/** * 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 #include #include #include #include #include #include #include #include #include #include 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(def)), _zoneNum(std::get(def)), _defFloorSpeed(std::get(def)), _defCeilingSpeed(std::get(def)), _incDelay(std::get(def)), _decInterval(std::get(def)), _incTimer(event, std::bind(&Zone::incTimerExpired, this)), _decTimer(event, std::bind(&Zone::decTimerExpired, this)), _eventLoop(event) { auto& fanDefs = std::get(def); for (auto& fanDef : fanDefs) { _fans.emplace_back(std::make_unique(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(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(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(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(entry); }); if (it != std::end(sNames)) { std::get(*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(*it), std::get(*it)); hasOwner = util::SDBusPlus::callMethodAndRead( _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(event).begin(), std::get(event).end(), [this, &event](const auto& trigger) { if (!std::get(event).empty()) { std::for_each( std::get(event).begin(), std::get(event).end(), [this, &trigger, &event](const auto& action) { // Default to use group defined with action if exists if (!std::get(action).empty()) { trigger(*this, std::get(event), std::get(action), std::get(action)); } else { trigger(*this, std::get(event), std::get(event), std::get(action)); } }); } else { trigger(*this, std::get(event), std::get(event), {}); } }); } void Zone::removeEvent(const SetSpeedEvent& event) { // Remove event signals auto sigIter = _signalEvents.find(std::get(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(event)); if (timIter != _timerEvents.end()) { _timerEvents.erase(timIter); } } std::vector::iterator Zone::findTimer( const Group& eventGroup, const std::vector& eventActions, std::vector& eventTimers) { for (auto it = eventTimers.begin(); it != eventTimers.end(); ++it) { const auto& teEventData = *std::get(*it); if (std::get(teEventData) == eventGroup && std::get(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(teEventData).begin(), actsEqual)) { return it; } } } return eventTimers.end(); } void Zone::addTimer(const std::string& name, const Group& group, const std::vector& actions, const TimerConf& tConf) { auto eventData = std::make_unique(group, "", nullptr, actions); Timer timer( _eventLoop, std::bind(&Zone::timerExpired, this, std::cref(std::get(*eventData)), std::cref(std::get>(*eventData)))); if (std::get(tConf) == TimerType::repeating) { timer.restart(std::get(tConf)); } else if (std::get(tConf) == TimerType::oneshot) { timer.restartOnce(std::get(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& 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 (*eventData)(_bus, msg, *this); // Perform the actions std::for_each(std::get(*eventData).begin(), std::get(*eventData).end(), [this, &eventData](const auto& action) { action(*this, std::get(*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(e.what()); fs::remove(path); current = ThermalObject::current(); } this->current(current); } } // namespace control } // namespace fan } // namespace phosphor