occ_manager.hpp - openbmc/openpower-occ-control - Gitiles

 #pragma once

 #include "occ_pass_through.hpp"
 #include "occ_status.hpp"
 #ifdef PLDM
 #include "pldm.hpp"
 #endif
 #include "powercap.hpp"
 #include "utils.hpp"
 #ifdef POWER10
 #include "powermode.hpp"
 #endif

 #include <cstring>
 #include <functional>
 #include <sdbusplus/bus.hpp>
 #include <sdeventplus/event.hpp>
 #include <sdeventplus/utility/timer.hpp>
 #include <vector>

 namespace sdbusRule = sdbusplus::bus::match::rules;
 namespace open_power
 {
 namespace occ
 {

 #ifdef READ_OCC_SENSORS
 enum occFruType
 {
     processorCore = 0,
     internalMemCtlr = 1,
     dimm = 2,
     memCtrlAndDimm = 3,
     VRMVdd = 6,
     PMIC = 7,
     memCtlrExSensor = 8
 };
 #endif

 /** @brief Default time, in seconds, between OCC poll commands */
 constexpr unsigned int defaultPollingInterval = 1;

 /** @class Manager
  *  @brief Builds and manages OCC objects
  */
 struct Manager
 {
   public:
     Manager() = delete;
     Manager(const Manager&) = delete;
     Manager& operator=(const Manager&) = delete;
     Manager(Manager&&) = delete;
     Manager& operator=(Manager&&) = delete;
     ~Manager() = default;

     /** @brief Adds OCC pass-through and status objects on the bus
      *         when corresponding CPU inventory is created.
      *
      *  @param[in] event - Unique ptr reference to sd_event
      */
     Manager(EventPtr& event) :
         event(event), pollInterval(defaultPollingInterval),
         sdpEvent(sdeventplus::Event::get_default()),
         _pollTimer(
             std::make_unique<
                 sdeventplus::utility::Timer<sdeventplus::ClockId::Monotonic>>(
                 sdpEvent, std::bind(&Manager::pollerTimerExpired, this)))
 #ifdef PLDM
         ,
         pldmHandle(std::make_unique<pldm::Interface>(
             std::bind(std::mem_fn(&Manager::updateOCCActive), this,
                       std::placeholders::_1, std::placeholders::_2)))
 #endif

     {
 #ifdef I2C_OCC
         // I2C OCC status objects are initialized directly
         initStatusObjects();
 #else
         findAndCreateObjects();
 #endif
     }

     /** @brief Return the number of bound OCCs */
     inline auto getNumOCCs() const
     {
         return activeCount;
     }

   private:
     /** @brief Checks if the CPU inventory is present and if so, creates
      *         the occ D-Bus objects. Else, registers a handler to be
      *         called when inventory is created.
      */
     void findAndCreateObjects();

     /** @brief Callback that responds to cpu creation in the inventory -
      *         by creating the needed objects.
      *
      *  @param[in] msg - bus message
      *
      *  @returns 0 to indicate success
      */
     int cpuCreated(sdbusplus::message::message& msg);

     /** @brief Create child OCC objects.
      *
      *  @param[in] occ - the occ name, such as occ0.
      */
     void createObjects(const std::string& occ);

     /** @brief Callback handler invoked by Status object when the OccActive
      *         property is changed. This is needed to make sure that the
      *         error detection is started only after all the OCCs are bound.
      *         Similarly, when one of the OCC gets its OccActive property
      *         un-set, then the OCC error detection needs to be stopped on
      *         all the OCCs
      *
      *  @param[in] status - OccActive status
      */
     void statusCallBack(bool status);

     /** @brief Sends a Heartbeat command to host control command handler */
     void sendHeartBeat();

     /** @brief reference to sd_event wrapped in unique_ptr */
     EventPtr& event;

     /** @brief OCC pass-through objects */
     std::vector<std::unique_ptr<PassThrough>> passThroughObjects;

     /** @brief OCC Status objects */
     std::vector<std::unique_ptr<Status>> statusObjects;

     /** @brief Power cap monitor and occ notification object */
     std::unique_ptr<open_power::occ::powercap::PowerCap> pcap;

 #ifdef POWER10
     /** @brief Power mode monitor and notification object */
     std::unique_ptr<open_power::occ::powermode::PowerMode> pmode;
 #endif

