include/dbus-sdr/sdrutils.hpp - openbmc/phosphor-host-ipmid - 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.
 */

 #include <boost/algorithm/string.hpp>
 #include <boost/bimap.hpp>
 #include <boost/container/flat_map.hpp>
 #include <cstdio>
 #include <cstring>
 #include <exception>
 #include <filesystem>
 #include <ipmid/api.hpp>
 #include <ipmid/types.hpp>
 #include <map>
 #include <optional>
 #include <phosphor-logging/log.hpp>
 #include <sdbusplus/bus/match.hpp>
 #include <string>
 #include <unordered_set>
 #include <vector>

 #pragma once

 static constexpr bool debug = false;

 struct CmpStrVersion
 {
     bool operator()(std::string a, std::string b) const
     {
         return strverscmp(a.c_str(), b.c_str()) < 0;
     }
 };

 using SensorSubTree = boost::container::flat_map<
     std::string,
     boost::container::flat_map<std::string, std::vector<std::string>>,
     CmpStrVersion>;

 using SensorNumMap = boost::bimap<int, std::string>;

 static constexpr uint16_t maxSensorsPerLUN = 255;
 static constexpr uint16_t maxIPMISensors = (maxSensorsPerLUN * 3);
 static constexpr uint16_t lun1Sensor0 = 0x100;
 static constexpr uint16_t lun3Sensor0 = 0x300;
 static constexpr uint16_t invalidSensorNumber = 0xFFFF;
 static constexpr uint8_t reservedSensorNumber = 0xFF;

 namespace details
 {
 // Enable/disable the logging of stats instrumentation
 static constexpr bool enableInstrumentation = false;

 class IPMIStatsEntry
 {
   private:
     int numReadings = 0;
     int numMissings = 0;
     int numStreakRead = 0;
     int numStreakMiss = 0;
     double minValue = 0.0;
     double maxValue = 0.0;
     std::string sensorName;

   public:
     const std::string& getName(void) const
     {
         return sensorName;
     }

     void updateName(std::string_view name)
     {
         sensorName = name;
     }

     // Returns true if this is the first successful reading
     // This is so the caller can log the coefficients used
     bool updateReading(double reading, int raw)
     {
         if constexpr (!enableInstrumentation)
         {
             return false;
         }

         bool first = ((numReadings == 0) && (numMissings == 0));

         // Sensors can use "nan" to indicate unavailable reading
         if (!(std::isfinite(reading)))
         {
             // Only show this if beginning a new streak
             if (numStreakMiss == 0)
             {
                 std::cerr << "IPMI sensor " << sensorName
                           << ": Missing reading, byte=" << raw
                           << ", Reading counts good=" << numReadings
                           << " miss=" << numMissings
                           << ", Prior good streak=" << numStreakRead << "\n";
             }

             numStreakRead = 0;
             ++numMissings;
             ++numStreakMiss;

             return first;
         }

         // Only show this if beginning a new streak and not the first time
         if ((numStreakRead == 0) && (numReadings != 0))
         {
             std::cerr << "IPMI sensor " << sensorName
                       << ": Recovered reading, value=" << reading
                       << " byte=" << raw
                       << ", Reading counts good=" << numReadings
                       << " miss=" << numMissings
                       << ", Prior miss streak=" << numStreakMiss << "\n";
         }

         // Initialize min/max if the first successful reading
         if (numReadings == 0)
         {
             std::cerr << "IPMI sensor " << sensorName
                       << ": First reading, value=" << reading << " byte=" << raw
                       << "\n";

             minValue = reading;
             maxValue = reading;
         }

         numStreakMiss = 0;
         ++numReadings;
         ++numStreakRead;

         // Only provide subsequent output if new min/max established
         if (reading < minValue)
         {
             std::cerr << "IPMI sensor " << sensorName
                       << ": Lowest reading, value=" << reading
                       << " byte=" << raw << "\n";

             minValue = reading;
         }

         if (reading > maxValue)
         {
             std::cerr << "IPMI sensor " << sensorName
                       << ": Highest reading, value=" << reading
                       << " byte=" << raw << "\n";

             maxValue = reading;
         }

         return first;
     }
 };

 class IPMIStatsTable
 {
   private:
     std::vector<IPMIStatsEntry> entries;

   private:
     void padEntries(size_t index)
     {
         char hexbuf[16];

