redfish-core/lib/sensors.hpp - openbmc/bmcweb - Gitiles

 /*
 // 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 <math.h>
 #include <dbus_singleton.hpp>
 #include <boost/algorithm/string/predicate.hpp>
 #include <boost/algorithm/string/split.hpp>
 #include <boost/container/flat_map.hpp>
 #include <boost/range/algorithm/replace_copy_if.hpp>

 namespace redfish {

 constexpr const char* DBUS_SENSOR_PREFIX = "/xyz/openbmc_project/sensors/";

 using GetSubTreeType = std::vector<
     std::pair<std::string,
               std::vector<std::pair<std::string, std::vector<std::string>>>>>;

 using SensorVariant = sdbusplus::message::variant<int64_t, double>;

 using ManagedObjectsVectorType = std::vector<std::pair<
     sdbusplus::message::object_path,
     boost::container::flat_map<
         std::string, boost::container::flat_map<std::string, SensorVariant>>>>;

 /**
  * 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<const char*> types)
       : res(response), chassisId(chassisId), types(types) {
     res.jsonValue["@odata.id"] =
         "/redfish/v1/Chassis/" + chassisId + "/Thermal";
   }

   ~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();
   }

   void setErrorStatus() {
     res.result(boost::beast::http::status::internal_server_error);
   }

   crow::Response& res;
   std::string chassisId{};
   const std::vector<const char*> types;
 };

 /**
  * @brief Creates connections necessary for chassis sensors
  * @param SensorsAsyncResp Pointer to object holding response data
  * @param sensorNames Sensors retrieved from chassis
  * @param callback Callback for processing gathered connections
  */
 template <typename Callback>
 void getConnections(std::shared_ptr<SensorsAsyncResp> SensorsAsyncResp,
                     const boost::container::flat_set<std::string>& sensorNames,
                     Callback&& callback) {
   BMCWEB_LOG_DEBUG << "getConnections enter";
   const std::string path = "/xyz/openbmc_project/sensors";
   const std::array<std::string, 1> 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 << "getConnections resp_handler enter";
     if (ec) {
       SensorsAsyncResp->setErrorStatus();
       BMCWEB_LOG_ERROR << "getConnections 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<std::string> connections;
     // 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<std::pair<std::string, std::vector<std::string>>>>&
              object : subtree) {
       for (const char* type : SensorsAsyncResp->types) {
         if (boost::starts_with(object.first, type)) {
           auto lastPos = object.first.rfind('/');
           if (lastPos != std::string::npos) {
             std::string sensorName = object.first.substr(lastPos + 1);

             if (sensorNames.find(sensorName) != sensorNames.end()) {
               // For each Connection name
               for (const std::pair<std::string, std::vector<std::string>>&
                        objData : object.second) {
                 BMCWEB_LOG_DEBUG << "Adding connection: " << objData.first;
                 connections.insert(objData.first);
               }
             }
           }
           break;
         }
       }
     }
     BMCWEB_LOG_DEBUG << "Found " << connections.size() << " connections";
     callback(std::move(connections));
     BMCWEB_LOG_DEBUG << "getConnections 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 << "getConnections exit";
 }

 /**
  * @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 <typename Callback>
 void getChassis(std::shared_ptr<SensorsAsyncResp> SensorsAsyncResp,
                 Callback&& callback) {
   BMCWEB_LOG_DEBUG << "getChassis enter";
   // Process response from EntityManager and extract chassis data
   auto respHandler = [ callback{std::move(callback)}, SensorsAsyncResp ](
       const boost::system::error_code ec, ManagedObjectsVectorType& resp) {
     BMCWEB_LOG_DEBUG << "getChassis respHandler enter";
     if (ec) {
       BMCWEB_LOG_ERROR << "getChassis respHandler DBUS error: " << ec;
       SensorsAsyncResp->setErrorStatus();
       return;
     }
     boost::container::flat_set<std::string> sensorNames;

