/* // Copyright (c) 2018 Intel 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. */ #pragma once #include #include #include #include #include #include #include #include namespace redfish { using GetSubTreeType = std::vector< std::pair>>>>; using SensorVariant = std::variant; using ManagedObjectsVectorType = std::vector>>>; /** * SensorsAsyncResp * Gathers data needed for response processing after async calls are done */ class SensorsAsyncResp { public: SensorsAsyncResp(crow::Response& response, const std::string& chassisId, const std::initializer_list types, const std::string& subNode) : res(response), chassisId(chassisId), types(types), chassisSubNode(subNode) { } ~SensorsAsyncResp() { if (res.result() == boost::beast::http::status::internal_server_error) { // Reset the json object to clear out any data that made it in // before the error happened todo(ed) handle error condition with // proper code res.jsonValue = nlohmann::json::object(); } res.end(); } crow::Response& res; std::string chassisId{}; const std::vector types; std::string chassisSubNode{}; }; /** * @brief Get objects with connection necessary for sensors * @param SensorsAsyncResp Pointer to object holding response data * @param sensorNames Sensors retrieved from chassis * @param callback Callback for processing gathered connections */ template void getObjectsWithConnection( std::shared_ptr SensorsAsyncResp, const std::shared_ptr> sensorNames, Callback&& callback) { BMCWEB_LOG_DEBUG << "getObjectsWithConnection enter"; const std::string path = "/xyz/openbmc_project/sensors"; const std::array interfaces = { "xyz.openbmc_project.Sensor.Value"}; // Response handler for parsing objects subtree auto respHandler = [callback{std::move(callback)}, SensorsAsyncResp, sensorNames](const boost::system::error_code ec, const GetSubTreeType& subtree) { BMCWEB_LOG_DEBUG << "getObjectsWithConnection resp_handler enter"; if (ec) { messages::internalError(SensorsAsyncResp->res); BMCWEB_LOG_ERROR << "getObjectsWithConnection resp_handler: Dbus error " << ec; return; } BMCWEB_LOG_DEBUG << "Found " << subtree.size() << " subtrees"; // Make unique list of connections only for requested sensor types and // found in the chassis boost::container::flat_set connections; std::set> objectsWithConnection; // Intrinsic to avoid malloc. Most systems will have < 8 sensor // producers connections.reserve(8); BMCWEB_LOG_DEBUG << "sensorNames list count: " << sensorNames->size(); for (const std::string& tsensor : *sensorNames) { BMCWEB_LOG_DEBUG << "Sensor to find: " << tsensor; } for (const std::pair< std::string, std::vector>>>& object : subtree) { if (sensorNames->find(object.first) != sensorNames->end()) { for (const std::pair>& objData : object.second) { BMCWEB_LOG_DEBUG << "Adding connection: " << objData.first; connections.insert(objData.first); objectsWithConnection.insert( std::make_pair(object.first, objData.first)); } } } BMCWEB_LOG_DEBUG << "Found " << connections.size() << " connections"; callback(std::move(connections), std::move(objectsWithConnection)); BMCWEB_LOG_DEBUG << "getObjectsWithConnection resp_handler exit"; }; // Make call to ObjectMapper to find all sensors objects crow::connections::systemBus->async_method_call( std::move(respHandler), "xyz.openbmc_project.ObjectMapper", "/xyz/openbmc_project/object_mapper", "xyz.openbmc_project.ObjectMapper", "GetSubTree", path, 2, interfaces); BMCWEB_LOG_DEBUG << "getObjectsWithConnection exit"; } /** * @brief Create connections necessary for sensors * @param SensorsAsyncResp Pointer to object holding response data * @param sensorNames Sensors retrieved from chassis * @param callback Callback for processing gathered connections */ template void getConnections( std::shared_ptr SensorsAsyncResp, const std::shared_ptr> sensorNames, Callback&& callback) { auto objectsWithConnectionCb = [callback](const boost::container::flat_set& connections, const std::set>& objectsWithConnection) { callback(std::move(connections)); }; getObjectsWithConnection(SensorsAsyncResp, sensorNames, std::move(objectsWithConnectionCb)); } /** * @brief Shrinks the list of sensors for processing * @param SensorsAysncResp The class holding the Redfish response * @param allSensors A list of all the sensors associated to the * chassis element (i.e. baseboard, front panel, etc...) * @param activeSensors A list that is a reduction of the incoming * allSensors list. Eliminate Thermal sensors when a Power request is * made, and eliminate Power sensors when a Thermal request is made. */ void reduceSensorList( std::shared_ptr SensorsAsyncResp, const std::vector* allSensors, std::shared_ptr> activeSensors) { if (SensorsAsyncResp == nullptr) { return; } if ((allSensors == nullptr) || (activeSensors == nullptr)) { messages::resourceNotFound( SensorsAsyncResp->res, SensorsAsyncResp->chassisSubNode, SensorsAsyncResp->chassisSubNode == "Thermal" ? "Temperatures" : "Voltages"); return; } if (allSensors->empty()) { // Nothing to do, the activeSensors object is also empty return; } for (const char* type : SensorsAsyncResp->types) { for (const std::string& sensor : *allSensors) { if (boost::starts_with(sensor, type)) { activeSensors->emplace(sensor); } } } } /** * @brief Retrieves requested chassis sensors and redundancy data from DBus . * @param SensorsAsyncResp Pointer to object holding response data * @param callback Callback for next step in gathered sensor processing */ template void getChassis(std::shared_ptr sensorsAsyncResp, Callback&& callback) { BMCWEB_LOG_DEBUG << "getChassis enter"; const std::array interfaces = { "xyz.openbmc_project.Inventory.Item.Board", "xyz.openbmc_project.Inventory.Item.Chassis", "xyz.openbmc_project.Inventory.Item.PowerSupply"}; auto respHandler = [callback{std::move(callback)}, sensorsAsyncResp]( const boost::system::error_code ec, const std::vector& chassisPaths) { BMCWEB_LOG_DEBUG << "getChassis respHandler enter"; if (ec) { BMCWEB_LOG_ERROR << "getChassis respHandler DBUS error: " << ec; messages::internalError(sensorsAsyncResp->res); return; } const std::string* chassisPath = nullptr; std::string chassisName; for (const std::string& chassis : chassisPaths) { std::size_t lastPos = chassis.rfind("/"); if (lastPos == std::string::npos) { BMCWEB_LOG_ERROR << "Failed to find '/' in " << chassis; continue; } chassisName = chassis.substr(lastPos + 1); if (chassisName == sensorsAsyncResp->chassisId) { chassisPath = &chassis; break; } } if (chassisPath == nullptr) { messages::resourceNotFound(sensorsAsyncResp->res, "Chassis", sensorsAsyncResp->chassisId); return; } const std::string& chassisSubNode = sensorsAsyncResp->chassisSubNode; if (chassisSubNode == "Power") { sensorsAsyncResp->res.jsonValue["@odata.type"] = "#Power.v1_5_2.Power"; } else if (chassisSubNode == "Thermal") { sensorsAsyncResp->res.jsonValue["@odata.type"] = "#Thermal.v1_4_0.Thermal"; sensorsAsyncResp->res.jsonValue["Fans"] = nlohmann::json::array(); sensorsAsyncResp->res.jsonValue["Temperatures"] = nlohmann::json::array(); } sensorsAsyncResp->res.jsonValue["@odata.id"] = "/redfish/v1/Chassis/" + sensorsAsyncResp->chassisId + "/" + chassisSubNode; sensorsAsyncResp->res.jsonValue["@odata.context"] = "/redfish/v1/$metadata#" + chassisSubNode + "." + chassisSubNode; sensorsAsyncResp->res.jsonValue["Id"] = chassisSubNode; sensorsAsyncResp->res.jsonValue["Name"] = chassisSubNode; // Get the list of all sensors for this Chassis element std::string sensorPath = *chassisPath + "/all_sensors"; crow::connections::systemBus->async_method_call( [sensorsAsyncResp, callback{std::move(callback)}]( const boost::system::error_code ec, const std::variant>& variantEndpoints) { if (ec) { if (ec.value() != EBADR) { messages::internalError(sensorsAsyncResp->res); return; } } const std::vector* nodeSensorList = std::get_if>(&(variantEndpoints)); if (nodeSensorList == nullptr) { messages::resourceNotFound( sensorsAsyncResp->res, sensorsAsyncResp->chassisSubNode, sensorsAsyncResp->chassisSubNode == "Thermal" ? "Temperatures" : "Voltages"); return; } const std::shared_ptr> culledSensorList = std::make_shared< boost::container::flat_set>(); reduceSensorList(sensorsAsyncResp, nodeSensorList, culledSensorList); callback(culledSensorList); }, "xyz.openbmc_project.ObjectMapper", sensorPath, "org.freedesktop.DBus.Properties", "Get", "xyz.openbmc_project.Association", "endpoints"); }; // Get the Chassis Collection crow::connections::systemBus->async_method_call( respHandler, "xyz.openbmc_project.ObjectMapper", "/xyz/openbmc_project/object_mapper", "xyz.openbmc_project.ObjectMapper", "GetSubTreePaths", "/xyz/openbmc_project/inventory", int32_t(0), interfaces); BMCWEB_LOG_DEBUG << "getChassis exit"; } /** * @brief Finds all DBus object paths that implement ObjectManager. * * Creates a mapping from the associated connection name to the object path. * * Finds the object paths asynchronously. Invokes callback when information has * been obtained. * * The callback must have the following signature: * @code * callback(std::shared_ptr> objectMgrPaths) * @endcode * * @param sensorsAsyncResp Pointer to object holding response data. * @param callback Callback to invoke when object paths obtained. */ template void getObjectManagerPaths(std::shared_ptr SensorsAsyncResp, Callback&& callback) { BMCWEB_LOG_DEBUG << "getObjectManagerPaths enter"; const std::array interfaces = { "org.freedesktop.DBus.ObjectManager"}; // Response handler for GetSubTree DBus method auto respHandler = [callback{std::move(callback)}, SensorsAsyncResp](const boost::system::error_code ec, const GetSubTreeType& subtree) { BMCWEB_LOG_DEBUG << "getObjectManagerPaths respHandler enter"; if (ec) { messages::internalError(SensorsAsyncResp->res); BMCWEB_LOG_ERROR << "getObjectManagerPaths respHandler: DBus error " << ec; return; } // Loop over returned object paths std::shared_ptr> objectMgrPaths = std::make_shared< boost::container::flat_map>(); for (const std::pair< std::string, std::vector>>>& object : subtree) { // Loop over connections for current object path const std::string& objectPath = object.first; for (const std::pair>& objData : object.second) { // Add mapping from connection to object path const std::string& connection = objData.first; (*objectMgrPaths)[connection] = objectPath; BMCWEB_LOG_DEBUG << "Added mapping " << connection << " -> " << objectPath; } } callback(objectMgrPaths); BMCWEB_LOG_DEBUG << "getObjectManagerPaths respHandler exit"; }; // Query mapper for all DBus object paths that implement ObjectManager crow::connections::systemBus->async_method_call( std::move(respHandler), "xyz.openbmc_project.ObjectMapper", "/xyz/openbmc_project/object_mapper", "xyz.openbmc_project.ObjectMapper", "GetSubTree", "/", int32_t(0), interfaces); BMCWEB_LOG_DEBUG << "getObjectManagerPaths exit"; } /** * @brief Retrieves the health from a sensor . * @param interfacesDict Map of all sensor interfaces */ static std::string getHealth( const boost::container::flat_map< std::string, boost::container::flat_map>& interfacesDict) { auto criticalThresholdIt = interfacesDict.find("xyz.openbmc_project.Sensor.Threshold.Critical"); if (criticalThresholdIt != interfacesDict.end()) { auto thresholdHighIt = criticalThresholdIt->second.find("CriticalAlarmHigh"); auto thresholdLowIt = criticalThresholdIt->second.find("CriticalAlarmLow"); if (thresholdHighIt != criticalThresholdIt->second.end()) { const bool* asserted = std::get_if(&thresholdHighIt->second); if (asserted == nullptr) { BMCWEB_LOG_ERROR << "Illegal sensor threshold"; } else if (*asserted) { return "Critical"; } } if (thresholdLowIt != criticalThresholdIt->second.end()) { const bool* asserted = std::get_if(&thresholdLowIt->second); if (asserted == nullptr) { BMCWEB_LOG_ERROR << "Illegal sensor threshold"; } else if (*asserted) { return "Critical"; } } } auto warningThresholdIt = interfacesDict.find("xyz.openbmc_project.Sensor.Threshold.Warning"); if (warningThresholdIt != interfacesDict.end()) { auto thresholdHighIt = warningThresholdIt->second.find("WarningAlarmHigh"); auto thresholdLowIt = warningThresholdIt->second.find("WarningAlarmLow"); if (thresholdHighIt != warningThresholdIt->second.end()) { const