         // Pad vector until entries[index] becomes a valid index
         while (entries.size() <= index)
         {
             // As name not known yet, use human-readable hex as name
             IPMIStatsEntry newEntry;
             sprintf(hexbuf, "0x%02zX", entries.size());
             newEntry.updateName(hexbuf);

             entries.push_back(std::move(newEntry));
         }
     }

   public:
     void wipeTable(void)
     {
         entries.clear();
     }

     const std::string& getName(size_t index)
     {
         padEntries(index);
         return entries[index].getName();
     }

     void updateName(size_t index, std::string_view name)
     {
         padEntries(index);
         entries[index].updateName(name);
     }

     bool updateReading(size_t index, double reading, int raw)
     {
         padEntries(index);
         return entries[index].updateReading(reading, raw);
     }
 };

 class IPMIWriteEntry
 {
   private:
     bool writePermission = false;

   public:
     bool getWritePermission(void) const
     {
         return writePermission;
     }

     void setWritePermission(bool permission)
     {
         writePermission = permission;
     }
 };

 class IPMIWriteTable
 {
   private:
     std::vector<IPMIWriteEntry> entries;

   private:
     void padEntries(size_t index)
     {
         // Pad vector until entries[index] becomes a valid index
         if (entries.size() <= index)
         {
             entries.resize(index + 1);
         }
     }

   public:
     void wipeTable(void)
     {
         entries.clear();
     }

     bool getWritePermission(size_t index)
     {
         padEntries(index);
         return entries[index].getWritePermission();
     }

     void setWritePermission(size_t index, bool permission)
     {
         padEntries(index);
         entries[index].setWritePermission(permission);
     }
 };

 // Store information for threshold sensors and they are not used by VR
 // sensors. These objects are global singletons, used from a variety of places.
 inline IPMIStatsTable sdrStatsTable;
 inline IPMIWriteTable sdrWriteTable;

 /**
  * Search ObjectMapper for sensors and update them to subtree.
  *
  * The function will search for sensors under either
  * /xyz/openbmc_project/sensors or /xyz/openbmc_project/extsensors. It will
  * optionally search VR typed sensors under /xyz/openbmc_project/vr
  *
  * @return the updated amount of times any of "sensors" or "extsensors" sensor
  * paths updated successfully, previous amount if all failed. The "vr"
  * sensor path is optional, and does not participate in the return value.
  */
 uint16_t getSensorSubtree(std::shared_ptr<SensorSubTree>& subtree);

 bool getSensorNumMap(std::shared_ptr<SensorNumMap>& sensorNumMap);
 } // namespace details

 bool getSensorSubtree(SensorSubTree& subtree);

 #ifdef FEATURE_HYBRID_SENSORS
 ipmi::sensor::IdInfoMap::const_iterator
     findStaticSensor(const std::string& path);
 #endif

 struct CmpStr
 {
     bool operator()(const char* a, const char* b) const
     {
         return std::strcmp(a, b) < 0;
     }
 };

 static constexpr size_t sensorTypeCodes = 0;
 static constexpr size_t sensorEventTypeCodes = 1;

 enum class SensorTypeCodes : uint8_t
 {
     reserved = 0x00,
     temperature = 0x01,
     voltage = 0x02,
     current = 0x03,
     fan = 0x04,
     physical_security = 0x5,
     processor = 0x07,
     power_unit = 0x09,
     other = 0x0b,
     memory = 0x0c,
     buttons = 0x14,
     watchdog2 = 0x23,
     entity = 0x25,
 };

 enum class SensorEventTypeCodes : uint8_t
 {
     unspecified = 0x00,
     threshold = 0x01,
     sensorSpecified = 0x6f
 };