     //   SensorsAsyncResp->chassisId
     bool foundChassis = false;
     std::vector<std::string> split;
     // Reserve space for
     // /xyz/openbmc_project/inventory/<name>/<subname> + 3 subnames
     split.reserve(8);

     for (const auto& objDictEntry : resp) {
       const std::string& objectPath =
           static_cast<const std::string&>(objDictEntry.first);
       boost::algorithm::split(split, objectPath, boost::is_any_of("/"));
       if (split.size() < 2) {
         BMCWEB_LOG_ERROR << "Got path that isn't long enough " << objectPath;
         split.clear();
         continue;
       }
       const std::string& sensorName = split.end()[-1];
       const std::string& chassisName = split.end()[-2];

       if (chassisName != SensorsAsyncResp->chassisId) {
         split.clear();
         continue;
       }
       BMCWEB_LOG_DEBUG << "New sensor: " << sensorName;
       foundChassis = true;
       sensorNames.emplace(sensorName);
       split.clear();
     };
     BMCWEB_LOG_DEBUG << "Found " << sensorNames.size() << " Sensor names";

     if (!foundChassis) {
       BMCWEB_LOG_INFO << "Unable to find chassis named "
                       << SensorsAsyncResp->chassisId;
       SensorsAsyncResp->res.result(boost::beast::http::status::not_found);
     } else {
       callback(sensorNames);
     }
     BMCWEB_LOG_DEBUG << "getChassis respHandler exit";
   };

   // Make call to EntityManager to find all chassis objects
   crow::connections::systemBus->async_method_call(
       respHandler, "xyz.openbmc_project.EntityManager", "/",
       "org.freedesktop.DBus.ObjectManager", "GetManagedObjects");
   BMCWEB_LOG_DEBUG << "getChassis exit";
 }

 /**
  * @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<std::string, SensorVariant>>&
         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 = mapbox::getPtr<const int64_t>(scaleIt->second);
     if (int64Value != nullptr) {
       scaleMultiplier = *int64Value;
     }
   }

   sensor_json["MemberId"] = sensorName;
   sensor_json["Name"] = sensorName;
   sensor_json["Status"]["State"] = "Enabled";
   sensor_json["Status"]["Health"] = "OK";

   // 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 == "voltage") {
     unit = "ReadingVolts";
     sensor_json["@odata.type"] = "#Power.v1_0_0.Voltage";
   } 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<std::tuple<const char*, const char*, const char*>> properties;
   properties.reserve(7);

   properties.emplace_back("xyz.openbmc_project.Sensor.Value", "Value", unit);
   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");

   if (sensorType == "temperature") {
     properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MinValue",
                             "MinReadingRangeTemp");
     properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MaxValue",
                             "MaxReadingRangeTemp");
   } else {
     properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MinValue",
                             "MinReadingRange");
     properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MaxValue",
                             "MaxReadingRange");
   }

   for (const std::tuple<const char*, const char*, const char*>& 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 = mapbox::getPtr<const int64_t>(valueVariant);

         if (int64Value != nullptr) {
           if (forceToInt || scaleMultiplier >= 0) {
             valueIt = *int64Value * std::pow(10, scaleMultiplier);
           } else {
             valueIt = *int64Value *
                       std::pow(10, static_cast<double>(scaleMultiplier));
           }
         }
         // Attempt to pull the float directly
         const double* doubleValue = mapbox::getPtr<const double>(valueVariant);

         if (doubleValue != nullptr) {
           if (!forceToInt) {
             valueIt = *doubleValue *
                       std::pow(10, static_cast<double>(scaleMultiplier));
           } else {
             valueIt = static_cast<int64_t>(*doubleValue *
                                            std::pow(10, scaleMultiplier));
           }
         }
       }
     }
   }
   BMCWEB_LOG_DEBUG << "Added sensor " << sensorName;
 }

 /**
  * @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> SensorsAsyncResp) {
   BMCWEB_LOG_DEBUG << "getChassisData enter";
   auto getChassisCb = [&, SensorsAsyncResp](
                           boost::container::flat_set<std::string>&
                               sensorNames) {
     BMCWEB_LOG_DEBUG << "getChassisCb enter";
     auto getConnectionCb =
         [&, SensorsAsyncResp, sensorNames](
             const boost::container::flat_set<std::string>& connections) {
           BMCWEB_LOG_DEBUG << "getConnectionCb 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](
                                            const boost::system::error_code ec,
                                            ManagedObjectsVectorType& resp) {
               BMCWEB_LOG_DEBUG << "getManagedObjectsCb enter";
               if (ec) {
                 BMCWEB_LOG_ERROR << "getManagedObjectsCb DBUS error: " << ec;
                 SensorsAsyncResp->setErrorStatus();
                 return;
               }
               // Go through all objects and update response with
               // sensor data
               for (const auto& objDictEntry : resp) {
                 const std::string& objPath =
                     static_cast<const std::string&>(objDictEntry.first);
                 BMCWEB_LOG_DEBUG << "getManagedObjectsCb parsing object "
                                  << objPath;