bool* asserted = std::get_if(&thresholdHighIt->second); if (asserted == nullptr) { BMCWEB_LOG_ERROR << "Illegal sensor threshold"; } else if (*asserted) { return "Warning"; } } if (thresholdLowIt != warningThresholdIt->second.end()) { const bool* asserted = std::get_if(&thresholdLowIt->second); if (asserted == nullptr) { BMCWEB_LOG_ERROR << "Illegal sensor threshold"; } else if (*asserted) { return "Warning"; } } } return "OK"; } /** * @brief Builds a json sensor representation of a sensor. * @param sensorName The name of the sensor to be built * @param sensorType The type (temperature, fan_tach, etc) of the sensor to * build * @param interfacesDict A dictionary of the interfaces and properties of said * interfaces to be built from * @param sensor_json The json object to fill */ void objectInterfacesToJson( const std::string& sensorName, const std::string& sensorType, const boost::container::flat_map< std::string, boost::container::flat_map>& interfacesDict, nlohmann::json& sensor_json) { // We need a value interface before we can do anything with it auto valueIt = interfacesDict.find("xyz.openbmc_project.Sensor.Value"); if (valueIt == interfacesDict.end()) { BMCWEB_LOG_ERROR << "Sensor doesn't have a value interface"; return; } // Assume values exist as is (10^0 == 1) if no scale exists int64_t scaleMultiplier = 0; auto scaleIt = valueIt->second.find("Scale"); // If a scale exists, pull value as int64, and use the scaling. if (scaleIt != valueIt->second.end()) { const int64_t* int64Value = std::get_if(&scaleIt->second); if (int64Value != nullptr) { scaleMultiplier = *int64Value; } } sensor_json["MemberId"] = sensorName; sensor_json["Name"] = boost::replace_all_copy(sensorName, "_", " "); sensor_json["Status"]["State"] = "Enabled"; sensor_json["Status"]["Health"] = getHealth(interfacesDict); // Parameter to set to override the type we get from dbus, and force it to // int, regardless of what is available. This is used for schemas like fan, // that require integers, not floats. bool forceToInt = false; const char* unit = "Reading"; if (sensorType == "temperature") { unit = "ReadingCelsius"; sensor_json["@odata.type"] = "#Thermal.v1_3_0.Temperature"; // TODO(ed) Documentation says that path should be type fan_tach, // implementation seems to implement fan } else if (sensorType == "fan" || sensorType == "fan_tach") { unit = "Reading"; sensor_json["ReadingUnits"] = "RPM"; sensor_json["@odata.type"] = "#Thermal.v1_3_0.Fan"; forceToInt = true; } else if (sensorType == "fan_pwm") { unit = "Reading"; sensor_json["ReadingUnits"] = "Percent"; sensor_json["@odata.type"] = "#Thermal.v1_3_0.Fan"; forceToInt = true; } else if (sensorType == "voltage") { unit = "ReadingVolts"; sensor_json["@odata.type"] = "#Power.v1_0_0.Voltage"; } else if (sensorType == "power") { std::string sensorNameLower = boost::algorithm::to_lower_copy(sensorName); if (!sensorName.compare("total_power")) { unit = "PowerConsumedWatts"; } else if (sensorNameLower.find("input") != std::string::npos) { unit = "PowerInputWatts"; } else { unit = "PowerOutputWatts"; } } else { BMCWEB_LOG_ERROR << "Redfish cannot map object type for " << sensorName; return; } // Map of dbus interface name, dbus property name and redfish property_name std::vector> properties; properties.reserve(7); properties.emplace_back("xyz.openbmc_project.Sensor.Value", "Value", unit); // If sensor type doesn't map to Redfish PowerSupply, add threshold props if ((sensorType != "current") && (sensorType != "power")) { properties.emplace_back("xyz.openbmc_project.Sensor.Threshold.Warning", "WarningHigh", "UpperThresholdNonCritical"); properties.emplace_back("xyz.openbmc_project.Sensor.Threshold.Warning", "WarningLow", "LowerThresholdNonCritical"); properties.emplace_back("xyz.openbmc_project.Sensor.Threshold.Critical", "CriticalHigh", "UpperThresholdCritical"); properties.emplace_back("xyz.openbmc_project.Sensor.Threshold.Critical", "CriticalLow", "LowerThresholdCritical"); } // TODO Need to get UpperThresholdFatal and LowerThresholdFatal if (sensorType == "temperature") { properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MinValue", "MinReadingRangeTemp"); properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MaxValue", "MaxReadingRangeTemp"); } else if ((sensorType != "current") && (sensorType != "power")) { // Sensor type doesn't map to Redfish PowerSupply; add min/max props properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MinValue", "MinReadingRange"); properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MaxValue", "MaxReadingRange"); } for (const std::tuple& p : properties) { auto interfaceProperties = interfacesDict.find(std::get<0>(p)); if (interfaceProperties != interfacesDict.end()) { auto valueIt = interfaceProperties->second.find(std::get<1>(p)); if (valueIt != interfaceProperties->second.end()) { const SensorVariant& valueVariant = valueIt->second; nlohmann::json& valueIt = sensor_json[std::get<2>(p)]; // Attempt to pull the int64 directly const int64_t* int64Value = std::get_if(&valueVariant); const double* doubleValue = std::get_if(&valueVariant); const uint32_t* uValue = std::get_if(&valueVariant); double temp = 0.0; if (int64Value != nullptr) { temp = *int64Value; } else if (doubleValue != nullptr) { temp = *doubleValue; } else if (uValue != nullptr) { temp = *uValue; } else { BMCWEB_LOG_ERROR << "Got value interface that wasn't int or double"; continue; } temp = temp * std::pow(10, scaleMultiplier); if (forceToInt) { valueIt = static_cast(temp); } else { valueIt = temp; } } } } BMCWEB_LOG_DEBUG << "Added sensor " << sensorName; } static void populateFanRedundancy(std::shared_ptr sensorsAsyncResp) { crow::connections::systemBus->async_method_call( [sensorsAsyncResp](const boost::system::error_code ec, const GetSubTreeType& resp) { if (ec) { return; // don't have to have this interface } for (const std::pair>>>& pathPair : resp) { const std::string& path = pathPair.first; const std::vector< std::pair>>& objDict = pathPair.second; if (objDict.empty()) { continue; // this