 const static boost::container::flat_map<
     const char*, std::pair<SensorTypeCodes, SensorEventTypeCodes>, CmpStr>
     sensorTypes{
         {{"temperature", std::make_pair(SensorTypeCodes::temperature,
                                         SensorEventTypeCodes::threshold)},
          {"voltage", std::make_pair(SensorTypeCodes::voltage,
                                     SensorEventTypeCodes::threshold)},
          {"current", std::make_pair(SensorTypeCodes::current,
                                     SensorEventTypeCodes::threshold)},
          {"fan_tach", std::make_pair(SensorTypeCodes::fan,
                                      SensorEventTypeCodes::threshold)},
          {"fan_pwm", std::make_pair(SensorTypeCodes::fan,
                                     SensorEventTypeCodes::threshold)},
          {"intrusion", std::make_pair(SensorTypeCodes::physical_security,
                                       SensorEventTypeCodes::sensorSpecified)},
          {"processor", std::make_pair(SensorTypeCodes::processor,
                                       SensorEventTypeCodes::sensorSpecified)},
          {"power", std::make_pair(SensorTypeCodes::other,
                                   SensorEventTypeCodes::threshold)},
          {"memory", std::make_pair(SensorTypeCodes::memory,
                                    SensorEventTypeCodes::sensorSpecified)},
          {"state", std::make_pair(SensorTypeCodes::power_unit,
                                   SensorEventTypeCodes::sensorSpecified)},
          {"buttons", std::make_pair(SensorTypeCodes::buttons,
                                     SensorEventTypeCodes::sensorSpecified)},
          {"watchdog", std::make_pair(SensorTypeCodes::watchdog2,
                                      SensorEventTypeCodes::sensorSpecified)},
          {"entity", std::make_pair(SensorTypeCodes::entity,
                                    SensorEventTypeCodes::sensorSpecified)}}};
 std::string getSensorTypeStringFromPath(const std::string& path);

 uint8_t getSensorTypeFromPath(const std::string& path);

 uint16_t getSensorNumberFromPath(const std::string& path);

 uint8_t getSensorEventTypeFromPath(const std::string& path);

 std::string getPathFromSensorNumber(uint16_t sensorNum);

 namespace ipmi
 {
 std::map<std::string, std::vector<std::string>>
     getObjectInterfaces(const char* path);

 std::map<std::string, Value> getEntityManagerProperties(const char* path,
                                                         const char* interface);

 std::optional<std::unordered_set<std::string>>&
     getIpmiDecoratorPaths(const std::optional<ipmi::Context::ptr>& ctx);

 const std::string* getSensorConfigurationInterface(
     const std::map<std::string, std::vector<std::string>>&
         sensorInterfacesResponse);

 void updateIpmiFromAssociation(
     const std::string& path,
     const std::unordered_set<std::string>& ipmiDecoratorPaths,
     const DbusInterfaceMap& sensorMap, uint8_t& entityId,
     uint8_t& entityInstance);
 } // namespace ipmi
	/*
	// 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.
	*/

	#include <boost/algorithm/string.hpp>
	#include <boost/bimap.hpp>
	#include <boost/container/flat_map.hpp>
	#include <cstdio>
	#include <cstring>
	#include <exception>
	#include <filesystem>
	#include <ipmid/api.hpp>
	#include <ipmid/types.hpp>
	#include <map>
	#include <optional>
	#include <phosphor-logging/log.hpp>
	#include <sdbusplus/bus/match.hpp>
	#include <string>
	#include <unordered_set>
	#include <vector>

	#pragma once

	static constexpr bool debug = false;

	struct CmpStrVersion
	{
	bool operator()(std::string a, std::string b) const
	{
	return strverscmp(a.c_str(), b.c_str()) < 0;
	}
	};

	using SensorSubTree = boost::container::flat_map<
	std::string,
	boost::container::flat_map<std::string, std::vector<std::string>>,
	CmpStrVersion>;

	using SensorNumMap = boost::bimap<int, std::string>;

	static constexpr uint16_t maxSensorsPerLUN = 255;
	static constexpr uint16_t maxIPMISensors = (maxSensorsPerLUN * 3);
	static constexpr uint16_t lun1Sensor0 = 0x100;
	static constexpr uint16_t lun3Sensor0 = 0x300;
	static constexpr uint16_t invalidSensorNumber = 0xFFFF;
	static constexpr uint8_t reservedSensorNumber = 0xFF;

	namespace details
	{
	// Enable/disable the logging of stats instrumentation
	static constexpr bool enableInstrumentation = false;

	class IPMIStatsEntry
	{
	private:
	int numReadings = 0;
	int numMissings = 0;
	int numStreakRead = 0;
	int numStreakMiss = 0;
	double minValue = 0.0;
	double maxValue = 0.0;
	std::string sensorName;

	public:
	const std::string& getName(void) const
	{
	return sensorName;
	}

	void updateName(std::string_view name)
	{
	sensorName = name;
	}

	// Returns true if this is the first successful reading
	// This is so the caller can log the coefficients used
	bool updateReading(double reading, int raw)
	{
	if constexpr (!enableInstrumentation)
	{
	return false;
	}

	bool first = ((numReadings == 0) && (numMissings == 0));