                 std::vector<std::string> split;
                 // Reserve space for
                 // /xyz/openbmc_project/sensors/<name>/<subname>
                 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 beggining
                 const std::string& sensorType = split[4];
                 const std::string& sensorName = split[5];
                 BMCWEB_LOG_DEBUG << "sensorName " << sensorName
                                  << " sensorType " << sensorType;
                 if (sensorNames.find(sensorName) == 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") {
                   fieldName = "Fans";
                 } else if (sensorType == "voltage") {
                   fieldName = "Voltages";
                 } else if (sensorType == "current") {
                   fieldName = "PowerSupply";
                 } else if (sensorType == "power") {
                   fieldName = "PowerSupply";
                 } else {
                   BMCWEB_LOG_ERROR << "Unsure how to handle sensorType "
                                    << sensorType;
                   continue;
                 }

                 nlohmann::json& tempArray =
                     SensorsAsyncResp->res.jsonValue[fieldName];

                 // Create the array if it doesn't yet exist
                 if (tempArray.is_array() == false) {
                   tempArray = nlohmann::json::array();
                 }

                 tempArray.push_back(
                     {{"@odata.id", "/redfish/v1/Chassis/" +
                                        SensorsAsyncResp->chassisId +
                                        "/Thermal#/" + sensorName}});
                 nlohmann::json& sensorJson = tempArray.back();
                 objectInterfacesToJson(sensorName, sensorType,
                                        objDictEntry.second, sensorJson);
               }
               BMCWEB_LOG_DEBUG << "getManagedObjectsCb exit";
             };
             crow::connections::systemBus->async_method_call(
                 getManagedObjectsCb, connection, "/",
                 "org.freedesktop.DBus.ObjectManager", "GetManagedObjects");
           };
           BMCWEB_LOG_DEBUG << "getConnectionCb exit";
         };
     // get connections and then pass it to get sensors
     getConnections(SensorsAsyncResp, sensorNames, std::move(getConnectionCb));
     BMCWEB_LOG_DEBUG << "getChassisCb exit";
   };

   // get chassis information related to sensors
   getChassis(SensorsAsyncResp, std::move(getChassisCb));
   BMCWEB_LOG_DEBUG << "getChassisData exit";
 };

 }  // namespace redfish
	/*
	// 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 <math.h>
	#include <dbus_singleton.hpp>
	#include <boost/algorithm/string/predicate.hpp>
	#include <boost/algorithm/string/split.hpp>
	#include <boost/container/flat_map.hpp>
	#include <boost/range/algorithm/replace_copy_if.hpp>

	namespace redfish {

	constexpr const char* DBUS_SENSOR_PREFIX = "/xyz/openbmc_project/sensors/";

	using GetSubTreeType = std::vector<
	std::pair<std::string,
	std::vector<std::pair<std::string, std::vector<std::string>>>>>;

	using SensorVariant = sdbusplus::message::variant<int64_t, double>;

	using ManagedObjectsVectorType = std::vector<std::pair<
	sdbusplus::message::object_path,
	boost::container::flat_map<
	std::string, boost::container::flat_map<std::string, SensorVariant>>>>;

	/**
	* 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<const char*> types)
	: res(response), chassisId(chassisId), types(types) {
	res.jsonValue["@odata.id"] =
	"/redfish/v1/Chassis/" + chassisId + "/Thermal";
	}

	~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();
	}

	void setErrorStatus() {
	res.result(boost::beast::http::status::internal_server_error);
	}

	crow::Response& res;
	std::string chassisId{};
	const std::vector<const char*> types;
	};

	/**
	* @brief Creates connections necessary for chassis sensors
	* @param SensorsAsyncResp Pointer to object holding response data
	* @param sensorNames Sensors retrieved from chassis
	* @param callback Callback for processing gathered connections
	*/
	template <typename Callback>
	void getConnections(std::shared_ptr<SensorsAsyncResp> SensorsAsyncResp,
	const boost::container::flat_set<std::string>& sensorNames,
	Callback&& callback) {
	BMCWEB_LOG_DEBUG << "getConnections enter";
	const std::string path = "/xyz/openbmc_project/sensors";
	const std::array<std::string, 1> 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 << "getConnections resp_handler enter";
	if (ec) {
	SensorsAsyncResp->setErrorStatus();
	BMCWEB_LOG_ERROR << "getConnections 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<std::string> connections;
	// 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<std::pair<std::string, std::vector<std::string>>>>&
	object : subtree) {
	for (const char* type : SensorsAsyncResp->types) {
	if (boost::starts_with(object.first, type)) {
	auto lastPos = object.first.rfind('/');
	if (lastPos != std::string::npos) {
	std::string sensorName = object.first.substr(lastPos + 1);