should be impossible } const std::string& owner = objDict.begin()->first; crow::connections::systemBus->async_method_call( [path, owner, sensorsAsyncResp](const boost::system::error_code ec, std::variant> variantEndpoints) { if (ec) { return; // if they don't have an association we // can't tell what chassis is } // verify part of the right chassis auto endpoints = std::get_if>( &variantEndpoints); if (endpoints == nullptr) { BMCWEB_LOG_ERROR << "Invalid association interface"; messages::internalError(sensorsAsyncResp->res); return; } auto found = std::find_if( endpoints->begin(), endpoints->end(), [sensorsAsyncResp](const std::string& entry) { return entry.find( sensorsAsyncResp->chassisId) != std::string::npos; }); if (found == endpoints->end()) { return; } crow::connections::systemBus->async_method_call( [path, sensorsAsyncResp]( const boost::system::error_code ec, const boost::container::flat_map< std::string, std::variant, std::string>>& ret) { if (ec) { return; // don't have to have this // interface } auto findFailures = ret.find("AllowedFailures"); auto findCollection = ret.find("Collection"); auto findStatus = ret.find("Status"); if (findFailures == ret.end() || findCollection == ret.end() || findStatus == ret.end()) { BMCWEB_LOG_ERROR << "Invalid redundancy interface"; messages::internalError( sensorsAsyncResp->res); return; } auto allowedFailures = std::get_if( &(findFailures->second)); auto collection = std::get_if>( &(findCollection->second)); auto status = std::get_if( &(findStatus->second)); if (allowedFailures == nullptr || collection == nullptr || status == nullptr) { BMCWEB_LOG_ERROR << "Invalid redundancy interface " "types"; messages::internalError( sensorsAsyncResp->res); return; } size_t lastSlash = path.rfind("/"); if (lastSlash == std::string::npos) { // this should be impossible messages::internalError( sensorsAsyncResp->res); return; } std::string name = path.substr(lastSlash + 1); std::replace(name.begin(), name.end(), '_', ' '); std::string health; if (boost::ends_with(*status, "Full")) { health = "OK"; } else if (boost::ends_with(*status, "Degraded")) { health = "Warning"; } else { health = "Critical"; } std::vector redfishCollection; const auto& fanRedfish = sensorsAsyncResp->res.jsonValue["Fans"]; for (const std::string& item : *collection) { lastSlash = item.rfind("/"); // make a copy as collection is const std::string itemName = item.substr(lastSlash + 1); /* todo(ed): merge patch that fixes the names std::replace(itemName.begin(), itemName.end(), '_', ' ');*/ auto schemaItem = std::find_if( fanRedfish.begin(), fanRedfish.end(), [itemName](const nlohmann::json& fan) { return fan["MemberId"] == itemName; }); if (schemaItem != fanRedfish.end()) { redfishCollection.push_back( {{"@odata.id", (*schemaItem)["@odata.id"]}}); } else { BMCWEB_LOG_ERROR << "failed to find fan in schema"; messages::internalError( sensorsAsyncResp->res); return; } } auto& resp = sensorsAsyncResp->res .jsonValue["Redundancy"]; resp.push_back( {{"@odata.id", "/refish/v1/Chassis/" + sensorsAsyncResp->chassisId + "/" + sensorsAsyncResp->chassisSubNode + "#/Redundancy/" + std::to_string(resp.size())}, {"@odata.type", "#Redundancy.v1_3_2.Redundancy"}, {"MinNumNeeded", collection->size() - *allowedFailures}, {"MemberId", name}, {"Mode", "N+m"}, {"Name", name}, {"RedundancySet", redfishCollection}, {"Status", {{"Health", health}, {"State", "Enabled"}}}}); }, owner, path, "org.freedesktop.DBus.Properties", "GetAll", "xyz.openbmc_project.Control.FanRedundancy"); }, "xyz.openbmc_project.ObjectMapper", path + "/inventory", "org.freedesktop.DBus.Properties", "Get", "xyz.openbmc_project.Association", "endpoints"); } }, "xyz.openbmc_project.ObjectMapper", "/xyz/openbmc_project/object_mapper", "xyz.openbmc_project.ObjectMapper", "GetSubTree", "/xyz/openbmc_project/control", 2, std::array{ "xyz.openbmc_project.Control.FanRedundancy"}); } void sortJSONResponse(std::shared_ptr SensorsAsyncResp) { nlohmann::json& response = SensorsAsyncResp->res.jsonValue; std::array sensorHeaders{"Temperatures", "Fans"}; if (SensorsAsyncResp->chassisSubNode == "Power") { sensorHeaders = {"Voltages", "PowerSupplies"}; } for (const std::string& sensorGroup : sensorHeaders) { nlohmann::json::iterator entry = response.find(sensorGroup); if (entry != response.end()) { std::sort(entry->begin(), entry->end(), [](nlohmann::json& c1, nlohmann::json& c2) { return c1["Name"] < c2["Name"]; }); // add the index counts to the end of each entry size_t count = 0; for (nlohmann::json& sensorJson : *entry) { nlohmann::json::iterator odata = sensorJson.find("@odata.id"); if (odata == sensorJson.end()) { continue; } std::string* value = odata->get_ptr(); if (value != nullptr) { *value += std::to_string(count); count++; } } } } } /** * @brief Finds the JSON object for the specified sensor. * * Searches the JSON response in sensorsAsyncResp for an object corresponding to * the specified sensor. * * @param sensorsAsyncResp Pointer to object holding response data. * @param sensorName DBus object path to the sensor. * @return Pointer to JSON object, or nullptr if object not found. */ static nlohmann::json* findSensorJson(std::shared_ptr sensorsAsyncResp, const std::string& sensorName) { // Get base name of sensor std::size_t lastSlash = sensorName.rfind('/'); if (lastSlash != std::string::npos) { std::string baseSensorName = sensorName.substr(lastSlash + 1); // Loop through JSON sensor groups that could contain sensor nlohmann::json& response = sensorsAsyncResp->res.jsonValue; std::array sensorGroups{"Temperatures", "Fans", "Voltages", "PowerSupplies"}; for (const std::string& sensorGroup : sensorGroups) { nlohmann::json::iterator groupIt = response.find(sensorGroup); if (groupIt != response.end()) { // Loop through sensors in current group for (nlohmann::json& sensorJson : *groupIt) { // Check if this is the sensor we are looking for nlohmann::json::iterator memberIdIt = sensorJson.find("MemberId"); if (memberIdIt != sensorJson.end()) { std::string* memberId = memberIdIt->get_ptr(); if ((memberId != nullptr) && (*memberId == baseSensorName)) { return &sensorJson; } } } } } } // Unable to find JSON object for specified sensor return nullptr; } /** * @brief Updates sensor status in JSON response based on inventory item status. * * Updates the status of the specified sensor based on the status of a related * inventory item. * * Modifies the Redfish Status property in the JSON response if the inventory * item indicates the hardware is not present or not functional. * * The D-Bus Present and Functional properties are typically on the inventory * item rather than the sensor. * * @param sensorsAsyncResp Pointer to object holding response data. * @param sensorName DBus object path to the sensor. * @param interfacesDict Map containing the interfaces and properties of the * inventory item associated with this sensor. */ static void updateSensorStatus( std::shared_ptr sensorsAsyncResp, const std::string& sensorName, const boost::container::flat_map< std::string, boost::container::flat_map>& interfacesDict) { // Find the JSON object in the response for this sensor nlohmann::json* sensorJson = findSensorJson(sensorsAsyncResp, sensorName); if (sensorJson != nullptr) { // Get Inventory.Item.Present property of inventory item auto itemIt = interfacesDict.find("xyz.openbmc_project.Inventory.Item"); if (itemIt != interfacesDict.end()) { auto presentIt = itemIt->second.find("Present"); if (presentIt != itemIt->second.end()) { const bool* present = std::get_if(&presentIt->second); if ((present != nullptr) && (*present == false)) { // Inventory item is not present; update sensor State (*sensorJson)["Status"]["State"] = "Absent"; } } } // Get OperationalStatus.Functional property of inventory item auto opStatusIt = interfacesDict.find( "xyz.openbmc_project.State.Decorator.OperationalStatus"); if (opStatusIt != interfacesDict.end()) { auto functionalIt = opStatusIt->second.find("Functional"); if (functionalIt != opStatusIt->second.end()) { const bool* functional = std::get_if(&functionalIt->second); if ((functional != nullptr) && (*functional == false)) { // Inventory item is not functional; update sensor Health (*sensorJson)["Status"]["Health"] = "Critical"; } } } } } /** * @brief Gets status of inventory items associated with sensors. * * Gets the D-Bus status properties for the inventory items associated with * sensors. * * Updates the Redfish sensors status in the JSON response, if needed, based on * the inventory items status. * * @param sensorsAsyncResp Pointer to object holding response data. * @param sensorToInvMap Mappings from sensor object path to the associated * inventory object path. * @param invConnections Connections that provide the status * interfaces/properties for the inventory items. * @param objectMgrPaths Mappings from connection name to DBus object path that * implements ObjectManager. */ static void getInventoryItemsStatus( std::shared_ptr sensorsAsyncResp, std::shared_ptr> sensorToInvMap, std::shared_ptr> invConnections, std::shared_ptr> objectMgrPaths) { BMCWEB_LOG_DEBUG << "getInventoryItemsStatus enter"; // Loop through all connections providing inventory item status for (const std::string& invConnection : *invConnections) { // Response handler for GetManagedObjects auto respHandler = [sensorsAsyncResp, sensorToInvMap](const boost::system::error_code ec, ManagedObjectsVectorType& resp) { BMCWEB_LOG_DEBUG << "getInventoryItemsStatus respHandler enter"; if (ec) { BMCWEB_LOG_ERROR << "getInventoryItemsStatus respHandler DBus error " << ec; messages::internalError(sensorsAsyncResp->res); return; } // Loop through returned object paths for (const auto& objDictEntry : resp) { const std::string& objPath = static_cast(objDictEntry.first); // Find all sensors associated with this inventory item for (const std::pair& pair : *sensorToInvMap) { if (pair.second == objPath) { // Update sensor status based on inventory item status updateSensorStatus(sensorsAsyncResp, pair.first, objDictEntry.second); } } } BMCWEB_LOG_DEBUG << "getInventoryItemsStatus respHandler exit"; }; // Find DBus object path that implements ObjectManager for the current // connection. If no mapping found, default to "/". auto iter = objectMgrPaths->find(invConnection); const std::string& objectMgrPath = (iter != objectMgrPaths->end()) ? iter->second : "/"; BMCWEB_LOG_DEBUG << "ObjectManager path for " << invConnection << " is " << objectMgrPath; // Get all object paths and their interfaces for current connection crow::connections::systemBus->async_method_call( std::move(respHandler), invConnection, objectMgrPath, "org.freedesktop.DBus.ObjectManager", "GetManagedObjects"); } BMCWEB_LOG_DEBUG << "getInventoryItemsStatus exit"; } /** * @brief Gets connections that provide status information on inventory items. * * Gets the D-Bus connections (services) that provide the interfaces and * properties containing status information for the inventory items. * * Finds the connections asynchronously. Invokes callback when information has * been obtained. * * The callback must have the following signature: * @code * callback(std::shared_ptr> * invConnections) * @endcode * * @param sensorsAsyncResp Pointer to object holding response data. * @param sensorToInvMap Mappings from sensor object path to the associated * inventory object path. * @param callback Callback to invoke when connections have been obtained. */ template static void getInventoryItemsConnections( std::shared_ptr sensorsAsyncResp, std::shared_ptr> sensorToInvMap, Callback&& callback) { BMCWEB_LOG_DEBUG << "getInventoryItemsConnections enter"; const std::string path = "/xyz/openbmc_project/inventory"; const std::array interfaces = { "xyz.openbmc_project.Inventory.Item", "xyz.openbmc_project.State.Decorator.OperationalStatus"}; // Response handler for parsing output from GetSubTree auto respHandler = [callback{std::move(callback)}, sensorsAsyncResp, sensorToInvMap](const boost::system::error_code ec, const GetSubTreeType& subtree) { BMCWEB_LOG_DEBUG << "getInventoryItemsConnections respHandler enter"; if (ec) { messages::internalError(sensorsAsyncResp->res); BMCWEB_LOG_ERROR << "getInventoryItemsConnections respHandler DBus error " << ec; return; } // Make unique list of connections for desired inventory items std::shared_ptr> invConnections = std::make_shared>(); invConnections->reserve(8); // Loop through objects from GetSubTree for (const std::pair< std::string, std::vector>>>& object : subtree) { // Look for inventory item object path in the sensor->inventory map const std::string& objPath = object.first; for (const std::pair& pair : *sensorToInvMap) { if (pair.second == objPath) { // Store all connections to inventory item for (const std::pair>& objData : object.second) { const std::string& invConnection = objData.first; invConnections->insert(invConnection); } break; } } } callback(invConnections); BMCWEB_LOG_DEBUG << "getInventoryItemsConnections respHandler exit"; }; // Make call to ObjectMapper to find all inventory items crow::connections::systemBus->async_method_call( std::move(respHandler), "xyz.openbmc_project.ObjectMapper", "/xyz/openbmc_project/object_mapper", "xyz.openbmc_project.ObjectMapper", "GetSubTree", path, 0, interfaces); BMCWEB_LOG_DEBUG << "getInventoryItemsConnections exit"; } /** * @brief Gets inventory items associated with the specified sensors. * * Looks for ObjectMapper associations from the specified sensors to related * inventory items. Builds map where key is sensor object path and value is * inventory item object path. * * Finds the inventory items asynchronously. Invokes callback when information * has been obtained. * * The callback must have the following signature: * @code * callback(std::shared_ptr> sensorToInvMap) * @endcode * * @param sensorsAsyncResp Pointer to object holding response data. * @param sensorNames All sensors within the current chassis. * @param objectMgrPaths Mappings from connection name to DBus object path that * implements ObjectManager. * @param callback Callback to invoke when inventory items have been obtained. */ template static void getInventoryItems( std::shared_ptr sensorsAsyncResp, const std::shared_ptr> sensorNames, std::shared_ptr> objectMgrPaths, Callback&& callback) { BMCWEB_LOG_DEBUG << "getInventoryItems enter"; // Response handler for GetManagedObjects auto respHandler = [callback{std::move(callback)}, sensorsAsyncResp, sensorNames](const boost::system::error_code ec, dbus::utility::ManagedObjectType& resp) { BMCWEB_LOG_DEBUG << "getInventoryItems respHandler enter"; if (ec) { BMCWEB_LOG_ERROR << "getInventoryItems respHandler DBus error " << ec; messages::internalError(sensorsAsyncResp->res); return; } // Loop through returned object paths std::shared_ptr> sensorToInvMap = std::make_shared< boost::container::flat_map>(); std::string sensorAssocPath; sensorAssocPath.reserve(128); // avoid memory allocations for (const auto& objDictEntry : resp) { const std::string& objPath = static_cast(objDictEntry.first); const boost::container::flat_map< std::string, boost::container::flat_map< std::string, dbus::utility::DbusVariantType>>& interfacesDict = objDictEntry.second; // If path is inventory association for one of the specified sensors for (const std::string& sensorName : *sensorNames) { sensorAssocPath = sensorName; sensorAssocPath += "/inventory"; if (objPath == sensorAssocPath) { // Get Association interface for object path auto assocIt = interfacesDict.find("xyz.openbmc_project.Association"); if (assocIt != interfacesDict.end()) { // Get inventory item from end point auto endpointsIt = assocIt->second.find("endpoints"); if (endpointsIt != assocIt->second.end()) { const std::vector* endpoints = std::get_if>( &endpointsIt->second); if ((endpoints != nullptr) && !endpoints->empty()) { // Store sensor -> inventory item mapping const std::string& invItem = endpoints->front(); (*sensorToInvMap)[sensorName] = invItem; } } } break; } } } // Call callback if at least one inventory item was found if (!sensorToInvMap->empty()) { callback(sensorToInvMap); } BMCWEB_LOG_DEBUG << "getInventoryItems respHandler exit"; }; // Find DBus object path that implements ObjectManager for ObjectMapper std::string connection = "xyz.openbmc_project.ObjectMapper"; auto iter = objectMgrPaths->find(connection); const std::string& objectMgrPath = (iter != objectMgrPaths->end()) ? iter->second : "/"; BMCWEB_LOG_DEBUG << "ObjectManager path for " << connection << " is " << objectMgrPath; // Call GetManagedObjects on the ObjectMapper to get all associations crow::connections::systemBus->async_method_call( std::move(respHandler), connection, objectMgrPath, "org.freedesktop.DBus.ObjectManager", "GetManagedObjects"); BMCWEB_LOG_DEBUG << "getInventoryItems exit"; } /** * @brief Checks the status of inventory items associated with sensors. * * Finds the inventory items that are associated with the specified sensors. * Gets the status of those inventory items. * * If the inventory items are not present or functional, the sensor status is * updated in the JSON response. * * In D-Bus, the hardware present and functional properties are typically on the * inventory item rather than the sensor. * * @param sensorsAsyncResp Pointer to object holding response data. * @param sensorNames All sensors within the current chassis. * @param objectMgrPaths Mappings from connection name to DBus object path that * implements ObjectManager. */ static void checkInventoryItemsStatus( std::shared_ptr sensorsAsyncResp, const std::shared_ptr> sensorNames, std::shared_ptr> objectMgrPaths) { BMCWEB_LOG_DEBUG << "checkInventoryItemsStatus enter"; auto getInventoryItemsCb = [sensorsAsyncResp, objectMgrPaths](std::shared_ptr< boost::container::flat_map> sensorToInvMap) { BMCWEB_LOG_DEBUG << "getInventoryItemsCb enter"; auto getInventoryItemsConnectionsCb = [sensorsAsyncResp, sensorToInvMap, objectMgrPaths]( std::shared_ptr> invConnections) { BMCWEB_LOG_DEBUG << "getInventoryItemsConnectionsCb enter"; // Get status of inventory items and update sensors getInventoryItemsStatus(sensorsAsyncResp, sensorToInvMap, invConnections, objectMgrPaths); BMCWEB_LOG_DEBUG << "getInventoryItemsConnectionsCb