     /** @brief sbdbusplus match objects */
     std::vector<sdbusplus::bus::match_t> cpuMatches;

     /** @brief Number of OCCs that are bound */
     uint8_t activeCount = 0;

     /** @brief Number of seconds between poll commands */
     uint8_t pollInterval;

     /** @brief Poll timer event */
     sdeventplus::Event sdpEvent;

     /**
      * @brief The timer to be used once the OCC goes active.  When it expires,
      *        a POLL command will be sent to the OCC and then timer restarted.
      */
     std::unique_ptr<
         sdeventplus::utility::Timer<sdeventplus::ClockId::Monotonic>>
         _pollTimer;

 #ifdef I2C_OCC
     /** @brief Init Status objects for I2C OCC devices
      *
      * It iterates in /sys/bus/i2c/devices, finds all occ hwmon devices
      * and creates status objects.
      */
     void initStatusObjects();
 #endif

 #ifdef PLDM
     /** @brief Callback handler invoked by the PLDM event handler when state of
      *         the OCC is toggled by the host. The caller passes the instance
      *         of the OCC and state of the OCC.
      *
      *  @param[in] instance - instance of the OCC
      *  @param[in] status - true when the OCC goes active and false when the OCC
      *                      goes inactive
      *
      *  @return true if setting the state of OCC is successful and false if it
      *          fails.
      */
     bool updateOCCActive(instanceID instance, bool status);

     std::unique_ptr<pldm::Interface> pldmHandle = nullptr;
 #endif

     /**
      * @brief Called when poll timer expires and forces a POLL command to the
      * OCC. The poll timer will then be restarted.
      * */
     void pollerTimerExpired();

 #ifdef READ_OCC_SENSORS
     /**
      * @brief Gets the occ sensor values.
      * @param[in] id - Id of the OCC.
      * @param[in] masterOcc - Is this OCC the master OCC.
      * */
     void getSensorValues(uint32_t id, bool masterOcc);

     /**
      * @brief Trigger OCC driver to read the temperature sensors.
      * @param[in] path - path of the OCC sensors.
      * @param[in] id - Id of the OCC.
      * */
     void readTempSensors(const fs::path& path, uint32_t id);

     /**
      * @brief Trigger OCC driver to read the power sensors.
      * @param[in] path - path of the OCC sensors.
      * @param[in] id - Id of the OCC.
      * */
     void readPowerSensors(const fs::path& path, uint32_t id);

     /**
      * @brief Set all sensor values of this OCC to NaN.
      * @param[in] id - Id of the OCC.
      * */
     void setSensorValueToNaN(uint32_t id);

     /** @brief Store the existing OCC sensors on D-BUS */
     std::map<std::string, uint32_t> existingSensors;

     /** @brief Get FunctionID from the `powerX_label` file.
      *  @param[in] value - the value of the `powerX_label` file.
      *  @returns FunctionID of the power sensors.
      */
     std::optional<std::string>
         getPowerLabelFunctionID(const std::string& value);

     /** @brief The power sensor names map */
     const std::map<std::string, std::string> powerSensorName = {
         {"system", "total_power"}, {"1", "p0_mem_power"},
         {"2", "p1_mem_power"},     {"3", "p2_mem_power"},
         {"4", "p3_mem_power"},     {"5", "p0_power"},
         {"6", "p1_power"},         {"7", "p2_power"},
         {"8", "p3_power"},         {"9", "p0_cache_power"},
         {"10", "p1_cache_power"},  {"11", "p2_cache_power"},
         {"12", "p3_cache_power"},  {"13", "io_a_power"},
         {"14", "io_b_power"},      {"15", "io_c_power"},
         {"16", "fans_a_power"},    {"17", "fans_b_power"},
         {"18", "storage_a_power"}, {"19", "storage_b_power"},
         {"23", "mem_cache_power"}, {"25", "p0_mem_0_power"},
         {"26", "p0_mem_1_power"},  {"27", "p0_mem_2_power"}};

     /** @brief The dimm temperature sensor names map */
     const std::map<uint32_t, std::string> dimmTempSensorName = {
         {internalMemCtlr, "_intmb_temp"},
         {dimm, "_dram_temp"},
         {memCtrlAndDimm, "_dram_extmb_temp"},
         {PMIC, "_pmic_temp"},
         {memCtlrExSensor, "_extmb_temp"}};
 #endif
 };