	// Sensors can use "nan" to indicate unavailable reading
	if (!(std::isfinite(reading)))
	{
	// Only show this if beginning a new streak
	if (numStreakMiss == 0)
	{
	std::cerr << "IPMI sensor " << sensorName
	<< ": Missing reading, byte=" << raw
	<< ", Reading counts good=" << numReadings
	<< " miss=" << numMissings
	<< ", Prior good streak=" << numStreakRead << "\n";
	}

	numStreakRead = 0;
	++numMissings;
	++numStreakMiss;

	return first;
	}

	// Only show this if beginning a new streak and not the first time
	if ((numStreakRead == 0) && (numReadings != 0))
	{
	std::cerr << "IPMI sensor " << sensorName
	<< ": Recovered reading, value=" << reading
	<< " byte=" << raw
	<< ", Reading counts good=" << numReadings
	<< " miss=" << numMissings
	<< ", Prior miss streak=" << numStreakMiss << "\n";
	}

	// Initialize min/max if the first successful reading
	if (numReadings == 0)
	{
	std::cerr << "IPMI sensor " << sensorName
	<< ": First reading, value=" << reading << " byte=" << raw
	<< "\n";

	minValue = reading;
	maxValue = reading;
	}

	numStreakMiss = 0;
	++numReadings;
	++numStreakRead;

	// Only provide subsequent output if new min/max established
	if (reading < minValue)
	{
	std::cerr << "IPMI sensor " << sensorName
	<< ": Lowest reading, value=" << reading
	<< " byte=" << raw << "\n";

	minValue = reading;
	}

	if (reading > maxValue)
	{
	std::cerr << "IPMI sensor " << sensorName
	<< ": Highest reading, value=" << reading
	<< " byte=" << raw << "\n";

	maxValue = reading;
	}

	return first;
	}
	};

	class IPMIStatsTable
	{
	private:
	std::vector<IPMIStatsEntry> entries;

	private:
	void padEntries(size_t index)
	{
	char hexbuf[16];

	// Pad vector until entries[index] becomes a valid index
	while (entries.size() <= index)
	{
	// As name not known yet, use human-readable hex as name
	IPMIStatsEntry newEntry;
	sprintf(hexbuf, "0x%02zX", entries.size());
	newEntry.updateName(hexbuf);

	entries.push_back(std::move(newEntry));
	}
	}

	public:
	void wipeTable(void)
	{
	entries.clear();
	}

	const std::string& getName(size_t index)
	{
	padEntries(index);
	return entries[index].getName();
	}

	void updateName(size_t index, std::string_view name)
	{
	padEntries(index);
	entries[index].updateName(name);
	}

	bool updateReading(size_t index, double reading, int raw)
	{
	padEntries(index);
	return entries[index].updateReading(reading, raw);
	}
	};

	class IPMIWriteEntry
	{
	private:
	bool writePermission = false;

	public:
	bool getWritePermission(void) const
	{
	return writePermission;
	}

	void setWritePermission(bool permission)
	{
	writePermission = permission;
	}
	};

	class IPMIWriteTable
	{
	private:
	std::vector<IPMIWriteEntry> entries;

	private:
	void padEntries(size_t index)
	{
	// Pad vector until entries[index] becomes a valid index
	if (entries.size() <= index)
	{
	entries.resize(index + 1);
	}
	}

	public:
	void wipeTable(void)
	{
	entries.clear();
	}

	bool getWritePermission(size_t index)
	{
	padEntries(index);
	return entries[index].getWritePermission();
	}

	void setWritePermission(size_t index, bool permission)
	{
	padEntries(index);
	entries[index].setWritePermission(permission);
	}
	};

	// Store information for threshold sensors and they are not used by VR
	// sensors. These objects are global singletons, used from a variety of places.
	inline IPMIStatsTable sdrStatsTable;
	inline IPMIWriteTable sdrWriteTable;