exit"; }; // Get connections that provide status of inventory items getInventoryItemsConnections( sensorsAsyncResp, sensorToInvMap, std::move(getInventoryItemsConnectionsCb)); BMCWEB_LOG_DEBUG << "getInventoryItemsCb exit"; }; // Get inventory items that are associated with specified sensors getInventoryItems(sensorsAsyncResp, sensorNames, objectMgrPaths, std::move(getInventoryItemsCb)); BMCWEB_LOG_DEBUG << "checkInventoryItemsStatus exit"; } /** * @brief Gets the values of the specified sensors. * * Stores the results as JSON in the SensorsAsyncResp. * * Gets the sensor values asynchronously. Stores the results later when the * information has been obtained. * * The sensorNames set contains all sensors for the current chassis. * SensorsAsyncResp contains the requested sensor types. Only sensors of a * requested type are included in the JSON output. * * To minimize the number of DBus calls, the DBus method * org.freedesktop.DBus.ObjectManager.GetManagedObjects() is used to get the * values of all sensors provided by a connection (service). * * The connections set contains all the connections that provide sensor values. * * The objectMgrPaths map contains mappings from a connection name to the * corresponding DBus object path that implements ObjectManager. * * @param SensorsAsyncResp Pointer to object holding response data. * @param sensorNames All sensors within the current chassis. * @param connections Connections that provide sensor values. * @param objectMgrPaths Mappings from connection name to DBus object path that * implements ObjectManager. */ void getSensorData( std::shared_ptr SensorsAsyncResp, const std::shared_ptr> sensorNames, const boost::container::flat_set& connections, std::shared_ptr> objectMgrPaths) { BMCWEB_LOG_DEBUG << "getSensorData enter"; // Get managed objects from all services exposing sensors for (const std::string& connection : connections) { // Response handler to process managed objects auto getManagedObjectsCb = [SensorsAsyncResp, sensorNames, objectMgrPaths]( const boost::system::error_code ec, ManagedObjectsVectorType& resp) { BMCWEB_LOG_DEBUG << "getManagedObjectsCb enter"; if (ec) { BMCWEB_LOG_ERROR << "getManagedObjectsCb DBUS error: " << ec; messages::internalError(SensorsAsyncResp->res); return; } // Go through all objects and update response with sensor data for (const auto& objDictEntry : resp) { const std::string& objPath = static_cast(objDictEntry.first); BMCWEB_LOG_DEBUG << "getManagedObjectsCb parsing object " << objPath; std::vector split; // Reserve space for // /xyz/openbmc_project/sensors// split.reserve(6); boost::algorithm::split(split, objPath, boost::is_any_of("/")); if (split.size() < 6) { BMCWEB_LOG_ERROR << "Got path that isn't long enough " << objPath; continue; } // These indexes aren't intuitive, as boost::split puts an empty // string at the beginning const std::string& sensorType = split[4]; const std::string& sensorName = split[5]; BMCWEB_LOG_DEBUG << "sensorName " << sensorName << " sensorType " << sensorType; if (sensorNames->find(objPath) == sensorNames->end()) { BMCWEB_LOG_ERROR << sensorName << " not in sensor list "; continue; } const char* fieldName = nullptr; if (sensorType == "temperature") { fieldName = "Temperatures"; } else if (sensorType == "fan" || sensorType == "fan_tach" || sensorType == "fan_pwm") { fieldName = "Fans"; } else if (sensorType == "voltage") { fieldName = "Voltages"; } else if (sensorType == "current") { fieldName = "PowerSupplies"; } else if (sensorType == "power") { if (!sensorName.compare("total_power")) { fieldName = "PowerControl"; } else { fieldName = "PowerSupplies"; } } else { BMCWEB_LOG_ERROR << "Unsure how to handle sensorType " << sensorType; continue; } nlohmann::json& tempArray = SensorsAsyncResp->res.jsonValue[fieldName]; if (fieldName == "PowerSupplies" && !tempArray.empty()) { // Power supplies put multiple "sensors" into a single power // supply entry, so only create the first one } else { tempArray.push_back( {{"@odata.id", "/redfish/v1/Chassis/" + SensorsAsyncResp->chassisId + "/" + SensorsAsyncResp->chassisSubNode + "#/" + fieldName + "/"}}); } nlohmann::json& sensorJson = tempArray.back(); objectInterfacesToJson(sensorName, sensorType, objDictEntry.second, sensorJson); } if (SensorsAsyncResp.use_count() == 1) { sortJSONResponse(SensorsAsyncResp); checkInventoryItemsStatus(SensorsAsyncResp, sensorNames, objectMgrPaths); if (SensorsAsyncResp->chassisSubNode == "Thermal") { populateFanRedundancy(SensorsAsyncResp); } } BMCWEB_LOG_DEBUG << "getManagedObjectsCb exit"; }; // Find DBus object path that implements ObjectManager for the current // connection. If no mapping found, default to "/". auto iter = objectMgrPaths->find(connection); const std::string& objectMgrPath = (iter != objectMgrPaths->end()) ? iter->second : "/"; BMCWEB_LOG_DEBUG << "ObjectManager path for " << connection << " is " << objectMgrPath; crow::connections::systemBus->async_method_call( getManagedObjectsCb, connection, objectMgrPath, "org.freedesktop.DBus.ObjectManager", "GetManagedObjects"); }; BMCWEB_LOG_DEBUG << "getSensorData exit"; } /** * @brief Entry point for retrieving sensors data related to requested * chassis. * @param SensorsAsyncResp Pointer to object holding response data */ void getChassisData(std::shared_ptr SensorsAsyncResp) { BMCWEB_LOG_DEBUG << "getChassisData enter"; auto getChassisCb = [SensorsAsyncResp]( std::shared_ptr> sensorNames) { BMCWEB_LOG_DEBUG << "getChassisCb enter"; auto getConnectionCb = [SensorsAsyncResp, sensorNames]( const boost::container::flat_set< std::string>& connections) { BMCWEB_LOG_DEBUG << "getConnectionCb enter"; auto getObjectManagerPathsCb = [SensorsAsyncResp, sensorNames, connections]( std::shared_ptr> objectMgrPaths) { BMCWEB_LOG_DEBUG << "getObjectManagerPathsCb enter"; // Get sensor data and store results in JSON // response getSensorData(SensorsAsyncResp, sensorNames, connections, objectMgrPaths); BMCWEB_LOG_DEBUG << "getObjectManagerPathsCb exit"; }; // Get mapping from connection names to the DBus object // paths that