 } // namespace occ
 } // namespace open_power
	#pragma once

	#include "occ_pass_through.hpp"
	#include "occ_status.hpp"
	#ifdef PLDM
	#include "pldm.hpp"
	#endif
	#include "powercap.hpp"
	#include "utils.hpp"
	#ifdef POWER10
	#include "powermode.hpp"
	#endif

	#include <cstring>
	#include <functional>
	#include <sdbusplus/bus.hpp>
	#include <sdeventplus/event.hpp>
	#include <sdeventplus/utility/timer.hpp>
	#include <vector>

	namespace sdbusRule = sdbusplus::bus::match::rules;
	namespace open_power
	{
	namespace occ
	{

	#ifdef READ_OCC_SENSORS
	enum occFruType
	{
	processorCore = 0,
	internalMemCtlr = 1,
	dimm = 2,
	memCtrlAndDimm = 3,
	VRMVdd = 6,
	PMIC = 7,
	memCtlrExSensor = 8
	};
	#endif

	/** @brief Default time, in seconds, between OCC poll commands */
	constexpr unsigned int defaultPollingInterval = 1;

	/** @class Manager
	* @brief Builds and manages OCC objects
	*/
	struct Manager
	{
	public:
	Manager() = delete;
	Manager(const Manager&) = delete;
	Manager& operator=(const Manager&) = delete;
	Manager(Manager&&) = delete;
	Manager& operator=(Manager&&) = delete;
	~Manager() = default;

	/** @brief Adds OCC pass-through and status objects on the bus
	* when corresponding CPU inventory is created.
	*
	* @param[in] event - Unique ptr reference to sd_event
	*/
	Manager(EventPtr& event) :
	event(event), pollInterval(defaultPollingInterval),
	sdpEvent(sdeventplus::Event::get_default()),
	_pollTimer(
	std::make_unique<
	sdeventplus::utility::Timer<sdeventplus::ClockId::Monotonic>>(
	sdpEvent, std::bind(&Manager::pollerTimerExpired, this)))
	#ifdef PLDM
	,
	pldmHandle(std::make_unique<pldm::Interface>(
	std::bind(std::mem_fn(&Manager::updateOCCActive), this,
	std::placeholders::_1, std::placeholders::_2)))
	#endif

	{
	#ifdef I2C_OCC
	// I2C OCC status objects are initialized directly
	initStatusObjects();
	#else
	findAndCreateObjects();
	#endif
	}

	/** @brief Return the number of bound OCCs */
	inline auto getNumOCCs() const
	{
	return activeCount;
	}

	private:
	/** @brief Checks if the CPU inventory is present and if so, creates
	* the occ D-Bus objects. Else, registers a handler to be
	* called when inventory is created.
	*/
	void findAndCreateObjects();

	/** @brief Callback that responds to cpu creation in the inventory -
	* by creating the needed objects.
	*
	* @param[in] msg - bus message
	*
	* @returns 0 to indicate success
	*/
	int cpuCreated(sdbusplus::message::message& msg);

	/** @brief Create child OCC objects.
	*
	* @param[in] occ - the occ name, such as occ0.
	*/
	void createObjects(const std::string& occ);

	/** @brief Callback handler invoked by Status object when the OccActive
	* property is changed. This is needed to make sure that the
	* error detection is started only after all the OCCs are bound.
	* Similarly, when one of the OCC gets its OccActive property
	* un-set, then the OCC error detection needs to be stopped on
	* all the OCCs
	*
	* @param[in] status - OccActive status
	*/
	void statusCallBack(bool status);

	/** @brief Sends a Heartbeat command to host control command handler */
	void sendHeartBeat();

	/** @brief reference to sd_event wrapped in unique_ptr */
	EventPtr& event;

	/** @brief OCC pass-through objects */
	std::vector<std::unique_ptr<PassThrough>> passThroughObjects;

	/** @brief OCC Status objects */
	std::vector<std::unique_ptr<Status>> statusObjects;

	/** @brief Power cap monitor and occ notification object */
	std::unique_ptr<open_power::occ::powercap::PowerCap> pcap;

	#ifdef POWER10
	/** @brief Power mode monitor and notification object */
	std::unique_ptr<open_power::occ::powermode::PowerMode> pmode;
	#endif

	/** @brief sbdbusplus match objects */
	std::vector<sdbusplus::bus::match_t> cpuMatches;

