpeed < _ceilingSpeed)
	{
	auto requestTarget = getRequestSpeedBase();
	requestTarget = (targetDelta - _incSpeedDelta) + requestTarget;
	_incSpeedDelta = targetDelta;
	// Target speed can not go above a defined ceiling speed
	if (requestTarget > _ceilingSpeed)
	{
	requestTarget = _ceilingSpeed;
	}
	setSpeed(requestTarget);
	// Retart timer countdown for fan speed increase
	_incTimer.restartOnce(_incDelay);
	}
	}

	void Zone::incTimerExpired()
	{
	// Clear increase delta when timer expires allowing additional speed
	// increase requests or speed decreases to occur
	_incSpeedDelta = 0;
	}

	void Zone::requestSpeedDecrease(uint64_t targetDelta)
	{
	// Only decrease the lowest target delta requested
	if (_decSpeedDelta == 0 \|\| targetDelta < _decSpeedDelta)
	{
	_decSpeedDelta = targetDelta;
	}
	}

	void Zone::decTimerExpired()
	{
	// Check all entries are set to allow a decrease
	auto pred = [](const auto& entry) { return entry.second; };
	auto decAllowed = std::all_of(_decAllowed.begin(), _decAllowed.end(), pred);

	// Only decrease speeds when allowed,
	// a requested decrease speed delta exists,
	// where no requested increases exist and
	// the increase timer is not running
	// (i.e. not in the middle of increasing)
	if (decAllowed && _decSpeedDelta != 0 && _incSpeedDelta == 0 &&
	!_incTimer.isEnabled())
	{
	auto requestTarget = getRequestSpeedBase();
	// Request target speed should not start above ceiling
	if (requestTarget > _ceilingSpeed)
	{
	requestTarget = _ceilingSpeed;
	}
	// Target speed can not go below the defined floor speed
	if ((requestTarget < _decSpeedDelta) \|\|
	(requestTarget - _decSpeedDelta < _floorSpeed))
	{
	requestTarget = _floorSpeed;
	}
	else
	{
	requestTarget = requestTarget - _decSpeedDelta;
	}
	setSpeed(requestTarget);
	}
	// Clear decrease delta when timer expires
	_decSpeedDelta = 0;
	// Decrease timer is restarted since its repeating
	}

	void Zone::initEvent(const SetSpeedEvent& event)
	{
	// Enable event triggers
	std::for_each(
	std::get<triggerPos>(event).begin(), std::get<triggerPos>(event).end(),
	[this, &event](const auto& trigger) {
	if (!std::get<actionsPos>(event).empty())
	{
	std::for_each(
	std::get<actionsPos>(event).begin(),
	std::get<actionsPos>(event).end(),
	[this, &trigger, &event](const auto& action) {
	// Default to use group defined with action if exists
	if (!std::get<adGroupPos>(action).empty())
	{
	trigger(*this, std::get<sseNamePos>(event),
	std::get<adGroupPos>(action),
	std::get<adActionsPos>(action));
	}
	else
	{
	trigger(*this, std::get<sseNamePos>(event),
	std::get<groupPos>(event),
	std::get<adActionsPos>(action));
	}
	});
	}
	else
	{
	trigger(*this, std::get<sseNamePos>(event),
	std::get<groupPos>(event), {});
	}
	});
	}

	void Zone::removeEvent(const SetSpeedEvent& event)
	{
	// Remove event signals
	auto sigIter = _signalEvents.find(std::get<sseNamePos>(event));
	if (sigIter != _signalEvents.end())
	{
	auto& signals = sigIter->second;
	for (auto it = signals.begin(); it != signals.end(); ++it)
	{
	removeSignal(it);
	}
	_signalEvents.erase(sigIter);
	}

	// Remove event timers
	auto timIter = _timerEvents.find(std::get<sseNamePos>(event));
	if (timIter != _timerEvents.end())
	{
	_timerEvents.erase(timIter);
	}
	}

	std::vector<TimerEvent>::iterator Zone::findTimer(
	const Group& eventGroup, const std::vector<Action>& eventActions,
	std::vector<TimerEvent>& eventTimers)
	{
	for (auto it = eventTimers.begin(); it != eventTimers.end(); ++it)
	{
	const auto& teEventData = std::get<timerEventDataPos>(it);
	if (std::get<eventGroupPos>(teEventData) == eventGroup &&
	std::get<eventActionsPos>(teEventData).size() ==
	eventActions.size())
	{
	// TODO openbmc/openbmc#2328 - Use the action function target
	// for comparison
	auto actsEqual = [](const auto& a1, const auto& a2) {
	return a1.target_type().name() == a2.target_type().name();
	};
	if (std::equal(eventActions.begin(), eventActions.end(),
	std::get<eventActionsPos>(teEventData).begin(),
	actsEqual))
	{
	return it;
	}
	}
	}

	return eventTimers.end();
	}

	void Zone::addTimer(const std::string& name, const Group& group,
	const std::vector<Action>& actions, const TimerConf& tConf)
	{
	auto eventData = std::make_unique<EventData>(group, "", nullptr, actions);
	Timer timer(
	_eventLoop,
	std::bind(&Zone::timerExpired, this,
	std::cref(std::get<Group>(*eventData)),
	std::cref(std::get<std::vector<Action>>(*eventData))));
	if (std::get<TimerType>(tConf) == TimerType::repeating)
	{
	timer.restart(std::get<intervalPos>(tConf));
	}
	else if (std::get<TimerType>(tConf) == TimerType::oneshot)
	{
	timer.restartOnce(std::get<intervalPos>(tConf));
	}
	else
	{
	throw std::invalid_argument("Invalid Timer Type");
	}
	_timerEvents[name].emplace_back(std::move(eventData), std::move(timer));
	}