implement the ObjectManager interface getObjectManagerPaths(SensorsAsyncResp, std::move(getObjectManagerPathsCb)); BMCWEB_LOG_DEBUG << "getConnectionCb exit"; }; // Get set of connections that provide sensor values getConnections(SensorsAsyncResp, sensorNames, std::move(getConnectionCb)); BMCWEB_LOG_DEBUG << "getChassisCb exit"; }; SensorsAsyncResp->res.jsonValue["Redundancy"] = nlohmann::json::array(); // Get set of sensors in chassis getChassis(SensorsAsyncResp, std::move(getChassisCb)); BMCWEB_LOG_DEBUG << "getChassisData exit"; }; /** * @brief Find the requested sensorName in the list of all sensors supplied by * the chassis node * * @param sensorName The sensor name supplied in the PATCH request * @param sensorsList The list of sensors managed by the chassis node * @param sensorsModified The list of sensors that were found as a result of * repeated calls to this function */ bool findSensorNameUsingSensorPath( std::string_view sensorName, boost::container::flat_set& sensorsList, boost::container::flat_set& sensorsModified) { for (std::string_view chassisSensor : sensorsList) { std::size_t pos = chassisSensor.rfind("/"); if (pos >= (chassisSensor.size() - 1)) { continue; } std::string_view thisSensorName = chassisSensor.substr(pos + 1); if (thisSensorName == sensorName) { sensorsModified.emplace(chassisSensor); return true; } } return false; } /** * @brief Entry point for overriding sensor values of given sensor * * @param res response object * @param req request object * @param params parameter passed for CRUD * @param typeList TypeList of sensors for the resource queried * @param chassisSubNode Chassis Node for which the query has to happen */ void setSensorOverride(crow::Response& res, const crow::Request& req, const std::vector& params, const std::initializer_list typeList, const std::string& chassisSubNode) { // TODO: Need to figure out dynamic way to restrict patch (Set Sensor // override) based on another d-bus announcement to be more generic. if (params.size() != 1) { messages::internalError(res); res.end(); return; } std::unordered_map> allCollections; std::optional> temperatureCollections; std::optional> fanCollections; std::vector voltageCollections; BMCWEB_LOG_INFO << "setSensorOverride for subNode" << chassisSubNode << "\n"; if (chassisSubNode == "Thermal") { if (!json_util::readJson(req, res, "Temperatures", temperatureCollections, "Fans", fanCollections)) { return; } if (!temperatureCollections && !fanCollections) { messages::resourceNotFound(res, "Thermal", "Temperatures / Voltages"); res.end(); return; } if (temperatureCollections) { allCollections.emplace("Temperatures", *std::move(temperatureCollections)); } if (fanCollections) { allCollections.emplace("Fans", *std::move(fanCollections)); } } else if (chassisSubNode == "Power") { if (!json_util::readJson(req, res, "Voltages", voltageCollections)) { return; } allCollections.emplace("Voltages", std::move(voltageCollections)); } else { res.result(boost::beast::http::status::not_found); res.end(); return; } const char* propertyValueName; std::unordered_map> overrideMap; std::string memberId; double value; for (auto& collectionItems : allCollections) { if (collectionItems.first == "Temperatures") { propertyValueName = "ReadingCelsius"; } else if (collectionItems.first == "Fans") { propertyValueName = "Reading"; } else { propertyValueName = "ReadingVolts"; } for (auto& item : collectionItems.second) { if (!json_util::readJson(item, res, "MemberId", memberId, propertyValueName, value)) { return; } overrideMap.emplace(memberId, std::make_pair(value, collectionItems.first)); } } const std::string& chassisName = params[0]; auto sensorAsyncResp = std::make_shared( res, chassisName, typeList, chassisSubNode); auto getChassisSensorListCb = [sensorAsyncResp, overrideMap](const std::shared_ptr< boost::container::flat_set< std::string>> sensorsList) { // Match sensor names in the PATCH request to those managed by the // chassis node const std::shared_ptr> sensorNames = std::make_shared>(); for (const auto& item : overrideMap) { const auto& sensor = item.first; if (!findSensorNameUsingSensorPath(sensor, *sensorsList, *sensorNames)) { BMCWEB_LOG_INFO << "Unable to find memberId " << item.first; messages::resourceNotFound(sensorAsyncResp->res, item.second.second, item.first); return; } } // Get the connection to which the memberId belongs auto getObjectsWithConnectionCb = [sensorAsyncResp, overrideMap]( const boost::container::flat_set& connections, const std::set>& objectsWithConnection) { if (objectsWithConnection.size() != overrideMap.size()) { BMCWEB_LOG_INFO << "Unable to find all objects with proper connection " << objectsWithConnection.size() << " requested " << overrideMap.size() << "\n"; messages::resourceNotFound( sensorAsyncResp->res, sensorAsyncResp->chassisSubNode == "Thermal" ? "Temperatures" : "Voltages", "Count"); return; } for (const auto& item : objectsWithConnection) { auto lastPos = item.first.rfind('/'); if (lastPos == std::string::npos) { messages::internalError(sensorAsyncResp->res); return; } std::string sensorName = item.first.substr(lastPos + 1); const auto& iterator = overrideMap.find(sensorName); if (iterator == overrideMap.end()) { BMCWEB_LOG_INFO << "Unable to find sensor object" << item.first << "\n"; messages::internalError(sensorAsyncResp->res); return; } crow::connections::systemBus->async_method_call( [sensorAsyncResp](const boost::system::error_code ec) { if (ec) { BMCWEB_LOG_DEBUG << "setOverrideValueStatus DBUS error: " << ec; messages::internalError(sensorAsyncResp->res); return; } }, item.second, item.first, "org.freedesktop.DBus.Properties", "Set", "xyz.openbmc_project.Sensor.Value", "Value", sdbusplus::message::variant( iterator->second.first)); } }; // Get object with connection for the given sensor name getObjectsWithConnection(sensorAsyncResp, sensorNames, std::move(getObjectsWithConnectionCb)); }; // get full sensor list for the given chassisId and cross verify the sensor. getChassis(sensorAsyncResp, std::move(getChassisSensorListCb)); } } // namespace redfish