	/** @brief Number of OCCs that are bound */
	uint8_t activeCount = 0;

	/** @brief Number of seconds between poll commands */
	uint8_t pollInterval;

	/** @brief Poll timer event */
	sdeventplus::Event sdpEvent;

	/**
	* @brief The timer to be used once the OCC goes active. When it expires,
	* a POLL command will be sent to the OCC and then timer restarted.
	*/
	std::unique_ptr<
	sdeventplus::utility::Timer<sdeventplus::ClockId::Monotonic>>
	_pollTimer;

	#ifdef I2C_OCC
	/** @brief Init Status objects for I2C OCC devices
	*
	* It iterates in /sys/bus/i2c/devices, finds all occ hwmon devices
	* and creates status objects.
	*/
	void initStatusObjects();
	#endif

	#ifdef PLDM
	/** @brief Callback handler invoked by the PLDM event handler when state of
	* the OCC is toggled by the host. The caller passes the instance
	* of the OCC and state of the OCC.
	*
	* @param[in] instance - instance of the OCC
	* @param[in] status - true when the OCC goes active and false when the OCC
	* goes inactive
	*
	* @return true if setting the state of OCC is successful and false if it
	* fails.
	*/
	bool updateOCCActive(instanceID instance, bool status);

	std::unique_ptr<pldm::Interface> pldmHandle = nullptr;
	#endif

	/**
	* @brief Called when poll timer expires and forces a POLL command to the
	* OCC. The poll timer will then be restarted.
	* */
	void pollerTimerExpired();

	#ifdef READ_OCC_SENSORS
	/**
	* @brief Gets the occ sensor values.
	* @param[in] id - Id of the OCC.
	* @param[in] masterOcc - Is this OCC the master OCC.
	* */
	void getSensorValues(uint32_t id, bool masterOcc);

	/**
	* @brief Trigger OCC driver to read the temperature sensors.
	* @param[in] path - path of the OCC sensors.
	* @param[in] id - Id of the OCC.
	* */
	void readTempSensors(const fs::path& path, uint32_t id);

	/**
	* @brief Trigger OCC driver to read the power sensors.
	* @param[in] path - path of the OCC sensors.
	* @param[in] id - Id of the OCC.
	* */
	void readPowerSensors(const fs::path& path, uint32_t id);

	/**
	* @brief Set all sensor values of this OCC to NaN.
	* @param[in] id - Id of the OCC.
	* */
	void setSensorValueToNaN(uint32_t id);

	/** @brief Store the existing OCC sensors on D-BUS */
	std::map<std::string, uint32_t> existingSensors;

	/** @brief Get FunctionID from the `powerX_label` file.
	* @param[in] value - the value of the `powerX_label` file.
	* @returns FunctionID of the power sensors.
	*/
	std::optional<std::string>
	getPowerLabelFunctionID(const std::string& value);

	/** @brief The power sensor names map */
	const std::map<std::string, std::string> powerSensorName = {
	{"system", "total_power"}, {"1", "p0_mem_power"},
	{"2", "p1_mem_power"}, {"3", "p2_mem_power"},
	{"4", "p3_mem_power"}, {"5", "p0_power"},
	{"6", "p1_power"}, {"7", "p2_power"},
	{"8", "p3_power"}, {"9", "p0_cache_power"},
	{"10", "p1_cache_power"}, {"11", "p2_cache_power"},
	{"12", "p3_cache_power"}, {"13", "io_a_power"},
	{"14", "io_b_power"}, {"15", "io_c_power"},
	{"16", "fans_a_power"}, {"17", "fans_b_power"},
	{"18", "storage_a_power"}, {"19", "storage_b_power"},
	{"23", "mem_cache_power"}, {"25", "p0_mem_0_power"},
	{"26", "p0_mem_1_power"}, {"27", "p0_mem_2_power"}};

	/** @brief The dimm temperature sensor names map */
	const std::map<uint32_t, std::string> dimmTempSensorName = {
	{internalMemCtlr, "_intmb_temp"},
	{dimm, "_dram_temp"},
	{memCtrlAndDimm, "_dram_extmb_temp"},
	{PMIC, "_pmic_temp"},
	{memCtlrExSensor, "_extmb_temp"}};
	#endif
	};

	} // namespace occ
	} // namespace open_power