	/**
	* Search ObjectMapper for sensors and update them to subtree.
	*
	* The function will search for sensors under either
	* /xyz/openbmc_project/sensors or /xyz/openbmc_project/extsensors. It will
	* optionally search VR typed sensors under /xyz/openbmc_project/vr
	*
	* @return the updated amount of times any of "sensors" or "extsensors" sensor
	* paths updated successfully, previous amount if all failed. The "vr"
	* sensor path is optional, and does not participate in the return value.
	*/
	uint16_t getSensorSubtree(std::shared_ptr<SensorSubTree>& subtree);

	bool getSensorNumMap(std::shared_ptr<SensorNumMap>& sensorNumMap);
	} // namespace details

	bool getSensorSubtree(SensorSubTree& subtree);

	#ifdef FEATURE_HYBRID_SENSORS
	ipmi::sensor::IdInfoMap::const_iterator
	findStaticSensor(const std::string& path);
	#endif

	struct CmpStr
	{
	bool operator()(const char* a, const char* b) const
	{
	return std::strcmp(a, b) < 0;
	}
	};

	static constexpr size_t sensorTypeCodes = 0;
	static constexpr size_t sensorEventTypeCodes = 1;

	enum class SensorTypeCodes : uint8_t
	{
	reserved = 0x00,
	temperature = 0x01,
	voltage = 0x02,
	current = 0x03,
	fan = 0x04,
	physical_security = 0x5,
	processor = 0x07,
	power_unit = 0x09,
	other = 0x0b,
	memory = 0x0c,
	buttons = 0x14,
	watchdog2 = 0x23,
	entity = 0x25,
	};

	enum class SensorEventTypeCodes : uint8_t
	{
	unspecified = 0x00,
	threshold = 0x01,
	sensorSpecified = 0x6f
	};

	const static boost::container::flat_map<
	const char*, std::pair<SensorTypeCodes, SensorEventTypeCodes>, CmpStr>
	sensorTypes{
	{{"temperature", std::make_pair(SensorTypeCodes::temperature,
	SensorEventTypeCodes::threshold)},
	{"voltage", std::make_pair(SensorTypeCodes::voltage,
	SensorEventTypeCodes::threshold)},
	{"current", std::make_pair(SensorTypeCodes::current,
	SensorEventTypeCodes::threshold)},
	{"fan_tach", std::make_pair(SensorTypeCodes::fan,
	SensorEventTypeCodes::threshold)},
	{"fan_pwm", std::make_pair(SensorTypeCodes::fan,
	SensorEventTypeCodes::threshold)},
	{"intrusion", std::make_pair(SensorTypeCodes::physical_security,
	SensorEventTypeCodes::sensorSpecified)},
	{"processor", std::make_pair(SensorTypeCodes::processor,
	SensorEventTypeCodes::sensorSpecified)},
	{"power", std::make_pair(SensorTypeCodes::other,
	SensorEventTypeCodes::threshold)},
	{"memory", std::make_pair(SensorTypeCodes::memory,
	SensorEventTypeCodes::sensorSpecified)},
	{"state", std::make_pair(SensorTypeCodes::power_unit,
	SensorEventTypeCodes::sensorSpecified)},
	{"buttons", std::make_pair(SensorTypeCodes::buttons,
	SensorEventTypeCodes::sensorSpecified)},
	{"watchdog", std::make_pair(SensorTypeCodes::watchdog2,
	SensorEventTypeCodes::sensorSpecified)},
	{"entity", std::make_pair(SensorTypeCodes::entity,
	SensorEventTypeCodes::sensorSpecified)}}};
	std::string getSensorTypeStringFromPath(const std::string& path);

	uint8_t getSensorTypeFromPath(const std::string& path);

	uint16_t getSensorNumberFromPath(const std::string& path);

	uint8_t getSensorEventTypeFromPath(const std::string& path);

	std::string getPathFromSensorNumber(uint16_t sensorNum);

	namespace ipmi
	{
	std::map<std::string, std::vector<std::string>>
	getObjectInterfaces(const char* path);

	std::map<std::string, Value> getEntityManagerProperties(const char* path,
	const char* interface);

	std::optional<std::unordered_set<std::string>>&
	getIpmiDecoratorPaths(const std::optional<ipmi::Context::ptr>& ctx);

	const std::string* getSensorConfigurationInterface(
	const std::map<std::string, std::vector<std::string>>&
	sensorInterfacesResponse);

	void updateIpmiFromAssociation(
	const std::string& path,
	const std::unordered_set<std::string>& ipmiDecoratorPaths,
	const DbusInterfaceMap& sensorMap, uint8_t& entityId,
	uint8_t& entityInstance);
	} // namespace ipmi