	if (sensorNames.find(sensorName) != sensorNames.end()) {
	// For each Connection name
	for (const std::pair<std::string, std::vector<std::string>>&
	objData : object.second) {
	BMCWEB_LOG_DEBUG << "Adding connection: " << objData.first;
	connections.insert(objData.first);
	}
	}
	}
	break;
	}
	}
	}
	BMCWEB_LOG_DEBUG << "Found " << connections.size() << " connections";
	callback(std::move(connections));
	BMCWEB_LOG_DEBUG << "getConnections 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 << "getConnections exit";
	}

	/**
	* @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 <typename Callback>
	void getChassis(std::shared_ptr<SensorsAsyncResp> SensorsAsyncResp,
	Callback&& callback) {
	BMCWEB_LOG_DEBUG << "getChassis enter";
	// Process response from EntityManager and extract chassis data
	auto respHandler = [ callback{std::move(callback)}, SensorsAsyncResp ](
	const boost::system::error_code ec, ManagedObjectsVectorType& resp) {
	BMCWEB_LOG_DEBUG << "getChassis respHandler enter";
	if (ec) {
	BMCWEB_LOG_ERROR << "getChassis respHandler DBUS error: " << ec;
	SensorsAsyncResp->setErrorStatus();
	return;
	}
	boost::container::flat_set<std::string> sensorNames;

	// SensorsAsyncResp->chassisId
	bool foundChassis = false;
	std::vector<std::string> split;
	// Reserve space for
	// /xyz/openbmc_project/inventory/<name>/<subname> + 3 subnames
	split.reserve(8);

	for (const auto& objDictEntry : resp) {
	const std::string& objectPath =
	static_cast<const std::string&>(objDictEntry.first);
	boost::algorithm::split(split, objectPath, boost::is_any_of("/"));
	if (split.size() < 2) {
	BMCWEB_LOG_ERROR << "Got path that isn't long enough " << objectPath;
	split.clear();
	continue;
	}
	const std::string& sensorName = split.end()[-1];
	const std::string& chassisName = split.end()[-2];

	if (chassisName != SensorsAsyncResp->chassisId) {
	split.clear();
	continue;
	}
	BMCWEB_LOG_DEBUG << "New sensor: " << sensorName;
	foundChassis = true;
	sensorNames.emplace(sensorName);
	split.clear();
	};
	BMCWEB_LOG_DEBUG << "Found " << sensorNames.size() << " Sensor names";

	if (!foundChassis) {
	BMCWEB_LOG_INFO << "Unable to find chassis named "
	<< SensorsAsyncResp->chassisId;
	SensorsAsyncResp->res.result(boost::beast::http::status::not_found);
	} else {
	callback(sensorNames);
	}
	BMCWEB_LOG_DEBUG << "getChassis respHandler exit";
	};

	// Make call to EntityManager to find all chassis objects
	crow::connections::systemBus->async_method_call(
	respHandler, "xyz.openbmc_project.EntityManager", "/",
	"org.freedesktop.DBus.ObjectManager", "GetManagedObjects");
	BMCWEB_LOG_DEBUG << "getChassis exit";
	}

	/**
	* @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<std::string, SensorVariant>>&
	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 = mapbox::getPtr<const int64_t>(scaleIt->second);
	if (int64Value != nullptr) {
	scaleMultiplier = *int64Value;
	}
	}

	sensor_json["MemberId"] = sensorName;
	sensor_json["Name"] = sensorName;
	sensor_json["Status"]["State"] = "Enabled";
	sensor_json["Status"]["Health"] = "OK";