	void Zone::timerExpired(const Group& eventGroup,
	const std::vector<Action>& eventActions)
	{
	// Perform the actions
	std::for_each(eventActions.begin(), eventActions.end(),
	[this, &eventGroup](const auto& action) {
	action(*this, eventGroup);
	});
	}

	void Zone::handleEvent(sdbusplus::message_t& msg, const EventData* eventData)
	{
	// Handle the callback
	std::get<eventHandlerPos> (eventData)(_bus, msg, this);
	// Perform the actions
	std::for_each(std::get<eventActionsPos>(*eventData).begin(),
	std::get<eventActionsPos>(*eventData).end(),
	[this, &eventData](const auto& action) {
	action(this, std::get<eventGroupPos>(eventData));
	});
	}

	const std::string& Zone::getService(const std::string& path,
	const std::string& intf)
	{
	// Retrieve service from cache
	auto srvIter = _servTree.find(path);
	if (srvIter != _servTree.end())
	{
	for (auto& serv : srvIter->second)
	{
	auto it = std::find_if(
	serv.second.begin(), serv.second.end(),
	[&intf](const auto& interface) { return intf == interface; });
	if (it != std::end(serv.second))
	{
	// Service found
	return serv.first;
	}
	}
	// Interface not found in cache, add and return
	return addServices(path, intf, 0);
	}
	else
	{
	// Path not found in cache, add and return
	return addServices(path, intf, 0);
	}
	}

	const std::string& Zone::addServices(const std::string& path,
	const std::string& intf, int32_t depth)
	{
	static const std::string empty = "";
	auto it = _servTree.end();

	// Get all subtree objects for the given interface
	auto objects = util::SDBusPlus::getSubTree(_bus, "/", intf, depth);
	// Add what's returned to the cache of path->services
	for (auto& pIter : objects)
	{
	auto pathIter = _servTree.find(pIter.first);
	if (pathIter != _servTree.end())
	{
	// Path found in cache
	for (auto& sIter : pIter.second)
	{
	auto servIter = pathIter->second.find(sIter.first);
	if (servIter != pathIter->second.end())
	{
	// Service found in cache
	for (auto& iIter : sIter.second)
	{
	if (std::find(servIter->second.begin(),
	servIter->second.end(), iIter) ==
	servIter->second.end())
	{
	// Add interface to cache
	servIter->second.emplace_back(iIter);
	}
	}
	}
	else
	{
	// Service not found in cache
	pathIter->second.insert(sIter);
	}
	}
	}
	else
	{
	_servTree.insert(pIter);
	}
	// When the paths match, since a single interface constraint is given,
	// that is the service to return
	if (path == pIter.first)
	{
	it = _servTree.find(pIter.first);
	}
	}

	if (it != _servTree.end())
	{
	return it->second.begin()->first;
	}

	return empty;
	}

	auto Zone::getPersisted(const std::string& intf, const std::string& prop)
	{
	auto persisted = false;

	auto it = _persisted.find(intf);
	if (it != _persisted.end())
	{
	return std::any_of(it->second.begin(), it->second.end(),
	[&prop](const auto& p) { return prop == p; });
	}

	return persisted;
	}

	std::string Zone::current(std::string value)
	{
	auto current = ThermalObject::current();
	std::transform(value.begin(), value.end(), value.begin(), toupper);

	auto supported = ThermalObject::supported();
	auto isSupported =
	std::any_of(supported.begin(), supported.end(), [&value](auto& s) {
	std::transform(s.begin(), s.end(), s.begin(), toupper);
	return value == s;
	});

	if (value != current && isSupported)
	{
	current = ThermalObject::current(value);
	if (getPersisted("xyz.openbmc_project.Control.ThermalMode", "Current"))
	{
	saveCurrentMode();
	}
	// Trigger event(s) for current mode property change
	auto eData = _objects[_path]["xyz.openbmc_project.Control.ThermalMode"]
	["Current"];
	if (eData != nullptr)
	{
	sdbusplus::message_t nullMsg{nullptr};
	handleEvent(nullMsg, eData);
	}
	}

	return current;
	}

	void Zone::saveCurrentMode()
	{
	fs::path path{CONTROL_PERSIST_ROOT_PATH};
	// Append zone and property description
	path /= std::to_string(_zoneNum);
	path /= "CurrentMode";
	std::ofstream ofs(path.c_str(), std::ios::binary);
	cereal::JSONOutputArchive oArch(ofs);
	oArch(ThermalObject::current());
	}

	void Zone::restoreCurrentMode()
	{
	auto current = ThermalObject::current();
	fs::path path{CONTROL_PERSIST_ROOT_PATH};
	path /= std::to_string(_zoneNum);
	path /= "CurrentMode";
	fs::create_directories(path.parent_path());

	try
	{
	if (fs::exists(path))
	{
	std::ifstream ifs(path.c_str(), std::ios::in \| std::ios::binary);
	cereal::JSONInputArchive iArch(ifs);
	iArch(current);
	}
	}
	catch (const std::exception& e)
	{
	log<level::ERR>(e.what());
	fs::remove(path);
	current = ThermalObject::current();
	}

	this->current(current);
	}

	} // namespace control
	} // namespace fan
	} // namespace phosphor