	// 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 == "voltage") {
	unit = "ReadingVolts";
	sensor_json["@odata.type"] = "#Power.v1_0_0.Voltage";
	} 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<std::tuple<const char, const char, const char*>> properties;
	properties.reserve(7);

	properties.emplace_back("xyz.openbmc_project.Sensor.Value", "Value", unit);
	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");

	if (sensorType == "temperature") {
	properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MinValue",
	"MinReadingRangeTemp");
	properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MaxValue",
	"MaxReadingRangeTemp");
	} else {
	properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MinValue",
	"MinReadingRange");
	properties.emplace_back("xyz.openbmc_project.Sensor.Value", "MaxValue",
	"MaxReadingRange");
	}

	for (const std::tuple<const char, const char, const char*>& 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 = mapbox::getPtr<const int64_t>(valueVariant);

	if (int64Value != nullptr) {
	if (forceToInt \|\| scaleMultiplier >= 0) {
	valueIt = int64Value std::pow(10, scaleMultiplier);
	} else {
	valueIt = int64Value
	std::pow(10, static_cast<double>(scaleMultiplier));
	}
	}
	// Attempt to pull the float directly
	const double* doubleValue = mapbox::getPtr<const double>(valueVariant);

	if (doubleValue != nullptr) {
	if (!forceToInt) {
	valueIt = doubleValue
	std::pow(10, static_cast<double>(scaleMultiplier));
	} else {
	valueIt = static_cast<int64_t>(doubleValue
	std::pow(10, scaleMultiplier));
	}
	}
	}
	}
	}
	BMCWEB_LOG_DEBUG << "Added sensor " << sensorName;
	}

	/**
	* @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> SensorsAsyncResp) {
	BMCWEB_LOG_DEBUG << "getChassisData enter";
	auto getChassisCb = [&, SensorsAsyncResp](
	boost::container::flat_set<std::string>&
	sensorNames) {
	BMCWEB_LOG_DEBUG << "getChassisCb enter";
	auto getConnectionCb =
	[&, SensorsAsyncResp, sensorNames](
	const boost::container::flat_set<std::string>& connections) {
	BMCWEB_LOG_DEBUG << "getConnectionCb 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](
	const boost::system::error_code ec,
	ManagedObjectsVectorType& resp) {
	BMCWEB_LOG_DEBUG << "getManagedObjectsCb enter";
	if (ec) {
	BMCWEB_LOG_ERROR << "getManagedObjectsCb DBUS error: " << ec;
	SensorsAsyncResp->setErrorStatus();
	return;
	}
	// Go through all objects and update response with
	// sensor data
	for (const auto& objDictEntry : resp) {
	const std::string& objPath =
	static_cast<const std::string&>(objDictEntry.first);
	BMCWEB_LOG_DEBUG << "getManagedObjectsCb parsing object "
	<< objPath;

	std::vector<std::string> split;
	// Reserve space for
	// /xyz/openbmc_project/sensors/<name>/<subname>
	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 beggining
	const std::string& sensorType = split[4];
	const std::string& sensorName = split[5];
	BMCWEB_LOG_DEBUG << "sensorName " << sensorName
	<< " sensorType " << sensorType;
	if (sensorNames.find(sensorName) == 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") {
	fieldName = "Fans";
	} else if (sensorType == "voltage") {
	fieldName = "Voltages";
	} else if (sensorType == "current") {
	fieldName = "PowerSupply";
	} else if (sensorType == "power") {
	fieldName = "PowerSupply";
	} else {
	BMCWEB_LOG_ERROR << "Unsure how to handle sensorType "
	<< sensorType;
	continue;
	}

	nlohmann::json& tempArray =
	SensorsAsyncResp->res.jsonValue[fieldName];

	// Create the array if it doesn't yet exist
	if (tempArray.is_array() == false) {
	tempArray = nlohmann::json::array();
	}

	tempArray.push_back(
	{{"@odata.id", "/redfish/v1/Chassis/" +
	SensorsAsyncResp->chassisId +
	"/Thermal#/" + sensorName}});
	nlohmann::json& sensorJson = tempArray.back();
	objectInterfacesToJson(sensorName, sensorType,
	objDictEntry.second, sensorJson);
	}
	BMCWEB_LOG_DEBUG << "getManagedObjectsCb exit";
	};
	crow::connections::systemBus->async_method_call(
	getManagedObjectsCb, connection, "/",
	"org.freedesktop.DBus.ObjectManager", "GetManagedObjects");
	};
	BMCWEB_LOG_DEBUG << "getConnectionCb exit";
	};
	// get connections and then pass it to get sensors
	getConnections(SensorsAsyncResp, sensorNames, std::move(getConnectionCb));
	BMCWEB_LOG_DEBUG << "getChassisCb exit";
	};

	// get chassis information related to sensors
	getChassis(SensorsAsyncResp, std::move(getChassisCb));
	BMCWEB_LOG_DEBUG << "getChassisData exit";
	};

	} // namespace redfish